Academic year 2020 - 2021

•   3D plant engineering EN00BH68-3003 31.08.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  You are able to use plant design software to model plants, piping and equipment and are able to generate manufacturing drawings from them.
  You know the basics of plant engineering
  You know the basics of piping desing
  You know how to read PI-Diagrams

  Prerequisites and co-requisites

  Statiikka ja lujuuslaskenta
  Materiaali- ja valmistustekniikka
  Tekninen visualisointi ja CAD (not translated)

  Course contents

  How to use 3D plant design software?
  How to do plant engineering?
  How to do piping design?
  How to read PI-diagrams?
  What do piping classes mean?

  ---

  Name of lecturer(s)

  Lassi Salminen

  Teacher(s)

  Lassi Salminen

  Kalle Tarhonen

  Mode of delivery

  Face-to-face

  Recommended or required reading

  SmartPlant-ohjelman opiskelumateriaali (englanninkielinen, jaetaan oppitunneilla).
  PSK-käsikirjat, mm. putkiluokat. (not translated)

  Planned learning activities and teaching methods

  Työviikkopohjainen oppimisväylä:
  Kuinka käytän 3D-tehdasmallinnusohjelmaa? Minkälainen on tehtaan tietokonemallin rakenne? Mikä on siihen integroidun tietokantainformaation merkitys ja miten sitä hyödynnetään? Mitä tehdään ohjelman osissa yleinen, laitteet, putkitus sekä rakenteet ja piirustukset?
  Minkälaisia laitteita (mm. pumput, säiliöt, venttiilit) suunnitteluohjelman laitekirjastoissa on, miten niitä sijoitellaan ja minkälaista tietokantainformaatiota niihin voidaan liittää (esim. käyttölämpötila ja -paine)?
  Minkälainen on tehdasrakennuksen teräsrakennemalli ja millaisista osista se koostuu? Miten luon tehdasrakennuksen tietokonemallin (mm. koordinaatisto kerrostasoineen, runkopilarit ja palkit liitoksineen, lattiatasot ja niiden materiaalit, kulkuaukot, portaat ja kaiteet)?
  Kuinka teen putkistosuunnittelua? Mitä tarkoittavat putkiluokat? Miten mallinnan geometrisesti vaativan putkiston?
  Kuinka tulkitsen PI-kaavioita ja miten ne voidaan integroida 3D-malliin?
  Kuinka teen layout-suunnittelua? Miten generoin layout-kuvat 3D-mallista?
  Miten luon tietokantaraportin tehdasmallin osista ja niiden ominaisuuksista?
  
  Opintoja nopeuttava oppimisväylä:
  Kuinka käytän 3D-tehdasmallinnusohjelmaa? Minkälainen on tehtaan tietokonemallin rakenne? Mikä on siihen integroidun tietokantainformaation merkitys ja miten sitä hyödynnetään? Mitä tehdään ohjelman osissa yleinen, laitteet, putkitus sekä rakenteet ja piirustukset?
  Minkälaisia laitteita (mm. pumput, säiliöt, venttiilit) suunnitteluohjelman laitekirjastoissa on, miten niitä sijoitellaan ja minkälaista tietokantainformaatiota niihin voidaan liittää (esim. käyttölämpötila ja -paine)?
  Minkälainen on tehdasrakennuksen teräsrakennemalli ja millaisista osista se koostuu? Miten luon tehdasrakennuksen tietokonemallin (mm. koordinaatisto kerrostasoineen, runkopilarit ja palkit liitoksineen, lattiatasot ja niiden materiaalit, kulkuaukot, portaat ja kaiteet)?
  Kuinka teen putkistosuunnittelua? Mitä tarkoittavat putkiluokat? Miten mallinnan geometrisesti vaativan putkiston?
  Kuinka tulkitsen PI-kaavioita ja miten ne voidaan integroida 3D-malliin?
  Kuinka teen layout-suunnittelua? Miten generoin layout-kuvat 3D-mallista?
  Miten luon tietokantaraportin tehdasmallin osista ja niiden ominaisuuksista?
  
  Työhön integroitu oppimisväylä:
  Kuinka käytän 3D-tehdasmallinnusohjelmaa? Minkälainen on tehtaan tietokonemallin rakenne? Mikä on siihen integroidun tietokantainformaation merkitys ja miten sitä hyödynnetään? Mitä tehdään ohjelman osissa yleinen, laitteet, putkitus sekä rakenteet ja piirustukset?
  Minkälaisia laitteita (mm. pumput, säiliöt, venttiilit) suunnitteluohjelman laitekirjastoissa on, miten niitä sijoitellaan ja minkälaista tietokantainformaatiota niihin voidaan liittää (esim. käyttölämpötila ja -paine)?
  Minkälainen on tehdasrakennuksen teräsrakennemalli ja millaisista osista se koostuu? Miten luon tehdasrakennuksen tietokonemallin (mm. koordinaatisto kerrostasoineen, runkopilarit ja palkit liitoksineen, lattiatasot ja niiden materiaalit, kulkuaukot, portaat ja kaiteet)?
  Kuinka teen putkistosuunnittelua? Mitä tarkoittavat putkiluokat? Miten mallinnan geometrisesti vaativan putkiston?
  Kuinka tulkitsen PI-kaavioita ja miten ne voidaan integroida 3D-malliin?
  Kuinka teen layout-suunnittelua? Miten generoin layout-kuvat 3D-mallista?
  Miten luon tietokantaraportin tehdasmallin osista ja niiden ominaisuuksista? (not translated)

  Assessment methods and criteria

  Opintojakson suorittaminen vaatii tietokoneella tehtävien mallinnusharjoitusten suorittamisen. Arvosanan 1 saa näiden harjoitusten perusteella.
  Oppitunneilla järjestettävällä loppukokeella tai korotustentillä arvosanaa voi korottaa tasolle 2-5. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Tentillä voi korottaa kurssin arvosanaa tasolle 2-5. Pelkkä tentti ei riitä kurssin suorittamiseen.
  Uusinta- eli korotustentin voi suorittaa yleisenä uusintatenttipäivänä. (not translated)

  Students use of time and load

  Oppitunnit 60 h (pääosin tietokonemallinnusta).
  Mallinnusharjoitukset, täydennys 15 h.
  Tehdassuunnitteluun perehtyminen 20 h.
  Tenttiin valmistautuminen ja tentti 15 h. (not translated)
•   Automaatiotekniikka (not translated) AV00DN74-3001 04.01.2021-30.04.2021  3 credits  (AVKTDAKKDI20K) +-
  Course contents

  • Automaatioväylät (not translated)

  ---

  Name of lecturer(s)

  Vesa Kankkunen

  Teacher(s)

  Vesa Kankkunen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  04.01.2021 - 30.04.2021

  Enrollment date

  05.12.2020 - 03.01.2021

  • 3 credits

  Group(s)

  • AVKTDAKKDI20K

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Automation engineering EN00BH62-3003 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  - explain the main phases and outputs of an automation project
  - specify automation loop by loop
  - analyze and design field instrumentation
  - program, test and commission measurement and control applications and control room graphics of power plants
  - use CAD programs and shared database and documentation programs for automation engineering
  - work out a budget for an automation project.

  Prerequisites and co-requisites

  Prerequisite courses are
  Measurement and control technology
  Process control systems and communication networks.

  Course contents

  What should you do in the specification, design, implementation, installation, functional testing, validation, production and removal phases of an automation project?
  How do you work out an instrumentation or motor loop description, and how is it utilized by an operator or maintenance engineer?
  How do you present cabling and connections in instrumentation and electrical loop diagrams?
  In which way is the design of automation applications supported by block programming?
  How do you manage the engineering and maintenance of instrumentation and motor control?
  Which elements make the price of an automation project?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  1. Learn-materiaali.
  2. Automaatiosuunnittelun prosessimalli. Yhteiset käsitteet verkottuneen suunnittelun perustana. Suomen Automaatioseura ry., Helsinki, 2007. 43 s.
  3. Tommila, T., toim. Laatu automaatiossa. Suomen Automaatioseura ry. , Helsinki, 2001. 245 s.
  4. Automaatiosovellusten ohjelmistokehitys. Suunnittelun työtavat, välineet ja sovellusarkkitehtuurit. Suomen Automaatioseura ry. 2005. 152 s.
  5. Harju, T., Marttinen, A. Säätötekniikan koulutusmateriaali (verkkojulkaisu), Säätöpiirin virityksen perusteet (kirja). Suomen Automaatioseura ry. , Helsinki, 2000. 166 s.
  6. Automaatio liiketoimintaprosessien tukena (verkkojulkaisu Suomen automaatioseura ry.), Tekesin katsaus 271, 2010.
  7. SFS-ISO 14617-6 Kaavioissa käytettävät piirrosmerkit. Osa 6: Mittaus- ja ohjaustoiminnot. SFS, Helsinki, 2004.
  8. SFS-EN ISO 10628 Prosessikaaviot. Yleiset ohjeet. SFS, Helsinki, 2001.
  9. PSK 3601 Prosessiteollisuuden virtauskaavioiden piirrosmerkit. PSK Standardisointi, Helsinki, 2005. 38 s.
  10. PSK 5201 - PSK 5210 Instrumenttiasennusten tyyppipiirustukset. PSK Standardisointi, Helsinki, 2003.
  11. PSK 4601 Automaation hankinta. Yleiset periaatteet. käsitteet ja määritelmät. PSK Standardisointi, Helsinki, 1996. 24 s.
  12. PSK 4602 Automaation hankinta. Prosessinohjausjärjestelmä. PSK Standardisointi, Helsinki, 1996. 11 s.
  13. PSK 4603 Automaation hankinta. Instrumentointi. PSK Standardisointi, Helsinki, 1996. 10 s.
  14. PSK 7902 Teollisuuden suunnittelu. Sopimusmalli. PSK Standardisointi, Helsinki, 2005. 2 + 29 s.
  15. SFS-IEC 61506 Teollisuusprosessien mittaus ja ohjaus. Sovellusohjelmiston dokumentaatio. Suomen Standar-disoimisliitto SFS, Helsinki, 1998. 121 s.
  16. SFS-IEC 848 Ohjausjärjestelmien toimintodiagrammien laatiminen.
  17. SFS 5098 Prosessi-instrumentoinnin piirustukset ja muut asiakirjat.
  18. SFS 2972 Sähkölaitteiden kotelointiluokat.
  19. Heimbürger et. al., Valvomo – Suunnittelu periaatteet ja käytännöt, Suomen automaatioseura ry., 2010, 268 s.
  PSK-standardeihin on pääsy XAMK:n kirjaston verkkotietokannoista.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  • explain the main phases and outputs of an automation project
  • specify automation loop by loop, or tag by tag
  • analyze and design field instrumentation
  • program, test and commission measurement and control applications and control room graphics of power plants
  • use CAD programs and shared database and documentation programs for automation engineering
  • work out a budget of an automation project.
  What should you do in a specification, design, implementation, installation, functional testing, validation, production and removal phases of an automation project?
  How do you work out an instrumentation or motor loop description, and how is it utilized by an operator or a maintenance engineer?
  How do you present cabling and connections in instrumentation and electrical loop diagrams?
  In which way is the design of automation applications supported by block programming?
  How do you manage the engineering and maintenance of instrumentation and motor control?
  Which elements make the price of an automation project?
  
  Independent track:
  Exam and work-related projec
  
  Blended track:
  Exam and project

  Assessment methods and criteria

  Exam (50 %) and project (50 %), with grades 0-5.

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Seats

  0 - 30

  Further information for students

  Prerequisite courses are:
  Measurement and Control Technology
  Process Control Systems and Communication Networks,
  or related qualifications are required.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam.

  Students use of time and load

  - 24 h online lectures
  - 36 h supervised project working
  - 75 h self-study

•   Basics of electrical engineering and electronics EN00BH41-3004 31.08.2020-18.12.2020  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  After the course you can:
  take electrical safety into consideration in designing and operating with electrical circuits
  analyse the electrical and electronic equipment
  analyse DC and AC circuits
  analyse and develop electrical circuits.

  Course contents

  How to consider electrical safety in circuits?
  What are the most common operating principles of electrical and electronic equipment?
  How to analyze and synthesize DC and AC circuits?
  How to make electronic circuit connections?

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Kurssin varsinainen tentti:
  Ke 09.12.20 klo 11:30 - 13.30
  
  Uusintatenttikerrat:
  Ti 12.1.2021
  Ti 9.3.2021
  Ti 11.5.2021
  
  Tenttitilaisuuksien järjestelyt tarkentuvat myöhemmin, kun tiedetään lähi-/etäopetusohjeista (not translated)

•   Basics of electrical engineering and electronics EN00BH41-3006 11.01.2021-30.04.2021  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  After the course you can:
  take electrical safety into consideration in designing and operating with electrical circuits
  analyse the electrical and electronic equipment
  analyse DC and AC circuits
  analyse and develop electrical circuits.

  Course contents

  How to consider electrical safety in circuits?
  What are the most common operating principles of electrical and electronic equipment?
  How to analyze and synthesize DC and AC circuits?
  How to make electronic circuit connections?

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Basics of energy production and power stations EN00BH36-3007 31.08.2020-27.11.2020  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  After the course you:
  - can describe energy as a quantity as well as its forms and units
  - understand the basics of both heat and electricity production and consumption
  - are familiar with electrical power network structure
  - understand the importance of the transfer voltages in power lines
  - can describe the main electric power plant equipment.

  Course contents

  In what units is energy indicated?
  What is energy and who are its users?
  How is electrical energy transferred to the consumer?
  Why are different voltages used in electric power transmission?
  How are different electrical components related to the operation of the electrical power plants?

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Jyri Mulari

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 27.11.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Basics of energy production and power stations EN00BH36-3010 11.01.2021-30.04.2021  5 credits  (ENKT21KM) +-
  Learning outcomes of the course

  After the course you:
  - can describe energy as a quantity as well as its forms and units
  - understand the basics of both heat and electricity production and consumption
  - are familiar with electrical power network structure
  - understand the importance of the transfer voltages in power lines
  - can describe the main electric power plant equipment.

  Course contents

  In what units is energy indicated?
  What is energy and who are its users?
  How is electrical energy transferred to the consumer?
  Why are different voltages used in electric power transmission?
  How are different electrical components related to the operation of the electrical power plants?

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Jyri Mulari

  Marko Saxell

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Osoitetaan tai jaetaan Learnissa (not translated)

  Planned learning activities and teaching methods

  Harjoitustehtävät ja tentit (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT21KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Ilmoitetaan Learnissa (not translated)

  Students use of time and load

  5 op = 135 työtuntia (not translated)

•   Basics of maintenance activities EN00DW25-3003 31.08.2020-18.12.2020  5 credits  (ENKT20SM) +-
  Learning outcomes of the course

  After completing the course, students will be aware of
  the impact of maintenance activities on production
  the importance of different systems for operational activities.

  Course contents

  What are the goals and content of maintenance, the functions and concepts of maintenance?
  Why use information systems?
  How do standards relate to maintenance?
  What does project management mean?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT20SM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  eCampus

  Evaluation scale

  1-5

•   Bioeconomy in support of business AV00EG98-3001 14.09.2020-30.11.2020  2 credits +-
  Learning outcomes of the course

  Opit tuntemaan käsitteet bio- ja kiertotalous, jonka jälkeen osaat löytää ja arvioida niiden tuomia mahdollisuuksia liiketoiminnassa. (not translated)

  Course contents

  Mitä on yhteistä ja eroa on bio- ja kiertotaloudella?
  Miten resurssitehokkuus liittyy biotalouteen?
  Mikä on biotalouden rooli liiketoiminnassa ja toisaalta mikä on liiketoiminnan rooli biotaloudessa? (not translated)

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Jyri Mulari

  Mode of delivery

  Distance learning

  Recommended or required reading

  Jaetaan Open-Learn-alustalla (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  14.09.2020 - 30.11.2020

  Enrollment date

  01.09.2020 - 04.09.2020

  • 2 credits

  Seats

  20 - 40

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  eCampus

  Virtual proportion

  2 credits

  Evaluation scale

  Approved/Failed

  Exam schedule

  Ei erillistä tenttiä eikä tentittävissä (not translated)

•   Bioenergy EN00CY17-3002 31.08.2020-11.12.2020  5 credits  (ENKT18SP, ...) +-
  Learning outcomes of the course

  After this course you can:
  - name different bio-energy raw material sources and applications
  - describe the most common methods to produce bioenergy
  - discuss the advantages and disadvantages of the use of bio-energy
  - analyze the strengths and weaknesses of different raw materials and processing chains
  - identify the role of bioenergy in circulation economy
  - determine the profitability of production and use of bioenergy.

  Prerequisites and co-requisites

  1. Fuels and heating systems
  2. Renewable energy
  3. Energy engineering chemistry

  Course contents

  • What materials can be processed into bioenergy?
  • How are solid biofuels manufactured and processed?
  • How to produce liquid biofuels and biogas?
  • Why are biofuels used and supported?
  • What are the limitations and challenges associated with the production of biofuels?
  • What does the price of bioenergy consist of?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Jyri Mulari

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Osoitetaan tai jaetaan Learnissa (not translated)

  Planned learning activities and teaching methods

  Luennot, harjoitukset, tehtävät, kokeet
  Vaihtoehtona itseopiskelu ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 11.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP
  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  R&D proportion

  1 credits

  Evaluation scale

  1-5

•   Dieselmoottorit ja varavoima (not translated) AV00DN73-3001 07.09.2020-30.11.2020  3 credits  (AVERKT, ...) +-
  Learning outcomes of the course

  ¨Tunnet dieselmoottorin toimitatavan ja rakenteen. Tunnet tärkeimmät varavoimalähteet. (not translated)

  Course contents

  • Dieselmoottorin toiminta
  • Muut varavoimalähteet (not translated)

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Marko Saxell

  Mode of delivery

  34% Face-to-face, 66% Distance learning

  Assessment methods and criteria

  Harjoitustehtävät ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  07.09.2020 - 30.11.2020

  • 3 credits

  Group(s)

  • AVERKT
  • AVKTDAKKDI20K

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  2 credits

  Evaluation scale

  1-5

•   Electrical and HVAC Measurements EN00BH66-3003 26.10.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After this study you can:
  use the necessary energy audit measuring devices
  analyze measurement data collected over a long period of time
  distinguish relevant information related to the measurement data from energy audits
  make conclusions related to measurements.

  Prerequisites and co-requisites

  Energy Audits

  Course contents

  What devices are used in the energy audit?
  How is measurement data analysed?
  What measurements are essential for energy savings?
  What conclusions can be drawn based on the measurement results?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  26.10.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Electrical networks EN00BH46-3005 01.02.2021-30.04.2021  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  After the course you can:
  search information concerning electrical regulations and standards
  present the structure of electrical power network, from the electric power plant to the consumer
  analyze the parameters related to power quality
  determine the reactive power compensation and harmonic filtering related equipment solutions

  Prerequisites and co-requisites

  Sähkötekniikan perusteiden sekä energiatekniikan matematiikan hallinta (not translated)

  Course contents

  What standards regulate electrical work?
  How does the electricity transmission system work?
  How to measure the quality of electricity?
  Why is reactive power compensated and harmonics limited in power networks?

  ---

  Teacher(s)

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  01.02.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Electrical networks EN00BH46-3003 31.08.2020-18.12.2020  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After the course you can:
  search information concerning electrical regulations and standards
  present the structure of electrical power network, from the electric power plant to the consumer
  analyze the parameters related to power quality
  determine the reactive power compensation and harmonic filtering related equipment solutions

  Prerequisites and co-requisites

  Sähkötekniikan perusteiden sekä energiatekniikan matematiikan hallinta (not translated)

  Course contents

  What standards regulate electrical work?
  How does the electricity transmission system work?
  How to measure the quality of electricity?
  Why is reactive power compensated and harmonics limited in power networks?

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Emission measurements and environmental technology AV00EF16-3003 01.05.2021-31.07.2021  5 credits +-
  Learning outcomes of the course

  Student will recognize, understand and will be able to apply the following: - mechanisms of environmental pollution and cleaning - soil, air and water related cleaning technologies and waste handling process - basics of the field specific environmental administration, legislation, regulation and related economic factors - physcial and chemical functional principles of emission masurement equipment - theoretical principles of emission measurement - use of measurement equipment in practice - calculation of emissions and producing emission measurement reports - functional princciples of analyzers and related emission methods (not translated)

  Course contents

  What are the theoretical principles and mechanisms related to the pollution and cleaning of emissions? What are the key cleaning technologies? What are the main emission related adminisrative, legislative and economic issues? How the emission measurement equipment and analyzers work? How to calculate emissions and produce measurement reports? (not translated)

  Further information

  Not required to have any prior know-how or skills. (not translated)

  ---

  Teacher(s)

  Merja Mäkelä

  Mode of delivery

  Distance learning

  Recommended or required reading

  Learn materials.
  • Learning Environment for Papermaking and Automation, KnowPap, AEL and Prowledge, 2015, Finland.
  • Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL and Prowledge, 2015, Finland.
  • TOXOER MOOC material in http://moodle.toxoer.com/, EU ERASMUS TOXOER project 2015-2018.

  Planned learning activities and teaching methods

  Opintoja nopeuttava oppimisväylä:
  After completing this course, you will be able to
  • explain the mechanisms of environmental pollution in soil, air and water
  • describe the related cleaning technologies and waste handling processes
  • physical and chemical working principles of online and offline emission measurement technology
  • use emission measurement equipment in industrial and authority practices
  • analyse and calculate the amount of emissions coming from different anthropogenic activities, and produce emission measurement reports
  • describe the main features of field specific environmental administration, legislation, regulation and related economic factors.
  What are the theoretical principles and mechanisms related to the pollution and cleaning of emissions?
  What are the key cleaning technologies?
  How do the emission measurement systems and analysers work?
  How are you able to estimate emissions and produce measurement reports?
  What are most significant emissions related administrative, legislative and economic issues?
  STUDENTS MAY CHOOSE THE LEARNING PERIOD.

  Assessment methods and criteria

  The course grade consists of partial grades: Total grade = 0.4 * Part 1 grade + 0.2 * Part 2 grade + 0.2 * Part 3 grade + 0.2 * Part 4 grade.
  Partial grades 0-5.

  Language of instruction

  English

  Timing

  01.05.2021 - 31.07.2021

  • 5 credits

  Seats

  20 - 50

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  eCampus

  Virtual proportion

  5 credits

  Evaluation scale

  1-5

  Exam schedule

  Four partial exams.

  International connections

  Course materials produced in the TOX-OER project together with 6 other EU partner institutions.
  http://moodle.toxoer.com/.

  Students use of time and load

  135 hours self-study with Massive Open Online Course (MOOC) materials and Learn materials.

•   Emission measurements and environmental technology AV00EF16-3002 01.09.2020-18.12.2020  5 credits +-
  Learning outcomes of the course

  Student will recognize, understand and will be able to apply the following: - mechanisms of environmental pollution and cleaning - soil, air and water related cleaning technologies and waste handling process - basics of the field specific environmental administration, legislation, regulation and related economic factors - physcial and chemical functional principles of emission masurement equipment - theoretical principles of emission measurement - use of measurement equipment in practice - calculation of emissions and producing emission measurement reports - functional princciples of analyzers and related emission methods (not translated)

  Course contents

  What are the theoretical principles and mechanisms related to the pollution and cleaning of emissions? What are the key cleaning technologies? What are the main emission related adminisrative, legislative and economic issues? How the emission measurement equipment and analyzers work? How to calculate emissions and produce measurement reports? (not translated)

  Further information

  Not required to have any prior know-how or skills. (not translated)

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Mode of delivery

  Distance learning

  Recommended or required reading

  Learn materials.
  • Learning Environment for Papermaking and Automation, KnowPap, AEL and Prowledge, 2015, Finland.
  • Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL and Prowledge, 2015, Finland.
  • TOXOER MOOC material in http://moodle.toxoer.com/, EU ERASMUS TOXOER project 2015-2018.

  Planned learning activities and teaching methods

  Työviikkopohjainen oppimisväylä:
  -
  
  Opintoja nopeuttava oppimisväylä:
  -
  
  Työhön integroitu oppimisväylä:
  After completing this course, you will be able to
  • explain the mechanisms of environmental pollution in soil, air and water
  • describe the related cleaning technologies and waste handling processes
  • physical and chemical working principles of online and offline emission measurement technology
  • use emission measurement equipment in industrial and authority practices
  • analyse and calculate the amount of emissions coming from different anthropogenic activities, and produce emission measurement reports
  • describe the main features of field specific environmental administration, legislation, regulation and related economic factors.
  What are the theoretical principles and mechanisms related to the pollution and cleaning of emissions?
  What are the key cleaning technologies?
  How do the emission measurement systems and analysers work?
  How are you able to estimate emissions and produce measurement reports?
  What are most significant emissions related administrative, legislative and economic issues?
  STUDENTS MAY CHOOSE THE LEARNING PERIOD.

  Assessment methods and criteria

  The course grade consists of partial grades: Total grade = 0.4 * Part 1 grade + 0.2 * Part 2 grade + 0.2 * Part 3 grade + 0.2 * Part 4 grade.
  Partial grades 0-5.

  Language of instruction

  English

  Timing

  01.09.2020 - 18.12.2020

  • 5 credits

  Seats

  0 - 110

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  eCampus

  Virtual proportion

  5 credits

  Evaluation scale

  1-5

  International connections

  Course materials produced in the TOX-OER project together with 6 other EU partner institutions.
  http://moodle.toxoer.com/.

  Students use of time and load

  135 hours self-study with Massive Open Online Course (MOOC) materials and Learn materials.

•   Energiankäytön optimointi (not translated) AV00DN79-3001 04.01.2021-30.04.2021  3 credits  (AVKTDAKKDI20K) +-
  Course contents

  • Pumppujen, puhaltimien ja kompressorien energiatehokkuuden parantaminen
  • Säätötapamuutokset (not translated)

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  04.01.2021 - 30.04.2021

  Enrollment date

  05.12.2020 - 03.01.2021

  • 3 credits

  Group(s)

  • AVKTDAKKDI20K

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy Audit Project EN00BH67-3002 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After this study you can:
  act as a member of a project team, and follow the project schedules and requirements
  view the most essential equipment and assemblies in the field, which have a significant impact on energy use
  cooperate with people in the building, as well as comply with safety regulations
  report and present the results of an energy audit to the customer.

  Prerequisites and co-requisites

  Energy Audits
  Electrical and HVAC Measurements

  Course contents

  What is project work like?
  What is the role of an energy audit field work?
  In what ways do the contact persons of the site assist in carrying out energy audits?
  How are the project results reported and presented to the commissioner?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy Audits EN00BH65-3003 31.08.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After this course you can:
  analyze the current state of use of energy and water in the building or the production plant based on historical data
  understand the content and significance of the building or production plant energy audit
  divide the consumption of energy and water between the largest groups of devices
  understand factors that can typically improve the energy efficiency of building.

  Prerequisites and co-requisites

  Fluid Dynamics
  Thermodynamics and Heat Transfer
  Energy Economics
  Basics of Electrical Engineering and Electronics
  Electrical Networks

  Course contents

  Where is energy and water consumed in buildings and plants?
  What is an energy audit and what is its significance?
  What equipment and assemblies consume energy and water?
  Which actions can typically improve energy efficiency?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Marko Saxell

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy conversion processes EN00BH53-3003 31.08.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After the course you can:
  - explain the most common energy conversion processes and their operating principles.
  - solve energy conversion process power and efficiencies mathematically.
  - apply the h, s and p, h diagrams for calculating energy conversion processes.
  - explain steam turbine control methods.

  Prerequisites and co-requisites

  Requires basic knowledge of energy technology, mathematics and physics (solving equations, basic units, units)
  Energy production and electricity technology basics
  Steam boilers

  Course contents

  How do the most common energy conversion processes work:
  - steam turbine
  - gas turbine
  - water turbine
  - wind turbine
  - diesel and gas engines
  - ORC process
  - heat pumps
  
  How are energy conversion process power and efficiencies calculated?
  How are the h, s and p, h diagrams used?
  What are the steam turbine control methods?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Harjoitustehtävät ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy economics EN00BH50-3003 31.08.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After this study you:
  - understand energy economy from the perspectives of both energy consumers and producers
  - can calculate the investment costs and profitability of an investment
  - can determine the profitability of changing the heating method
  - know the objectives and measures of energy policy.

  Prerequisites and co-requisites

  Basic of energy production and power stations
  Fuels and heating systems

  Course contents

  How is the price of energy formed?
  What is energy efficiency?
  How to calculate the profitability of an investment?
  How does the electricity market work?
  Why are there taxes in the price of energy?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Jyri Mulari

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy economics EN00BH50-3004 11.01.2021-31.05.2021  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After this study you:
  - understand energy economy from the perspectives of both energy consumers and producers
  - can calculate the investment costs and profitability of an investment
  - can determine the profitability of changing the heating method
  - know the objectives and measures of energy policy.

  Prerequisites and co-requisites

  Basic of energy production and power stations
  Fuels and heating systems

  Course contents

  How is the price of energy formed?
  What is energy efficiency?
  How to calculate the profitability of an investment?
  How does the electricity market work?
  Why are there taxes in the price of energy?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Jyri Mulari

  Mode of delivery

  40% Face-to-face, 60% Distance learning

  Recommended or required reading

  Jaetaan tai osoitetaan Learnissa (not translated)

  Planned learning activities and teaching methods

  Ensisijainen suoritustapa:
  -alkukoe Learnissa
  -ajoitetut ja arvioitavat tehtävät Learnissa
  -loppukoe Learnissa
  Vaihtoehtoinen suoritustapa:
  1. itsenäinen opiskelu
  2. Exam-koe
  3. Learn-koe (not translated)

  Assessment methods and criteria

  tehtävät 50 % ja Learn-koe 50 %, läpäisyraja 50 %
  
  exam-koe 50 % ja exam-koe 50 %, läpäisyraja 50 % (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  3 credits

  Evaluation scale

  1-5

  Exam schedule

  Alkukoe tammikuun 2020 loppuun mennessä
  Learn-loppukoe toukokuun 2020 lopussa
  
  Vaihtoehtoisen suoritustavan kokeet (not translated)

  Students use of time and load

  5 op on keskiverto-opiskelijan 135 tunnin työmäärä. (not translated)

•   Energy engineering chemistry EN00BH43-3004 31.08.2020-18.12.2020  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  Part I
  You understand the atomic structure, periodic table and chemical bonding.
  You understand behavior of solids, liquids and gases.
  You have ability to balance a chemical equation and performe stoichiometric calculations for example in reactions of acids and bases and in combustion reactions.
  
  Part II
  You have ability to performe thermochemistry calculations.
  You understand the mechanism in redox reactions and you can apply your knowledge in corrosion reactions.
  You have ability to understand the meaning and importance of water chemical performance in steam generation chemistry.

  Prerequisites and co-requisites

  Basics of mathematics and physics (solving equations, physical quantities and units)

  Course contents

  Part I:
  How the structure of an atom affects on chemical behaviour of an element ?
  What information you get from the periodic table ?
  How the chemical bonding affects on the behavour of matter ?
  What information you get from phasediagram and what information give gas laws ?
  How you perform stoichiometric calculations and what kind of reactions are acid-base reactions and combustion reactions ?
  
  Part II
  How you calculate enthalpy changes, free energy changes and entropy changes in chemical reactions ?
  How you can use electrochemical series ?
  How the steam generation chemistry and chemical treatment programs give methods preventing scales and corrosion.

  ---

  Name of lecturer(s)

  Anne Gango

  Teacher(s)

  Anne Gango

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy engineering mathematics 2 EN00BH42-3004 31.08.2020-18.12.2020  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  Opintojakson suoritettuasi osaat:
  ratkaista muutosnopeuksia kinematiikan ja automaatiotekniikan ongelmissa derivaatan avulla
  käyttää integraalilaskentaa ongelmien ratkaisussa, kun muutosnopeus tunnetaan
  tarkastella jaksollisia ilmiöitä sin-käyrän avulla
  käyttää matriisimerkintää ongelmanratkaisun yksinkertaistamisessa
  käyttää kompleksilukuja vaihtovirtapiirien laskennassa. (not translated)

  Prerequisites and co-requisites

  Energiatekniikan insinöörimatematiikka 1 (not translated)

  Course contents

  Miten ilmiön muutosnopeus (kuvaajan jyrkkyys) lasketaan?
  Kuinka kiihtyvyysfunktiosta saadaan integraalilaskennan avulla nopeusfunktio?
  Kuinka jaksollinen ilmiö kuvataan sin-käyrän avulla (parametrien merkitys)?
  Kuinka yhtälöryhmä (virtauksissa tai sähkötekniikassa) ratkaistaan matriisien avulla?
  Kuinka vaihtovirtapiiri ratkaistaan kompleksilukuja hyödyntämällä? (not translated)

  ---

  Name of lecturer(s)

  Timo Lyytikäinen

  Teacher(s)

  Timo Lyytikäinen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Energy engineering physics EN00BH45-3004 31.08.2020-31.01.2021  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  You are able to solve the basic equations between quantities and modify values from one unit to another.
  You are able to do the basic calculations using vector quantities and determine quantities graphically.
  You are able to use the basic concepts of solids, liquids, gas, heat, electricity and wave motion in physics and in technology to solve the problems theoretically and experimentally.

  Course contents

  How to modify values from one unit to another.
  How to present vectors and use vector components?
  How to evaluate quantities graphically?
  What are the fundamental phenomenons, quantities, units, definitions and natural laws of solids, liquids, gas, heat, electricity and wave motion.
  How to solve equations between quantities of physics?
  How to measure physical quantities, study natural laws and write a testreport?

  ---

  Name of lecturer(s)

  Tiina Kettunen

  Teacher(s)

  Tiina Kettunen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 31.01.2021

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Engineering mathematics 1 TY00DR36-3011 11.01.2021-30.04.2021  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  You are able to solve different types of equations and also solve for a variable in a formula.
  
  You know the basic methods for solving a system of equations and are able to use these methods flexibly.
  
  You are familiar with the directional angle and the basic properties of trigonometric functions. You can solve a triangle and understand the prerequisites in the solving process.
  
  You know basic methods for solving a system of equations and are able to use them flexibly.
  
  You know the fundamental properties of vectors and are able to deal with basic vector problems.
  
  You know the idea of the logarithms and are familiar with basic logarithm formulas. You can solve exponential equations and deal with problems of exponential growth and decrease.

  Prerequisites and co-requisites

  General knowledge of mathematics of the upper secondary school or the course of Intensive course in mathematics is required.

  Course contents

  How do you solve equations of the first and second degree and square-root equations?
  
  How do you deal with problems of electric circuits, mixture and proportions and curve fitting by forming a system of equations?
  
  How do you solve a triangle? How do you construct basic trigonometric formulas using the unit circle?
  
  How do you solve problems of relative velocity using vectors? How do you use the component form of vector and scalar product for calculating angles and projections?
  
  How do you apply logarithm operations for defining noise levels?
  
  How do you deal with problems of temperature of a cooling particle, decreasing rate of radioactive decay, charging or discharging a capacitor and intensity of radiation e.g. visible light?

  ---

  Teacher(s)

  Timo Lyytikäinen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Engineering project EN00BH69-3002 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  You know how to use the systematic method in product development.
  You know the different phases of a product development project.
  You know the basics in patent law.
  You are able to lead an independent equipment, plant, or process design project.

  Prerequisites and co-requisites

  Statiikka ja lujuuslaskenta
  Materiaali- ja valmistustekniikka
  Tekninen visualisointi ja CAD (not translated)

  Course contents

  What must be taken into account when applying for a patent for an invention?
  What phases does a product development project include?
  How to use the systematic method in product development?

  ---

  Name of lecturer(s)

  Kalle Tarhonen

  Teacher(s)

  Kalle Tarhonen

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Materials will be distributed in class
  Engineering design - Pahl Gerhard, Beitz Wolfgang

  Assessment methods and criteria

  Project work and report 70 %
  Exam 30%

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Further information for students

  Kurssilla opeteltavan teorian pohjalta viedään läpi suunnitteluprojekti teollisuudesta.
  Se voi olla Laite-, Laitos- tai prosessisuunnitteluprojekti, ja luonteeltaan laajempi tuotekehitystehtävä tai detaljin kehitys.
  Työ tehdään ryhmissä, ja raportoidaan asiaankuuluvasti. (not translated)

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Students use of time and load

  Luentoja 12 h
  Itsenäistä työskentelyä ryhmissä 60 h
  Ohjattua suunnittelua 30 h (not translated)

•   Environmental impacts of energy production EN00BH54-3004 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After this course you:
  - are familiar with sustainability criteria of energy production
  - understand the environmental impact of energy production
  - know the means to reduce adverse environmental impacts in energy production

  Prerequisites and co-requisites

  1. Energy engineering chemistry
  2. Steam boilers

  Course contents

  How does energy production affect the environment?
  What permits does energy industry need?
  How is the environmental impact assessed and measured?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Markku Tommiska

  Anne Gango

  Jyri Mulari

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Finnish communication skills KY00DS51-3008 31.08.2020-18.12.2020  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  You understand the significance of interaction as part of your professional expertise and you can act appropriately in various communication situations.
  You are familiar with Xamk's instructions for written assignments.
  You are able to search reliable information and use it ethically.
  You can express your views justifying them based on facts and use standard Finnish appropriate in each context.
  You know how to write texts that meet the standards for layout, content and style required in your studies and in your own field, and use appropriate tools and forums.
  You improve your interactive communication skills and manage fluently in different cooperation situations, such as meetings and negotiations.
  You develop your presentation skills for professional purposes and acquire skills in giving and receiving feedback.

  Course contents

  What interaction skills are required in your own studies and in workplaces in your field?
  How do you justify your views using standard Finnish?
  How do you search reliable information from different sources and use it ethically?
  Which written skills (genres, styles, tools) should you master both in your studies and in work assignments in your own professional field?
  How do you utilize language regulations and tools in your studies and workplace communication?
  Which skills do you need in presentations, meetings and negotiations?
  How do you assess your own communication skills and ease your stage fright?
  How do you give constructive feedback?
  How do you utilize the feedback you received?

  ---

  Name of lecturer(s)

  Leena Griinari

  Teacher(s)

  Leena Griinari

  Mode of delivery

  60% Face-to-face, 40% Distance learning

  Recommended or required reading

  Kurssilla jaettava materiaali, joka sijaitsee pääosin Learnissa. (not translated)

  Planned learning activities and teaching methods

  yöviikkopohjainen oppimisväylä:
  Työjärjestyksen mukainen opetus. Aktiivinen osallistuminen ja tehdyt harjoitukset ja etätehtävät. (not translated)

  Assessment methods and criteria

  Arvioinnin perusteena on kurssin osaamistavoitteiden mukaiset tehtävät.
  Arvioinnin perusteiden ja arviointimenetelmien tarkempi kuvaus löytyy Learn-alustalta. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Seats

  20 - 35

  Further information for students

  leena.griinari@xamk.fi (not translated)

  Unit, in charge

  Kielet ja viestintä, Kotka (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  2 credits

  Evaluation scale

  1-5

  Students use of time and load

  5 op on 135 työtuntia (not translated)

•   Fluid dynamics EN00BH47-3003 31.08.2020-18.12.2020  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After this course you can:
  - define the fluid volume flow rate, flow velocity and pressure loss in a pipe system on the basis of equations and diagrams
  - choose a suitable pump for a pipe system and define the system operating point
  - examine system flow control methods by throttling or VSD control (basics of affinity laws)
  - solve simple mathematical problems in fluid dynamics
  - examine cavitation in different systems.

  Prerequisites and co-requisites

  Fuels and heating systems
  Energy engineering mathematics 1
  Energy engineering mathematics 2
  Energy engineering physics

  Course contents

  Why are there pressure losses in pipes?
  How do pumps and fans move fluid?
  How can the volume flow rate be controlled?
  How can mathematics be used in fluid dynamics?
  What is pump cavitation?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Timo Lyytikäinen

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Fluid dynamics EN00BH47-3005 01.02.2021-30.04.2021  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  After this course you can:
  - define the fluid volume flow rate, flow velocity and pressure loss in a pipe system on the basis of equations and diagrams
  - choose a suitable pump for a pipe system and define the system operating point
  - examine system flow control methods by throttling or VSD control (basics of affinity laws)
  - solve simple mathematical problems in fluid dynamics
  - examine cavitation in different systems.

  Prerequisites and co-requisites

  Fuels and heating systems
  Energy engineering mathematics 1
  Energy engineering mathematics 2
  Energy engineering physics

  Course contents

  Why are there pressure losses in pipes?
  How do pumps and fans move fluid?
  How can the volume flow rate be controlled?
  How can mathematics be used in fluid dynamics?
  What is pump cavitation?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Timo Lyytikäinen

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Kaksi välikoetta ja harjoitustyö (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  01.02.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Fuels and heating systems EN00BH39-3005 05.10.2020-18.12.2020  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  After this study you can:
  - define the required thermal power and annual thermal energy for a simple building
  - understand the basics of district heating network design
  - calculate heating plant thermal and fuel power for a district heating network
  - examine the profitability of alternate heating methods in buildings
  - examine the profitability of heat production.

  Prerequisites and co-requisites

  Energiantuotannon ja sähkölaitostekniikan perusteet (not translated)

  Course contents

  Why must buildings be heated?
  How is thermal energy transferred in a district heating network?
  Where is thermal energy used in heat production?
  Which kind of fuel is used for heat production?
  What is entrepreneurship in heat production?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Jyri Mulari

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  05.10.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Fuels and heating systems EN00BH39-3010 11.01.2021-31.05.2021  5 credits  (ENKT21KM) +-
  Learning outcomes of the course

  After this study you can:
  - define the required thermal power and annual thermal energy for a simple building
  - understand the basics of district heating network design
  - calculate heating plant thermal and fuel power for a district heating network
  - examine the profitability of alternate heating methods in buildings
  - examine the profitability of heat production.

  Prerequisites and co-requisites

  Energiantuotannon ja sähkölaitostekniikan perusteet (not translated)

  Course contents

  Why must buildings be heated?
  How is thermal energy transferred in a district heating network?
  Where is thermal energy used in heat production?
  Which kind of fuel is used for heat production?
  What is entrepreneurship in heat production?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Jyri Mulari

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Kokeet, harjoitustyöt ja palautettavat kotitehtävät (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT21KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Hukkalämmön hyödyntäminen (not translated) AV00DN80-3001 04.01.2021-30.04.2021  2 credits  (AVKTDAKKDI20K) +-
  Course contents

  • Jäähdytyksen ja lämmityksen yhdistäminen
  • Ylijäämälämmön käyttömahdollisuudet (not translated)

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  04.01.2021 - 30.04.2021

  Enrollment date

  05.12.2020 - 03.01.2021

  • 2 credits

  Group(s)

  • AVKTDAKKDI20K

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Information systems EN00BH61-3001 26.10.2020-18.12.2020  5 credits  (ENKT17SP) +-
  Learning outcomes of the course

  After this course you can:
  identify what is meant by the production control system from the point of view of maintenance
  explain basics of 1-3 maintenance information system
  solve problems related to information systems
  recognize the potential of software in the development of production

  Course contents

  What are the key principles of information systems?
  How do production management systems (MES Manufacturing Execution Systems) operate from the point of view of maintenance?
  What kind of production control systems are SAP, Microsoft Dynamics NAV and Amos?
  How and why do companies use information systems?

  ---

  Name of lecturer(s)

  Eeva Ala-Krekola

  Teacher(s)

  Eeva Ala-Krekola

  Mode of delivery

  Distance learning

  Recommended or required reading

  To be informed on digital learning environment Learn

  Planned learning activities and teaching methods

  If the student wishes to follow an individual learning track, the student writes a plan on the individual learning track. The plan has to be approved by their work place and must comply with the learning outcomes of the course. The individual learning track must be presented to and agreed with the teacher prior to the course start.

  Assessment methods and criteria

  Students can
  a. use professional vocabulary systematically.
  b. look for information in the key information sources of the field.
  c. identify interrelated tasks.

  Language of instruction

  Tuition in Finnish

  Timing

  26.10.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  5 credits

  Evaluation scale

  1-5

  Exam schedule

  To be informed on digital learning environment Learn

  Students use of time and load

  5 cr / 135 h

•   Information systems EN00BH61-3002 26.10.2020-18.12.2020  5 credits  (ENKT17SM) +-
  Learning outcomes of the course

  After this course you can:
  identify what is meant by the production control system from the point of view of maintenance
  explain basics of 1-3 maintenance information system
  solve problems related to information systems
  recognize the potential of software in the development of production

  Course contents

  What are the key principles of information systems?
  How do production management systems (MES Manufacturing Execution Systems) operate from the point of view of maintenance?
  What kind of production control systems are SAP, Microsoft Dynamics NAV and Amos?
  How and why do companies use information systems?

  ---

  Name of lecturer(s)

  Eeva Ala-Krekola

  Teacher(s)

  Eeva Ala-Krekola

  Mode of delivery

  Distance learning

  Recommended or required reading

  To be informed on digital learning environment Learn

  Planned learning activities and teaching methods

  If the student wishes to follow an individual learning track, the student writes a plan on the individual learning track. The plan has to be approved by their work place and must comply with the learning outcomes of the course. The individual learning track must be presented to and agreed with the teacher prior to the course start.

  Assessment methods and criteria

  Students can
  a. use professional vocabulary systematically.
  b. look for information in the key information sources of the field.
  c. identify interrelated tasks.

  Language of instruction

  Tuition in Finnish

  Timing

  26.10.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  5 credits

  Evaluation scale

  1-5

  Exam schedule

  To be informed on digital learning environment Learn

  Students use of time and load

  5 cr / 135 h

•   Instrumentation and electrification EN00BH49-3005 11.01.2021-30.04.2021  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  
  identify an industrial process based on a flow chart or a PI diagram
  describe basic instrumentation loops, their tags and instruments
  present the process industry instruments and their working principles
  explain the basic principles of electrification, cabling and grounding systems
  choose and rate instruments and electric drives for different applications.

  Prerequisites and co-requisites

  Prerequisite courses are
  Energy engineering physics
  Energy engineering chemistry
  Basics of electrical engineering and electronics

  Course contents

  How to identify different kinds of process machines and instruments in flow charts?
  How to identify measurement, control, valve and motor loops and their operation principles in PI diagrams?
  How to measure the temperature of a furnace, the flow and conductivity of feed water, or the level of a steam drum?
  How to connect an instrument or an electric motor to a control system?
  How to choose and rate an electric motor and what kind of power supply does it need?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Vesa Kankkunen

  Merja Mäkelä

  Marko Saxell

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  1. Materials, instructions and assignments in Learn.
  2. Joronen, T., Kovacs, J., Majanne, Y., Voimalaitosautomaatio. Suomen Automaatioseura ry 2007. 276 s. Kappaleet 3, 4, 6, 7, 8.
  3. Bolton, W. Instrumentation and control systems, Elsevier, UK, 2004, 339 p.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - identify an industrial process based on a flow chart or PI diagram
  - describe basic instrumentation loops, their tags and instruments
  - present basic measurement instruments and their working principles
  - explain the basic principles of electrification, cabling and grounding systems
  - choose and rate instruments and electric motors for different applications.
  How are able to see different kinds of process machines and instruments in flow charts?
  How are you able to identify measurement, control, valve and motor loops and their operation principles in PI diagrams?
  How are you able to measure the temperature of a furnace, the flow and conductivity of feed water, or the level of a steam drum? How do you connect an instrument or an electric motor to a control system?
  How do you choose and rate an electric motor and what kind of power supply does it need?
  
  Independent track:
  Exam and project integrated in one's own work.
  
  Blended track:
  Exam and intended training projects.

  Assessment methods and criteria

  Exam (60 %) and projects (40 %), with grades 0-5, both are expected to be accepted.

  Language of instruction

  English

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Seats

  0 - 35

  Further information for students

  Prerequisite courses are
  1. Energiatekniikan insinöörifysiikka - Energy Engineering Physics
  2. Energiatekniikan insinöörikemia - Energy Engineering Chemistry
  3. Sähkötekniikan ja elektroniikan perusteet - Basics of Electrical Engineering and Electronics,
  or related qualifications are required.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam.

  Students use of time and load

  Contact and online lectures 36 h
  Lab projects 24 h
  Self-study 75 h

•   Instrumentation and electrification EN00BH49-3006 11.01.2021-30.04.2021  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  
  identify an industrial process based on a flow chart or a PI diagram
  describe basic instrumentation loops, their tags and instruments
  present the process industry instruments and their working principles
  explain the basic principles of electrification, cabling and grounding systems
  choose and rate instruments and electric drives for different applications.

  Prerequisites and co-requisites

  Prerequisite courses are
  Energy engineering physics
  Energy engineering chemistry
  Basics of electrical engineering and electronics

  Course contents

  How to identify different kinds of process machines and instruments in flow charts?
  How to identify measurement, control, valve and motor loops and their operation principles in PI diagrams?
  How to measure the temperature of a furnace, the flow and conductivity of feed water, or the level of a steam drum?
  How to connect an instrument or an electric motor to a control system?
  How to choose and rate an electric motor and what kind of power supply does it need?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Vesa Kankkunen

  Merja Mäkelä

  Marko Saxell

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  1. Materials, instructions and assignments in Learn.
  2. Joronen, T., Kovacs, J., Majanne, Y., Voimalaitosautomaatio. Suomen Automaatioseura ry 2007. 276 s. Kappaleet 3, 4, 6, 7, 8.
  3. Bolton, W. Instrumentation and control systems, Elsevier, UK, 2004, 339 p.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - identify an industrial process based on a flow chart or PI diagram
  - describe basic instrumentation loops, their tags and instruments
  - present basic measurement instruments and their working principles
  - explain the basic principles of electrification, cabling and grounding systems
  - choose and rate instruments and electric motors for different applications.
  How are able to see different kinds of process machines and instruments in flow charts?
  How are you able to identify measurement, control, valve and motor loops and their operation principles in PI diagrams?
  How are you able to measure the temperature of a furnace, the flow and conductivity of feed water, or the level of a steam drum? How do you connect an instrument or an electric motor to a control system?
  How do you choose and rate an electric motor and what kind of power supply does it need?
  
  Independent track:
  Exam and project integrated in one's own work.
  
  Blended track:
  Exam and intended training projects.

  Assessment methods and criteria

  Exam (60 %) and projects (40 %), with grades 0-5, both are expected to be accepted.

  Language of instruction

  English

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Seats

  0 - 35

  Further information for students

  Prerequisite courses are
  1. Energiatekniikan insinöörifysiikka - Energy Engineering Physics
  2. Energiatekniikan insinöörikemia - Energy Engineering Chemistry
  3. Sähkötekniikan ja elektroniikan perusteet - Basics of Electrical Engineering and Electronics,
  or related qualifications are required.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam.

  Students use of time and load

  Contact and online lectures 36 h
  Lab projects 24 h
  Self-study 75 h

•   Instrumentointi ja sähköistys - Instrumentation and Electrification EN00BH49-3003 31.08.2020-18.12.2020  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  
  identify an industrial process based on a flow chart or a PI diagram
  describe basic instrumentation loops, their tags and instruments
  present the process industry instruments and their working principles
  explain the basic principles of electrification, cabling and grounding systems
  choose and rate instruments and electric drives for different applications.

  Prerequisites and co-requisites

  Prerequisite courses are
  Energy engineering physics
  Energy engineering chemistry
  Basics of electrical engineering and electronics

  Course contents

  How to identify different kinds of process machines and instruments in flow charts?
  How to identify measurement, control, valve and motor loops and their operation principles in PI diagrams?
  How to measure the temperature of a furnace, the flow and conductivity of feed water, or the level of a steam drum?
  How to connect an instrument or an electric motor to a control system?
  How to choose and rate an electric motor and what kind of power supply does it need?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Vesa Kankkunen

  Merja Mäkelä

  Marko Saxell

  Mode of delivery

  20% Face-to-face, 80% Distance learning

  Recommended or required reading

  Materials, instructions and assignments in Learn.
  2. Joronen, T., Kovacs, J., Majanne, Y., Voimalaitosautomaatio. Suomen Automaatioseura ry 2007. 276 s. Kappaleet 3, 4, 6, 7, 8.
  3. Bolton, W. Instrumentation and control systems, Elsevier, UK, 2004, 339 p.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - identify an industrial process based on a flow chart or PI diagram
  - describe basic instrumentation loops, their tags and instruments
  - present basic measurement instruments and their working principles
  - explain the basic principles of electrification, cabling and grounding systems
  - choose and rate instruments and electric motors for different applications.
  How are able to see different kinds of process machines and instruments in flow charts?
  How are you able to identify measurement, control, valve and motor loops and their operation principles in PI diagrams?
  How are you able to measure the temperature of a furnace, the flow and conductivity of feed water, or the level of a steam drum? How do you connect an instrument or an electric motor to a control system?
  How do you choose and rate an electric motor and what kind of power supply does it need?
  
  Independent track:
  Exam and project integrated in one's own work.
  
  Blended track:
  Exam and intended training projects.

  Assessment methods and criteria

  Exam (60 %) and projects (40 %), with grades 0-5, both are expected to be accepted.

  Language of instruction

  English

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Seats

  0 - 35

  Further information for students

  Prerequisite courses are
  1. Energiatekniikan insinöörifysiikka - Energy Engineering Physics
  2. Energiatekniikan insinöörikemia - Energy Engineering Chemistry
  3. Sähkötekniikan ja elektroniikan perusteet - Basics of Electrical Engineering and Electronics

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  4 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam 12.12.2020.
  Resit exam 11.1.2021.

  Students use of time and load

  Contact and online lectures 32 h
  Lab projects 14 h
  Self-study 89 h

•   Intensive course in mathematics in the field of engineering VV00ED88-3011 24.08.2020-18.12.2020  3 credits  (RAKT20SP) +-
  Learning outcomes of the course

  You are able to flexibly deal with expressions containing fractional numbers also in the symbolic form.
  
  You are able to simplify mathematical expressions, to find a common factor and use the square of a binomial as well as the product of sum and difference.
  
  You are familiar with basic formulas of powers and roots and you are able to use them effortlessly. You are also familiar with negative exponents.
  
  You know thoroughly how to solve equations of first and second degree.
  
  You area able to solve for a given variable in a formula.
  
  You are able to solve a system of two linear equations and to create equations based on simple verbal problems.
  
  You are familiar with mathematical functions and you are able to draw the graph of a line or a parabola.
  
  You know the prerequisites for solving a right-angled triangle and you can carry out the solving process effortlessly.

  Prerequisites and co-requisites

  passing the entrance examination of engineering studies

  Course contents

  How do you carry out the basic calculations of fractional numbers?
  How do you simplify expressions by removing parentheses, performing the multiplications and combining similar terms?
  How do you perform mathematical operations for simplifying power and root expressions?
  How do you factorizate a mathematical expression by using a common factor?
  How are the formulas of the square of a binomial and the product of sum and difference work used?
  How do you solve an equation of first degree and similar formulas?
  What are the three forms of a quadratic equation and how can these be solved efficiently?
  How do you define the slope, form the equation and draw the graph of a line?
  How do you solve a system of two linear equations and present it graphically in the coordinate system?
  How do you calculate the apex and zero positions of a parabola and draw the graph of it?
  What are the right triangle definitions for trigonometry functions? How can the right triangle be solved?

  ---

  Teacher(s)

  Lassi Salminen

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Moodlessa oleva verkkomateriaali (sisältää myös ACP-luentoja). (not translated)

  Planned learning activities and teaching methods

  Työviikkopohjainen oppimisväylä:
  Miten käsittelet matemaattisia summalausekkeita?
  ======================================
  • Lausekkeen arvo
  • Samanmuotoisten termien yhdistäminen
  • Sulkujen poistaminen summalausekkeesta
  • Summan kertominen ja jakaminen luvulla
  • Tekijän erottaminen
  ======================================
  Miten suoritat laskutoimituksia murtoluvuilla?
  ======================================
  • Murtolukujen yhteenlasku
  • Murtolukujen vähennyslasku
  • Murtolukujen kertolasku
  • Murtolukujen jakolasku
  ======================================
  Miten ratkaiset ensimmäisen asteen yhtälön? Miten tulkitset yhtälön kuvaaman ongelman?
  ======================================
  • Yhtälön peruskäsitteitä
  • Kaavat sovelluksissa
  • Kuvaaja: suora
  ======================================
  Mikä on yhtälöpari? Millaisista ongelmista syntyy yhtälöpareja? Miten se ratkaistaan?
  ======================================
  • ratkaiseminen sijoitusmenettelyllä
  • ratkaiseminen yhteenlaskumenettelyllä
  • yhtälöparin graafinen tulkinta
  ======================================
  Miten käsittelet potenssilausekkeita? Mitä tarkoittaa negatiivinen potenssi?
  ======================================
  • Neliö ja kuutio
  • Eksponenttina nolla
  • Eksponenttina negatiivinen luku
  • Tulon ja osamäärän potenssi
  • Samankantaisten potenssien tulo ja osamäärä
  • Potenssin potenssi
  ======================================
  Miten käsitellään juurilausekkeita?
  ======================================
  • Neliöjuuri
  • Kuutiojuuri
  • Juuret kaavoissa
  ======================================
  Mikä on polynomilauseke? Miten kerrot ja jaat polynomeja keskenään? Mitä ovat binomin neliö ja summan ja erotuksen tulo?
  ======================================
  • Käsitteitä
  • Polynomien yhteen- ja vähennyslasku
  • Polynomien kertolasku
  • Binomin neliö
  • Summan ja erotuksen tulo
  • Polynomien jakolasku – myös jakokulmaa käyttäen
  • Polynomin jakaminen tekijöihin
  ======================================
  Mikä on toisen asteen yhtälö? Miten ratkaistaan erityyppisiä toisen asteen yhtälöitä?
  ======================================
  • Peruskäsitteitä
  • Juurtaminen
  • Tekijöihin jakaminen yhtälöä ratkaistaessa
  • Ratkaisukaava
  • Yhtälön juurten reaalisuuden tutkiminen diskriminantin avulla
  • Kuvaaja: paraabeli
  ======================================
  Mikä on funktio? Miten piirretään perusfunktioiden kuvaajat (suora ja paraabeli)?
  Miten kuvaajia tulkitaan?
  ======================================
  • Funktion käsite
  • Ensimmäisen asteen funktion kuvaaja: suora
  • Kulmakerroin
  • Yhdensuuntaiset suorat
  • Nouseva ja laskeva suora
  • Toisen asteen funktion kuvaaja: paraabeli
  • Nollakohtien ja aukeamissuunnan määrittäminen
  ======================================
  Miten ratkaistaan suorakulmainen kolmio?
  ======================================
  • Pythagoraan lause ja suorakulmaisen kolmion trigonometria
  ======================================
  Suoritustapa: Tunneille osallistuminen (vähintään 70 %) ja kurssikoe.
  
  Opintoja nopeuttava oppimisväylä:
  Miten käsittelet matemaattisia summalausekkeita?
  ======================================
  • Lausekkeen arvo
  • Samanmuotoisten termien yhdistäminen
  • Sulkujen poistaminen summalausekkeesta
  • Summan kertominen ja jakaminen luvulla
  • Tekijän erottaminen
  ======================================
  Miten suoritat laskutoimituksia murtoluvuilla?
  ======================================
  • Murtolukujen yhteenlasku
  • Murtolukujen vähennyslasku
  • Murtolukujen kertolasku
  • Murtolukujen jakolasku
  ======================================
  Miten ratkaiset ensimmäisen asteen yhtälön? Miten tulkitset yhtälön kuvaaman ongelman?
  ======================================
  • Yhtälön peruskäsitteitä
  • Kaavat sovelluksissa
  • Kuvaaja: suora
  ======================================
  Mikä on yhtälöpari? Millaisista ongelmista syntyy yhtälöpareja? Miten se ratkaistaan?
  ======================================
  • ratkaiseminen sijoitusmenettelyllä
  • ratkaiseminen yhteenlaskumenettelyllä
  • yhtälöparin graafinen tulkinta
  ======================================
  Miten käsittelet potenssilausekkeita? Mitä tarkoittaa negatiivinen potenssi?
  ======================================
  • Neliö ja kuutio
  • Eksponenttina nolla
  • Eksponenttina negatiivinen luku
  • Tulon ja osamäärän potenssi
  • Samankantaisten potenssien tulo ja osamäärä
  • Potenssin potenssi
  ======================================
  Miten käsitellään juurilausekkeita?
  ======================================
  • Neliöjuuri
  • Kuutiojuuri
  • Juuret kaavoissa
  ======================================
  Mikä on polynomilauseke? Miten kerrot ja jaat polynomeja keskenään? Mitä ovat binomin neliö ja summan ja erotuksen tulo?
  ======================================
  • Käsitteitä
  • Polynomien yhteen- ja vähennyslasku
  • Polynomien kertolasku
  • Binomin neliö
  • Summan ja erotuksen tulo
  • Polynomien jakolasku – myös jakokulmaa käyttäen
  • Polynomin jakaminen tekijöihin
  ======================================
  Mikä on toisen asteen yhtälö? Miten ratkaistaan erityyppisiä toisen asteen yhtälöitä?
  ======================================
  • Peruskäsitteitä
  • Juurtaminen
  • Tekijöihin jakaminen yhtälöä ratkaistaessa
  • Ratkaisukaava
  • Yhtälön juurten reaalisuuden tutkiminen diskriminantin avulla
  • Kuvaaja: paraabeli
  ======================================
  Mikä on funktio? Miten piirretään perusfunktioiden kuvaajat (suora ja paraabeli)?
  Miten kuvaajia tulkitaan?
  ======================================
  • Funktion käsite
  • Ensimmäisen asteen funktion kuvaaja: suora
  • Kulmakerroin
  • Yhdensuuntaiset suorat
  • Nouseva ja laskeva suora
  • Toisen asteen funktion kuvaaja: paraabeli
  • Nollakohtien ja aukeamissuunnan määrittäminen
  ======================================
  Miten ratkaistaan suorakulmainen kolmio?
  ======================================
  • Pythagoraan lause ja suorakulmaisen kolmion trigonometria
  ======================================
  Suoritustapa: Tunneille osallistuminen (vähintään 70 %) ja kurssikoe.
  
  Työhön integroitu oppimisväylä:
  Miten käsittelet matemaattisia summalausekkeita?
  ======================================
  • Lausekkeen arvo
  • Samanmuotoisten termien yhdistäminen
  • Sulkujen poistaminen summalausekkeesta
  • Summan kertominen ja jakaminen luvulla
  • Tekijän erottaminen
  ======================================
  Miten suoritat laskutoimituksia murtoluvuilla?
  ======================================
  • Murtolukujen yhteenlasku
  • Murtolukujen vähennyslasku
  • Murtolukujen kertolasku
  • Murtolukujen jakolasku
  ======================================
  Miten ratkaiset ensimmäisen asteen yhtälön? Miten tulkitset yhtälön kuvaaman ongelman?
  ======================================
  • Yhtälön peruskäsitteitä
  • Kaavat sovelluksissa
  • Kuvaaja: suora
  ======================================
  Mikä on yhtälöpari? Millaisista ongelmista syntyy yhtälöpareja? Miten se ratkaistaan?
  ======================================
  • ratkaiseminen sijoitusmenettelyllä
  • ratkaiseminen yhteenlaskumenettelyllä
  • yhtälöparin graafinen tulkinta
  ======================================
  Miten käsittelet potenssilausekkeita? Mitä tarkoittaa negatiivinen potenssi?
  ======================================
  • Neliö ja kuutio
  • Eksponenttina nolla
  • Eksponenttina negatiivinen luku
  • Tulon ja osamäärän potenssi
  • Samankantaisten potenssien tulo ja osamäärä
  • Potenssin potenssi
  ======================================
  Miten käsitellään juurilausekkeita?
  ======================================
  • Neliöjuuri
  • Kuutiojuuri
  • Juuret kaavoissa
  ======================================
  Mikä on polynomilauseke? Miten kerrot ja jaat polynomeja keskenään? Mitä ovat binomin neliö ja summan ja erotuksen tulo?
  ======================================
  • Käsitteitä
  • Polynomien yhteen- ja vähennyslasku
  • Polynomien kertolasku
  • Binomin neliö
  • Summan ja erotuksen tulo
  • Polynomien jakolasku – myös jakokulmaa käyttäen
  • Polynomin jakaminen tekijöihin
  ======================================
  Mikä on toisen asteen yhtälö? Miten ratkaistaan erityyppisiä toisen asteen yhtälöitä?
  ======================================
  • Peruskäsitteitä
  • Juurtaminen
  • Tekijöihin jakaminen yhtälöä ratkaistaessa
  • Ratkaisukaava
  • Yhtälön juurten reaalisuuden tutkiminen diskriminantin avulla
  • Kuvaaja: paraabeli
  ======================================
  Mikä on funktio? Miten piirretään perusfunktioiden kuvaajat (suora ja paraabeli)?
  Miten kuvaajia tulkitaan?
  ======================================
  • Funktion käsite
  • Ensimmäisen asteen funktion kuvaaja: suora
  • Kulmakerroin
  • Yhdensuuntaiset suorat
  • Nouseva ja laskeva suora
  • Toisen asteen funktion kuvaaja: paraabeli
  • Nollakohtien ja aukeamissuunnan määrittäminen
  ======================================
  Miten ratkaistaan suorakulmainen kolmio?
  ======================================
  • Pythagoraan lause ja suorakulmaisen kolmion trigonometria
  ======================================
  Suoritustapa: Tunneille osallistuminen (vähintään 70 %) ja kurssikoe. (not translated)

  Assessment methods and criteria

  Tunti- ja kotitehtävät ja loppukoe. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  24.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 3 credits

  Group(s)

  • RAKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Yleisinä uusintatenttipäivinä. (not translated)

  Students use of time and load

  Oppitunnit 36 h.
  Itsenäinen verkko-opiskelu (Moodle) 20 h.
  Loppukoe ja siihen valmistautuminen 15 h. (not translated)

•   Intensive course in mathematics in the field of engineering VV00ED88-3009 31.08.2020-18.12.2020  3 credits  (ENKT20SP) +-
  Learning outcomes of the course

  You are able to flexibly deal with expressions containing fractional numbers also in the symbolic form.
  
  You are able to simplify mathematical expressions, to find a common factor and use the square of a binomial as well as the product of sum and difference.
  
  You are familiar with basic formulas of powers and roots and you are able to use them effortlessly. You are also familiar with negative exponents.
  
  You know thoroughly how to solve equations of first and second degree.
  
  You area able to solve for a given variable in a formula.
  
  You are able to solve a system of two linear equations and to create equations based on simple verbal problems.
  
  You are familiar with mathematical functions and you are able to draw the graph of a line or a parabola.
  
  You know the prerequisites for solving a right-angled triangle and you can carry out the solving process effortlessly.

  Prerequisites and co-requisites

  passing the entrance examination of engineering studies

  Course contents

  How do you carry out the basic calculations of fractional numbers?
  How do you simplify expressions by removing parentheses, performing the multiplications and combining similar terms?
  How do you perform mathematical operations for simplifying power and root expressions?
  How do you factorizate a mathematical expression by using a common factor?
  How are the formulas of the square of a binomial and the product of sum and difference work used?
  How do you solve an equation of first degree and similar formulas?
  What are the three forms of a quadratic equation and how can these be solved efficiently?
  How do you define the slope, form the equation and draw the graph of a line?
  How do you solve a system of two linear equations and present it graphically in the coordinate system?
  How do you calculate the apex and zero positions of a parabola and draw the graph of it?
  What are the right triangle definitions for trigonometry functions? How can the right triangle be solved?

  ---

  Name of lecturer(s)

  Henry Lähteenmäki

  Teacher(s)

  Henry Lähteenmäki

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Moodlessa oleva verkkomateriaali (sisältää myös ACP-luentoja). (not translated)

  Planned learning activities and teaching methods

  Työviikkopohjainen oppimisväylä:
  Miten käsittelet matemaattisia summalausekkeita?
  ======================================
  • Lausekkeen arvo
  • Samanmuotoisten termien yhdistäminen
  • Sulkujen poistaminen summalausekkeesta
  • Summan kertominen ja jakaminen luvulla
  • Tekijän erottaminen
  ======================================
  Miten suoritat laskutoimituksia murtoluvuilla?
  ======================================
  • Murtolukujen yhteenlasku
  • Murtolukujen vähennyslasku
  • Murtolukujen kertolasku
  • Murtolukujen jakolasku
  ======================================
  Miten ratkaiset ensimmäisen asteen yhtälön? Miten tulkitset yhtälön kuvaaman ongelman?
  ======================================
  • Yhtälön peruskäsitteitä
  • Kaavat sovelluksissa
  • Kuvaaja: suora
  ======================================
  Mikä on yhtälöpari? Millaisista ongelmista syntyy yhtälöpareja? Miten se ratkaistaan?
  ======================================
  • ratkaiseminen sijoitusmenettelyllä
  • ratkaiseminen yhteenlaskumenettelyllä
  • yhtälöparin graafinen tulkinta
  ======================================
  Miten käsittelet potenssilausekkeita? Mitä tarkoittaa negatiivinen potenssi?
  ======================================
  • Neliö ja kuutio
  • Eksponenttina nolla
  • Eksponenttina negatiivinen luku
  • Tulon ja osamäärän potenssi
  • Samankantaisten potenssien tulo ja osamäärä
  • Potenssin potenssi
  ======================================
  Miten käsitellään juurilausekkeita?
  ======================================
  • Neliöjuuri
  • Kuutiojuuri
  • Juuret kaavoissa
  ======================================
  Mikä on polynomilauseke? Miten kerrot ja jaat polynomeja keskenään? Mitä ovat binomin neliö ja summan ja erotuksen tulo?
  ======================================
  • Käsitteitä
  • Polynomien yhteen- ja vähennyslasku
  • Polynomien kertolasku
  • Binomin neliö
  • Summan ja erotuksen tulo
  • Polynomien jakolasku – myös jakokulmaa käyttäen
  • Polynomin jakaminen tekijöihin
  ======================================
  Mikä on toisen asteen yhtälö? Miten ratkaistaan erityyppisiä toisen asteen yhtälöitä?
  ======================================
  • Peruskäsitteitä
  • Juurtaminen
  • Tekijöihin jakaminen yhtälöä ratkaistaessa
  • Ratkaisukaava
  • Yhtälön juurten reaalisuuden tutkiminen diskriminantin avulla
  • Kuvaaja: paraabeli
  ======================================
  Mikä on funktio? Miten piirretään perusfunktioiden kuvaajat (suora ja paraabeli)?
  Miten kuvaajia tulkitaan?
  ======================================
  • Funktion käsite
  • Ensimmäisen asteen funktion kuvaaja: suora
  • Kulmakerroin
  • Yhdensuuntaiset suorat
  • Nouseva ja laskeva suora
  • Toisen asteen funktion kuvaaja: paraabeli
  • Nollakohtien ja aukeamissuunnan määrittäminen
  ======================================
  Miten ratkaistaan suorakulmainen kolmio?
  ======================================
  • Pythagoraan lause ja suorakulmaisen kolmion trigonometria
  ======================================
  Suoritustapa: Tunneille osallistuminen (vähintään 70 %) ja kurssikoe.
  
  Opintoja nopeuttava oppimisväylä:
  Miten käsittelet matemaattisia summalausekkeita?
  ======================================
  • Lausekkeen arvo
  • Samanmuotoisten termien yhdistäminen
  • Sulkujen poistaminen summalausekkeesta
  • Summan kertominen ja jakaminen luvulla
  • Tekijän erottaminen
  ======================================
  Miten suoritat laskutoimituksia murtoluvuilla?
  ======================================
  • Murtolukujen yhteenlasku
  • Murtolukujen vähennyslasku
  • Murtolukujen kertolasku
  • Murtolukujen jakolasku
  ======================================
  Miten ratkaiset ensimmäisen asteen yhtälön? Miten tulkitset yhtälön kuvaaman ongelman?
  ======================================
  • Yhtälön peruskäsitteitä
  • Kaavat sovelluksissa
  • Kuvaaja: suora
  ======================================
  Mikä on yhtälöpari? Millaisista ongelmista syntyy yhtälöpareja? Miten se ratkaistaan?
  ======================================
  • ratkaiseminen sijoitusmenettelyllä
  • ratkaiseminen yhteenlaskumenettelyllä
  • yhtälöparin graafinen tulkinta
  ======================================
  Miten käsittelet potenssilausekkeita? Mitä tarkoittaa negatiivinen potenssi?
  ======================================
  • Neliö ja kuutio
  • Eksponenttina nolla
  • Eksponenttina negatiivinen luku
  • Tulon ja osamäärän potenssi
  • Samankantaisten potenssien tulo ja osamäärä
  • Potenssin potenssi
  ======================================
  Miten käsitellään juurilausekkeita?
  ======================================
  • Neliöjuuri
  • Kuutiojuuri
  • Juuret kaavoissa
  ======================================
  Mikä on polynomilauseke? Miten kerrot ja jaat polynomeja keskenään? Mitä ovat binomin neliö ja summan ja erotuksen tulo?
  ======================================
  • Käsitteitä
  • Polynomien yhteen- ja vähennyslasku
  • Polynomien kertolasku
  • Binomin neliö
  • Summan ja erotuksen tulo
  • Polynomien jakolasku – myös jakokulmaa käyttäen
  • Polynomin jakaminen tekijöihin
  ======================================
  Mikä on toisen asteen yhtälö? Miten ratkaistaan erityyppisiä toisen asteen yhtälöitä?
  ======================================
  • Peruskäsitteitä
  • Juurtaminen
  • Tekijöihin jakaminen yhtälöä ratkaistaessa
  • Ratkaisukaava
  • Yhtälön juurten reaalisuuden tutkiminen diskriminantin avulla
  • Kuvaaja: paraabeli
  ======================================
  Mikä on funktio? Miten piirretään perusfunktioiden kuvaajat (suora ja paraabeli)?
  Miten kuvaajia tulkitaan?
  ======================================
  • Funktion käsite
  • Ensimmäisen asteen funktion kuvaaja: suora
  • Kulmakerroin
  • Yhdensuuntaiset suorat
  • Nouseva ja laskeva suora
  • Toisen asteen funktion kuvaaja: paraabeli
  • Nollakohtien ja aukeamissuunnan määrittäminen
  ======================================
  Miten ratkaistaan suorakulmainen kolmio?
  ======================================
  • Pythagoraan lause ja suorakulmaisen kolmion trigonometria
  ======================================
  Suoritustapa: Tunneille osallistuminen (vähintään 70 %) ja kurssikoe.
  
  Työhön integroitu oppimisväylä:
  Miten käsittelet matemaattisia summalausekkeita?
  ======================================
  • Lausekkeen arvo
  • Samanmuotoisten termien yhdistäminen
  • Sulkujen poistaminen summalausekkeesta
  • Summan kertominen ja jakaminen luvulla
  • Tekijän erottaminen
  ======================================
  Miten suoritat laskutoimituksia murtoluvuilla?
  ======================================
  • Murtolukujen yhteenlasku
  • Murtolukujen vähennyslasku
  • Murtolukujen kertolasku
  • Murtolukujen jakolasku
  ======================================
  Miten ratkaiset ensimmäisen asteen yhtälön? Miten tulkitset yhtälön kuvaaman ongelman?
  ======================================
  • Yhtälön peruskäsitteitä
  • Kaavat sovelluksissa
  • Kuvaaja: suora
  ======================================
  Mikä on yhtälöpari? Millaisista ongelmista syntyy yhtälöpareja? Miten se ratkaistaan?
  ======================================
  • ratkaiseminen sijoitusmenettelyllä
  • ratkaiseminen yhteenlaskumenettelyllä
  • yhtälöparin graafinen tulkinta
  ======================================
  Miten käsittelet potenssilausekkeita? Mitä tarkoittaa negatiivinen potenssi?
  ======================================
  • Neliö ja kuutio
  • Eksponenttina nolla
  • Eksponenttina negatiivinen luku
  • Tulon ja osamäärän potenssi
  • Samankantaisten potenssien tulo ja osamäärä
  • Potenssin potenssi
  ======================================
  Miten käsitellään juurilausekkeita?
  ======================================
  • Neliöjuuri
  • Kuutiojuuri
  • Juuret kaavoissa
  ======================================
  Mikä on polynomilauseke? Miten kerrot ja jaat polynomeja keskenään? Mitä ovat binomin neliö ja summan ja erotuksen tulo?
  ======================================
  • Käsitteitä
  • Polynomien yhteen- ja vähennyslasku
  • Polynomien kertolasku
  • Binomin neliö
  • Summan ja erotuksen tulo
  • Polynomien jakolasku – myös jakokulmaa käyttäen
  • Polynomin jakaminen tekijöihin
  ======================================
  Mikä on toisen asteen yhtälö? Miten ratkaistaan erityyppisiä toisen asteen yhtälöitä?
  ======================================
  • Peruskäsitteitä
  • Juurtaminen
  • Tekijöihin jakaminen yhtälöä ratkaistaessa
  • Ratkaisukaava
  • Yhtälön juurten reaalisuuden tutkiminen diskriminantin avulla
  • Kuvaaja: paraabeli
  ======================================
  Mikä on funktio? Miten piirretään perusfunktioiden kuvaajat (suora ja paraabeli)?
  Miten kuvaajia tulkitaan?
  ======================================
  • Funktion käsite
  • Ensimmäisen asteen funktion kuvaaja: suora
  • Kulmakerroin
  • Yhdensuuntaiset suorat
  • Nouseva ja laskeva suora
  • Toisen asteen funktion kuvaaja: paraabeli
  • Nollakohtien ja aukeamissuunnan määrittäminen
  ======================================
  Miten ratkaistaan suorakulmainen kolmio?
  ======================================
  • Pythagoraan lause ja suorakulmaisen kolmion trigonometria
  ======================================
  Suoritustapa: Tunneille osallistuminen (vähintään 70 %) ja kurssikoe. (not translated)

  Assessment methods and criteria

  Tunti- ja kotitehtävät ja loppukoe. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 3 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Yleisinä uusintatenttipäivinä. (not translated)

  Students use of time and load

  Oppitunnit 36 h.
  Itsenäinen verkko-opiskelu (Moodle) 20 h.
  Loppukoe ja siihen valmistautuminen 15 h. (not translated)

•   Lämpöpumpputekniikat (not translated) AV00DN77-3001 02.11.2020-31.12.2020  2 credits  (AVERKT, ...) +-
  Course contents

  • Lämpöpumppujen toiminta
  • Lämpöpumppujen mitoituksen perusteet (not translated)

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Mode of delivery

  50% Face-to-face, 50% Distance learning

  Language of instruction

  Tuition in Finnish

  Timing

  02.11.2020 - 31.12.2020

  • 2 credits

  Group(s)

  • AVERKT
  • AVKTDAKKDI20K

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

•   Maintenance of mechanical and electrical systems EN00BH59-3007 11.01.2021-31.05.2021  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  Kurssin suoritettuaan opiskelija tuntee tärkeimpien sähkölaitteiden ja -järjestelmien kunnossapidon periaatteet.
  Opintojakson suoritettuaan opiskelija osaa:
  • luokitella laitteet kunnossapitotarpeen mukaan
  • valita sopivat mittausmenetelmät eri kohteisiin
  • tutkia laiteissa ilmeneviä ongelmia
  • tehdä johtopäätöksiä parhaan suorituskyvyn ylläpitämiseksi (not translated)

  Course contents

  - Mitä on kunnossapito
  - Kunnossapitolajit
  - Pyörivien koneiden kunnonvalvonta
  - Kunnossapidon taloudellinen merkitys
  - Kriittisyysanalyysi
  - Todennäköisyys vikaantumiselle
  - kunnostaminen (on suunniteltua korjaamista)
  - mittaavan kunnossapidon menetelmä
  - Erityyppisten sähkölaitteiden ja sähkömekaanisten komponenttien kunnossapito ja huolto
  - Huollon mittauslaitteet:
  - yleismittarit
  - asennustesteri
  - lämpökamera
  - sähkönlaadun analysaattori
  - värähtelymittari. (not translated)

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Tuomo Pimiä

  Marko Saxell

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Hyväksytyt harjoitustyöt ja tentit. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Maintenance of mechanical and electrical systems EN00BH59-3008 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  Kurssin suoritettuaan opiskelija tuntee tärkeimpien sähkölaitteiden ja -järjestelmien kunnossapidon periaatteet.
  Opintojakson suoritettuaan opiskelija osaa:
  • luokitella laitteet kunnossapitotarpeen mukaan
  • valita sopivat mittausmenetelmät eri kohteisiin
  • tutkia laiteissa ilmeneviä ongelmia
  • tehdä johtopäätöksiä parhaan suorituskyvyn ylläpitämiseksi (not translated)

  Course contents

  - Mitä on kunnossapito
  - Kunnossapitolajit
  - Pyörivien koneiden kunnonvalvonta
  - Kunnossapidon taloudellinen merkitys
  - Kriittisyysanalyysi
  - Todennäköisyys vikaantumiselle
  - kunnostaminen (on suunniteltua korjaamista)
  - mittaavan kunnossapidon menetelmä
  - Erityyppisten sähkölaitteiden ja sähkömekaanisten komponenttien kunnossapito ja huolto
  - Huollon mittauslaitteet:
  - yleismittarit
  - asennustesteri
  - lämpökamera
  - sähkönlaadun analysaattori
  - värähtelymittari. (not translated)

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Tuomo Pimiä

  Marko Saxell

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Hyväksytyt harjoitustyöt ja tentit. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Management and entrepreneurship in energy technology EN00BH55-3001 31.08.2020-04.12.2020  5 credits  (ENKT17SP) +-
  Learning outcomes of the course

  After this study you can:
  understand the responsibilities and obligations of both employee and employer
  create prerequisites for the management of work
  identify and develop business ideas in the energy sector
  draft a business plan
  market your skills or the commodities you represent

  Prerequisites and co-requisites

  Professional Communication
  Energy Economics

  Course contents

  What are the rules of the working life and where are they defined?
  How do I plan and manage a project?
  What kind of service business is needed in planning in the energy sector, maintenance, remote operation and energy audits?
  What do I have to know and do when I am going to start a business?
  How do I sell energy, industry products or services?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Markku Tommiska

  Jyri Mulari

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 04.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Management and entrepreneurship in energy technology EN00BH55-3002 31.08.2020-04.12.2020  5 credits  (ENKT17SM) +-
  Learning outcomes of the course

  After this study you can:
  understand the responsibilities and obligations of both employee and employer
  create prerequisites for the management of work
  identify and develop business ideas in the energy sector
  draft a business plan
  market your skills or the commodities you represent

  Prerequisites and co-requisites

  Professional Communication
  Energy Economics

  Course contents

  What are the rules of the working life and where are they defined?
  How do I plan and manage a project?
  What kind of service business is needed in planning in the energy sector, maintenance, remote operation and energy audits?
  What do I have to know and do when I am going to start a business?
  How do I sell energy, industry products or services?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Markku Tommiska

  Jyri Mulari

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 04.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Materials and manufacturing technology EN00BH34-3007 31.08.2020-18.12.2020  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  After completing the course, you will be able to:
  identify the general structural materials of metal products
  explain the general manufacturing methods of metal products
  present the technical properties of structural materials for manufacturing
  choose the suitable material to the target
  identify the most important machine tools and hand tools of metal products
  use machine tools and hand tools safely
  use different welding methods safely

  Course contents

  What kind of materials are used in the structures of the metal products, machine parts and machines?
  How are the metal products made?
  What technical properties and processing properties are required from the production materials of the metal product and how can the properties of the metal be influenced with heat treatment?
  How do I choose a suitable material for the separate targets?
  What kind of tools and machine tools are used for the making of metal products?
  How do I operate machine tools and tools safely?
  What welding methods exist, what are their special characteristics ,and how to weld safely?

  ---

  Name of lecturer(s)

  Kalle Tarhonen

  Teacher(s)

  Esa Huuhtanen

  Kalle Tarhonen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Materials and manufacturing technology EN00BH34-3010 11.01.2021-31.05.2021  5 credits  (ENKT21KM) +-
  Learning outcomes of the course

  After completing the course, you will be able to:
  identify the general structural materials of metal products
  explain the general manufacturing methods of metal products
  present the technical properties of structural materials for manufacturing
  choose the suitable material to the target
  identify the most important machine tools and hand tools of metal products
  use machine tools and hand tools safely
  use different welding methods safely

  Course contents

  What kind of materials are used in the structures of the metal products, machine parts and machines?
  How are the metal products made?
  What technical properties and processing properties are required from the production materials of the metal product and how can the properties of the metal be influenced with heat treatment?
  How do I choose a suitable material for the separate targets?
  What kind of tools and machine tools are used for the making of metal products?
  How do I operate machine tools and tools safely?
  What welding methods exist, what are their special characteristics ,and how to weld safely?

  ---

  Name of lecturer(s)

  Kalle Tarhonen

  Teacher(s)

  Kalle Tarhonen

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Material that is distributed in classroom and in moodle.
  - Koivisto et al, Konetekniikan materiaalioppi
  - Ihalainen et al, Valmistustekniikka

  Planned learning activities and teaching methods

  Scheduled track:
  Theory lectures and excercises. Mandatory laboratory excercises.
  
  Independent track:
  If you are working a company that is in the similar industry, you can make a a larger development project within your company, which is graded and replaces the excercises within the course. Additionally you have to take the tests in the course. Please contact the lecturer on the start of the course.

  Assessment methods and criteria

  Approved excercises and exam.

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT21KM

  Further information for students

  Participation in first classroom lecture is mandatory. If student can't participate for some good reason He/She must contact the teacher before the first lecture.
  More detailed description and schedule of the course will be told in the first lecture.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Exams to upgrade grading must be taken within one year from the end of the course. These exams are to be taken in predetermined days, which are given in the first lecture.

  Students use of time and load

  Theory + laboratory excercises (60h) Excercises to be done in home (60 h)

•   Measurement and control technology EN00BH52-3004 11.01.2021-31.05.2021  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  - explain the main operating principles in measuring and controlling levels, temperatures, pressures and flows
  - realize PID controllers
  - analyze the relationship of process dynamics and PID controller tuning
  - realize and commission basic instrumentation and motor loops in programmable logic controllers (PLC).

  Prerequisites and co-requisites

  Prerequisite courses are:
  Energy engineering mathematics 2
  Instrumentation and electrification

  Course contents

  How to control automatically the level of a tank, the temperature of a fluid, the flow in a pipeline or the pressure of steam, and thus improve the energy efficiency of a process?
  How does a PID controller compute the control signal to an actuator in a feedback control loop, and how are the tuning parameters specified?
  How do differential equations and Laplace transfer function models describe process dynamics, and how are these models applied to Matlab Simulink for simulations?
  How to make a program for a measurement, feedback control or pump control in a programmable logic controller (PLC)?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Vesa Kankkunen

  Merja Mäkelä

  Mode of delivery

  20% Face-to-face, 80% Distance learning

  Recommended or required reading

  1. Lecture slides and other materials in Learn.
  2. Harju, T., Marttinen, A., Säätöpiirin virityksen perusteet, Control CAD, Espoo 2001, 166 s. Vastaava teksti on saatavissa Suomen Automaatioseuran sivuilta.
  3. Bolton, W. Instrumentation and control systems, Elsevier, UK, 2004, 339 p.
  4. Learning Environment for Papermaking and Automation, KnowPap, AEL and Prowledge, 2015, Finland.
  5. Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL and Prowledge, 2015, Finland.
  6. Sell, N. J., Process Control Fundamentals for the Pulp and Paper Industry, Tappi Press, 1995, Atlanta, USA, 612 p., ISBN 0-89852-294-3
  7. http://en.wikipedia.org/wiki/Programmable_logic_controller Programmable logic controller
  8. S7-200 Programmable Controller, System Manual, Siemens, 2008
  9. Getting started with S7-200, Manual, Siemens, 2007
  10. Getting started with S7-1200, Manual, Siemens, 2009
  11. http://www.automation.siemens.com/mcms/programmable-logic-controller/en/simatic-s7-controller/s7-1200/Pages/Default.aspx
  12. Automaatiosovellusten ohjelmistokehitys. Suunnittelun työtavat, välineet ja sovellusarkkitehtuurit. Suomen Automaatioseura ry. 2005. 152 s.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - explain main operating principles in measuring and controlling levels, temperatures, pressures and flows
  - implement PID controllers
  - analyze the relationship of process dynamics and PID controller tuning
  - implement and commission basic instrumentation and motor loops in programmable logic controllers (PLC).
  How are you able to control automatically the level of a tank, the temperature of a fluid, the flow in a
  pipeline or the pressure of steam, and thus improve the energy efficiency of a process?
  How does a PID controller compute the control signal to an actuator in a feedback control loop, and how are the tuning parameters specified?
  How do differential equations and Laplace transfer function models describe process dynamics, and how are these models applied to Matlab Simulink for simulations?
  How are you able to make program for a measurement, feedback control or pump control in a programmable logic controller (PLC)?
  
  Independent track:
  Exam and working life project.
  
  Blended track:
  Exam and RDI project

  Assessment methods and criteria

  Exam (60 %) and laboratory projects (40 %), with grades 0-5, both are expected to be accepted.

  Language of instruction

  English

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Seats

  0 - 35

  Further information for students

  Prerequisite courses are
  1. Energiatekniikan insinöörimatematiikka 2 - Energy Engineering Mathematics 2
  2. Instrumentointi ja sähköistys - Instrumentation and Electrification.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  4 credits

  Evaluation scale

  1-5

  Students use of time and load

  Lectures 36 h
  Lab projects 24 h
  Self-study 75 h

•   Mitttaus- ja säätötekniikka - Measurement and Control Technology EN00BH52-3003 31.08.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  - explain the main operating principles in measuring and controlling levels, temperatures, pressures and flows
  - realize PID controllers
  - analyze the relationship of process dynamics and PID controller tuning
  - realize and commission basic instrumentation and motor loops in programmable logic controllers (PLC).

  Prerequisites and co-requisites

  Prerequisite courses are:
  Energy engineering mathematics 2
  Instrumentation and electrification

  Course contents

  How to control automatically the level of a tank, the temperature of a fluid, the flow in a pipeline or the pressure of steam, and thus improve the energy efficiency of a process?
  How does a PID controller compute the control signal to an actuator in a feedback control loop, and how are the tuning parameters specified?
  How do differential equations and Laplace transfer function models describe process dynamics, and how are these models applied to Matlab Simulink for simulations?
  How to make a program for a measurement, feedback control or pump control in a programmable logic controller (PLC)?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Vesa Kankkunen

  Merja Mäkelä

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  1. Lecture slides and other materials in Moodle.
  2. Harju, T., Marttinen, A., Säätöpiirin virityksen perusteet, Control CAD, Espoo 2001, 166 s. Vastaava teksti on saatavissa Suomen Automaatioseuran sivuilta.
  3. Bolton, W. Instrumentation and control systems, Elsevier, UK, 2004, 339 p.
  4. Learning Environment for Papermaking and Automation, KnowPap, AEL and Prowledge, 2015, Finland.
  5. Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL and Prowledge, 2015, Finland.
  6. Sell, N. J., Process Control Fundamentals for the Pulp and Paper Industry, Tappi Press, 1995, Atlanta, USA, 612 p., ISBN 0-89852-294-3
  7. http://en.wikipedia.org/wiki/Programmable_logic_controller Programmable logic controller
  8. S7-200 Programmable Controller, System Manual, Siemens, 2008
  9. Getting started with S7-200, Manual, Siemens, 2007
  10. Getting started with S7-1200, Manual, Siemens, 2009
  11. http://www.automation.siemens.com/mcms/programmable-logic-controller/en/simatic-s7-controller/s7-1200/Pages/Default.aspx
  12. Automaatiosovellusten ohjelmistokehitys. Suunnittelun työtavat, välineet ja sovellusarkkitehtuurit. Suomen Automaatioseura ry. 2005. 152 s.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - explain main operating principles in measuring and controlling levels, temperatures, pressures and flows
  - implement PID controllers
  - analyze the relationship of process dynamics and PID controller tuning
  - implement and commission basic instrumentation and motor loops in programmable logic controllers (PLC).
  How are you able to control automatically the level of a tank, the temperature of a fluid, the flow in a
  pipeline or the pressure of steam, and thus improve the energy efficiency of a process?
  How does a PID controller compute the control signal to an actuator in a feedback control loop, and how are the tuning parameters specified?
  How do differential equations and Laplace transfer function models describe process dynamics, and how are these models applied to Matlab Simulink for simulations?
  How are you able to make program for a measurement, feedback control or pump control in a programmable logic controller (PLC)?
  
  Independent track:
  Exam and working life project.
  
  Blended track:
  Exam and RDI project

  Assessment methods and criteria

  Exam (60 %) and laboratory projects (40 %), with grades 0-5, both are expected to be accepted.

  Language of instruction

  English

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Seats

  0 - 35

  Further information for students

  Prerequisite courses are
  1. Energiatekniikan insinöörimatematiikka 2 - Energy Engineering Mathematics 2
  2. Instrumentointi ja sähköistys - Instrumentation and Electrification.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam 17.12.2020.
  Resit exam 11.1.2021.

  Students use of time and load

  Lectures 36 h
  Lab projects 24 h
  Self-study 75 h

•   Modelling and simulation of process systems EN00BH64-3004 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Timo Lyytikäinen

  Merja Mäkelä

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  1. Learn materials.
  2. Dorf, C.D., Bishop, R.H., Modern Control Systems, 10. edition or some later edition, Addison-Wesley, USA 2005, 881 s.
  3. Harju, T., Marttinen, A., Säätöpiirin virityksen perusteet, Control CAD, Espoo 2001, 166 s.

  Planned learning activities and teaching methods

  After completing this course, you will be able to
  * derive for dynamic phenomena differential equation models based on first principles
  * design and realize process experiments, analyze them and create continuous and discrete models based on sampled data
  * present the arrangement and realization of multivariable control methods used in energy production and other process industries
  * apply simulation and design program tools to the description of process systems.
  How would you create dynamic flow balance and heat balances of a flow-through tank using differential equations for Matlab Simulink simulations
  How would you realize a process experiment of a heat exchanger and work out a time-series model based on sampled data and describing heat content, using Matlab Identification Toolbox?
  Why could fuzzy logic or modelpredictive control improve the quality of products or the energy efficiency of a process plant?
  Why is Matlab Simulink very widely used as a basic modelling and simulation tool, and how are you able to utilize Matlab in simulations of processes?

  Assessment methods and criteria

  Exam (50 %) and Matlab Simulink projects (50 %), with grades 0 - 5.

  Language of instruction

  English

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Seats

  0 - 35

  Further information for students

  Prerequisite courses are
  1. Fluid Dynamics
  2. Thermodynamics and Heat Transfer
  3. Energy Engineering Mathematics 2
  4. Measurement and Control Technology,
  or related qualifications are expected.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam.

  Students use of time and load

  60 h lectures, and mathematical and Matlab Simulink based exercises
  75 h self-study

•   Occupational safety EN00BH35-3008 11.01.2021-30.04.2021  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  After the course you can:
  explain the basic principles of common workplace cooperation, together with general risks and good practices
  take into account the job and assignment-specific protective equipment and devices (hot works, occupational safety and first aid)
  evaluate the significant shortcomings in electrical safety in the working environment
  define the requirements specific to electrical work.

  Course contents

  What is a common workplace and how can accidents and occupational illnesses be prevented?
  What is the practical implementation of the occupational safety organization and what kind of general instructions and safety rules are used?
  How to identify electric safety defects and react to them?
  When is electrical work done in live working and inspection is required?

  ---

  Name of lecturer(s)

  Marko Saxell

  Teacher(s)

  Marko Saxell

  Esa Huuhtanen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Power plant processes EN00BH56-3001 31.08.2020-30.10.2020  5 credits  (ENKT17SP) +-
  Learning outcomes of the course

  After the course you can:
  explain the typical power plant processes
  calculate the parts of a whole power plant process, efficiencies and energy balances
  explain the international INES rating
  design a power plant process at a general level
  identify the power plant auxiliary systems.

  Prerequisites and co-requisites

  Basics of energy production and power plant technology
  Steam boilers
  Energy conversion processes

  Course contents

  How do the conventional powerplant work?
  How do nuclear power plant processes work?
  How are the power plant processes calculated?
  What is the INES scale?
  How are the power plant processes designed?

  ---

  Name of lecturer(s)

  Kirsi Hovikorpi

  Teacher(s)

  Kirsi Hovikorpi

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Harjoitustehtävät ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 30.10.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Power plant processes EN00BH56-3002 31.08.2020-31.10.2020  5 credits  (ENKT17SM) +-
  Learning outcomes of the course

  After the course you can:
  explain the typical power plant processes
  calculate the parts of a whole power plant process, efficiencies and energy balances
  explain the international INES rating
  design a power plant process at a general level
  identify the power plant auxiliary systems.

  Prerequisites and co-requisites

  Basics of energy production and power plant technology
  Steam boilers
  Energy conversion processes

  Course contents

  How do the conventional powerplant work?
  How do nuclear power plant processes work?
  How are the power plant processes calculated?
  What is the INES scale?
  How are the power plant processes designed?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Mode of delivery

  20% Face-to-face, 80% Distance learning

  Assessment methods and criteria

  Harjoitustehtävät ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 31.10.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  4 credits

  Evaluation scale

  1-5

•   Power plant processes EN00BH56-3004 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After the course you can:
  explain the typical power plant processes
  calculate the parts of a whole power plant process, efficiencies and energy balances
  explain the international INES rating
  design a power plant process at a general level
  identify the power plant auxiliary systems.

  Prerequisites and co-requisites

  Basics of energy production and power plant technology
  Steam boilers
  Energy conversion processes

  Course contents

  How do the conventional powerplant work?
  How do nuclear power plant processes work?
  How are the power plant processes calculated?
  What is the INES scale?
  How are the power plant processes designed?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Yliopettaja REY3

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Hyväksytyt harjoitustyöt ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Preventive maintenance EN00BH60-3001 31.08.2020-18.12.2020  5 credits  (ENKT17SP) +-
  Learning outcomes of the course

  After the course you can:
  classify equipment based on their maintenance need
  select suitable measurement methods to different destinations
  examine the problems that may arise in devices
  make conclusions in order to maintain the best performance
  use mathematics related to maintenance

  Course contents

  How is condition-based maintenance carried out?
  What are the measuring methods for maintenance?
  How are different problems solved by means of maintenance methods?
  How does maintenance affect plant condition?
  What mathematical methods can be used to analyse the maintenance data?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Marko Saxell

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Ryhmätyöt ja harjoitustehtävät (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Preventive maintenance EN00BH60-3002 31.08.2020-18.12.2020  5 credits  (ENKT17SM) +-
  Learning outcomes of the course

  After the course you can:
  classify equipment based on their maintenance need
  select suitable measurement methods to different destinations
  examine the problems that may arise in devices
  make conclusions in order to maintain the best performance
  use mathematics related to maintenance

  Course contents

  How is condition-based maintenance carried out?
  What are the measuring methods for maintenance?
  How are different problems solved by means of maintenance methods?
  How does maintenance affect plant condition?
  What mathematical methods can be used to analyse the maintenance data?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Tuomo Pimiä

  Marko Saxell

  Mode of delivery

  20% Face-to-face, 80% Distance learning

  Assessment methods and criteria

  Ryhmätyöt ja harjoitustehtävät (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  4 credits

  Evaluation scale

  1-5

•   Process Engineering EN00BH70-3003 31.08.2020-16.10.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  • describe the significance of process design in process integration
  • present main processes and machinery of process industries
  • work out the dimensioning of process machinery and compute steady states
  • define dynamic flow, heat and mass balances for simulations
  • identify authority obligations in process design.

  Course contents

  How are you able to design processes by taking into account technical, economic, safety-related and environment-related aspects?
  What kinds of machines are used in processes and how do they work?
  How do you compute the capacity of a process and its steady state?
  How do you create a dynamic process model and make a simulation program?
  Which processes need authority obligations?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Kalle Tarhonen

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  Learn materials
  Learning Environment for Papermaking and Automation, KnowPap, AEL and Prowledge, 2015, Finland.
  Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL and Prowledge, 2015, Finland.
  AutoCAD ja CADMATIC
  Matlab Simulink

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - describe the role of process design in process integration
  - present main processes and machinery of process industries
  - work out the dimensioning of process machinery and compute steady states
  - define dynamic flow, heat and mass balances for simulations
  - identify authority obligations in process design.
  How are you able to design processes by taking into account technical, economic, safety-related and environment-related aspects?
  What kinds of machines are used in processes and how are they working?
  How do you compute the capacity of a process and compute its steady state?
  How do you come to a dynamic process model and make a simulation program?
  Which processes do need authority obligations?
  
  Independent track:
  Working as a process designer and portfolio
  
  Blended track:
  Exam and design project

  Assessment methods and criteria

  Written exam, with grades 0-5, 60 %.
  Project, with grades 0-5, 40 %.
  Both should be accepted.

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 16.10.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Seats

  0 - 30

  Further information for students

  Prerequisite courses are:
  Energy Engineering Mathematics 2
  Technical visualisation and CAD
  Statics and strength of materials
  Thermodynamics and heat transfer
  The participation in design and simulation exercises according to the schedule is required.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam 28.10.2020.
  Resit exam 11.1.2021.

  Students use of time and load

  20 h lectures
  40 h supervised design and simulation exercises
  75 h self-study

•   Process control systems and communication networks EN00BH63-3003 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  - explain the layers of the OSI network model and describe the role of main protocols used in communication networks
  - present the arrangement and components of a process control system used in a process plant
  - design and configure simple automation networks and fieldbus applications
  - program and commission instrumentation and motor loops of power plant automation.

  Prerequisites and co-requisites

  Prerequisite courses are
  Basics of electrical engineering and electronics
  Measurement and control technology

  Course contents

  How do communication standards, cloud services and the Internet of Things (IoT) affect industrial networks and the development of digitalization in industrial applications?
  How is a measurement signal transferred from a sensor to a remote control room of a power plant, or a command signal from an operator to a controlled actuator?
  Which hardware and software tools do you need to be able to connect a smart level transmitter to an available control system?
  How are you able to improve the safety of power production using programmed forced control and redundancy?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Vesa Kankkunen

  Merja Mäkelä

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  - Learn
  - Learning Environment for Papermaking and Automation, KnowPap, AEL ja Prowledge 2015.
  - Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL ja Prowledge 2015.
  - ValmetDNA manuals, Valmet Automation 2011 - 2012.
  - DNAuse -operointiohje, Valmet Automation 2012.
  - Function Block CAD -käyttöohje, Valmet Automation 2011.
  - DNA Explorer -käyttöohje, Valmet Automation 2011.
  - www.valmet.com
  - http://www.siemens.fi/fi/industry/teollisuus.php
  - https://www.honeywell.com/industries/industrial
  - http://www.abb.fi/ProductGuide/?_ga=1.200027118.1505060176.1434641307
  - https://www.phoenixcontact.com/online/portal/fi

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - explain the layers of the OSI network model and describe the role of main protocols used in communication networks
  - present the arrangement and components of a process control system used in a process plant
  - design and configure simple automation networks and fieldbus applications
  - program and commission instrumentation and motor loops of power plant automation.
  How do communication standards, cloud services and Internet of Things (IoT) affect industrial networks and the development of digitalization in industrial applications?
  How is a measurement signal transferred from a sensor to a remote control room of a power plant, or a command signal from an operator to a controlled actuator?
  Which hardware and software tools do you need to be able to connect a smart level transmitter to an available control system?
  How are you able to improve the safety of power production using programmed forced control and redundancy?
  How are you able to realize measurement, open control, feedback control, on-off valve and on-off motor loops in a process control system?
  
  Independent track:
  - Exam and a working life project
  
  Blended track:
  - Exam and projects

  Assessment methods and criteria

  Exam (40 %) and laboratory projects (60 %), with grades 0-5.

  Language of instruction

  English

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Seats

  0 - 15

  Further information for students

  Prerequisite courses are
  - Basics of Electrical Engineering and Electronics
  - Instrumentation and Electrification
  - Measurement and Control Technology,
  or related qualifications are required.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam.

  Students use of time and load

  - 24 h lectures
  - 36 h supervised project working
  - 75 h self-study

•   Process engineering EN00BH70-3005 11.01.2021-31.05.2021  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  • describe the significance of process design in process integration
  • present main processes and machinery of process industries
  • work out the dimensioning of process machinery and compute steady states
  • define dynamic flow, heat and mass balances for simulations
  • identify authority obligations in process design.

  Course contents

  How are you able to design processes by taking into account technical, economic, safety-related and environment-related aspects?
  What kinds of machines are used in processes and how do they work?
  How do you compute the capacity of a process and its steady state?
  How do you create a dynamic process model and make a simulation program?
  Which processes need authority obligations?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Kalle Tarhonen

  Mode of delivery

  20% Face-to-face, 80% Distance learning

  Recommended or required reading

  Learn materials
  Learning Environment for Papermaking and Automation, KnowPap, AEL and Prowledge, 2015, Finland.
  Learning Environment for Chemical Pulping and Automation, KnowPulp, AEL and Prowledge, 2015, Finland.
  AutoCAD ja CADMATIC
  Matlab Simulink

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  - describe the role of process design in process integration
  - present main processes and machinery of process industries
  - work out the dimensioning of process machinery and compute steady states
  - define dynamic flow, heat and mass balances for simulations
  - identify authority obligations in process design.
  How are you able to design processes by taking into account technical, economic, safety-related and environment-related aspects?
  What kinds of machines are used in processes and how are they working?
  How do you compute the capacity of a process and compute its steady state?
  How do you come to a dynamic process model and make a simulation program?
  Which processes do need authority obligations?
  
  Independent track:
  Working as a process designer and portfolio
  
  Blended track:
  Exam and design project

  Assessment methods and criteria

  Written exam, with grades 0-5, 60 %.
  Project, with grades 0-5, 40 %.
  Both should be accepted.

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Seats

  0 - 30

  Further information for students

  Prerequisite courses are:
  Energy Engineering Mathematics 2
  Technical visualisation and CAD
  Statics and strength of materials
  Thermodynamics and heat transfer,
  or related qualifications are required.
  The participation in design and simulation exercises according to the schedule is required.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  4 credits

  Evaluation scale

  1-5

  Exam schedule

  Exam.

  Students use of time and load

  20 h lectures
  40 h supervised design and simulation exercises
  75 h self-study

•   Professional English KY00AA04-3160 31.08.2020-18.12.2020  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  You are able to actively use the basic professional vocabulary of your field.
  You are able to look for information in English in professional sources and apply it in different study and work related communication situations.
  You are able to communicate in English orally and in writing in various situations in your professional field.

  Prerequisites and co-requisites

  If you have been instructed to participate in the Intensive course of English, you must complete it or independently acquire the equivalent knowledge and skills before you can participate in this course.

  Course contents

  What professional vocabulary is essentially necessary?
  How to look for information in professional sources in English and how to apply this information?
  How to interact in spoken communication situations in English and how to draw up texts in English for professional purposes?
  How to communicate in study-related situations and work communities in English?

  ---

  Name of lecturer(s)

  Tarmo Ahvenainen

  Teacher(s)

  Tarmo Ahvenainen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Kielet ja viestintä, Kotka (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Professional English KY00DS47-3028 11.01.2021-30.04.2021  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  You are able to actively use the basic professional vocabulary of your field.
  You are able to look for information in English in professional sources and apply it in different study and work related communication situations.
  You are able to communicate in English in various spoken and written situations in your professional field at the European level B2.

  Prerequisites and co-requisites

  If you have been instructed to participate in the Intensive course in English, you must complete it or independently acquire the equivalent knowledge and skills before you can participate in this course.

  Course contents

  What professional vocabulary is essential in your professional field?
  How to look for information in professional sources in English and how to apply this information?
  How to interact in spoken communication situations in English and how to draw up texts in English for professional purposes?
  How to communicate in study-related situations and work communities in English?

  Assessment criteria

  Satisfactory

  Ability to communicate in English orally and in writing in various situations in the professional field mainly at the European (CEFR) level B1.

  Good

  Ability to communicate in English orally and in writing in various situations in the professional field mainly at the European (CEFR) level B2.

  Excellent

  Ability to communicate in English orally and in writing in various situations in the professional field mainly at the European (CEFR) level C1.

  ---

  Name of lecturer(s)

  Tarmo Ahvenainen

  Teacher(s)

  Tarmo Ahvenainen

  Mode of delivery

  40% Face-to-face, 60% Distance learning

  Recommended or required reading

  Opettaja jakaa Learn-alustan kautta. (not translated)

  Assessment methods and criteria

  Arviointi perustuu tenttiin, suullisiin näyttöihin ja raporttiin, jotka yksilöidään ensimmäisellä opetuskerralla. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Kielet ja viestintä, Kotka (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  3 credits

  Evaluation scale

  1-5

  Exam schedule

  Tentti viimeisellä opetuskerralla. Ensimmäisellä opetuskerralla esitellän kurssin aikataulu. (not translated)

  International connections

  Mahdollisesti yhteistyö pietarilaisen korkeakoulun kanssa, jossa työstetään energiatekniikkaan liittyvä esitys englanniksi. (not translated)

  Students use of time and load

  Lähipetus 45h, itsenäinen työskentely 88h. (not translated)

•   Professional Swedish KY00AA03-3187 11.01.2021-30.04.2021  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  You are able to function in oral and written communication situations in your own field. You are familiar with the terminology of your field and able to communicate in Swedish in professional situations.
  
  The objectives are based on the Common European Framework of Languages, level B1 and the Decree 18.12.2014/1129.
  After completing the course with a grade of 3, you are able to:
  - understand clear standard and job-related speech.
  - use basic structures reasonably well both orally and in writing.
  - speak relatively fluently in such a way that occasional mistakes in pronunciation or prosody do not lead to misunderstanding.
  - describe your education and work experience e.g. when applying for a job.
  - describe and discuss key issues of your professional field (e.g. the operation, products, processes or services of companies and/or organizations)

  Prerequisites and co-requisites

  If you have been instructed to participate in the Intensive course of Swedish, you must complete it or independently acquire the equivalent knowledge and skills before you can participate in this course.

  Course contents

  How do you use Swedish vocabulary related to education, work environment and workplace duties?
  How do you use Swedish in different communicative situations of working life, e.g. emails, telephoning and meetings?
  How do you use the basic professional vocabulary required in your field and operational environment?

  ---

  Name of lecturer(s)

  Marie Laaksonen

  Teacher(s)

  Marie Laaksonen

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  Kontakt, teknisk svenska (not translated)

  Assessment methods and criteria

  suullinen ja kirjallinen taito arvioidaan kokeiden perusteella, valtakunnalliset kriteerit (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Seats

  20 - 40

  Further information for students

  Lähiopetuksessa 50 % minimiläsnäolo (not translated)

  Unit, in charge

  Kielet ja viestintä, Kotka (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Students use of time and load

  130 t (not translated)

•   Putkistojen ja pumppausjärjestelmien toiminta (not translated) AV00DN78-3001 21.09.2020-30.11.2020  3 credits  (AVERKT, ...) +-
  Course contents

  • Putkistojen mitoitus
  • Pumppujen valinta ja mitoitus (not translated)

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Hannu Sarvelainen

  Mode of delivery

  67% Face-to-face, 33% Distance learning

  Language of instruction

  Tuition in Finnish

  Timing

  21.09.2020 - 30.11.2020

  • 3 credits

  Group(s)

  • AVERKT
  • AVKTDAKKDI20K

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

•   Renewable Energy (not translated) AV00EF92-3001 01.09.2020-18.12.2020  5 credits +-
  Learning outcomes of the course

  After this study unit, a student is able toexplain significant renewable energy sources and their trends in Finland and globallydescribe how renewable energy sources can be technically utilizedevaluate the profitability of different renewable energy sources.

  Course contents

  HydropowerWind powerSolar powerWood, peat and biomass energyWaste energyGeothermal powerOcean energyHydrogen technology and fuel cells.

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Mode of delivery

  Distance learning

  Recommended or required reading

  1. Ready-made course materials and recordings in Learn https://learn.xamk.fi/course/view.php?id=4764.

  Planned learning activities and teaching methods

  After completing this course, you will be able to
  • list main renewable energy sources in Finland and globally
  • identify the role of large-scale centralized and small-scale distributed energy production
  • describe the basic principles of energy production processes using renewable sources
  • analyze the energy efficiency of renewable sources
  • evaluate the importance of production methods and subsidies in a national and international context.
  • work up collaboratively in internet.
  How are photosynthesis and carbon cycle related to renewable energy?
  In which level hydro, solarpower is produced in large-scale centralized and small-scale distributed energy production?
  Which machinery and devices are needed to produce heat and electricity from renewable sources and waste?
  How would you compute the operating efficiency of a distant-monitored solar panel or solar collector, and how would you optimize the production?
  In which way do the production subsidies affect the development of production and price in Finland and in Germany, for example?

  Assessment methods and criteria

  The examinations are scheduled. All chosen four parts have a weight of 25 % in the final course grade.

  Language of instruction

  English

  Timing

  01.09.2020 - 18.12.2020

  • 5 credits

  Seats

  0 - 50

  Unit, in charge

  Open UAS and Continuing Education

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  5 credits

  Evaluation scale

  1-5

  Exam schedule

  CHOICE OF FOUR ITEMS:
  • Self-study 1 Solar power with an exam 30.9.2020
  • Self-study 2 Wind power with an exam 28.10.2020
  • Self-study 3 Bio energy with an exam 25.11.2020
  • Self-study 4 Hydro power with an exam 16.12.2020
  • Project 1 Animation, deadline 30.11.2020
  • Project 2 Solar thermal system, deadline 30.9.2020

  Students use of time and load

  4 h introduction lectures.
  131 h self-study.

•   Renewable energy EN00BH44-3004 31.08.2020-31.01.2021  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  list main renewable energy sources in Finland and globally
  identify the role of large-scale centralized and small-scale distributed energy production
  describe the basic principles of energy production processes using renewable sources
  analyze the energy efficiency of renewable sources
  evaluate the importance of production methods and subsidies in a national and international context.

  Prerequisites and co-requisites

  Energy engineering mathematics 1
  Basics of energy technology and power stations
  Fuels and heating systems

  Course contents

  How are photosynthesis and carbon cycle related to renewable energy?
  At which level are hydro and solarpower produced in large-scale centralized and small-scale distributed energy production?
  Which machinery and devices are needed to produce heat and electricity from renewable sources and waste?
  How would you compute the operating efficiency of a distant-monitored solar panel or solar collector, and how would you optimize the production?
  In which way do the production subsidies affect the development of production and price in Finland and in Germany, for example?

  ---

  Name of lecturer(s)

  Jyri Mulari

  Teacher(s)

  Jyri Mulari

  Merja Mäkelä

  Marko Saxell

  Mode of delivery

  Face-to-face

  Recommended or required reading

  Jaetaan ja osoitetaan Learn-alustalla (not translated)

  Assessment methods and criteria

  Kolme erillistä osaa, jotka arvostellaan erikseen ja on kaikki läpäistävä. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 31.01.2021

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

  Exam schedule

  Kolme erillistä tenttiä, jotka kaikki on läpäistävä.
  Learn-alustalla ilmoitetaan toteutuksen alussa muut vaaditut suoritukset ja määräajat. (not translated)

•   Statics and strength of materials EN00BH40-3005 31.08.2020-18.12.2020  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  Opintojakson suoritettuasi osaat:
  yhdistää voimavektorit ja jakaa voimien resultantin komponentteihin
  yhdistää voimasysteemin ja ratkaista sen tasapainoyhtälöt
  määrittää poikkileikkauksen painopisteen
  määrittää kannattimen rasitukset ja piirtää voima- ja momenttikuviot
  laskea normaali- ja leikkausjännityksiä
  laskea materiaalivahvuuksia materiaalin ominaisuuksien ja varmuusluvun avulla
  määrittää sauvan muodonmuutoksen ja lämpöjännityksen
  määrittää niitti- ja ruuviliitoksen jännitykset ja mitoittaa liitoksen
  mitoittaa taivutuspalkin ja määrittää sen taipuman
  mitoittaa voimansiirtoakselin vääntöjännityksen ja kiertymän perusteella
  mitoittaa puristussauvan eri nurjahdustapausten perusteella (not translated)

  Prerequisites and co-requisites

  Materiaali- ja valmistustekniikka
  Insinöörimatematiikka 1
  Fysiikka (not translated)

  Course contents

  Mihin mekaniikkaa ja lujuusoppia tarvitaan?
  Miten yhdistän voimavektoreita ja miten jaan voiman
  komponentteihin?
  Miten voimasysteemi yhdistetään momentin avulla?
  Miten ratkaistaan tukivoimat?
  Mitä ovat kappaleen sisäiset rasitukset ja miten ne syntyvät?
  Mitä tarkoitetaan lujuusopin käsitteillä venymä, jännitys, kimmokerroin, neliömomentti, taivutusvastus, jäykkyys, hoikkuus, yms.
  Miten ja miksi käytetään varmuuslukua?
  Miten mitoitan taivutuspalkin?
  Miten mitoitan voimansiirtoakselin?
  Miten mitoitan palkkinosturin ja sen osia? (not translated)

  ---

  Name of lecturer(s)

  Kalle Tarhonen

  Teacher(s)

  Kalle Tarhonen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Steam boilers EN00BH51-3003 31.08.2020-18.12.2020  5 credits  (ENKT18SP) +-
  Learning outcomes of the course

  After the course you can:
  - calculate the power of heat exchangers in a power plant and the efficiency of a boiler
  - calculate the reactions of combustion and emissions
  - explain the characteristics of the various boiler types and operating principles
  - explain boiler use and operation.

  Prerequisites and co-requisites

  Requires basic knowledge of energy technology, mathematics and physics (solving equations, basic units, units)

  Course contents

  How is the power plant boiler efficiency calculated and how are the boiler heat exchangers designed?
  What are the chemical reactions of combustion and what emissions do they form?
  What is the meaning of boiler operation and real-time condition monitoring?
  What are the most common boiler types?
  What is meant by boiler preservation, pickling and magnetite film run?

  ---

  Name of lecturer(s)

  Anne Gango

  Teacher(s)

  Anne Gango

  Hannu Sarvelainen

  Kirsi Hovikorpi

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Harjoitustehtävät ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT18SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Steam boilers EN00BH51-3005 11.01.2021-31.05.2021  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  After the course you can:
  - calculate the power of heat exchangers in a power plant and the efficiency of a boiler
  - calculate the reactions of combustion and emissions
  - explain the characteristics of the various boiler types and operating principles
  - explain boiler use and operation.

  Prerequisites and co-requisites

  Requires basic knowledge of energy technology, mathematics and physics (solving equations, basic units, units)

  Course contents

  How is the power plant boiler efficiency calculated and how are the boiler heat exchangers designed?
  What are the chemical reactions of combustion and what emissions do they form?
  What is the meaning of boiler operation and real-time condition monitoring?
  What are the most common boiler types?
  What is meant by boiler preservation, pickling and magnetite film run?

  ---

  Name of lecturer(s)

  Tuomo Pimiä

  Teacher(s)

  Anne Gango

  Tuomo Pimiä

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Hyväksytyt harjoitustyöt ja tentit. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.05.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Study and career planning KY00DS63-3008 24.08.2020-31.12.2023  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  You act responsibly as a student and a member of the university community.
  You are able to set learning objectives, plan your study and career path, follow your progress in studies and assess your learning.
  You are able to improve your working life competencies.
  You know how to act according to the ethical principles of your field.
  You are able to promote your skills and competencies.

  Course contents

  What is Xamk like as a study community and learning environment?
  How do you create a personal study and career plan?
  How do you identify your skills and competences?
  How do you improve your general competences?
  What are your profession and line of work like?
  What ethical principles are relevant to your field?
  How do you promote your competences and strengthen your skills with respect to applying for jobs?
  How do you enhance continuous learning?

  ---

  Name of lecturer(s)

  Vesa Kankkunen

  Teacher(s)

  Vesa Kankkunen

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Planned learning activities and teaching methods

  Työviikkopohjainen oppimisväylä:
  Opintojakso sisältää lähiopetusta, harjoitustehtäviä ja itsenäistä opiskelua
  
  Opintoja nopeuttava oppimisväylä:
  Opiskelija osallistuu opetukseen tarvittavin osin ja tekee oppimistehtäviä Learn -alustalla
  
  Työhön integroitu oppimisväylä:
  Opiskelija osallistuu opetukseen tarvittavin osin ja tekee oppimistehtäviä Learn -alustalla. (not translated)

  Assessment methods and criteria

  Hyväksytyn suorituksen saa osallistumalla kontaktitunneille ja tekemällä harjoitustehtävät. (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  24.08.2020 - 31.12.2023

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Seats

  0 - 60

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  Approved/Failed

•   Study and career planning KY00DS63-3101 11.01.2021-31.12.2023  5 credits  (ENKT21KM) +-
  Learning outcomes of the course

  You act responsibly as a student and a member of the university community.
  You are able to set learning objectives, plan your study and career path, follow your progress in studies and assess your learning.
  You are able to improve your working life competencies.
  You know how to act according to the ethical principles of your field.
  You are able to promote your skills and competencies.

  Course contents

  What is Xamk like as a study community and learning environment?
  How do you create a personal study and career plan?
  How do you identify your skills and competences?
  How do you improve your general competences?
  What are your profession and line of work like?
  What ethical principles are relevant to your field?
  How do you promote your competences and strengthen your skills with respect to applying for jobs?
  How do you enhance continuous learning?

  ---

  Name of lecturer(s)

  Vesa Kankkunen

  Teacher(s)

  Vesa Kankkunen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 31.12.2023

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT21KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Technical drawing and CAD TY00DW38-3004 11.01.2021-30.04.2021  5 credits  (ENKT20SP) +-
  Learning outcomes of the course

  You know how to use CAD program basics and can create architectural and construction drawings.

  Course contents

  Core content
  What are marks of drawing?
  How to use basic commands in your CAD program?
  How does scale influence drawing?
  How does the coordinate system facilitate drawing?
  How to create dimension lines in drawings?
  How do I print to scale?
  
  Complementary knowledge
  How is a CAD program utilized in making wall constructions?
  How to make the facades of ground plans?
  
  Specialist knowledge
  How to use facade products in facades?
  How to draw the markings for a plot plan?
  How to create different printouts?
  How to create construction drawings?

  ---

  Name of lecturer(s)

  Kalle Tarhonen

  Teacher(s)

  Kalle Tarhonen

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  Virtuaalimateriaali (not translated)

  Planned learning activities and teaching methods

  Työviikkopohjainen oppimisväylä:
  Luennoilla käsitellään koneenpiirtämisen teoriaa ja tehdään harjoituksia nykyaikaisilla ohjelmistoilla (Inventor, Autocad)
  Harjoituksia teet myös omalla ajalla, ja tähän tarvitset omaa tietokonetta.
  
  Opintoja nopeuttava oppimisväylä:
  Jos työskenetelet alan yrityksessä, voit korvata osan harjoitustöistä projektitehtävällä.
  
  Työhön integroitu oppimisväylä:
  Voit suorittaa harjoitukset itsenäisesti videoita seuraamalla, ja tenttiä teoriaosuuden (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Students use of time and load

  Luentoja ja ohjattuja harjoituksia 66 h
  Omassa tahdissa työskentelyä 60 h
  Tentti + tenttiin kertaus 9 h (not translated)

•   Technical drawing and CAD TY00DW38-3010 11.01.2021-30.04.2021  5 credits  (ENKT20SM) +-
  Learning outcomes of the course

  You know how to use CAD program basics and can create architectural and construction drawings.

  Course contents

  Core content
  What are marks of drawing?
  How to use basic commands in your CAD program?
  How does scale influence drawing?
  How does the coordinate system facilitate drawing?
  How to create dimension lines in drawings?
  How do I print to scale?
  
  Complementary knowledge
  How is a CAD program utilized in making wall constructions?
  How to make the facades of ground plans?
  
  Specialist knowledge
  How to use facade products in facades?
  How to draw the markings for a plot plan?
  How to create different printouts?
  How to create construction drawings?

  ---

  Name of lecturer(s)

  Kalle Tarhonen

  Teacher(s)

  Kalle Tarhonen

  Mode of delivery

  Distance learning

  Recommended or required reading

  Virtuaalimateriaali
  Autodesk Inventor- ja Autocad-ohjelmistot (not translated)

  Planned learning activities and teaching methods

  Teet Learnin avulla ohjattuja harjoituksia Autodeskin tuotteiden avulla. Samalla opiskelet koneenpiirtämisen teoriaa ja teet oppimista arvioivia testejä. (not translated)

  Assessment methods and criteria

  Hyväksytyt harjoitustyöt ja tentti (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT20SM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  eCampus

  Virtual proportion

  5 credits

  Evaluation scale

  1-5

  Students use of time and load

  Luentoja ja ohjattuja harjoituksia 66 h
  Omassa tahdissa työskentelyä 60 h
  Tentti + tenttiin kertaus 9 h (not translated)

•   Thermodynamics and heat transfer EN00BH48-3003 31.08.2020-18.12.2020  5 credits  (ENKT19KM) +-
  Learning outcomes of the course

  You are able to use the basic concepts of quantities and units of thermodynamics.
  You are able to use the concepts of thermodynamics laws.
  You know the principles of heat transfer.
  You know how to apply your knowledge to different environments and systems.
  You can solve the equations of thermodynamics quantities.
  You are able to use mathematical methods to solve technical problems of equipments and processes.
  You know how to analyze and dimension heat exchangers.

  Prerequisites and co-requisites

  Prerequisities: Energy engineering physics course

  Course contents

  What are the quantities and units of thermodynamics?
  How to use the laws of thermodynamics?
  What is an energy conversion process?
  How to form and solve the equations of quantities of thermodynamics?
  How to use numerical methods and matrices to design and dimension systems?
  What are the basic principles of heat transfer?
  How to dimension heat exchangers?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Timo Lyytikäinen

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Language of instruction

  Tuition in Finnish

  Timing

  31.08.2020 - 18.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT19KM

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Thermodynamics and heat transfer EN00BH48-3005 11.01.2021-30.04.2021  5 credits  (ENKT19SP) +-
  Learning outcomes of the course

  You are able to use the basic concepts of quantities and units of thermodynamics.
  You are able to use the concepts of thermodynamics laws.
  You know the principles of heat transfer.
  You know how to apply your knowledge to different environments and systems.
  You can solve the equations of thermodynamics quantities.
  You are able to use mathematical methods to solve technical problems of equipments and processes.
  You know how to analyze and dimension heat exchangers.

  Prerequisites and co-requisites

  Prerequisities: Energy engineering physics course

  Course contents

  What are the quantities and units of thermodynamics?
  How to use the laws of thermodynamics?
  What is an energy conversion process?
  How to form and solve the equations of quantities of thermodynamics?
  How to use numerical methods and matrices to design and dimension systems?
  What are the basic principles of heat transfer?
  How to dimension heat exchangers?

  ---

  Name of lecturer(s)

  Hannu Sarvelainen

  Teacher(s)

  Timo Lyytikäinen

  Hannu Sarvelainen

  Mode of delivery

  Face-to-face

  Assessment methods and criteria

  Kaksi välikoetta ja palautettavia kotitehtäviä (not translated)

  Language of instruction

  Tuition in Finnish

  Timing

  11.01.2021 - 30.04.2021

  Enrollment date

  01.10.2020 - 15.10.2020

  • 5 credits

  Group(s)

  • ENKT19SP

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Evaluation scale

  1-5

•   Valvomo-operointi ja simulointi - Control Room Operation and Simulation EN00BH57-3001 05.10.2020-14.12.2020  5 credits  (ENKT17SM) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  describe the cooperation of main machinery and other process devices of a power plant
  analyze the working principles of main measurement, control, valve and motor loops in power plant processes
  present the arrangement and operation of process control systems in energy production processes
  use human machine interfaces (HMI) of process control systems
  run power plant simulators and analyze power plant processes related to them.

  Prerequisites and co-requisites

  Prerequisite courses are:
  Power Plant Processes
  Measurement and Control Technology

  Course contents

  How are fuel and air feed, combustion and flue gases, water feed, steam production and power generation functionally related to each other?
  How are you able to affect the production of high pressure steam, the electric power of a turbine or the toxic emissions of flue gases?
  What kinds of control systems are needed in large-scale, centralized or small-scale, distributed energy production?
  How should an operator take the fuel feed into a manual mode or start a feed water pump?
  How should we take care of functional safety in energy production?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Mode of delivery

  20% Face-to-face, 80% Distance learning

  Recommended or required reading

  1. Lecture slides and other materials in Learn.
  2. Joronen, T., Kovacs, J., Majanne, Y., Voimalaitosautomaatio. Suomen Automaatioseura ry 2007. 276 s. Kappaleet 1, 9 ja 10.
  3. Related material in English, given in Learn.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  * describe the cooperation of main machinery and other process devices of a power plant
  * analyze the working principles of main measurement, control, valve and motor loops in power plant processes
  * present the arrangement and operation of process control systems in energy production processes
  * use human machine interfaces (HMI) of process control systems
  * run power plant simulators and analyze power plant processes related to them.
  How are fuel and air feed, combustion and flue gases, water feed, steam production and power generation functionally related to each other?
  How are you able to affect the production of high pressure steam, the electric power of a turbine or the toxic emissions of flue gases?
  What kinds of control systems are needed in large-scale, centralized or small-scale, distributed energy production?
  How should an operator take the fuel feed into a manual mode or start a feed water pump?
  How should we take care of functional safety in energy production?
  
  Independent track:
  Exam and power plant experience report
  
  Blended track:
  Exam and power plant experience report

  Assessment methods and criteria

  Exam (60 %) and simulation exercises (40 %), with grades 0-5, both accepted.

  Language of instruction

  English

  Timing

  05.10.2020 - 14.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SM

  Seats

  0 - 30

  Further information for students

  Prerequisite courses are
  1. Power Plant Processes or Steam Boilers
  2. Measurement and Control Technology,
  or related qualifications.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  4 credits

  Evaluation scale

  1-5

  Students use of time and load

  * 12 h lectures
  * (16 + 4) h supervised simulation exercises
  * 103 h self-study

•   Valvomo-operointi ja simulointi - Control Room Operation and Simulation EN00BH57-3002 05.10.2020-14.12.2020  5 credits  (ENKT17SP) +-
  Learning outcomes of the course

  After completing this course, you will be able to
  describe the cooperation of main machinery and other process devices of a power plant
  analyze the working principles of main measurement, control, valve and motor loops in power plant processes
  present the arrangement and operation of process control systems in energy production processes
  use human machine interfaces (HMI) of process control systems
  run power plant simulators and analyze power plant processes related to them.

  Prerequisites and co-requisites

  Prerequisite courses are:
  Power Plant Processes
  Measurement and Control Technology

  Course contents

  How are fuel and air feed, combustion and flue gases, water feed, steam production and power generation functionally related to each other?
  How are you able to affect the production of high pressure steam, the electric power of a turbine or the toxic emissions of flue gases?
  What kinds of control systems are needed in large-scale, centralized or small-scale, distributed energy production?
  How should an operator take the fuel feed into a manual mode or start a feed water pump?
  How should we take care of functional safety in energy production?

  ---

  Name of lecturer(s)

  Merja Mäkelä

  Teacher(s)

  Merja Mäkelä

  Mode of delivery

  80% Face-to-face, 20% Distance learning

  Recommended or required reading

  1. Lecture slides and other materials in Learn.
  2. Joronen, T., Kovacs, J., Majanne, Y., Voimalaitosautomaatio. Suomen Automaatioseura ry 2007. 276 s. Kappaleet 1, 9 ja 10.
  3. Related material in English, given in Learn.

  Planned learning activities and teaching methods

  Scheduled track:
  After completing this course, you will be able to
  * describe the cooperation of main machinery and other process devices of a power plant
  * analyze the working principles of main measurement, control, valve and motor loops in power plant processes
  * present the arrangement and operation of process control systems in energy production processes
  * use human machine interfaces (HMI) of process control systems
  * run power plant simulators and analyze power plant processes related to them.
  How are fuel and air feed, combustion and flue gases, water feed, steam production and power generation functionally related to each other?
  How are you able to affect the production of high pressure steam, the electric power of a turbine or the toxic emissions of flue gases?
  What kinds of control systems are needed in large-scale, centralized or small-scale, distributed energy production?
  How should an operator take the fuel feed into a manual mode or start a feed water pump?
  How should we take care of functional safety in energy production?
  
  Independent track:
  Exam and power plant experience report
  
  Blended track:
  Exam and power plant experience report

  Assessment methods and criteria

  Exam (60 %) and simulation exercises (40 %), with grades 0-5, both accepted.

  Language of instruction

  English

  Timing

  05.10.2020 - 14.12.2020

  Enrollment date

  15.08.2020 - 04.09.2020

  • 5 credits

  Group(s)

  • ENKT17SP

  Seats

  0 - 30

  Further information for students

  Prerequisite courses are
  1. Power Plant Processes or Steam Boilers
  2. Measurement and Control Technology,
  or related qualifications.

  Unit, in charge

  Rakennus- ja energiatekniikan koulutusyksikkö (not translated)

  Programme(s)

  Degree Programme in Energy Engineering

  Unit location

  Kotka Campus

  Virtual proportion

  1 credits

  Evaluation scale

  1-5

  Students use of time and load

  * 36 h lectures
  * 24 h supervised simulation exercises (100% presence demand)
  * 75 h self-study