Course Details
Computer modeling 1
Academic Year 2025/26
NTA039 course is part of 1 study plan
NPC-EVB Summer Semester 1st year
Schedule:
1. Modeling and simulation of time-based heat conduction - power and surface temperatures of thermally activated structures.
2. Numerical modeling of time-uninterrupted heat conduction - reheating and cooling of the wall.
3. Simulation of time-uninterrupted heat conduction - reheating and cooling of thermally activated structures.
4. Modeling the energy performance of a building I. Marginal conditions of simulations. Climate data, use profile, regulation.
5. Modeling the energy performance of a building II - a detailed model of the building's thermal load.
6. Modeling the energy performance of TZB I systems - heating, ventilation and cooling systems.
7. Modeling of energy performance of TZB II systems - dynamic behavior of heating and cooling bodies.
1. Modeling and simulation of time-based heat conduction - power and surface temperatures of thermally activated structures.
2. Numerical modeling of time-uninterrupted heat conduction - reheating and cooling of the wall.
3. Simulation of time-uninterrupted heat conduction - reheating and cooling of thermally activated structures.
4. Modeling the energy performance of a building I. Marginal conditions of simulations. Climate data, use profile, regulation.
5. Modeling the energy performance of a building II - a detailed model of the building's thermal load.
6. Modeling the energy performance of TZB I systems - heating, ventilation and cooling systems.
7. Modeling of energy performance of TZB II systems - dynamic behavior of heating and cooling bodies.
Credits
2 credits
Language of instruction
Czech
Semester
summer
Course Guarantor
Institute
Forms and criteria of assessment
course-unit credit
Entry Knowledge
Prerequisites: Knowledge of physical laws in the field of heat transfer and materials and thermomechanics. Basic knowledge of numerical methods. Knowledge of heating, ventilation and cooling systems of buildings. Knowledge of indoor climate of buildings.
Basic Literature
KRAJČÍK, Michal a Ondřej ŠIKULA, 2020. Heat storage efficiency and effective thermal output: Indicators of thermal response and output of radiant heating and cooling systems: Indicators of thermal response and output of radiant heating and cooling systems. Energy and Buildings. 229, 110524. ISSN 0378-7788. Dostupné z: doi:https://doi.org/10.1016/j.enbuild.2020.110524 (en)
ČSN EN ISO 10211-1, 2009. Tepelné mosty ve stavebních konstrukcích - Tepelné toky a povrchové teploty: Podrobné výpočty. Praha: ČNI. (cs)
ČSN EN ISO 10211-2, 2002. ČSN EN ISO 10211-2 Tepelné mosty ve stavebních konstrukcích - Tepelné toky a povrchová teplota - Část 2: Lineární tepelné mosty. 1. Praha: ČNI. (cs)
ISO 11855-2, 2012. ISO 11855-2 Building Environment Design. Design, Construction and Operation of Radiant Heating and Cooling Systems. Geneva: ISO. (cs)
PATANKAR, Suhas V, 1980. Numerical heat transfer and fluid flow. 1. Bristol, PA: Taylor, xiii, 197 s. Series in computational and physical processes mechanics and thermal sciences. ISBN 08-911-6522-3. (en)
ŠIKULA, Ondřej, 2009. Manuál k softwaru CalA. Brno: Tribun EU. ISBN 978-80-7399-879-0. (cs)
ČSN EN ISO 10211-1, 2009. Tepelné mosty ve stavebních konstrukcích - Tepelné toky a povrchové teploty: Podrobné výpočty. Praha: ČNI. (cs)
ČSN EN ISO 10211-2, 2002. ČSN EN ISO 10211-2 Tepelné mosty ve stavebních konstrukcích - Tepelné toky a povrchová teplota - Část 2: Lineární tepelné mosty. 1. Praha: ČNI. (cs)
ISO 11855-2, 2012. ISO 11855-2 Building Environment Design. Design, Construction and Operation of Radiant Heating and Cooling Systems. Geneva: ISO. (cs)
PATANKAR, Suhas V, 1980. Numerical heat transfer and fluid flow. 1. Bristol, PA: Taylor, xiii, 197 s. Series in computational and physical processes mechanics and thermal sciences. ISBN 08-911-6522-3. (en)
ŠIKULA, Ondřej, 2009. Manuál k softwaru CalA. Brno: Tribun EU. ISBN 978-80-7399-879-0. (cs)
Recommended Reading
Offered to foreign students
Not to offer
Course on BUT site
Exercise
13 weeks, 2 hours/week, compulsory
Syllabus
- 1. Modeling and simulation of time-based heat conduction - power and surface temperatures of thermally activated structures.
- 2. Numerical modeling of time-uninterrupted heat conduction - reheating and cooling of the wall.
- 3. Simulation of time-uninterrupted heat conduction - reheating and cooling of thermally activated structures.
- 4. Modeling the energy performance of a building I. Marginal conditions of simulations. Climate data, use profile, regulation.
- 5. Modeling the energy performance of a building II - a detailed model of the building's thermal load.
- 6. Modeling the energy performance of TZB I systems - heating, ventilation and cooling systems.
- 7. Modeling of energy performance of TZB II systems - dynamic behavior of heating and cooling bodies.