Course Details

Theory of Energy and Environment of Buildings

Academic Year 2023/24

DTB043 course is part of 4 study plans

DPC-S Winter Semester 2nd year

DPA-S Winter Semester 2nd year

DKC-S Winter Semester 2nd year

DKA-S Winter Semester 2nd year

Solution of sectorial problem from selected field in energy balance of buildings, energy performance of building services and building environment completed to theoretical and in some case experimental papers.

Course Guarantor

Institute

Objective

Theoretical and experimental knowledge required for solution of energy balace of buildings, heat and mass transfer in building services systems and assuring of indoor environment quality.

Syllabus

1. Submission and definition of subject.
2. Individual study of technical literature.
3. Creation of literature backround research.
4. Creation of model for problem solution.
5. Definition of problem boundary conditions.
6. Definition of simplification conditions for problem solution.
7. Self theoretical solution of problem.
8. Experimental calibration of theoretical solution of problem.
9. Changes and verification of theoretical solution of problem.
10. Elaboration and generalization of solving problem outputs.
11.–12. Elaboration of writen output.
13. Prezetation and discussion about compiled work (papers).

Prerequisites

Applied physics, applied mathematics, computer modelling, english language, basic of experimental measurements in Building services, basics of energy evaluation of buildings, indoor building microclimate.

Language of instruction

Czech

Credits

8 credits

Semester

winter

Forms and criteria of assessment

examination

Specification of controlled instruction, the form of instruction, and the form of compensation of the absences

Extent and forms are specified by guarantor’s regulation updated for every academic year.

Offered to foreign students

Not to offer

Course on BUT site

Lecture

13 weeks, 3 hours/week, elective

Syllabus

1. Submission and definition of subject. 2. Individual study of technical literature. 3. Creation of literature backround research. 4. Creation of model for problem solution. 5. Definition of problem boundary conditions. 6. Definition of simplification conditions for problem solution. 7. Self theoretical solution of problem. 8. Experimental calibration of theoretical solution of problem. 9. Changes and verification of theoretical solution of problem. 10. Elaboration and generalization of solving problem outputs. 11.–12. Elaboration of writen output. 13. Prezetation and discussion about compiled work (papers).