BMEEOEMMS51_EN: Subject Datasheet

Subject Datasheet

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I. Tantárgyleírás

1. Alapadatok

1.1 Tantárgy neve

Building Physics

1.2 Azonosító (tantárgykód)

BMEEOEMMS51

1.3 Tantárgy jellege

Kontaktórás tanegység

1.4 Óraszámok

Típus	Óraszám / (nap)
Előadás (elmélet)	2

1.5 Tanulmányi teljesítményértékelés (minőségi értékelés) típusa

Félévközi érdemjegy

1.6 Kreditszám

1.7 Tárgyfelelős

név	Dr. Nagy Balázs
beosztás	Egyetemi docens
email	nagy.balazs@emk.bme.hu

1.8 Tantárgyat gondozó oktatási szervezeti egység

Építőanyagok és Magasépítés Tanszék

1.9 A tantárgy weblapja

https://epito.bme.hu/BMEEOEMMS51
https://edu.epito.bme.hu/course/view.php?id=1977

1.10 Az oktatás nyelve

magyar

1.11 Tantárgy típusa

Kötelezően választható a Szerkezet-építőmérnök (MSc) szakon

1.12 Előkövetelmények

1.13 Tantárgyleírás érvényessége

2022. szeptember 1.

2. Célkitűzések és tanulási eredmények

2.1 Célkitűzések

The aim of the course is to provide the student with the principles of modern building physics, the theory of heat conduction, heat flow, heat radiation, heat transport processes, technical alternatives for heat loss reduction in buildings and structures, the role of outdoor and indoor environmental boundary conditions for building physics calculations and how to determine them, analytical thermal calculations of building structures, the theory and practical application of unsteady, transient, non-linear and multi-dimensional thermal processes, coupled heat, air and moisture transport simulations and basic knowledge of urban building physics.

2.2 Tanulási eredmények

A tantárgy sikeres teljesítése utána a hallgató

A. Tudás

know the commonly used concepts of modern building physics,
knowledge of unsteady, transient, non-linear, complex and multidimensional heat and mass transfer processes,
knowledge of standardized and detailed calculation procedures for building structures in terms of thermal and moisture engineering,
knowledge of the specific building physics of ground-contact structures,
knowledge of the outdoor and indoor environmental boundary conditions essential for building physics calculations and numerical simulations,
knowledge of the principles of coupled heat, air, and moisture transport simulations,
knowledge of the commonly used concepts of urban building physics and building aerodynamics,
knowledge of laboratory and field-testing procedures for building physics and building energy.

B. Képesség

carry out standardized and detailed thermal calculations of building structures,
be able to include the boundary conditions of building physics calculations and numerical simulations, depending on the indoor and outdoor environment,
able to perform coupled heat, air, and moisture transport simulations,
ability to perform building physics diagnostic tests, use infrared thermography,
able to identify heat loss reduction alternatives for buildings and structures,
the ability to solve complex and computationally demanding problems, based on knowledge of building physics,
express ideas in an organized way, both orally and in writing.

C. Attitűd

collaborate with the lecturer and fellow students to develop their knowledge,
continuously expand their knowledge by acquiring new knowledge,
is open to the use of information technology tools,
strive to learn and routinely use the tools needed to solve problems in building physics,
strive for accurate and error-free problem solving,
to apply the principles of energy efficiency and environmental awareness in solving building physics problems.

D. Önállóság és felelősség

independently think through building physics problems and problems and solve them based on given resources,
independently solve a homework assignment,
is open to well-founded critical comments,
collaborate with fellow students as part of a team in certain situations,
uses a systematic thinking approach.

2.3 Oktatási módszertan

Lectures, computational and software exercises, written and oral communication, IT tools and techniques, group work, and work organization techniques.

2.4 Részletes tárgyprogram

Week	Topics of lectures and/or exercise classes
1.	Principles of heat transport processes: heat conduction, heat flow, heat radiation I.
2.	Principles of heat transport processes: heat conduction, heat flow, heat radiation II.
3.	History of the development of standards and legislation on building physics and energy performance
4.	Detailed thermal calculations of building structures - MSZ EN ISO standard calculations I.
5.	Detailed thermal calculations of building structures - MSZ EN ISO standard calculations II.
6.	Basics of transient thermal calculations. Summary.
7.	Overview.
8.	Coupled heat, air and moisture transport simulations for structural engineers I.
9.	Coupled heat, air and moisture transport simulations for structural engineers II.
10.	Building physics laboratory and on-site diagnostic studies.
11.	Building physics development of traditional and modern thermal insulation materials and building systems
12.	Building and urban scale building physics simulations and fundamentals of building aerodynamics. Building physics from BIM principles. Air tightness of buildings.
13.	Building physics case studies from the Hungarian construction industry, building defects and their prevention
14.	Summary, overview.

A félév közbeni munkaszüneti napok miatt a program csak tájékoztató jellegű, a pontos időpontokat a tárgy honlapján elérhető "Részletes féléves ütemterv" tartalmazza.

2.5 Tanulástámogató anyagok

Course materials uploaded to edu.epito.bme.hu
Theodore L. Bergman, Adrienne S. Lavine, Frank P. Incropera, David P. DeWitt (2011): Fundamentals of Heat and Mass Transfer, John Wiley & Sons , 7th ed., p. 1076
Hugo Hens (2012): Building Physics: Heat, Air and Moisture, Fundamentals and Engineering Methods with Examples and Exercises, Ernst & Sohn, 2nd ed., p. 324
Hugo Hens (2010): Applied Building Physics: Boundary Conditions, Building Performance and Material Properties, Ernst & Sohn, p. 319
João M.P.Q. Delgado, Eva Barreira, Nuno M.M. Ramos, Vasco Peixoto de Freitas (2013): Hygrothermal Numerical Simulation Tools Applied to Building Physics, Springer, p. 72
MSZ EN ISO standards

2.6 Egyéb tudnivalók

Attendance is compulsory for at least 50% of the lectures.

2.7 Konzultációs lehetőségek

As indicated on the department's website, or by prior arrangement by e-mail or MS Teams: nagy.balazs@emk.bme.hu

Jelen TAD az alábbi félévre érvényes:

Inactive courses

II. Tárgykövetelmények

3. A tanulmányi teljesítmény ellenőrzése és értékelése

3.1 Általános szabályok

The assessment of the learning outcomes in 2.2 is based on a test, a homework assignment and active participation in lectures (partial assessment).

3.2 Teljesítményértékelési módszerek

Evaluation form	Abbreviation	Assessed learning outcomes
test	ZH	A.1-A.4; B.1
homework assignment	HF	A.5-A.7; B.2-B.7
active participation	A	A.1-A.8; C.1-C.6; D.1-D.5

A szorgalmi időszakban tartott értékelések pontos idejét, a házi feladatok ki- és beadási határidejét a "Részletes féléves ütemterv" tartalmazza, mely elérhető a tárgy honlapján.

3.3 Teljesítményértékelések részaránya a minősítésben

Abbreviation	Score
ZH	40%
HF	50%
A	10%
Sum	100%

3.4 Az aláírás megszerzésének feltétele, az aláírás érvényessége

No signature can be obtained on the subject.

3.5 Érdemjegy megállapítása

Grade	Points (P)
excellent (5)	90% ≤ P
good (4)	75% ≤ P < 90%
satisfactory (3)	60% ≤ P < 75%
passed (2)	50% ≤ P < 60%
failed (1)	50% < P

3.6 Javítás és pótlás

By its nature, active participation cannot be replaced, corrected or otherwise substituted,
The final examination may be replaced or corrected once during the repeat period, free of charge. The student's preference will be considered in the case of a correction.
The homework may be submitted in the repeat period.

3.7 A tantárgy elvégzéséhez szükséges tanulmányi munka

Activity	Hours/semester
participation in lectures	14×2=28
preparation for lectures	14
preparation for test	24
homework assignment	24
Sum	90

3.8 A tárgykövetelmények érvényessége