Course Unit / Hygrothermal behavior of facades

Hygrothermal behavior of facades

Year
1
Academic year
2020-2021
Code
03004962
Subject Area
Constructions
Language of Instruction
Portuguese
Other Languages of Instruction
English
Mode of Delivery
Face-to-face
Duration
SEMESTRIAL
ECTS Credits
6.0
Type
Elective
Level
3rd Cycle Studies

Recommended Prerequisites

1st cycle studies: knowledge in the area of Building Physics or Heat Transfer Phenomena.

Teaching Methods

The theoretical and practical contents of the curricular unit will be presented through lectures illustrated whenever possible with practical cases. Students are encouraged to apply the competences acquired through practical and laboratorial activities, and to develop and to discuss research works. 

Learning Outcomes

Provide students with the skills enabling them: to study the hygrothermal behaviour and energy performance of buildings; to master the methods for determining hygrothermal behaviour of construction solutions used on the building envelope; to identify opportunities for optimizing construction solutions and to select appropriated methods to assess their influence on the energy performance of buildings. The students will be prepared to develop advanced studies of hygrothermal characterization of building solutions (numerical and experimental).

Work Placement(s)

No

Syllabus

1.Evaluation hygrothermal behaviour

1.1 Fundamentals of heat and mass transfer

1.2 Advanced thermal characterization of building envelope

1.3 Simulation models for calculating the thermal and energy performance of buildings

2. Rules of thermal quality, energy performance and indoor air quality

3. Concepts of rational use of energy

3.1. Bioclimatic strategies;

3.1.1. Solar shading geometry;

3.1.2. Solar heating systems;

3.1.3. Passive cooling systems.

4. Cost optimal assessment. 

Assessment Methods

Assessment
Synthesis work: 15.0%
Resolution Problems: 15.0%
Exam: 70.0%

Bibliography

• Incropera, F. P.; Dewitt D. P., Fundamentals of Heat and Mass Transfer, Fifth Edition, Wiley & Sons, 2002.

• Kreider, J. F.; Curtiss, P. S.; Rabl, A., Heating and Cooling of Buildings, Design for Efficiency, 2009.

• J.A. Clarke, “Energy Simulation in Building Design”, Butterworth Heinemann, 2001.

• Canha da Piedade A., Marta Braga A., Moret Rodrigues, A., Térmica de Edifícios, Editora Orion, 2009.

• Gonçalves, H.; Graça, J. M., Conceitos bioclimáticos para os edifícios em Portugal, DGGE/IP-3E, 2004.

• Dec- Lei nº 118/2013.

• Watson, Donald, La casa solar: diseño y construccion, Madrid: Hermann Blume, 1985.

• Viegas, João Carlos, Ventilação Natural de Edifícios de Habitação, LNEC, 1995.

• Silva, Armando Cavaleiro, Malato, João José, Geometria da insolação de edifícios Lisboa: LNEC, 1969.

• Simões N., Prata J. Caderno sobre Pontes Térmicas Lineares, Universidade de Coimbra, 2010.

• Simões N., Martins S., Caderno sobre Ensaios de Caracterização de Isolamentos Térmicos, UC 2010.