Performance evaluation of PV-Trombe wall for sustainable building development

Procedia CIRP

Volumn 26, Issue , 2015, Pages 624-629

  Irshad, Kashif ^a   Habib, Khairul ^a   Thirumalaiswamy, Nagarajan ^a  

^a DEPARTMENT OF CHEMICAL ENGINEERING   (Malaysia)

Author keywords

Air flow velocity; Glazing type; Photo voltaic Trombe wall; PV efficiency; Room temperature

Indexed keywords

AIR CONDITIONING; ARGON; BUILDINGS; COMPUTER SOFTWARE; DUCTS; EFFICIENCY; FLOW VELOCITY; GLAZES; INTELLIGENT BUILDINGS; MANUFACTURE; MATERIALS PROPERTIES; PHOTOVOLTAIC CELLS; VELOCITY; WALLS (STRUCTURAL PARTITIONS);

AIR FLOW VELOCITY; GLAZING TYPE; PV EFFICIENCIES; ROOM TEMPERATURE; TROMBE WALL;

AIR;

EID: 84939617158     PISSN: 22128271     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1016/j.procir.2014.07.116     Document Type: Conference Paper

References (20)

1. World Business Council for Sustainable Development. Energy Efficiency in Buildings Transforming the Market. Atar Roto Presse SA, Switzerland 2009.
2. Koeppel S, Uerge VD. Assessment of policy instruments for reducing greenhouse gas emissions from buildings. Central European University 2007.
3. Ali H, Nsairat S. Developing a green building assessment tool for developing countries Case of Jordan", Building and Environment 2009;44:1053-1064.
4. Beggs C. Passive solar and low energy building design. Energy Management and Conservation 2007;243-270.
5. Kundakci KB, Yilmaz Z. The comparison of Trombe wall systems with single glass, double glass and PV panels. Renewable Energy 2012;45:111-8.
6. Jie J, Yi H, He W, Pei G. PV-Trombe wall design for buildings in composite climates. Journal of Solar Energy Engineering by ASME 2007;129:431-437.
7. Ji J, Yi H, Pei G, Lu J. Study of PV-Trombe wall installed in fenestrated room with heat storage. Applied Thermal Engineering 2007;27(8-9):1507-15.
8. Sun W, Ji J, Luo C, He W. Performance of PV-Trombe wall in winter correlated with south façade design. Applied Energy 2011;88:224-231.
9. Jie J, Hua Y, Wei H, Gang P, Jianping L, Bin J. Modeling of a novel Trombe wall with pv cells. Building and Environment 2007;42(3):1544-1552.
10. Ji J, Yi H, He W, Pei G, Lu J, Jiang B. Modeling of a novel Trombe wall with PV cells. Build Environment 2008;42(3):1544-52.
11. Jie J, Hua Y, Gang P, Bin J, Wei H. Study of PV-Trombe wall assisted with DC fan. Building and Environment 2007;42:3529-39
12. Solar Energy Laboratory Univ. of Wisconsin-Madison, TRNSYS 17 - a TRaNsient SYstem Simulation program, 2009.
13. V. S. A. Efficient simulation of large, controlled passive solar systems: forward differencing in thermal networks. Solar Energy 1985;34:221-30.
14. Sandberg M, Moshfegh B. Buoyancy-induced air flow in photovoltaic facades, effect of geometry of the air gap and location of solar cell modules. Building and Environment 2002;37:211-218.
15. Chen ZD, Bandopadhayay P, Halldorsson J, Byrjalsen C, Heiselberg P, Li Y. An experimental investigation of solar chimney model with uniform wall heat flux. Building and Environment 2003;38:893-906.
16. Irshad K, Habib K, Thirumalaiswamy N, Elmahdi AEA. Performance analysis of Photo Voltaic Trombe Wall for Tropical climate. Applied Mechanics and Materials 2014;465-466:211-215.
17. Duffin RJ. A passive-wall design to minimize building temperature swings. Sol Energy 1984;33:337-42.
18. Peng J, Lu L, Yang H, Han J. Investigation on the annual thermal performance of a photovoltaic wall mounted on a multi-layer façade. Applied energy 2013;112:646-656.
19. Lu L, Law KM. Overall energy performance of semi-transparent single-glazed photovoltaic (PV) window for a typical office in Hong Kong. Renew Energy 2013;49:250-4.
20. Pantic S, Candanedo L, Athientis AK. Modeling of energy performance of a house with three configuration of building-integrated photovoltaic/thermal system. Energy and buildings 2010;42:1779-1789.