Improving indoor air quality and thermal comfort by total heat exchanger for an office building in hot and humid climate

HVAC and R Research

Volumn 20, Issue 7, 2014, Pages 731-737

  Wang, Fu Jen ^a   Lee, Meng Chieh ^b   Chang, Tong Bou ^c   Chen, Yong Sheng ^a   Jung, Ron Chin ^a  

^a NATIONAL CHIN YI UNIVERSITY OF TECHNOLOGY   (Taiwan)

^b NATIONAL TAICHUNG UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Taiwan)

^c NATIONAL CHIAYI UNIVERSITY   (Taiwan)

Author keywords

[No Author keywords available]

Indexed keywords

AIR CONDITIONING; AIR QUALITY; CARBON DIOXIDE; DOMESTIC APPLIANCES; ELECTRIC POWER UTILIZATION; ENTHALPY; HEAT EXCHANGERS; INDOOR AIR POLLUTION; OFFICE BUILDINGS; THERMAL COMFORT;

FIELD MEASUREMENT; HOT AND HUMID CLIMATE; INDOOR AIR QUALITY; INDOOR TEMPERATURE; SPLIT TYPE AIR CONDITIONER; THERMAL COMFORT EVALUATIONS; THERMAL SENSATION VOTES; WORKING PERFORMANCE;

ENERGY UTILIZATION;

EID: 84907815486     PISSN: 10789669     EISSN: None     Source Type: Journal    
DOI: 10.1080/10789669.2014.948362     Document Type: Article

References (17)

1. Arens, E., S. Turner, H. Zhang, and G. Paliaga. 2009. Moving air for comfort. ASHRAE Journal 51: 18-28
2. ASHRAE. 2009. 2009 ASHRAE Handbook-AFundamentals, Chapter 9, Thermal comfort. Atlanta: ASHRAE
3. ASHRAE. 2010a. ANSI/ASHRAE Standard 55-2010, Thermal Environmental Conditions for Human Occupancy. Atlanta: ASHRAE
4. ASHRAE. 2010b. ANSI/ASHRAE Standard 62.1-2010, Ventilation for Acceptable Indoor Air Quality. Atlanta: ASHRAE
5. ASHRAE. 2010c. Thermal comfort tool, version 2. Atlanta: ASHRAE
6. Calay, R.K., and W.C. Wang. 2013. A hybrid energy efficient building ventilation system. Applied Thermal Engineering 57: 7-13
7. Candido, C., R.J. de Dear, R. Lamberts, and L. Bittencourt. 2010. Air movement acceptability limits and thermal comfort in Brazil's hot humid climate zone. Building and Environment 45: 222-9
8. Delfani, S., H. Pasdarshahri, andM. Karami. 2012. Experimental investigation of heat recovery system for building air conditioning in hot and humid areas. Energy and Buildings 49: 62-8
9. ISO. 2005. ̄SO 7730, Ergonomics of the thermal environment-Aanalytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria. Geneva, Switzerland: International Organization for Standardization
10. Jeong, J., S. Yamaguchi, K. Saito, and S. Kawai. 2010. Performance analysis of four-Apartition desiccant wheel and hybrid dehumidification air-Aconditioning system. ̄nternational Journal of Refrigeration 33: 496-509
11. Mardiana, A., and S.B.Riffat. 2013.Reviewon physical and performance parameters of heat recovery systems for building applications. Renewable and Sustainable Energy Reviews 28: 174-90
12. Noh, K.C., J.S. Jang, and M.D. Oh. 2007. Thermal comfort and indoor air quality in the lecture room with 4-Away cassette air-Aconditioner andmixing ventilation system. Building and Environment 42: 689-98
13. Olesen, B.W. 2004. ̄nternational standards for the indoor environment. ̄ndoor Air 14: 18-26
14. Wang, F.J., M.J. Lee, T.J. Cheng, and Y.Q. Law. 2012. Field evaluation of thermal comfort and indoor air quality for a hospital in a hot and humid climate. HVAC & Research 18: 671-80
15. Yau, Y.H., and B.T. Chew 2009. Thermal comfort study of hospital workers in Malaysia. ̄ndoor Air 19: 500-10
16. Zeiler, W., and G. Boxem. 2009. Effects of thermal activated building systems in schools on thermal comfort in winter. Building and Environment 44: 2308-17
17. Zhang, Y., and R. Zhao. 2008. Overall thermal sensation, acceptability and comfort. Building and Environment 43: 44-50