DOI QR코드

DOI QR Code

설비형 칠드빔 시스템 및 일반 공조 시스템 적용 공간의 온열환경 균일도 비교 평가

Comparative Evaluation of the Thermal Uniformity in a Space with Active Chilled Beam and Conventional Air Conditioning Systems

  • 이규남 (삼성물산 건설부문 기술연구실) ;
  • 최선호 (삼성물산 건설부문 빌딩사업부) ;
  • 김창훈 (삼성물산 건설부문 빌딩사업부)
  • 투고 : 2014.07.30
  • 심사 : 2014.09.11
  • 발행 : 2014.10.30

초록

It is one of major objectives to achieve a uniform thermal environment and to minimize the local discomfort, when designing or operating air distribution systems. An active chilled beam (ACB) system, which is gaining much popularity owing to reduced fan energy consumption, needs to be evaluated in terms of uniform thermal environment, because it is operated with much smaller air flow rate than conventional all-air systems. The uniform thermal environment, or thermal uniformity, can be evaluated by analyzing air diffusion performance index (ADPI), local discomfort parameters within conditioned space. This study presents an evaluation method on the thermal uniformity in a room with different air distribution systems. To do this, a test bed facility was constructed so that four different air distribution systems, including ACB system, can be separatively operated. The ADPI of the ACB system was 80.7%, which is lower than that of all-air system, however, it could satisfy the recommended level (80%) of ADPI by ASHRAE. Although the ACB system resulted in the relatively low draught risk, averagely 6.7%, it was found that some regions near the chilled beam can be exposed to the draught risk due to the descending cold air. Vertical air temperature difference was not higher than $1.0^{\circ}C$, showing that the ACB system resulted in efficient air mixture in the vertical direction. It can be concluded that the ACB system can attain an acceptable thermal uniformity with much less air flow rate than other conventional air distribution systems.

키워드

참고문헌

  1. 김지석, 주상현, 김정엽, 신현준, Chilled Beam System의 유인구조해석 연구, 대한설비공학회 하계학술발표대회 논문집, 2012. 6
  2. 송진용, 정재훈, 김수빈, 능동형 칠드빔 시스템의 최적설계 연구, 대한설비공학회 하계학술발표대회 논문집, 2012. 6
  3. 이규남, 최선호, 설비형 칠드빔 시스템 적용 공간의 공기확산 성능 및 국부적 불쾌적에 관한 실험적 연구, 대한건축학회 논문집 계획계, v.30(7), 2014 https://doi.org/10.5659/JAIK_PD.2014.30.7.203
  4. Alexander, D., O'Rourke, M. Design considerations for active chilled beams, ASHRAE Journal v.50(9), 2008
  5. ASHRAE, ASHRAE Handbook Fundamental, 2009
  6. ASHRAE, "Thermal Environmental Conditions for Human Occupancy", ANSI/ASHRAE Standard 55, 2010
  7. Awbi, H. Energy efficient ventilation for retrofit buildings, Proceedings of 48th AiCARR international conference on energy performance of existing buildings, 2011
  8. Betz, F., McNeill, J., Talbert, B., Thimmanna, H., Repka, N. Issues arising from the use of chilled beams in energy models, Proceedings of the 5th national conference of IBPSA-USA 2012
  9. Cao, G., Awbi, H., Yao, R., Fan, Y., Siren, K., Kosonen, R., Zhang, J. A review of the performance of different ventilation and airflow distribution systems in buildings, Building and Environment v.73, 2014
  10. Chung, K., Lee, C. Predicting air flow and thermal comfort in an indoor environment under different air diffusion models, Building and Environment v.31(1), 1996
  11. Hwang, T., Kim, J. Assessment of indoor environmental quality in open-plan offices, Indoor and Built Environment v.22(1), 2013
  12. ISO, ISO7730:2005, Ergonomics of the thermal environment . Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria, 2005
  13. John, D. Designing Air-distribution Systems to Maximize Comfort, ASHRAE Journal v.54(9), 2012
  14. Livchak, A., Lowell, C. Don't turn active beams into expensive diffusers, ASHRAE Journal v.54(4), 2012
  15. Loudermilk, K. Designing chilled beams for thermal comfort, ASHRAE Journal v.51(10), 2009
  16. Virta, M., Butler, D., Graslund, J., Hogeling, J., Kristiansen, E., Reinkainen, M., Svensson, G. Chilled Beam Application Guidebook, REHVA, Brussels, 2006.

피인용 문헌

  1. Analysis of Energy Saving Potential in High-Performance Building Technologies under Korean Climatic Conditions vol.11, pp.4, 2018, https://doi.org/10.3390/en11040884