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Advances in Building Energy Research Volume 14, 2020 - Issue 2: Advanced Engineering Designs in Buildings
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Articles

Multi-stage optimization of local environmental quality by comprehensive computer simulated person as a sensor for HVAC control

Sungjun YooFaculty of Engineering Sciences, Kyushu University, Fukuoka, JapanCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-0457-9203View further author information
ORCID Icon &
Kazuhide ItoFaculty of Engineering Sciences, Kyushu University, Fukuoka, JapanORCID Iconhttps://orcid.org/0000-0002-7715-7896View further author information
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Pages 171-188 | Received 30 Dec 2018, Accepted 19 Feb 2019, Published online: 20 Mar 2019

References

  • Abe, K., Kondo, T., & Nagano, Y. (1994). A new turbulent model for predicting fluid flow and heat transfer in separating and reattaching flows-1. Flow fields calculations. International Journal of Heat and Mass Transfer, 37(1), 139–151.
  • Abe, K., Kondo, T., & Nagano, Y. (1995). A new turbulent model for predicting fluid flow and heat transfer in separating and reattaching flows-2. Thermal fields calculations. International Journal of Heat and Mass Transfer, 38(8), 1467–1481.
  • American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE). (2013). Fundamentals of control, ASHRAE handbook fundamentals 2013, ASHRAE, Atlanta, USA, 7.1-7.21.
  • Azimi, A., & Daneshgar, E. (2018). Indoor contaminant source identification by inverse zonal method: Levenberg–marquardt and conjugate gradient methods. Advances in Building Energy Research, 12(2), 250–273.
  • Baldi, S., Korkas, C. D., Maolong, L., & Kosmatopoulos, E. B. (2018). Automating occupant-building interaction via smart zoning of thermostatic loads: A switched self-tuning approach. Applied Energy, 231, 1246–1258.
  • Chung, J., Lim, E., Sandberg, M., & Ito, K. (2017). Returning and net escape probabilities of contaminant at a local point in indoor environment. Building and Environment, 125, 67–76.
  • Corley, R. A., Kabilan, S., Kuprat, A. P., Carson, J. P., Jacob, R. E., Minard, K. R., … Einstein, D. R. (2015). Comparative risks of aldehyde constituents in cigarette smoke using transient computational fluid dynamics/physiologically based pharmacokinetic models of the rat and human respiratory tracts. Toxicological Sciences, 1–24.
  • Fanger, P. O. (1973). Thermal comfort. New York, NY: McGraw-Hill Inc.
  • Gagge, A. P., Fobelets, A. P., & Berglund, L. G. (1986). A standard predictive index of human response to the thermal environment. ASHRAE Transactions, 92, 709–731.
  • Gagge, A. P., Stolwijk, J. A. J., & Hardy, J. D. (1967). Comfort and thermal sensations and associated physiological responses at various ambient temperatures. Environmental Research, 1(1), 1–20.
  • Goyal, S., Barooah, P., & Middelkoop, T. (2015). Experimental study of occupancy-based control of HVAC zones. Applied Energy, 140, 75–84.
  • Howard, B. K., & Rohrich, R. J. (2002). Understanding the nasal airway: Principles and practice. Plastic and Reconstructive Surgery, 109, 1128–1144.
  • Ito, K. (2014). Integrated numerical approach of CFD and epidemiological model for multi-scale transmission analysis in indoor spaces. Indoor and Built Environment, 23(7), 1029–1049.
  • Ito, K. (2016). Toward the development of an in silico human model for indoor environmental design. Proceedings of the Japan Academy- Series B, 92(7), 185–203.
  • Ito, K., & Hotta, T. (2006). Development of virtual manikins and its grid library for CFD analysis. SHASE Transactions, 113, 27–34. (in Japanese).
  • Ito, K., Inthavong, K., Kurabuchi, T., Ueda, T., Endo, T., Omori, T., … Tu, J. (2015a). CFD benchmark tests for indoor environmental problems: Part 1 Isothermal/non-isothermal flow in 2D and 3D room model. International Journal of Architectural Engineering Technology, 2(1), 1–22.
  • Ito, K., Inthavong, K., Kurabuchi, T., Ueda, T., Endo, T., Omori, T., … Tu, J. (2015b). CFD benchmark tests for indoor environmental problems: Part 2 Cross-ventilation airflows and floor heating systems. International Journal of Architectural Engineering Technology, 2(1), 23–49.
  • Ito, K., Inthavong, K., Kurabuchi, T., Ueda, T., Endo, T., Omori, T., … Tu, J. (2015c). CFD benchmark tests for indoor environmental problems: Part 3 numerical thermal manikins. International Journal of Architectural Engineering Technology, 2(1), 50–75.
  • Ito, K., Inthavong, K., Kurabuchi, T., Ueda, T., Endo, T., Omori, T., … Tu, J. (2015d). CFD benchmark tests for indoor environmental problems: Part 4 Air-conditioning airflows, residential kitchen airflows and fire-induced flow. International Journal of Architectural Engineering Technology, 2(1), 76–102.
  • Ito, K., & Murakami, S. (2010). Cost-effectiveness analysis of improved indoor temperature and ventilation conditions in School buildings. Journal of Asian Architecture and Building Engineering, 9(2), 523–529.
  • Kelly, J. T., Asgharian, B., Kimbell, J. S., & Wong, B. A. (2004). Particle deposition in human nasal airway replicas manufactured by different methods. Part II: Ultrafine Particles. Aerosol Science and Technology, 38, 1072–1079.
  • Kemm, J., Parry, J., & Palmer, S. (2008). Health impact assessment: Concepts, theory, techniques, and applications. Oxford: Medical Publications.
  • Korkas, C. D., Baldi, S., Michailidis, I., & Kosmatopoulos, E. B. (2016). Occupancy-based demand response and thermal comfort optimization in microgrids with renewable energy sources and energy storage. Applied Energy, 163, 93–104.
  • Kuga, K., Ito, K., Yoo, S. J., Chen, W., Wang, P., Liao, J., … Kumagai, K. (2018). First- and second-hand smoke dispersion analysis from e-cigarettes using a computer-simulated person with a respiratory tract model. Indoor and Built Environment, 27(7), 898–916.
  • Li, C., & Ito, K. (2014). Numerical and experimental estimation of convective heat transfer coefficient of human body under strong forced convective flow. Journal of Wind Engineering and Industrial Aerodynamics, 126, 107–117.
  • Lim, E., Ito, K., & Sandberg, M. (2013). New ventilation index for evaluating imperfect mixing condition- analysis of Net Escape velocity based on RANS approach. Building and Environment, 61, 45–56.
  • Lim, E., Ito, K., & Sandberg, M. (2014). Performance evaluation of contaminant removal and air quality control for local ventilation systems using the ventilation index Net Escape velocity. Building and Environment, 79, 78–89.
  • Martinho, N., Lopes, A., & Gameiro da Silva, M. (2012). Evaluation of errors on the CFD computation of air flow and heat transfer around the human body. Building and Environment, 58, 58–69.
  • Murakami, S. (2004). Analysis and design of micro-climate around the human body with respiration by CFD. Indoor Air, 14, 144–156.
  • Murakami, S., Kato, S., & Zeng, J. (2000). Combined simulation of airflow, radiation and moisture transport for heat release from human body. Building and Environment, 35, 489–500.
  • Murakami, S., & Zeng, J. (1997). Flow and temperature fields around human body with various room air distributions: Part 1 - CFD study on computational thermal manikin. AHSRAE Transactions, 103, 3–15.
  • Murga, A., Sano, Y., Kawamoto, Y., & Ito, K. (2017). Integrated analysis of numerical weather prediction and computational fluid dynamics for estimating cross-ventilation effects on inhaled air quality inside a factory. Atmospheric Environment, 167, 11–22.
  • Murga, A., Yoo, S. J., & Ito, K. (2018). Multi-stage downscaling procedure to analyze the impact of exposure concentration in a factory on a specific worker through CFD. Indoor and Built Environment, 27(4), 486–498.
  • Nadarajan, M., & Kirubakaran, V. (2017). Simulation studies on small rural residential houses using sustainable building materials for thermal comfort – case comparison. Advances in Building Energy Research, 11(2), 193–207.
  • Nielsen, P. V. (2015). Fifty years of CFD for room air distribution. Building and Environment, 91, 78–90.
  • Nikdel, L., Janoyan, K., Bird, S. D., & Powers, S. E. (2018). Multiple perspectives of the value of occupancy-based HVAC control systems. Building and Environment, 129, 15–25.
  • Patankar, S. V. (1980). Numerical heat transfer and fluid flow. McGraw-Hill International Book Co.
  • Phuong, N. L., & Ito, K. (2015). Investigation of flow pattern in upper human airway including oral and nasal inhalation by PIV and CFD. Building and Environment, 94, 504–515.
  • Phuong, N. L., Yamashita, M., Yoo, S. J., & Ito, K. (2016). Prediction of convective heat transfer coefficient of human upper and lower airway surfaces in steady and unsteady breathing conditions. Building and Environment, 100, 172–185.
  • Sakoi, T., Tsuzuki, K., Kato, S., Ooka, R., Song, D., & Zhu, S. W. (2005). Development of a three-dimensional human thermal model accounting for direction of blood flow. Proceedings of the 3rd international conference on human-environment system, (2005).
  • Smith, C. E. (1991). A transient, three-dimensional model of the human thermal system (PhD thesis). Kansas State University.
  • Sorensen, D. N., & Voigt, L. K. (2003). Modeling flow and heat transfer around a seated human body by computational fluid dynamics. Building and Environment, 38(6), 753–762.
  • Spengler, J. D., & Chen, Q. (2000). Indoor air quality factors in designing a healthy building. Annual Review of Energy and the Environment, 25(1), 567–600.
  • Stolwijk, J. A. J. (1971). A mathematical model of physiological temperature regulation in man. NASA contractor report.
  • Tanabe, S. I., Kobayashi, K., Nakano, J., Ozeki, Y., & Konishi, M. (2002). Evaluation of thermal comfort using combined multi-node thermoregulation (65MN) and radiation models and computational fluid dynamics (CFD). Energy and Buildings, 34(6), 637–646.
  • Yoo, S. J., & Ito, K. (2018a). Assessment of transient inhalation exposure using in silico human model integrated with PBPK - CFD hybrid analysis. Sustainable Cities and Society, 40, 317–325.
  • Yoo, S. J., & Ito, K. (2018b). Numerical prediction of tissue dosimetry in respiratory tract using computer simulated person integrated with physiologically based pharmacokinetic–computational fluid dynamics hybrid analysis. Indoor and Built Environment, 27(7), 877–889.
  • Zhu, S., Kato, S., Ooka, R., & Sakoi, T. (2007). Development of a computational thermal manikin applicable in a nonuniform thermal environment - part 1: Coupled simulation of convection, radiation, and Smith’s human thermal physiological model for sensible heat transfer from a seated human body in radiant environment. HVAC&R Research, 13(4), 661–679.
  • Zhu, S., Kato, S., Ooka, R., Sakoi, T., & Tsuzuki, K. (2008). Development of a computational thermal manikin applicable in a nonuniform thermal environment - part 2: Coupled simulation using Sakoi’s human thermal physiological model. HVAC&R Research, 14(4), 545–564.

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