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Research Article

Optimization of indoor environmental quality and ventilation load in office space by multilevel coupling of building energy simulation and computational fluid dynamics

Yunqing FanKazuhide Ito( )
Interdisciplinary Graduate School of Engineering Science, Kyushu University, 6-1 Kasuga-koen, Kasuga, Fukuoka 816-8580, Japan
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Abstract

The fundamentals, implementation, and application of an integrated simulation as an approach for predicting the indoor environmental quality for an open-type office and for quantifying energy saving potential under optimized ventilation are presented in this paper. An integrated simulation procedure based on a building energy simulation and computational fluid dynamics, incorporated with a conceptual model of a CO2 demand controlled ventilation (DCV) system and proportional integral control of an air conditioning system as the optimization assessment of conceptual model in the occupied zone, was developed. This numerical model quantitatively exhibits energy conservation and represents the non-uniform distribution patterns of airflow properties and CO2 concentration levels in terms of energy recovery and indoor thermal comfort. By means of an integrated simulation, the long-term energy consumption of heating, ventilation, and air conditioning systems are predicted precisely and dynamically. Relative to a ventilation system with a basic constant air volume supply rate characterized by a fixed outdoor air intake rate from the ceiling supply opening, the optimized CO2-DCV system coupled with energy recovery ventilators reduced total energy consumption by 29.1% (in summer conditions) and 40.9% (winter).

Keywords

CFDindoor environmental qualityintegrated simulationBESCO2 demand controlenergy recovery ventilator

References

 
Q Chen (1995). Comparison of different k-ε models for indoor airflow computations. Numerical Heat Transfer, Part B: Fundamentals, 28: 353-369.
Crossref Google Scholar
 
Q Chen, LR Glicksman (2000). Application of computational fluid dynamics for indoor air quality studies. In: JD Spengler, JF McCarthy, JM Samet (eds), Indoor Air Quality Handbook, Chapter 59. New York: McGraw-Hill.
Google Scholar
 
Y Fan, K Ito (2012). Energy consumption analysis intended for real office space with energy recovery ventilator by integrating BES and CFD approach. Building and Environment, 52: 57-67.
Crossref Google Scholar
 
Y Fan, T Hayashi, K Ito (2012). Coupled simulation of BES-CFD and performance assessment of energy recovery ventilation system for office model. Journal of Central South University of Technology, 19: 633-638.
Crossref Google Scholar
 
Y Fan, K Ito (2013). Integrated building energy-computational fluid dynamics simulation for estimating the energy saving effect of energy recovery ventilator with CO2 demand-control ventilation system in office space. Indoor and Built Environment. doi:.
Crossref Google Scholar
 
Y Fan, K Kameishi, S Onishi, K Ito (2014). Field-based study on energy saving effects of CO2 demand controlled ventilation in office with application of energy recovery ventilators. Energy and Buildings, 68: 412-422.
Crossref Google Scholar
 
WJ Fisk, AG Mirer, MJ Mendell (2009). Quantitative relationship of sick building syndrome symptoms with ventilation rates. Indoor Air, 19:159-165.
Crossref Google Scholar
 
K Hiyama, S Kato, Y Ishida (2010). Thermal simulation: Response factor analysis using three-dimensional CFD in the simulation of air conditioning control. Building Simulation, 3: 195-203.
Crossref Google Scholar
 
K Ito, S Murakami (2010). Cost-effectiveness analysis of improved indoor temperature and ventilation conditions in schoolhouse. Journal of Asian Architecture and Building Engineering, 9: 523-529.
Crossref Google Scholar
 
K Ito, S Murakami, T Kaneko, H Fukao (2006). Study on the productivity in classroom (Part 2): Realistic simulation experiment on effects of air quality/thermal environment on learning performance. In: Proceedings of Healthy Buildings, Lisbon, Portugal, vol. 3, pp. 207-212.
 
S Kato, S Murakami (1988). New ventilation efficiency scales based on spatial distribution of contaminant concentration aided by numerical simulation. ASHRAE Transactions, 94(2): 309-330.
Google Scholar
 
S Murakami, T Kaneko, K Ito, H Fukao (2006) Study on the productivity in classroom (Part 1): Field survey on effects of air quality/thermal environment on learning performance. In: Proceedings of Healthy Buildings, Lisbon, Portugal, vol. 1, pp. 271-276.
 
PV Nielsen (2000). Velocity distribution in a room ventilated by displacement ventilation and wall-mounted air terminal devices. Energy and Buildings. 31:179-187.
Crossref Google Scholar
 
PV Nielsen, F Allard, HB Awbi, L Davidson, A Schälin (2007). Computational Fluid Dynamics in Ventilation Design. Brussels: REHVA.
Crossref
 
SV Patanker (1980) Numerical Heat and Fluid Flow. New York: Taylor Francis.
 
P Wargocki,, DP Wyon, (2007). The effects of moderately raised classroom temperatures and classroom ventilation rate on the performance of schoolwork by children (RP-1257). HVAC & R Research, 13: 193-220.
Crossref Google Scholar
Building Simulation
Volume 7 Issue 6,
December 2014
Pages 649-659
DOI: 10.1007/s12273-014-0178-3
Cite this article:
Fan Y, Ito K. Optimization of indoor environmental quality and ventilation load in office space by multilevel coupling of building energy simulation and computational fluid dynamics. Building Simulation, 2014, 7(6): 649-659. https://doi.org/10.1007/s12273-014-0178-3

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Received: 29 October 2013
Revised: 23 January 2014
Accepted: 03 February 2014
Published: 05 April 2014
© Tsinghua University Press and Springer-Verlag Berlin Heidelberg 2014
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