Heating energy savings potential from retrofitting old apartments with an advanced double-skin façade system in cold climate

Yeo Beom YOON, Byeongmo SEO, Brian Baewon KOH, Soolyeon CHO

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Front. Energy ›› 2020, Vol. 14 ›› Issue (2) : 224-240. DOI: 10.1007/s11708-020-0801-1
RESEARCH ARTICLE
RESEARCH ARTICLE

Heating energy savings potential from retrofitting old apartments with an advanced double-skin façade system in cold climate

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Abstract

Apartments account for over 60% of total residential buildings and consume a significant portion of primary energy in South Korea. Various energy efficiency measures have been implemented for both new apartment constructions and existing apartment retrofits. Old apartment structures have poor thermal performances, resulting in a high energy consumption. The South Korean government initiated retrofitting projects to improve the energy efficiency in old apartments. Apartment owners typically replace old windows with high-performance windows; however, there is still a demand for better and more innovative retrofit methods for a highly improved energy efficiency. This paper proposes an advanced double-skin façade (DSF) system to replace existing balcony windows in old apartments. Considering the cold climate conditions of Seoul, South Korea, it mainly discusses heating energy savings. Three case models were developed: Base-Case with existing apartment, Case-1 with typical retrofitting, and Case-2 with the proposed DSF system. The EnergyPlus simulation program was used to develop simulation models for a floor radiant heating system. A typical gas boiler was selected for low-temperature radiant system modeling. The air flow network method was used to model the proposed DSF system. Five heating months, i.e., November to March, and one representative day, i.e., January 24, were selected for detailed analysis. The main heat loss areas consist of windows, walls, and infiltration. The results reveal that the apartment with the DSF retrofit saves 38.8% on the annual heating energy compared to the Base-Case and 35.2% compared to Case-1.

Keywords

double-skin façade / retrofitting / high-rise apartment / heating energy / building simulation

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Yeo Beom YOON, Byeongmo SEO, Brian Baewon KOH, Soolyeon CHO. Heating energy savings potential from retrofitting old apartments with an advanced double-skin façade system in cold climate. Front. Energy, 2020, 14(2): 224‒240 https://doi.org/10.1007/s11708-020-0801-1

References

[1]
Seo B M, Lee K H. Detailed analysis on part load ratio characteristics and cooling energy saving of chiller staging in an office building. Energy and Building, 2016, 119: 309–322
CrossRef Google scholar
[2]
Oliver T, Lew D, Redlinger R, Prijyanonda C. Global energy efficiency and renewable energy policy options and initiatives. Energy for Sustainable Development, 2001, 5(2): 15–25
CrossRef Google scholar
[3]
Song D S, Choi Y J. Effect of building regulation on energy consumption in residential buildings in Korea. Renewable & Sustainable Energy Reviews, 2012, 16(1): 1074–1081
CrossRef Google scholar
[4]
Lim J H, Han H G, Kang D R. Analysis on green remodeling status, satisfaction, and energy saving effect–focusing on window replacing of residential buildings. Journal of the Architectural Institute of Korea Structure & Construction, 2017, 33: 75–80
[5]
Chan A L S, Chow T T. Investigation on energy performance and energy payback period of application of balcony for residential apartment in Hong Kong. Energy and Building, 2010, 42(12): 2400–2405
CrossRef Google scholar
[6]
Raeissi S, Taheri M. Optimum overhang dimensions for energy saving. Building and Environment, 1998, 33(5): 293–302
CrossRef Google scholar
[7]
Kim D S, Cox S J, Cho H, Yoon J. Comparative investigation on building energy performance of double skin façade (DSF) with interior or exterior slat blinds. Journal of Building Engineering, 2018, 20: 411–423
CrossRef Google scholar
[8]
Qahtan A M. Thermal performance of a double-skin façade exposed to direct solar radiation in the tropical climate of Malaysia: a case study. Case Studies in Thermal Engineering, 2019, 14: 100419
CrossRef Google scholar
[9]
Chan A L S, Chow T T, Fong K F, Lin Z. Investigation on energy performance of double skin façade in Hong Kong. Energy and Building, 2009, 41(11): 1135–1142
CrossRef Google scholar
[10]
Zomorodian Z S, Tahsildoost M. Energy and carbon analysis of double skin façades in the hot and dry climate. Journal of Cleaner Production, 2018, 197: 85–96
CrossRef Google scholar
[11]
Gelesz A, Reith A. Climate-based performance evaluation of double skin facades by building energy modelling in Central Europe. Energy Procedia, 2015, 78: 555–560
CrossRef Google scholar
[12]
Alberto A, Ramos N M M, Almeida R M S F. Parametric study of double-skin facades performance in mild climate countries. Journal of Building Engineering, 2017, 12: 87–98
CrossRef Google scholar
[13]
Dutton S, Shao L, Riffat S. Validation and parametric analysis of EnergyPlus: air flow network model using contam. In: 3rd National Conference of International Building Performance Simulation Association (IBPSA-USA) (Simbuild 2008), Berkeley, California, USA, 2008, 124–131
[14]
EnergyPlus engineering reference. The reference to Energyplus calculations, version 9.0. 2019–08–15, available at the website of energyplus
[15]
Winkelmann F C. Modelling windows in EnergyPlus. In: 3rd National Conference of International Building Performance Simulation Association (IBPSA) (Building Simulation 2001), Rio de Janeiro, Brazil, 2011, 457–464
[16]
EnergyPlus input output reference. The encyclopedic reference to Energyplus input and output, version 9.0. 2019–08–15, available at the website of energyplus
[17]
Strand R K, Pedersen C O. Modeling radiant systems in an integrated heat balance based energy simulation program. ASHRAE Transactions, 2002, 108: 979–987
[18]
Raftery P, Lee K H, Webster T, Bauman F. Performance analysis of an integrated UFAD and radiant hydronic slab system. Applied Energy, 2011, 90(1): 250–257
CrossRef Google scholar
[19]
Chantrasrisalai C, Ghatti V, Fisher D E, Scheatzle D G. Experimental validation of the EnergyPlus low-temperature radiant simulation. ASHRAE Transactions, 2003, 109(2): 614–623
[20]
Henninger R H, Witte M J, Crawley D B. Analytical and comparative testing of EnergyPlus using IEA HVAC BESTEST E100–E200 test suite. Energy and Building, 2004, 36(8): 855–863
CrossRef Google scholar
[21]
Gratia E, Herde A D. Optimal operation of a south double-skin façade. Energy and Building, 2004, 36(1): 41–60
CrossRef Google scholar
[22]
Gratia E, Herde A D. Are energy consumptions decreased with the addition of a double skin? Energy and Building, 2007, 39(5): 605–619
CrossRef Google scholar
[23]
Kim D W, Park C S. Energy performance assessment of a double skin façade with different control strategies. Journal of Architectural Institute of Korea, 2010, 26: 389–398
[24]
Statistics Korea. 2016 population and housing census. 2019–03–25, available at the website of kostat
[25]
Kim S Y, Oh C O. A study of current status and residents’ needs of balcony extension in Korean apartment housing. Journal of the Korean Institute of Interior Design, 2012, 21: 152–162
[26]
Yoon Y B, Koh B B, Cho S. An analysis of energy efficiency of a smart envelope package in residential buildings. In: Proceeding of ARCC-EAAE 2018 International Conference, Philadelphia, PA, USA, 2018, 2: 27–35
[27]
Yoon Y B, Seo B M, Koh B B, Cho S. Performance analysis of a double-skin façade system installed at different floor levels of high-rise apartment building. Journal of Building Engineering, 2019, 26: 100900
[28]
Ministry of Land, Infrastructure and Transport (MOLIT), Korea Energy Agency (KEA). Guidebook of Building Energy Conservation Design Standard. 2017
[29]
U.S. Department of Energy (DOE). EnergyPlus version 9.0, ASHRAE 2005 HOF Materials.id. 2018
[30]
Korea Research Institute of Mechanical Facilities Industry (KRIMFI). Study on heating and cooling load standard per area for apartments in 2017. 2019–08–07, available at the website of krimfi
[31]
Korea Institute of Energy Research (KIER). Energy Technology Transfer and Diffusion 2007 Report. 2007
[32]
American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE). ASHRAE Handbook: Fundamentals. 2009
[33]
Lee E J, Lee D Y, Hong H K, Kim K Y. Measurement and simulation of heating energy for apartments with district heating. Korean Journal of Air-Conditioning and Refrigeration Engineering, 2014, 26: 572–578
[34]
Yu B H, Seo B M, Moon J W, Lee K H. Analysis of the part load ratio characteristics and gas energy consumption of a hot water boiler in a residential building under Korean climatic conditions. Korean Journal of Air-Conditioning and Refrigeration Engineering, 2015, 27: 455–462
[35]
Lee D Y, Seo B M, Hong S H, Choi J M, Lee K H. Part load ratio characteristics and energy saving performance of standing column well geothermal heat pump system assisted with storage tank in an apartment. Energy, 2019, 174: 1060–1078
CrossRef Google scholar
[36]
Cho J, Park B, Lim T. Experimental and numerical study on the application of low-temperature radiant floor heating system with capillary tube: thermal performance analysis. Applied Thermal Engineering, 2019, 163: 114360
CrossRef Google scholar

Acknowledgments

This work was supported by the Korea Institute of Energy Technology Evaluation and Planning (KETEP) and the Ministry of Trade, Industry & Energy (MOTIE) of the Republic of Korea (No. 20172010000370).

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2020 Higher Education Press
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