Efficient Operation of Heat Source using High-temperature Chilled Water in an Advanced Office Building

Yuya Suzuki, Misa Imazu, Jun Shinoda, Ryoya Furukawa, Yumiko Araki, Shinichi Tanabe, Kenji Fujino, Daisuke Hatori, Nobuhiro Hirasuga, Shun Kato, Shiori Sasahara, Hiroki Iwata

研究成果: Conference article

抄録

In recent years, energy conservation has become a major focus in the industrial sector. Many office buildings in Japan achieve energy savings by introducing highly efficient equipment and systems, such as high-temperature cooling water (14 °C), which increases heat source efficiency. However, such equipment requires adjustments to increase operational efficiency. In this case study, the efficiency of equipment using high-temperature cooling water was further improved through operation control optimization. The energy efficiency before and after the improvement was compared. The target building has chilled and hot water supplied to each floor from district heating and high-temperature chilled water supplied from cooling chillers on the rooftop. The energy consumption of two floors was evaluated: a subjective floor with equipment using high-temperature cooling water installed, and a common floor with a conventional system. After on-site verification, changes were made to the operation control of the cooling towers, condenser pumps, primary pumps, secondary pumps, and air handling units. As a result, the coefficient of performance of the water-cooled chiller and the whole system improved by 0.40 and 0.45, respectively. The flow rate of the air conditioning equipment using high-temperature cooling water decreased while maintaining an equivalent amount of heat extraction. In conclusion, the efficiency of the equipment was further improved by operation control optimization.

元の言語English
記事番号03071
ジャーナルE3S Web of Conferences
111
DOI
出版物ステータスPublished - 2019 8 13
イベント13th REHVA World Congress, CLIMA 2019 - Bucharest, Romania
継続期間: 2019 5 262019 5 29

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Office buildings
heat source
cooling water
Cooling water
Water
pump
Pumps
water
Temperature
Energy conservation
Condensers (liquefiers)
District heating
Cooling towers
air conditioning
energy conservation
energy efficiency
Air conditioning
Energy efficiency
Hot Temperature
Energy utilization

ASJC Scopus subject areas

  • Environmental Science(all)
  • Energy(all)
  • Earth and Planetary Sciences(all)

これを引用

Efficient Operation of Heat Source using High-temperature Chilled Water in an Advanced Office Building. / Suzuki, Yuya; Imazu, Misa; Shinoda, Jun; Furukawa, Ryoya; Araki, Yumiko; Tanabe, Shinichi; Fujino, Kenji; Hatori, Daisuke; Hirasuga, Nobuhiro; Kato, Shun; Sasahara, Shiori; Iwata, Hiroki.

:: E3S Web of Conferences, 巻 111, 03071, 13.08.2019.

研究成果: Conference article

Suzuki, Y, Imazu, M, Shinoda, J, Furukawa, R, Araki, Y, Tanabe, S, Fujino, K, Hatori, D, Hirasuga, N, Kato, S, Sasahara, S & Iwata, H 2019, 'Efficient Operation of Heat Source using High-temperature Chilled Water in an Advanced Office Building', E3S Web of Conferences, 巻. 111, 03071. https://doi.org/10.1051/e3sconf/201911103071
Suzuki, Yuya ; Imazu, Misa ; Shinoda, Jun ; Furukawa, Ryoya ; Araki, Yumiko ; Tanabe, Shinichi ; Fujino, Kenji ; Hatori, Daisuke ; Hirasuga, Nobuhiro ; Kato, Shun ; Sasahara, Shiori ; Iwata, Hiroki. / Efficient Operation of Heat Source using High-temperature Chilled Water in an Advanced Office Building. :: E3S Web of Conferences. 2019 ; 巻 111.
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