NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION

Yuki Shimanuki; Takashi Kurabuchi; Takao Osawa; Yoshihiro Toriumi; Sihwan Lee; Ami Kudo; Yasuhisa Asawa

doi:10.3130/aije.87.569

NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION

Yuki Shimanuki, Takashi Kurabuchi, Takao Osawa, Yoshihiro Toriumi, Sihwan Lee, Ami Kudo, Yasuhisa Asawa

Tokyo University of Science

Research output: Contribution to journal › Article › peer-review

Abstract

In this study, prediction method for thermal plume above the gas stove under open flame condition and for the capture efficiency of exhaust hood were investigated with CFD. The buoyancy production term of turbulent energy in the standard k-ε model was improved with general gradient diffusion hypothesis instead of standard gradient diffusion hypothesis widely used in the standard k-ε model. The calculated results of the temperature and velocity distribution in the plume above the gas stove exhibited good correspondence with the experimental results. The calculated capture efficiency of the exhaust hood was also in good agreement with the experimental results.

Translated title of the contribution	数値流体力学解析による業務用ガスコンロから発生する熱上昇気流の再現（その１）：裸火状態の温度分布、速度分布、および排気フードの捕集率
Original language	English
Pages (from-to)	569-578
Number of pages	10
Journal	Journal of Environmental Engineering (Japan)
Volume	87
Issue number	799
DOIs	https://doi.org/10.3130/aije.87.569
Publication status	Published - 2022

Keywords

CFD
Commercial Kitchen
Cooking Stove
GGDH
Measurement
Thermal Plume

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Shimanuki, Y., Kurabuchi, T., Osawa, T., Toriumi, Y., Lee, S., Kudo, A., & Asawa, Y. (2022). NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION. Journal of Environmental Engineering (Japan), 87(799), 569-578. https://doi.org/10.3130/aije.87.569

Shimanuki, Yuki ; Kurabuchi, Takashi ; Osawa, Takao et al. / NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1) : TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION. In: Journal of Environmental Engineering (Japan). 2022 ; Vol. 87, No. 799. pp. 569-578.

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title = "NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION",

abstract = "In this study, prediction method for thermal plume above the gas stove under open flame condition and for the capture efficiency of exhaust hood were investigated with CFD. The buoyancy production term of turbulent energy in the standard k-ε model was improved with general gradient diffusion hypothesis instead of standard gradient diffusion hypothesis widely used in the standard k-ε model. The calculated results of the temperature and velocity distribution in the plume above the gas stove exhibited good correspondence with the experimental results. The calculated capture efficiency of the exhaust hood was also in good agreement with the experimental results.",

keywords = "CFD, Commercial Kitchen, Cooking Stove, GGDH, Measurement, Thermal Plume",

author = "Yuki Shimanuki and Takashi Kurabuchi and Takao Osawa and Yoshihiro Toriumi and Sihwan Lee and Ami Kudo and Yasuhisa Asawa",

year = "2022",

doi = "10.3130/aije.87.569",

language = "English",

volume = "87",

pages = "569--578",

journal = "Journal of Environmental Engineering (Japan)",

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Shimanuki, Y, Kurabuchi, T, Osawa, T, Toriumi, Y, Lee, S, Kudo, A & Asawa, Y 2022, 'NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION', Journal of Environmental Engineering (Japan), vol. 87, no. 799, pp. 569-578. https://doi.org/10.3130/aije.87.569

NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION. / Shimanuki, Yuki; Kurabuchi, Takashi; Osawa, Takao et al.
In: Journal of Environmental Engineering (Japan), Vol. 87, No. 799, 2022, p. 569-578.

Research output: Contribution to journal › Article › peer-review

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T2 - TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION

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AU - Kurabuchi, Takashi

AU - Osawa, Takao

AU - Toriumi, Yoshihiro

AU - Lee, Sihwan

AU - Kudo, Ami

AU - Asawa, Yasuhisa

PY - 2022

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AB - In this study, prediction method for thermal plume above the gas stove under open flame condition and for the capture efficiency of exhaust hood were investigated with CFD. The buoyancy production term of turbulent energy in the standard k-ε model was improved with general gradient diffusion hypothesis instead of standard gradient diffusion hypothesis widely used in the standard k-ε model. The calculated results of the temperature and velocity distribution in the plume above the gas stove exhibited good correspondence with the experimental results. The calculated capture efficiency of the exhaust hood was also in good agreement with the experimental results.

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Shimanuki Y, Kurabuchi T, Osawa T, Toriumi Y, Lee S, Kudo A et al. NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION. Journal of Environmental Engineering (Japan). 2022;87(799):569-578. doi: 10.3130/aije.87.569

NUMERICAL SIMULATION OF THERMAL PLUME ABOVE COMMERCIAL COOKING GAS STOVE USING CFD ANALYSIS (PART 1): TEMPERATURE AND VELOCITY DISTRIBUTIONS OF EXHAUST GAS, AND CAPTURE EFFICIENCY OF EXHAUST HOOD UNDER OPEN FLAME CONDITION

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Keywords

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