• Title/Summary/Keyword: 와류냉각법

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A study on the cooling enhancement of electronic chips using vortex generator (와류발생기를 사용한 전자칩의 냉각촉진에 관한 연구)

  • Yu, Seong-Yeon;Ju, Byeong-Su;Lee, Sang-Yun;Park, Jong-Hak
    • Transactions of the Korean Society of Mechanical Engineers B
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    • v.21 no.8
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    • pp.973-982
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    • 1997
  • Effect of vortex generator on the heat transfer enhancement of electronic chips is investigated using naphthalene sublimation technique. Experiments are performed for a single chip and chip arrays, and shape of vortex generator, position of vortex generator, stream wise chip spacing and air velocity are varied. Local and average heat transfer coefficients are measured on the top surface of simulated electronic chips, and compared with those obtained without vortex generator. In case of a single chip, heat transfer augmentation is seen only on the upstream portion of chip surface, while heat transfer enhancement is found on the whole surface for chip arrays. Rectangular wing type vortex generator is found to be more effective than delta wing.

Analysis of Flow and Heat Transfer in Swirl Chamber for Cooling in Hot Section (고온부 냉각을 위한 스월챔버내의 유동 및 열전달 해석)

  • Lee K. Y.;Kim H. M.;Han Y. M.;Lee S. Y.
    • Journal of computational fluids engineering
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    • v.7 no.3
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    • pp.9-16
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    • 2002
  • Most of modem aerospace gas turbines must be operated at a gas temperature which is several hundreds of degrees higher than the melting temperatures of the materials used in their construction. Complicated cooling schemes need to be employed in the combustor walls and in the high pressure turbine stages. Internal passages are cast or machined into the hot sections of aero-gas turbine engines and air from the compressor is used for cooling. In many cases, the cooling system is engineered to utilize jets of high velocity air, which impinge on the internal surfaces of the components. They are categorized as 'Impinging Cooling Method' and 'Vortex Cooling Method'. Specially, research of new cooling system(Vortex Cooling Method) that overcomes inefficiency of film cooling and limitation of space. The focus of new cooling system that improves greatly cooling efficiency using less amount of cooling air on surface heat transfer elevation. Therefore, in this study, a numerical analysis has been peformed for characteristics of flow and heat transfer in the swirl chamber and compared with the flow measurements by LDV. Especially, for understanding high heat transfer efficiency in the vicinity of wall, we considered flow structure, vortex mechanism and heat transfer characteristics with variation of the Reynolds number.

A Study of the Prediction of the Temperature Reduction of Tire Sidewalls According to the Shape of the Cooling Fins (냉각핀 형상에 따른 타이어 사이드월의 표면온도 저감 효과 예측에 관한 연구)

  • Park, Jae Hyen;Jung, Sung Pil;Chung, Won Sun;Chun, Chul Kyun
    • Transactions of the Korean Society of Mechanical Engineers B
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    • v.40 no.4
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    • pp.245-253
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    • 2016
  • The friction and deformation of a tire causes heat generation, which causes a temperature rise of the tire. This temperature rise can be a source of tire damage. The object of this study is to investigate the cooling effect of the application of a fin to the tire side to suppress the temperature rise. Eight different fin shapes were considered, and the sidewall surface temperature reduction owing to the cooling fin shape was numerically analyzed. In addition, the flow characteristics and heat transfer characteristics of the vortex of the pin rear were compared.

Effect of Free-Stream Turbulence on Film-Cooling Upstream of Injection Hole on a Cylindrical Surface (자유유동 난류강도가 원형 곡면위의 분사홀 상류에서의 막냉각에 미치는 영향에 대한 연구)

  • Seo, Hyeong-Joon;Kuk, Keon;Lee, Joon-Sik;Lee, Sang-Woo
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.18 no.3
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    • pp.645-652
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    • 1994
  • The leading edge of a turbine blade was simulated as a circular cylindrical surface. The effect of free-stream turbulence on the mass transfer upstream of the injectionhole has been investigated experimentally. The effects of injection location, blowing ratio on the Sherwood number distribution were examined as well. The mass transfer coefficients were measured by a naphthalene sublimation technique. The free-stream Reynolds number based on the cylinder diameter is 53,000. Other conditions investigated are: free-stream turbulence intensities of 3.9% and 8.0%, injection locations of $40^{\circ}$, $50^{\circ}$, and $60^{\circ}$ from the front stagnation point of the cylinder, and blowing ratios of 0.5 and 1.0. The role of the horseshoe vortex formed upstream edge of the injected jet is dicussed in detail. When the blowing ratio is unity, and the coolant jet is injected at $40^{\circ}$, the mass transfer upstream of the jet is not affected by the coolant jet at all. On the other hand, when the injection hole is located beyond $50^{\circ}$, the mass transfer upstream edge of the injection hole suddenly increases due to the formation of the horseshoe vortex, but it dereases as the free-stream turbulence intensity increases because the strength of the horseshoe vortex structure becomes weakened. The role of the horseshoe vortex is clearly evidenced by placing a rigid rod at the injection hole instead of issuing the jet. In the case of the rigid rod, the spanwise Sherwood number upstream of the injection hole is much larger due to the intense influence of the horseshoe vortex.