水包油乳液射流冲击热金属表面的传热研究

Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering Pub Date : 2022-08-01 DOI:10.11159/htff22.190

K. Nabbout, L. Pasternak, M. Sommerfeld, B. Bock-Marbach, J. Kuhnert, E. Barth, E. Uhlmann

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引用次数: 2

摘要

-这项工作的目的是在数值上和实验上分析液体射流以不同角度(30°，60°和90°)和不同速度(4.7 m/s, 7.0 m/s和9.7 m/s)撞击到由Inconel 718制成的热圆形板上。实验中使用的液体是水和水包油乳液，含8%浓度的霍顿德国有限公司(Houghton Deutschland GmbH) Adrana AY 401矿物油。利用红外摄像机对喷流冷却过程中镀黑后表面进行测量。然后用得到的温度场作为输入来估计换热系数。通过求解一个反传热问题(IHTP)来估计传热系数。此外，还显示了两种液体的润湿面积的瞬态增长。将实验所得的换热系数作为输入，利用有限点集法(FPM)进行数值模拟。通过实验和模拟的对比，验证了MESHFREE软件中最近实现的蒸发模型。

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Heat Transfer Study for Oil-in-Water Emulsion Jets Impinging onto hot Metal Surface

– The purpose of this work is to analyse numerically as well as experimentally liquid jets impinging at different angles (30°, 60° and 90°) and different velocities (4.7 m/s, 7.0 m/s and 9.7 m/s) onto a hot circular plate made of Inconel 718. Liquids used in the experiments are water and oil-in-water emulsion with 8% concentration of the mineral oil Adrana AY 401 from Houghton Deutschland GmbH. An infrared camera is used to measure the black-coated rear face of the plate during the jet cooling process. The temperature field obtained is then used as input to estimate the heat transfer coefficient. The heat transfer coefficient is estimated by solving an Inverse Heat Transfer Problem (IHTP). In addition, the transient growth of the wetting area is also shown for both liquids. The heat transfer coefficient obtained from the experiments are utilised as input in numerical simulations with the Finite-Pointset-Method (FPM). Comparison between experiments and simulations is done to validate the recently implemented evaporation modelling in the MESHFREE software.

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Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering

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