Critical Heat Flux Enhancement on Cylindrical Tubes With Circumferential Micro-Channels During Saturated Pool Boiling of Water

Volume 8: Fluids Engineering; Heat Transfer and Thermal Engineering Pub Date : 2022-10-30 DOI:10.1115/imece2022-95846

Omar Hernandez Rodriguez, Md Mahamudur Rahman

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Abstract

This work presents the experimental characterization of pool boiling heat transfer enhancement on cylindrical tubes with circumferential micro-channels using saturated water at atmospheric pressure as the working fluid. Three engineered copper tubes with 300 μm, 600 μm and 900 μm fin width and a fixed 400 μm channel width with 410 μm channel depth were machined using CNC. To compare the boiling enhancement on engineered tubes, one plain copper tube was used as the reference heater. The active heating area on the cylindrical tubes had a dimension of 9.5 mm outer diameter and 10.5 mm length. A custom-built cylindrical heater was designed using a nichrome wire coil of 30 AWG with a resistance of 19.57 Ω/inch of coil to provide joule heating to the cylindrical tubes. The electrical wire was insulated from the copper heater using a thin layer of alumina paste. The saturated pool boiling tests up to critical heat flux (CHF) were conducted at atmospheric pressure. While an approximate CHF of ∼70 W/cm2 was achieved for the plain copper tube, the cylindrical tube with microchannel geometry showed a CHF range of 131–144 W/cm2 that corresponds to 87%–100% enhancement as compared to plain cylindrical tube.

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带周向微通道圆柱管饱和池沸腾过程中临界热流密度的增强

本文以常压饱和水为工质，对带周向微通道的圆柱管进行了池沸强化换热的实验研究。采用数控加工技术加工了3根翅片宽度分别为300 μm、600 μm和900 μm的工程铜管和固定的400 μm通道宽度、410 μm通道深度的工程铜管。为了比较工程管的沸腾增强效果，采用一根普通铜管作为参考加热器。圆柱形管上的主动加热区外径9.5 mm，长10.5 mm。采用电阻为19.57 Ω/英寸的30 AWG镍铬合金线圈为圆柱形管提供焦耳加热，设计了定制的圆柱形加热器。电线用一层薄薄的氧化铝糊与铜加热器绝缘。在常压下进行了饱和池沸腾试验，达到临界热流密度(CHF)。虽然普通铜管的CHF约为~ 70 W/cm2，但具有微通道几何形状的圆柱形管的CHF范围为131-144 W/cm2，与普通圆柱形管相比，CHF增强了87%-100%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Volume 8: Fluids Engineering; Heat Transfer and Thermal Engineering

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