# Analyses and estimation of certain design parameters of micro-grooved   heat pipes

**Authors:** Ramachandran.R, S. Anil Lal

arXiv: 1702.05134 · 2017-02-20

## TL;DR

This paper presents a comprehensive numerical and optimization analysis of micro-grooved heat pipes, focusing on heat conduction, transfer requirements, and fluid dynamics to improve design parameters and prevent dry out.

## Contribution

It introduces a novel analysis combining heat conduction, genetic algorithm optimization, and fluid mechanics to better estimate and optimize micro-grooved heat pipe performance.

## Key findings

- Effect of cover plate thickness on heat transfer
- Minimum surface tension needed to prevent dry out
- Impact of inclination angle and viscosity on fluid flow

## Abstract

A numerical analysis of heat conduction through the cover plate of a heat pipe is carried out to determine the temperature of the working substance, average temperature of heating and cooling surfaces, heat spread in the transmitter, and the heat bypass through the cover plate. Analysis has been extended for the estimation of heat transfer requirements at the outer surface of the con- denser under different heat load conditions using Genetic Algorithm. This paper also presents the estimation of an average heat transfer coefficient for the boiling and condensation of the working substance inside the microgrooves corresponding to a known temperature of the heat source. The equation of motion of the working fluid in the meniscus of an equilateral triangular groove has been presented from which a new term called the minimum surface tension required for avoiding the dry out condition is defined. Quantitative results showing the effect of thickness of cover plate, heat load, angle of inclination and viscosity of the working fluid on the different aspects of the heat transfer, minimum surface tension required to avoid dry out, velocity distribution of the liquid, and radius of liquid meniscus inside the micro-grooves have been presented and discussed.

## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1702.05134/full.md

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Source: https://tomesphere.com/paper/1702.05134