A New Approach in Developing Optimal Defrost/Demist Performance in a Passenger Car (TECHNICAL NOTE)

International journal of engineering. Transactions A: basics Pub Date : 2017-04-21 DOI:10.5829/ije.2017.30.07a.18

R. Mehdipour, Z. Baniamerian, M. H. Saidi

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引用次数: 2

Abstract

The objective of this paper is to optimize defrost/demist performance in a vehicle. However, to initiate the problem, it is necessary to have a thorough understanding of flow behavior within the compartment. So a full-scale model of passenger compartment has been modeled and the air stream from very near to the windshield up to back of the compartment has been analyzed applying computational fluid dynamics. A computational C++ code is developed to calculate vapor film thickness glass temperature and some other parameters in different time steps. The code inputs are the air flow parameters resulted from the CFD simulation. Some different flow arrangements are prepared by changing locations of demist panels and outlet pores to evaluate defrost and demist performance. Ultimately, between 6 different cases suggested, the optimum location of demist panels and exit vents is determined. For the case in which warm air enters through left A-Pillar in addition to the bottom panel, and exits through right A-Pillar, the windshield clearance time is minimum for the same initial conditions.

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开发乘用车最佳除霜/除霜性能的新方法(技术说明)

本文的目标是优化车辆的除霜/除霜性能。然而，为了解决这个问题，有必要对隔室内的流动行为有一个彻底的了解。为此，本文建立了全尺寸客舱模型，并应用计算流体力学方法对从靠近挡风玻璃到客舱后部的气流进行了分析。编写了计算性c++程序，用于计算不同时间步长的气膜厚度、玻璃温度和其他参数。代码输入为CFD模拟得到的气流参数。通过改变除霜板和出口孔的位置，制备了不同的流动布置，以评价除霜和除霜性能。最终，在6种不同的情况下，确定了除雾板和出口通风口的最佳位置。在相同初始条件下，当热空气除底部外由左a柱进入，由右a柱排出时，挡风玻璃间隙时间最小。

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

International journal of engineering. Transactions A: basics

CiteScore

3.10

自引率

0.00%

发文量