炭黑增强高密度聚乙烯管与管板接头的搅拌摩擦焊

Syed Haris Iftikhar , Abdel-Hamid Ismail Mourad , Dinu Thomas Thekkuden , Nizamudeen Cherupurakal , R. Krishnapriya
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引用次数: 1

摘要

处理高腐蚀性流体的工业热交换器应用需要使用热塑性热交换器,因为热塑性塑料具有化学惰性和防污性质。基于搅拌摩擦焊(FSW)技术的非传统连接框架用于形成高质量的热塑性管-管板接头(TTJ)。所提出的技术在热塑性管壳式换热器和管道行业(如法兰到管道接头)具有潜在的应用前景。在这项工作中,使用了由炭黑增强高密度聚乙烯制成的管和管板材料。研究了不同FSW参数(转速、插入深度、管突出量、停留时间)对管拔出行为的影响。FSW技术显示出在广泛的操作条件下的能力。使用FSW工艺实现了517N的最高承载能力,远高于粘合接头。此外,在最大载荷下,它比粘合接头提供了更高的延伸率,最高延伸率为5.161 mm。两个FSW案例提供了77%和58%的剩余片材厚度(大于管道厚度)的高泄漏路径,以及高承载能力和相应的延伸率。基于宏观和SEM的断口形貌研究表明了三种类型的失效行为:韧性、脆性或混合型,具体取决于FSW工艺条件。DSC结果显示焊接材料中没有显著的结晶度变化。TGA结果显示焊接材料中没有发生显著的热降解。此外,FTIR分析表明焊接材料可能被氧化。形成具有高泄漏路径、高承载能力和无显著材料降解的TTJ的能力使FSW技术适用于热塑性管壳式换热器应用。
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Friction stir welding of carbon black reinforced high-density polyethylene tube-to-tubesheet joints

Industrial heat exchanger applications dealing with highly corrosive fluids demand the use of thermoplastic heat exchangers because of the chemically inert and anti-fouling nature of the thermoplastics. A non-conventional joining framework, based on the friction stir welding (FSW) technique, is used to form high-quality thermoplastic tube-to-tubesheet joints (TTJs). The proposed technique has potential applications for thermoplastic shell-and-tube heat exchangers and piping industries (as flange-to-pipe joints). In this work, the tube and tubesheet materials made of carbon black reinforced high-density polyethylene were used. The effect of different FSW parameters (rotational speed, plunge depth, tube protrusion, dwell time) on the tube pull-out behavior was investigated. The FSW technique showed capabilities at a wide range of operating conditions. The highest load bearing capacity of 517 N was achieved using the FSW process, much higher than adhesive joints. Also, it provides higher extensions at maximum load than adhesive joints, with the highest extension of 5.161 mm. Two FSW cases provided high leak paths of 77% and 58% remaining sheet thickness (greater than tube thickness) along with high load bearing capacity and corresponding extensions. The macroscopic and SEM-based fractographic studies illustrated three types of failure behavior: ductile, brittle, or mixed depending on the FSW process conditions. The DSC results showed no significant crystallinity changes in the weld material. The TGA results showed no significant thermal degradation occurring in the weld material. Further, the FTIR analysis indicated possible oxidation of the weld material. The capability to form TTJs with high leak path, high load bearing capacity, and no significant material degradations makes the FSW technique suitable for thermoplastic shell-and-tube heat exchanger applications.

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来源期刊
International Journal of Lightweight Materials and Manufacture
International Journal of Lightweight Materials and Manufacture Engineering-Industrial and Manufacturing Engineering
CiteScore
9.90
自引率
0.00%
发文量
52
审稿时长
48 days
期刊最新文献
Editorial Board Editorial Board Modeling and investigation of combined processes of casting, rolling, and extrusion to produce electrical wire from alloys Al–Zr system Characteristics of phases and processing techniques of high entropy alloys Editorial Board
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