模拟燃料条件下注塑成型玻璃纤维增强聚苯硫醚复合材料的磨损

Q4 Engineering

International Journal of Modern Manufacturing Technologies Pub Date : 2023-06-20 DOI:10.54684/ijmmt.2023.15.1.115

M. Wiater, J. Żmudzki, G. Chladek

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引用次数: 0

摘要

降低二氧化碳排放的要求导致燃料系统组件和材料的负载增加，这需要适应变化的工作条件。假设在高温汽油环境下，玻璃纤维增强聚苯硫醚是可靠的高载荷钢制部件活动联轴器。在模具温度为140 ~ 150℃，注射压力为165 MPa的条件下，将最后筒身距离温度从285℃提高到325℃，进行板样的注塑成型。在207°C/4h退火，在-180°C/4h冷却。板材在汽油混合物中经过了4300h的运行试验和1.2E6的启停负荷间隔。在模拟操作时间范围的30-40%后，板显示出在某些应用可接受范围内的磨损迹象。经过40 ~ 50%的工作时间，瓦片边缘出现损伤，其次是疲劳损伤。试验表明，40% GF-PPS注塑成型仅在有限程度上适用于高负荷零件。

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INJECTION MOLDED GLASS FIBER REINFORCED POLYPHENYLENE SULFIDE COMPOSITE WEAR IN SIMULATED FUEL CONDITIONS

The required lowering of CO2 emission results in increased loading of a fuel system components and thus materials, which require adaptation to the changed working conditions. The hypothesis was that glass-fibre reinforced polyphenylene sulphide is reliable in high loaded movable couplings with steel components under a hot gasoline environment. Plate samples were formed in injection moulding process where mould temperature was 140-150°C and injection pressure 165 MPa, while the temperature at last barrel distance was increased from 285°C to 325°C. Plates were annealed in 207°C/4h and cooled down -180°C/4h. Plates went through 4300h operational tests and 1.2E6 start/stop load intervals in gasoline mixture. The plates after 30-40% of the simulated operating time range showed signs of wear that were within the acceptable range for some applications. After 40-50% of the working time, there was damage on the edges of the tiles, followed by fatigue damage. Tests revealed that injection moulded 40% GF-PPS is suitable for high loaded parts only to a limited extent.

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来源期刊

International Journal of Modern Manufacturing Technologies Engineering-Industrial and Manufacturing Engineering

CiteScore

0.70

自引率

0.00%

发文量

期刊介绍： The main topics of the journal are: Micro & Nano Technologies; Rapid Prototyping Technologies; High Speed Manufacturing Processes; Ecological Technologies in Machine Manufacturing; Manufacturing and Automation; Flexible Manufacturing; New Manufacturing Processes; Design, Control and Exploitation; Assembly and Disassembly; Cold Forming Technologies; Optimization of Experimental Research and Manufacturing Processes; Maintenance, Reliability, Life Cycle Time and Cost; CAD/CAM/CAE/CAX Integrated Systems; Composite Materials Technologies; Non-conventional Technologies; Concurrent Engineering; Virtual Manufacturing; Innovation, Creativity and Industrial Development.