Additive Manufacturing and Hot Fire Testing of Complex Injectors With Integrated Temperature Sensors

ASME 2019 Power Conference Pub Date : 2019-12-03 DOI:10.1115/power2019-1938

Nawshad Arslan Islam, M. Hossain, A. Choudhuri, P. Morton, R. Wicker

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引用次数: 3

Abstract

The article presents an exploration of design and prototyping of oxy-fuel injectors with integrated temperature sensing capabilities using powder bed fusion additive manufacturing (AM) technologies. A primary focus of this work was to develop powder removal techniques to completely remove sintered powders from internal cavities, which facilitated the implementation of complex injector geometries as well as sensor placements within the parts. It was found that submerging the part in liquid nitrogen, in combination with exposure to ultrasonic vibration, provided effective powder removal. Mechanical testing of fabricated components and test coupons showed no significant change in the mechanical strength of the part due to the addition of liquid nitrogen which creates a thermal shock. Metallography and powder characterization through the use of SEM and EDS showed no change in metallurgical properties of the parts due to the use of liquid nitrogen and ultrasonic energy. The injectors were then test fired in both atmospheric and high-pressure conditions at different firing inputs (55–275 kW).

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具有集成温度传感器的复杂喷油器的增材制造和热火测试

本文介绍了使用粉末床熔融增材制造(AM)技术对具有集成温度传感功能的氧燃料喷射器的设计和原型制作的探索。这项工作的主要重点是开发粉末去除技术，以完全去除内部腔中的烧结粉末，这有助于实现复杂的注入器几何形状以及传感器在部件内的放置。研究发现，将零件浸在液氮中，再加上超声波振动，可以有效地去除粉末。对制造的部件和试样的力学试验表明，由于添加液氮产生热冲击，部件的机械强度没有明显变化。通过SEM和EDS的金相和粉末表征表明，液氮和超声能的使用没有改变零件的冶金性能。然后，在不同的点火输入(55-275 kW)下，在大气和高压条件下进行了喷油器点火测试。

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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ASME 2019 Power Conference

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