«Previous Article|Table of Contents|Next Article»

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2023年04期

Page:

68-73

Research Field:

目次

Publishing date:

Info

Title:

Design of large dimensions injector based on selective laser melting technology

Author(s):

KONG Weipeng;  XIE Heng;  WANG Xiaoli

(Beijing Aerospace Propulsion Institute, Beijing 100076, China)

Keywords:

liquid rocket engine;  selective laser melting;  additive manufacturing;  injector;  coaxial shear nozzle;  cold flow test;  hot-fire test

PACS:

V434

DOI:

-

Abstract:

In order to study the feasibility and the optimum scheme of selective laser melting technology applied to the injector of large dimensions liquid rocket engine, the design research was carried out according to the idea of injection unit first and then large dimensions injector. Four different schemes of injection unit test pieces were designed based on selective laser melting technology, and the cold flow test was carried out and the results were compared. Through the comparative test of injection unit, it was concluded that the injector formed by selective laser melting technology was not suitable for the design of large dimensions injector directly. According to the comparison results of the injection unit, the design scheme of the large dimensions injector was selected, the large dimensions injector was produced, and the liquid flow test and hot-fire test were carried out. The results show that the design scheme of forming blank and machining key dimensions by selective laser melting technology is the best scheme for large dimensions injector.

References:

[1] 顾冬冬,张红梅,陈洪宇,等.航空航天高性能金属材料构件激光增材制造[J].中国激光,2020,47(5):32-55.
[2] 任慧娇,周冠男,从保强,等.增材制造技术在航空航天金属构件领域的发展及应用[J].航空制造技术,2020,63(10):72-77.
[3] 刘琦,梁晓康,陈济轮,等.增材制造技术在国外航天领域的研究应用现状[J].导弹与航天运载技术,2016(6):103-106.
[4] 李涤尘,鲁中良,田小永,等.增材制造:面向航空航天制造的变革性技术[J].航空学报,2022,43(4):525387.
[5] 李海涛,谢书凯,张亮,等.增材制造技术在航天制造领域的应用及发展[J].中国航天,2017(1):28-32.
[6] GRADL P R,PROTZ C,GREENE S E,et al.Development and hot-fire testing of additively manufactured copper combustion chambers for liquid rocket engine applications[C]//53rd AIAA/SAE/ASEE Joint Propulsion Conference.Reston,Virginia:AIAA,2017.
[7] GRADL P R,PROTZ C S.Technology advancements for channel wall nozzle manufacturing in liquid rocket engines[J].Acta Astronautica,2020,174:148-158.
[8] BLAKEY-MILNER B,GRADL P,SNEDDEN G,et al.Metal additive manufacturing in aerospace:A review[J].Materials & Design,2021,209:110008.
[9] 田宗军,顾冬冬,沈理达,等.激光增材制造技术在航空航天领域的应用与发展[J].航空制造技术,2015,58(11):38-42.
[10] HAYNES J.Additive manufacturing for liquid rocket engine systems[C]//63rd International Astronautical Congress.Naples,Italy:IAC,2012.
[11] 李晓红,祁萌,朱洪武,等.先进制造技术助力 “太空发射系统”研制[J].国防制造技术,2013(4):5-9.
[12] THOMAS D.Center overview and additive manufacturing at MSFC[Z].2014.
[13] JONES C P,ROBERTSON E H,KOELBL M,et al.Additivemanufacturing a liquid hydrogen rocket engine[EB/OL].https://www.semanticscholar.org/paper/Additive-Manufacturing-a-Liquid-Hydrogen-Rocket-Jones-Robertson/00e
0c78d60fe84b5a540b1d10499ea0862d3544c,2016.
[14] SOLLER S,BEHR R,BEYER S,et al.Design and testing of liquid propellant injectors for additive manufactur-ing[EB/OL].https://www.semanticscholar.org/paper/Design-and-Testing-of-Liquid-Propellant-Injectors-Soller-Be
hr/de260de4298870daa231c30bfb7fd0e9db7b0fdc,2017.
[15] SOLLER S,BARATA A,BEYER S,et al.Selective laser melting(SLM)of Inconel 718 and stainless steel injectors for liquid rocket engines[C]//Space Propulsion Conference 2016.Rome:[s.n.],2016.
[16] GRADL P R,GREENE S E,PROTZ C,et al.Additive manufacturing of liquid rocket engine combustion devices:A summary of process developments and hot-fire testing results[C]//2018 Joint Propulsion Conference.Reston,Virginia:AIAA,2018.
[17] 张武昆,谭永华,高玉闪,等.液体火箭发动机增材制造技术研究进展[J].推进技术,2022,43(5):29-44.
[18] 孙纪国,何学青,阳代军,等.大推力氢氧发动机关键制造技术[J].火箭推进,2022,48(2):117-126.
SUN J G,HE X Q,YANG D J,et al.Key manufacturing technology for large thrust LH₂/LOx cycle engine[J].Journal of Rocket Propulsion,2022,48(2):117-126.

Memo

Memo:

-

Common functions

Last Update: 1900-01-01