• Proceedings of the Korean Society of Propulsion Engineers Conference
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• 1997.11a
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• pp.1-2
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• 1997

인공위성용 추력기는 위성의 자세제어 및 궤도조정용 소형 액체추진기관으로서 개발기술은 인공위성 그 자체는 물론 위성 발사체와 유도 미사일의 추진기관에 이르기까지 다양하게 확장 적용할 수 있는 핵심 기반기술이다. 때문에 선진국으로부터의 기술 이전을 기대하기 힘든 품목으로, 자체 개발을 통해 위성이나 유도무기에 장착 운용시험을 하기에도 막대한 비용 때문에 회피되고 있는 실정이다. (주)한화는 정부에서 국책과제로 추진하고 있는 KOMPSAT 위성 개발사업에 참여하여 소형 액체 추진기관인 단일 추진제 추력기의 개발을 추진하였다 1994년 11월 사업착수 이래 미국 TRW사로부터 추력기 설계, 해석 및 제작 기술을 이전 받았으며, 추력기 제작/시험 시설을 완공하여 TRW사의 제품 품질 요구조건(product assurance requirements)에 의거 제작에 착수하였다. 현재 총 8세트의 이중 추력기 모듈(dual thruster module)을 제작 납품하였으며 또한 추력기 자체의 핵심 부품을 원부자재 가공으로부터 제작하고 이의 인증 시험을 성공적으로 완료하였다. 현재 국산화 추력기를 KOMPSAT 위성에 장착하기 위한 이중 추력기 모듈 제작이 진행 중에 있다.

• Bulletin of the Korean Space Science Society
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• 2002.10a
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• pp.37.2-37
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• 2002

• Transactions of the Korean Society of Mechanical Engineers A
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• v.36 no.11
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• pp.1399-1404
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• 2012

Because satellites operate in space, it is impossible to repair them when they malfunction. Therefore, to ensure the normal function of the payload used in the satellites, accurate assembly and installation of parts are crucial. To prevent abnormal functioning in the extreme environments during launch and in space, it is essential to test changes at the parts and system levels by performing alignment measurement before and after the launch environment test and the space environment test. Recently, noncontact three-dimensional precision machinery for medium- and large-sized parts has been developed. One of these is the theodolite measurement system, which is widely used in the aerospace industry. This study measures the angle of the dual thruster module that is used to control the attitude of KOMPSAT by using a theodolite, and alignment measurement and a reliability analysis are performed.

• Journal of the Korean Society for Aeronautical & Space Sciences
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• v.32 no.6
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• pp.126-133
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• 2004

MRE-1 Dual Thruster Module(DTM), which will be used in KOMPSAT(Korea Multi-Purpose Satellite), can provide reliable and cost-effective means for attitude and maneuvering control system. Thruster heat shield, one of the main components of DTM, is designed to prevent the critical radiative heat exchange between thruster and satellite during firing. To overcome the manufacturing difficulties, a electroforming process is preferred to classical welding process. In this case, an inner diameter of a new shield will be decreased a little due to the change of manufacturing process. Therefore, the interference problem between thruster nozzle and heat shield is investigated through structural analysis and their results are described in this paper.

• Journal of the Korean Society of Propulsion Engineers
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• v.18 no.6
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• pp.59-67
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• 2014

Acceptance level random vibration and life firing test for development model of 1 N-class monopropellant thruster have been performed. From the results of random vibration, the natural frequency of the dual thurst module composed of 1 N-class development model thrusters was higher than the part level requirement(>100 Hz) and the structural robustness was verified. Thrust decrease of steady sate was below 7% and thrust instability was within ${\pm}5%$ in the life firing test using over 20 kg propellant throughput. The computerized tomography for catalyst bed showed a less than 7% of catalyst loss and it revealed the design appropriateness of the current thruster development model.

• Transactions of the Korean Society of Mechanical Engineers B
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• v.27 no.10
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• pp.1377-1384
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• 2003

An analysis has been performed for active thermal control of the KOMPSAT monopropellant rocket engine assembly, i.e., dual thruster module(DTM). The main efforts of this work have been directed at determining proper heater sizes for propellant valves and catalyst beds necessary to maintain their temperatures within specified temperature ranges under KOMPSAT environment and operational conditions. The TAS incorporated with TRASYS thermal radiation analyzer was used to establish a complete heat transfer model which allows to predict the DTM temperature as a function of time. The thermal analysis has been performed in transient mode to verify the appropriate power for catalyst bed heaters necessary to increase catalyst bed temperature to the required value within a specified period of time. Similar analysis has been executed to validate the heater power for the thermostatically controlled primary and redundant heater circuits used to prevent hydrazine freezing, i.e., single fault. Moreover the effect of the radiative property of thermal control coating of heat shield was examined. Thruster firing condition was also simulated for the heat soakback condition. As a consequence, all thermal analysis results for DTM satisfactorily met the thermal requirements for the KOMPSAT DTM under the worst case average voltage, i.e. 25 volt.