한국항공우주학회지 (Journal of the Korean Society for Aeronautical & Space Sciences)

  • 제49권3호
  • /
  • Pages.205-212
  • /
  • 2021
  • /
  • 1225-1348(pISSN)
  • /
  • 2287-6871(eISSN)
한국항공우주학회 (The Korean Society for Aeronautical and Space Sciences)
권호 표지
DOI QR코드

DOI QR Code

플렉셔를 적용한 추력 시험대 설계

Design of a Thrust Stand Using Flexure

  • 투고 : 2020.11.02
  • 심사 : 2021.02.16
  • 발행 : 2021.03.01
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

본 연구에서는 플렉셔를 적용한 추력 시험대 설계를 위해 두 가지 유형에 따른 추력 시험대 모델링을 제시하였다. Type A의 모델은 접선 하중(추력)과 지면에 대한 축 방향 하중(자중)이 압축하중으로 발생되고, Type B의 모델은 축 방향 하중이 인장하중으로 발생되도록 설계를 하였다. 두 가지 유형에 대해 하중에 따른 영향성을 확인하였고, 1D 계산 결과와 전산해석 결과에 대해 비교를 수행하였다. 거리 비(x/L)에 대해 총 10구간을 1D 계산 값과 전산해석 값을 비교하였고 그 결과는 매우 유사한 것을 확인할 수 있었다. 해석 결과에 대한 타당성을 입증하기 위해 플렉셔에 대한 전산해석으로부터 등가응력(Equivalent Stress)을 확인하였고, 항복조건(Von-Mises Yield Criterion) 평가로부터 Type B 모델의 제작을 선정하였다.

In this study, two types of thrust stand modeling were proposed for the design of a thrust stand using flexure. Type A model generate combined load for tangential (thrust) and axial compressive load (self weight). And type B generate combined load for tangential and axial tensile load. The research was done by comparing the influence of the load between the models through a 1D calculation and computational analysis. The 1D calculated value and the computational analysis value were compared for a total of 10 sections and the results were confirmed to be very similar. In order to prove the validity of the analysis results, the equivalent stress was confirmed from the computational analysis of the flexure, and the production of the Type B model was selected from the evaluation of the yield condition (Von-Mises Yield Criterion).

키워드

참고문헌

  1. Runyan, R. B., Rynd, J. P. and Seely, J. F., "Thrust stand design principles," AIAA 17th Aerospace Ground Testing Conference, July 1992.
  2. Mondragon, J. M. and Hubbard, J. E., "Design, Build, and Test of a Thrust Test Stand," AIAA 55th Aerospace Sciences Meeting, 2017.
  3. Vemula, R. C., "Thrust Measurements on a Rocket Nozzle Using Flow-Field Diagnostics," M.S. Thesis, Florida State University, February 2018.
  4. Kim, J. K. and Yoon, I. S., "Functional Analysis of Flexure in a Captive Thrust Stand," Journal of the Korean Society of Propulsion Engineers, Vol. 10, September 2006, pp. 73-81.
  5. Seemann, G. R., "Design of an Experimental Thrust Nozzle Test Stand," M.S. Thesis, Oklahoma State University, August 1960.
  6. Smith, R. E. Jr. and Wehofer, S., "Measurement of Engine Thrust in Altitude Ground Test Facilities," AIAA 12th Aerodynamic Testing Conference, March 1982.
  7. Haag, T, W., "Thrust stand for high-power electric propulsion devices," Review of Scientific Instruments, Vol. 62, May 1991.
  8. Schauer, F. and Depaola, R. A., "Microturbine Turbojets: Experimental Testing and Thermodynamic Modeling," AIAA Scitech Forum, 2020.
  9. Smith, S. T., Flexures: Elements of Elastic Mechanisms, 1st edition, CRC Press, 2000.