품질경영학회지 (Journal of Korean Society for Quality Management)

  • 제43권3호
  • /
  • Pages.299-312
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  • 2015
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  • 1229-1889(pISSN)
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  • 2287-9005(eISSN)
한국품질경영학회 (Korean Society for Quality Management)
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샌드위치형 레이돔의 전기적 성능개선 위한 성형압력 영향성 연구

A Study on Effects of the Cure Pressure for the Improvement of the Electrical Performance of the Sandwich Type Radome

  • 투고 : 2015.08.05
  • 심사 : 2015.09.14
  • 발행 : 2015.09.30
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초록

Purpose: This paper analyzes the phenomenon on the degradation of the electrical performance by the pressure in the manufacturing process of sandwich type radomes. Methods: This paper consists of two steps to analyze the relation between the electrical performance and the pressure. First, the thickness of the core of the flat panels which were fabricated with different pressure was measured with the microscope, and then the electrical performance of the flat panels was analyzed with simulation and experiment. Based on the results of the electrical performance and the measured thickness with respect to the flat panels, the relation between the electrical performance and the applied pressure in the manufacturing process was analyzed. Results: The simulated and measured results with respect to the flat panel shows that the high pressure results in the nonuniform thickness of the core, which is applied to the radome fabrication. As a result, the degradation of the electrical performance occurs because the unintended scattered field is generated as the electromagnetic wave transmits (or impinges upon) the radome. Furthermore, we observed that the electrical performance of both the flat panel and the radome got worse as the high pressure was applied. Conclusion: Through simulation and experiment, therefore, it is demonstrated that for the high pressure in the manufacturing process the nonuniform thickness of the core increases and results in the degradation of the electrical performance of the radome.

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참고문헌

  1. A. Kedar, U. K. Revankar. 2006. "Parametric study of flat sandwich multilayer radome." Progress in Electromagnetics Research. PIER 66:253-265. https://doi.org/10.2528/PIER06111202
  2. C. Park, C. Park. 1997. "Missile Radome Analysis using Surface Integration Method." 1st Annual IEEK SP Technology Conference 21(1).
  3. D. J. Kozakoff. 2010. Analysis of radome-enclosed antennas. Archech House. Norwood:81-84.
  4. Fiber Reinforced Epoxy Prefreg. $121^{\circ}C$ Cure. 83PS006.
  5. Gordon, R. K., and R. Mittra. 1993. "Finite element analysis of axisymmetirc radomes. " IEEE Trans. Antennas Propagat 41(7):975-981. https://doi.org/10.1109/8.237631
  6. H. Choi, H. Jeon, and J. Nam. 2000. "Bondline Strength Evaluation of Honeycomb Sandwich Panel For Cure Process and Moisture Absorption." Korean Soc. Mech. Eng, 25(1):115-126.
  7. IEEE Standard Test Procedures for Antennas. IEEE Std 149(R2008).
  8. J. A. Shifflett. 1997. "CADDRAD: a physical optics radar/radome analysis code for arbitrary 3D geometries." IEEE Antennas Propagat. Mag, 39:73-79. https://doi.org/10.1109/74.646806
  9. J. D. Walton. 1970. Radome Engineering Handbook. Marcel Dekker Inc.
  10. Korea Defence Standard. 2010. 5985-4003. FWD HB XMT Radome.
  11. O. I. Sukharevsky, S. V. Kukobko, and A. Z. Sazonov. 2005. "Volume integral equation analysis of a two dimensional radome with a sharp nose." IEEE Trans. Antennas Propagt. 53(4):1500-1506. https://doi.org/10.1109/TAP.2005.844406
  12. S. Kang, and J. Kum. 2008. "A Study on the Factor to Influnce Permittivity in the Radome Manufacturing Process." Korea Institute of Maritime Information and Communication Sciences 13(2).
  13. W. Kim, I. Koh, and J. Yook. 2010. "3D isotropic dispersion (ID)-FDTD algorithm: update equation and characteristics analysis." IEEE Trans. Antennas Propagt. 58(4):1251-1259. https://doi.org/10.1109/TAP.2010.2041311
  14. X. C. Nie, N. Yuan, L. W. Li, T. S. Yeo, and Y. B. Gan. 2005. "Fast analysis of electromagnetic transmission through arbitrary shaped airborne radome using precorrected-FFT method." Progress in Electromagnetics Research. PIER 54:37-59. https://doi.org/10.2528/PIER04100601
  15. Y. L. Zou, J. Y. Li, and Q. Z. Liu. 2007. "Modified mode decomposition for analyzing antennas with body of revolution radome." Journal of Electromagnetic Waves Applications 21(10):1403-1410. https://doi.org/10.1163/156939307783239519