• Title/Summary/Keyword: UNDerwater EXplosion(UNDEX) shock test

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A Study on the Characteristics of Underwater Explosion for the Development of a Non-Explosive Test System (무폭약 시험 장치 개발을 위한 수중폭발 특성에 대한 연구)

  • Lee, Hansol;Park, Kyudong;Na, Yangsub;Lee, Seunggyu;Pack, Kyunghoon;Chung, Hyun
    • Journal of the Society of Naval Architects of Korea
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    • v.57 no.6
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    • pp.322-330
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    • 2020
  • This study deals with underwater explosion (UNDEX) characteristics of various non-explosive underwater shock sources for the development of non-explosive underwater shock testing devices. UNDEX can neutralize ships' structure and the equipment onboard causing serious damage to combat and survivability. The shock proof performance of naval ships has been for a long time studied through simulations, but full-scale Live Fire Test and Evaluation (LFT&E) using real explosives have been limited due to the high risk and cost. For this reason, many researches have been tried to develop full scale ship shock tests without using actual explosives. In this study, experiments were conducted to find the characteristics of the underwater shock waves from actual explosive and non-explosive shock sources such as the airbag inflators and Vaporizing Foil Actuator (VFA). In order to derive the empirical equation for the maximum pressure value of the underwater shock wave generated by the non-explosive impact source, repeated experiments were conducted according to the number and distance. In addition, a Shock Response Spectrum (SRS) technique, which is a frequency-based function, was used to compare the response of floating bodies generated by underwater shock waves from each explosion source. In order to compare the magnitude of the underwater shock waves generated by each explosion source, Keel Shock Factor (KSF), which is a measure for estimating the amount of shock experienced by a naval ship from an underwater explosionan, was used.

The Shock-Test Result and Analysis Using Dual-Pulse Shock Testing Machine (이중충격파형 충격시험장비를 이용한 충격시험 결과 및 분석)

  • Bae, Jongsoo
    • Journal of the Korea Institute of Military Science and Technology
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    • v.21 no.3
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    • pp.342-348
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    • 2018
  • The important issue of equipment installed in maritime weapon system is shock survivability against underwater explosion(UNDEX). If the shock survivability of equipment should not be guaranteed, the successful mission also could not be achieved. For that reason, the shock-resistance of each equipment under UNDEX environment should be demonstrated before deployment at combat field. However, the actual UNDEX test on the ocean is too expensive to conduct. Also, it has diverse dangerous factors. The main characteristic of UNDEX is a dual-pulse shock. The vertical shock test machine able to simulate dual pulse shock signal on the ground will be introduced in this paper. The dual-pulse shock signal presented in certain shock standard was achieved with this shock-test machine on the ground. The analytical procedure to set a test condition was verified by comparing simulation result with experiment result.

Verification of Underwater Blasting Response Analysis of Air Gun Using FSI Analysis Technique (FSI 해석기법을 이용한 에어건 수중발파 응답해석 검증)

  • Lee, Sang-Gab;Lee, Jae-Seok;Park, Ji-Hoon;Jung, Tae-Young;Lee, Hwan-Soo;Park, Kyung-Hoon
    • Journal of the Society of Naval Architects of Korea
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    • v.54 no.6
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    • pp.522-529
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    • 2017
  • Air gun shock system is used as an alternative energy source as part of the attempt to overcome the restrictions of economical expense and environmental damage, etc., due to the use of explosives for the UNDerwater EXplosion (UNDEX) shock test. The objectivity of this study is to develop the simulation technique of air gun shock test for the design of model-scale one for the near field non-explosive UNDEX test through its verification with full-scale SERCEL shock test result. Underwater blasting response analysis of full-scale air gun shock test was carried out using highly advanced M&S (Modeling & Simulation) system of FSI (Fluid-Structure Interaction) analysis technique of LS-DYNA code, and was verified by comparing its shock characteristics and behaviors with the results of air gun shock test.

Development of Measurement System for the Underwater Explosion Shock Test of Naval Ships (함정의 수중폭발 충격시험을 위한 계측장비 시스템 개발)

  • 박일권;조대승;김종철
    • Journal of the Society of Naval Architects of Korea
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    • v.40 no.4
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    • pp.66-74
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    • 2003
  • In non-contact underwater explosion shock test of a real naval ship, measurement of shock loadings and responses should require onboard system to be able to safely trigger an explosive and to simultaneously and successfully measure scores of shock signals in the deteriorated environment. For this purpose, we have developed a shock-hardened measurement system resistible to 170g peak acceleration having 4 msec duration by resiliently mounting general purpose measurement instruments in racks. The system can simultaneously measure and record 200 signals to evaluate shock leadings and responses of the test ship by triggering an explosive and measurement instruments at the same time. We prove the performance of the developed system by introducing the signal acquisition results from of a real ship underwater shock test, firstly performed in Korea.

A Study on Shock Test Design Method Using Linear Dynamic Model of Light Weight Vertical Shock Test Machine (경중량 수직형 충격 시험 장비의 선형 동역학 모델 수립을 통한 충격 시험 설계 기법에 관한 연구)

  • Kim, Junhyeok;Oh, Boo-Jin;Im, Damhyeok
    • Journal of the Korea Institute of Military Science and Technology
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    • v.24 no.1
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    • pp.70-78
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    • 2021
  • Naval surface ships and submarines could be exposed to non-contact underwater explosion(UNDEX) environment. Equipment installed on the ships and submarines could be damaged by shock load generated by UNDEX environment. Therefore, shock survivability of equipment generally evaluated by shock tests. Ground based shock test machine such as Light weight shock test machine(LVSM) is developed to simulate shock load caused by UNDEX environment. In this study, linear dynamic model of LVSM is proposed and evaluated to improve shock test design procedure. Parameters of the model are decided by optimizing time domain response compared to zero payload experiment. Proposed model is verified by comparing simulation results and test results of maximum payload experiment. Finally, shock test design using the model is described for various test equipment weight.