• Title/Summary/Keyword: Point Detonation

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Rotating Detonation Engine Study in AGU

  • Hayashi, A. Koichi;Uemura, Yuho;Yamada, Takayuki;Yamada, Eisuke
    • Proceedings of the Korean Society of Propulsion Engineers Conference
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    • 2011.11a
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    • pp.1-4
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    • 2011
  • Detonation is useful phenomena to get an effective thrust for aerospace vehicle. Fast pressure rise of detonation provides a cycle close to the constant volume system to use energy efficiently. From this point detonation can be used as an aerospace engine system. There are several types of detonation engine; pulse detonation engine (PDE) which provides a thrust by detonation intermittently, and oblique detonation engine (ODE), spin detonation engine (SDE), and rotating detonation engine (RDE) which, on the other hand, provide a continuous thrust.

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Approximate Analysis Model and Detailed Unsteady Structure of Oblique Detonation Waves (경사 데토네이션파의 근사 해석 모델과 비정상 상세구조)

  • Choi Jeong-Yeol;Kim Don-Wan
    • Proceedings of the Korean Society of Propulsion Engineers Conference
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    • 2005.11a
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    • pp.136-140
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    • 2005
  • By extending one-dimensional ZND detonation structure analysis model, a simple model for two-dimensional oblique detonation wave structure analysis is presented by coupling Rankine-Hugoniot relation and chemical kinetics for oblique shock wave and oblique detonation wave. Base on this study, two-dimensional fluid dynamics analysis is carried out to investigate the detailed unsteady structure of oblique detonation waves involving triple point, transverse waves and cellular structures. CFD results provide a deeper insight into the detailed structure of oblique detonation waves, and the simple model could be used as a unified design tool for hypersonic propulsion systems employing oblique detonation wave as combustion mechanism.

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Experimental Study on the Line Shock Wave in Explosive Welding (폭발용접에서 선형 충격파에 관한 실험적 연구)

  • 김청균;문정기
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.16 no.6
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    • pp.1108-1114
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    • 1992
  • In this paper results from experimental studies on the line wave detonation of explosive welding were presented. Using the ultra high speed comera, the ling wave generation during the bonding, process of composite materials was observed with an equilateral triangle lens. Experimental results confirmed the line wave formation of the shock front. And the results indicated the effectiveness of the ling wave detonation method in the explosive welding of similar or dissimilar metals.

Performance Characteristics of Hydrogen Peroxide Mono Propellant PDE (Pulse Detonation Engine) (과산화수소 단일 추진제 PDE의 성능 특성에 관한 수치적 연구)

  • Cho, Heung-Sik;Jeung, In-Seuck;Choi, Jeong-Yeol
    • 한국연소학회:학술대회논문집
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    • 2003.12a
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    • pp.153-157
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    • 2003
  • Supersonic and hypersonic aircrafts must pass wide range of speed to reach high speed region. But for existing engines the most efficient operating speed ranges are decided according to their flying speed, so an engine which mixes several engines like TRJ (Turbo Ramjet) and ARJ (Air Turbo Ramjet) has been planed. This mixed type engine has inefficiency that more than two engines must be installed simultaneously, but the pulse detonation engine (PDE) that uses detonation wave has a strong point that it can operate in all speed range with single engine. This paper deals with the simulation of the pulse detonation engine which uses hydrogen peroxide $(H_2O_2)$ mono propellant. Hydrogen peroxide is low-cost propellant, and it is reacted without oxidizer. Comparison between $H_2-O_2$ mixture with $H_2O_2$ mono propellant about thrust, pressure, temperature and velocity shows that $H_2O_2$ is a very useful propellant.

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INSTABILITY OF OBLIQUE SHOCK WAVES WITH HEAT ADDITION (후방 발열이 있는 경사 충격파의 불안정성)

  • Choi, J.Y.;Shin, J.R.;Cho, D.R.
    • 한국전산유체공학회:학술대회논문집
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    • 2007.10a
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    • pp.232-235
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    • 2007
  • A comprehensive numerical study was carried out to identify the on-set condition of the cell structures of oblique detonation waves (ODWs). Mach 7 incoming flow was considered with all other flow variables were fixed except the flow turning angles varying from 35 to 38. For a given flow conditions theoretical maximum turning angle is $38.2^{\circ}$ where the oblique detonation wave may be stabilized. The effects of grid resolution were tested using grids from $255{\times}100$ to $4,005{\times}1,600$. The numerical smoked foil records exhibits the detonation cell structures with dual triple points running opposite directions for the 36 to 38 turning angles. As the turning angle get closer to the maximum angle the cell structures gets finer and the oscillatory behavior of the primary triple point was observed. The thermal occlusion behind the oblique detonation wave was observed for the $38^{\circ}$ turning angle.

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Maximum Pressure and the Blast Wave Analysis of a Amount of HMX (HMX의 양에 따른 최대압력 및 폭풍파속도 분석)

  • Kwon, Hweeung;Tak, Kyongjae;Kim, Junghwan;Oh, Min;Chae, Jooseung;Kim, Hyeonsoo;Moon, Il
    • Korean Chemical Engineering Research
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    • v.52 no.6
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    • pp.706-712
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    • 2014
  • Explosives are reactive material that contain a great amount of high potential energy. They produce detonation if released suddenly, accompanied by the production of strong light, high heat, great noise and high pressure. Damage at surrounding detonation point is affected by high pressure and blast wave for explosives detonation. Consequently, analysis of pressure and blast wave is very important. This study focuses on the analysis of maximum overpressure and blast wave of explosives for safety assurance. First of all, four cases of the amount of HMX were selected. Secondly, maximum pressure and blast wave were calculated through detonation simulation along with a set of TNT and HMX quantities. The peripheral effect of detonation point was analyzed by calculating overpressure and absolute velocity and considering detonation occurred in the center of geometry by HMX. Also, maximum overpressure and blast wave of HMX were compared to equivalent amount of TNT, which was taken as a base case and verified through theoretical HMX graph. This study contributes to the base case for overpressure and blast wave of complex gunpowder containing HMX.

Theoretical Study on the High Energetic Properties of HMX/LLM-116 Cocrystals (HMX/LLM-116 공결정의 고에너지 특성에 관한 이론 연구)

  • Kim, Sung-Hyun;Ko, Yoo-Mi;Shin, Chang-Ho;Kim, Seung-Joon
    • Journal of the Korean Chemical Society
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    • v.60 no.1
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    • pp.9-15
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    • 2016
  • The theoretical investigation has been performed to predict detonation velocity, detonation pressure, and thermodynamic stability of HMX/LLM-116 cocrystal. All possible geometries of HMX, LLM-116, and cocrystal have been optimized at the B3LYP/cc-pVTZ level of theory. The binding energy for the trigger bond and cluster has been calculated to predict the thermodynamic stability. The MP2 binding energies were obtained using single point energy calculation at the B3LYP optimized geometries, and the density has been calculated from monte carlo integration. The detonation velocity and detonation pressure have been calculated using Kamlet-Jacobs equation, while enthalpy has been predicted at the CBS-Q level of theory.

Detonation Characteristics of L. P. G /$O_2$Gas Mixture and the Self-Ignition Condition for the Formation of Detonative Wave (액화석유 가스 (L. P. G) 와 산소 혼합물의 폭발특성 및 점화조건에 관한 연구)

  • Sung Nak Choi;Kyu Sun Shim;Un Sik Kim;Sock Sung Yun;Ung Kim
    • Journal of the Korean Chemical Society
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    • v.30 no.4
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    • pp.394-402
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    • 1986
  • Detonation reaction in L.P.G./$O_2$ mixture gas has been investigated over the L.P.G. concentration range of 3∼45 volume%. The variation of detonation velocity with mixture ratio is very interesting as it shows and inflection point near at the stoichiometric ratio. This might be ascribed to the fact that the detonation reactions at fuel-rich condition and fuel-lean condition proceed via different mechanisms. The maximum detonation velocity of 2.65km/sec occurs not at stoichiometric ratio(${\phi}$=1) but at fuel-rich condition (${\phi}$=1.57). Assuming that a stable detonation wave must propagates with the constant velocity, The upper and lower limit of detonation were determined and found to be 40.0 and 3.40 L.P.G. volume% respectively. The shock-heating technique was also utilized for the measurement of self-ignition temperature onsetting a stable detonation wave at varous mixture ratios. The self-ignition temperature at stoichiometric ratio is $742{\pm}3{\circ}K$ and the self-ignition temperature increases as the mixture ratio deviates from the stoichiometric condition.

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Method for Determination of Maximum Allowable Pressure of Pressure Vessel Considering Detonation (폭굉을 고려한 압력용기 최대허용압력 결정방법의 제안)

  • Choi, Jinbok
    • Journal of the Computational Structural Engineering Institute of Korea
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    • v.31 no.5
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    • pp.235-241
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    • 2018
  • The internal pressure is a critical parameter for designing a pressure vessel. The static pressure that a pressure vessel must withstand is usually determined according to the various codes and standards with simple formula or numerical simulations considering the geometric parameters such as diameter and thickness of a vessel. However, there is no specific codes or technical standards we can use practically for designing of pressure vessels which have to endure the detonation pressure. Detonation pressure is a kind of dynamic pressure which causes an impulsive pressure on the vessel wall in a extremely short time duration. In addition, it is known that the magnitude of reflected pressure at the vessel wall due to the explosion can be over twice the incident pressure. Therefore, if we only consider the reflected pressure, the design of the pressure vessel can be too conservative from the economical point of view. In this study, we suggest a practical method to evaluate the magnitude of maximum allowable pressure that the pressure vessel can withstand against the detonation inside a vessel. As an example to validate the proposed method, we consider the pressure vessel containing hydrogen gas.

Analysis on Shock Attenuation of STS Bulkhead Initiator (STS 격벽착화기의 충격파 감쇠 특성 해석)

  • Kim, Bohoon;Jang, Seung-gyo;Yoh, Jai-ick
    • Proceedings of the Korean Society of Propulsion Engineers Conference
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    • 2017.05a
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    • pp.440-444
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    • 2017
  • Two-dimensional hydrodynamic analysis was performed to analyze the attenuating characteristics of shock waves generated by the detonation of the bulkhead initiator. Through the interlocking analysis between HNS and HMX stacking initiator and STS bulkhead, we have precisely simulated detonation growth and pressure wave attenuation phenomena. The free surface velocity at the surface of the bulkhead was measured for quantitative comparison with the test data by VISAR. As a result, it was confirmed that the pressure attenuating pattern of the shock wave exponentially decreased according to the bulkhead thickness. The observed inflection point at the particle velocity measured over time is due to the subsequent propagation of the shock wave due to the rapid spallation of the interface between the detonator and the bulkhead.

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