Seung-Won Cha scite author profile

In this study, numerical simulations were conducted to confirm the possibility of improved mixing performance by using a fluidic oscillator as a fuel injector. Three-dimensional URANS non-reacting simulations were conducted to examine air-fuel mixing in a supersonic flow field of Mach 3.38. The numerical methods were validated through simulations of the oscillating flow generated from the fluidic oscillator. The results show that the mass flow rate and momentum are reduced at the outlet because the total pressure loss increases inside the fluidic oscillator, which means that higher pressure needs to be applied to supply the same mass flow rate. The simulation showed that the flow structure varies over time as the injected flow is swept laterally. With lateral injection, the fuel distribution is long and narrow, and asymmetric vortexes are generated. However, with central injection, the fuel distribution is relatively similar to the case of using a simple injector. Compared to the simple injector, the penetration length, flammable area, and mixing efficiency were improved. However, the total pressure loss in the flow field increases as well. The results showed that the supersonic fluidic oscillator could be fully utilized as a means to enhance the mixing effect, however a method to reduce the total pressure loss is necessary for practical application.It is relatively easy to improve the mixing efficiency, but there is a disadvantage of significantly increasing the total pressure loss at a high Mach number. The cavity has been studied because it helps to mix the air-fuel and it can more effectively hold the flame in empty space where a recirculation zone can be formed on the wall [7][8][9][10][11][12][13][14]. A number of studies have been conducted on experiments or numerical simulations to observe the interaction of the cavity with flow fields in the combustion chamber [13] and derive the optimum cavity shape [7][8][9]. Recent studies have been conducted to find ways to improve the mixing performance through more diverse attempts, such as variable cavities and pylons and double cavities [10,11,14].Using the cavity, a scramjet engine can efficiently mix the air-fuel and hold the flame more easily with less total pressure loss. However, combustion instability can occur due to acoustic interference, and additional systems may be needed to compensate for this. A hyper-mixer is a system where a part of the wall of a combustion chamber has a form such as a ramp or a step. The shape generally induces a counter-rotating vortex, which helps to improve the mixing efficiency and expansion of the mixed area [15][16][17][18][19][20][21]. Studies have been carried out on adjusting the angle, arrangement, and shape of the injector [23-25] and using a swirler or counterflow nozzle [26,27].Unlike passive methods, active methods actively intervene in the flow of combustion chambers. Pulsed injection [28][29][30][31][32][33] and the Hartmann-Sprenger (H-S) tube [34,35] are examples of ways to directly affect the flow through variou...

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Concept of Unburning Ratio and Combustion Modeling of ZPP and BKNO₃ in Pyroshock‐Reduced Separation Nut

Woo

Cha

Kim

et al. 2020

Propellants Explo Pyrotec

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Although BKNO 3 ignited by ZPP is commonly used as an explosive charge for many pyrotechnics, only a limited number of modeling studies can be found in the literature. Thus, recently proposed governing equations for combustion modeling of ZPP are supplemented to simulate the combustion of the BKNO 3 with ZPP. The combustion model was independently validated using CBT results with fixed volume chambers of various sizes. In this process, the concept of the unburning ratio was introduced to correlate the combustion modeling with actual phenomena. The term "unburned" means that some fraction of explosive charge turns into non-reactive solid rather than into com-bustion products. The model was then coupled with the equations of motion for the internal moving parts of a pyroshock-reduced separation nut. Tests with prototype were performed to validate the coupled model. For accurate verification, the pressure of the expansion chamber and annular chamber and the displacement of the bolt were measured and compared. All measurements are in good agreement with the analysis results obtained from the coupled model. The results validated the generality of the modeling approach for the simulation of the pyroshock-reduced separation nut.

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Comparison of Performance on Hypersonic Intakes in Off-Design Conditions Through Numerical Simulations

Cha¹,

Roh²,

Lee³

2019

JKSAS

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Seung-Won Cha

Combustion Modeling of Explosive for Pyrotechnic Initiator

Effect of opening area on the suppression of self-ignition of high-pressure hydrogen gas leaking in the air by an extension tube

A Numerical Study on the Characteristics of Air–Fuel Mixing Using a Fluidic Oscillator in Supersonic Flow Fields

Concept of Unburning Ratio and Combustion Modeling of ZPP and BKNO₃ in Pyroshock‐Reduced Separation Nut

Comparison of Performance on Hypersonic Intakes in Off-Design Conditions Through Numerical Simulations

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Seung-Won Cha

Combustion Modeling of Explosive for Pyrotechnic Initiator

Effect of opening area on the suppression of self-ignition of high-pressure hydrogen gas leaking in the air by an extension tube

A Numerical Study on the Characteristics of Air–Fuel Mixing Using a Fluidic Oscillator in Supersonic Flow Fields

Concept of Unburning Ratio and Combustion Modeling of ZPP and BKNO3 in Pyroshock‐Reduced Separation Nut

Comparison of Performance on Hypersonic Intakes in Off-Design Conditions Through Numerical Simulations

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Product

Resources

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Concept of Unburning Ratio and Combustion Modeling of ZPP and BKNO₃ in Pyroshock‐Reduced Separation Nut