Application of immersed boundary method to the simulation of three-dimensional flow in solid rocket motors

Application of immersed boundary method to the simulation of three-dimensional flow in solid rocket motors

The immersed boundary method (IBM) is currently utilized in the simulation of two-dimensional axisymmetric flow in solid rocket motors. In this paper, the IBM is applied to three-dimensional flow fields, keeping the grain surface fixed. Based on the Cartesian grid, a three-dimensional Euler flow sol...

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Veröffentlicht in:AIP advances 2023-06, Vol.13 (6)
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Sprache:eng
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Axisymmetric flow
Ballistics
Boundary conditions
Computer graphics
Data structures
Finite difference method
Finite element method
Flow simulation
Fluid flow
Grid method
Interior ballistics
Mass flow
Mesh generation
Ray tracing
Rockets
Solid propellant rocket engines
Solvers
Three dimensional flow
Two dimensional flow
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description The immersed boundary method (IBM) is currently utilized in the simulation of two-dimensional axisymmetric flow in solid rocket motors. In this paper, the IBM is applied to three-dimensional flow fields, keeping the grain surface fixed. Based on the Cartesian grid, a three-dimensional Euler flow solver is developed using the finite difference method. All boundaries of the flow field are processed using the IBM, including the slip walls, mass flow inlet, pressure outlet, and rotational periodic boundary. Specific implementation of these boundary conditions and the mesh generation process are described. Using the ray-casting approach and the alternating digital tree data structure, an efficient method is proposed to determine the intersection relationship between a rectangular volume grid cell and a triangular surface mesh element. The numerical results of Taylor–Culick flow verify that the developed solver has more than one-order accuracy in space. To conduct the validation of the established method, three typical grains are selected for flow simulations, namely, the perforated cylindrical grain with burning on both the ends and the inner surface, the end-slotted end-burning grain, and the finocyl grain, respectively. The simulated results are compared with those of the zero-dimensional interior ballistics, the two-dimensional axisymmetric IBM, and the body-fitted grid method, verifying the fidelity of the developed three-dimensional flow solver.
doi_str_mv 10.1063/5.0157144
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In this paper, the IBM is applied to three-dimensional flow fields, keeping the grain surface fixed. Based on the Cartesian grid, a three-dimensional Euler flow solver is developed using the finite difference method. All boundaries of the flow field are processed using the IBM, including the slip walls, mass flow inlet, pressure outlet, and rotational periodic boundary. Specific implementation of these boundary conditions and the mesh generation process are described. Using the ray-casting approach and the alternating digital tree data structure, an efficient method is proposed to determine the intersection relationship between a rectangular volume grid cell and a triangular surface mesh element. The numerical results of Taylor–Culick flow verify that the developed solver has more than one-order accuracy in space. To conduct the validation of the established method, three typical grains are selected for flow simulations, namely, the perforated cylindrical grain with burning on both the ends and the inner surface, the end-slotted end-burning grain, and the finocyl grain, respectively. The simulated results are compared with those of the zero-dimensional interior ballistics, the two-dimensional axisymmetric IBM, and the body-fitted grid method, verifying the fidelity of the developed three-dimensional flow solver.</description><identifier>ISSN: 2158-3226</identifier><identifier>EISSN: 2158-3226</identifier><identifier>DOI: 10.1063/5.0157144</identifier><identifier>CODEN: AAIDBI</identifier><language>eng</language><publisher>Melville: American Institute of Physics</publisher><subject>Axisymmetric flow ; Ballistics ; Boundary conditions ; Computer graphics ; Data structures ; Finite difference method ; Finite element method ; Flow simulation ; Fluid flow ; Grid method ; Interior ballistics ; Mass flow ; Mesh generation ; Ray tracing ; Rockets ; Solid propellant rocket engines ; Solvers ; Three dimensional flow ; Two dimensional flow</subject><ispartof>AIP advances, 2023-06, Vol.13 (6)</ispartof><rights>Author(s)</rights><rights>2023 Author(s). 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subjects Axisymmetric flow
Ballistics
Boundary conditions
Computer graphics
Data structures
Finite difference method
Finite element method
Flow simulation
Fluid flow
Grid method
Interior ballistics
Mass flow
Mesh generation
Ray tracing
Rockets
Solid propellant rocket engines
Solvers
Three dimensional flow
Two dimensional flow
title Application of immersed boundary method to the simulation of three-dimensional flow in solid rocket motors
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