Bioinspired Microgroove’s Geometry Design and Finite Element Analysis of Bursting Influence Parameters for Metal-based Rupture Diaphragms

doi:10.1007/s42235-024-00614-3

Journal of Bionic Engineering ›› 2025, Vol. 22 ›› Issue (1): 293-305.doi: 10.1007/s42235-024-00614-3

Bioinspired Microgroove’s Geometry Design and Finite Element Analysis of Bursting Influence Parameters for Metal-based Rupture Diaphragms

Peilin Cao1; Cong Wang1; Zhenzhi Mu2; Shichao Niu2; Xiao Liu3; Xiaosong Feng3; Linpeng Liu1; Zhiwu Han2

1 State Key Laboratory of Precision Manufacturing for Extreme Service Performance, College of Mechanical and Electrical Engineering, Central South University, Changsha 410083, China
2 Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130022, China
3 Shanghai Aerospace Equipment Manufacture Co., Ltd, Shanghai 200245, China

出版日期:2025-01-03 发布日期:2025-02-19
通讯作者: Linpeng Liu E-mail:linpengliu@csu.edu.cn
作者简介:Peilin Cao1; Cong Wang1; Zhenzhi Mu2; Shichao Niu2; Xiao Liu3; Xiaosong Feng3; Linpeng Liu1; Zhiwu Han2

Bioinspired Microgroove’s Geometry Design and Finite Element Analysis of Bursting Influence Parameters for Metal-based Rupture Diaphragms

Peilin Cao1; Cong Wang1; Zhenzhi Mu2; Shichao Niu2; Xiao Liu3; Xiaosong Feng3; Linpeng Liu1; Zhiwu Han2

1 State Key Laboratory of Precision Manufacturing for Extreme Service Performance, College of Mechanical and Electrical Engineering, Central South University, Changsha 410083, China
2 Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun 130022, China
3 Shanghai Aerospace Equipment Manufacture Co., Ltd, Shanghai 200245, China

Online:2025-01-03 Published:2025-02-19
Contact: Linpeng Liu E-mail:linpengliu@csu.edu.cn
About author:Peilin Cao1; Cong Wang1; Zhenzhi Mu2; Shichao Niu2; Xiao Liu3; Xiaosong Feng3; Linpeng Liu1; Zhiwu Han2

摘要/Abstract

摘要： Serving as the initiating explosive devices between the propellant tank and the engines, metal-based rupture diaphragms are widely used in ramjet igniters owing to the advantages provided by their simple structure, small size, and low cost. However, the reliability of rupture pressure directly affects the success of engine ignition and rocket launch, which is mainly influenced by factors like material, structure, and residual thickness of the surface notch of the diaphragm. Among those, the geometry of the notch is easy to define and control when compared to the mechanical parameters of the ruptured diaphragm. Thus, to make the diaphragm rupture (1A30 Al) within the required pressure range (0.4 MPa?±?3.5%) with highly sensitive and reliability, we draw inspiration from the arthropod’s force-sensitive slit organ which encompasses curved microgrooves to design a Ω-shaped notch for the rupture diaphragm. Finite element analysis is used to study the relationship between the burst pressure and geometric dimension of the Ω-shaped and bioinspired microgroove. Based on that, metal-based rupture diaphragms are fabricated by femtosecond laser processing technology, followed by rupture tests. Experiment results demonstrate that the practical rupture pressure of the diaphragm is highly consistent with the finite element analysis results, which verifies the effectiveness of the bionic design.

关键词: Rupture diaphragm, Bioinspired microgroove, Ω-shaped, Finite element analysis, Burst pressur

Abstract: Serving as the initiating explosive devices between the propellant tank and the engines, metal-based rupture diaphragms are widely used in ramjet igniters owing to the advantages provided by their simple structure, small size, and low cost. However, the reliability of rupture pressure directly affects the success of engine ignition and rocket launch, which is mainly influenced by factors like material, structure, and residual thickness of the surface notch of the diaphragm. Among those, the geometry of the notch is easy to define and control when compared to the mechanical parameters of the ruptured diaphragm. Thus, to make the diaphragm rupture (1A30 Al) within the required pressure range (0.4 MPa?±?3.5%) with highly sensitive and reliability, we draw inspiration from the arthropod’s force-sensitive slit organ which encompasses curved microgrooves to design a Ω-shaped notch for the rupture diaphragm. Finite element analysis is used to study the relationship between the burst pressure and geometric dimension of the Ω-shaped and bioinspired microgroove. Based on that, metal-based rupture diaphragms are fabricated by femtosecond laser processing technology, followed by rupture tests. Experiment results demonstrate that the practical rupture pressure of the diaphragm is highly consistent with the finite element analysis results, which verifies the effectiveness of the bionic design.

Key words: Rupture diaphragm, Bioinspired microgroove, Ω-shaped, Finite element analysis, Burst pressur

Peilin Cao, Cong Wang, Zhenzhi Mu, Shichao Niu, Xiao Liu, Xiaosong Feng, Linpeng Liu, Zhiwu Han. Bioinspired Microgroove’s Geometry Design and Finite Element Analysis of Bursting Influence Parameters for Metal-based Rupture Diaphragms[J]. Journal of Bionic Engineering, 2025, 22(1): 293-305.

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Bioinspired Microgroove’s Geometry Design and Finite Element Analysis of Bursting Influence Parameters for Metal-based Rupture Diaphragms

Bioinspired Microgroove’s Geometry Design and Finite Element Analysis of Bursting Influence Parameters for Metal-based Rupture Diaphragms

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