Axial and lateral stiffness of spherical self-balancing fiber reinforced rubber pipes under internal pressure

Xu, Guangbiao; Shuai, Changgeng

doi:10.1515/secm-2021-0009

Science and Engineering of Composite Materials

2021

DOI: 10.1515/secm-2021-0009

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Axial and lateral stiffness of spherical self-balancing fiber reinforced rubber pipes under internal pressure

Guangbiao Xu

Changgeng Shuai

Abstract: Fiber reinforced rubber pipes are widely used to transport fluid at locations requiring flexible connections in pipeline systems. The spherical self-balancing fiber reinforced rubber pipes with low stiffness are drawing attention because of their vibration suppression performance under high internal pressure. In this paper, a theoretical model is proposed to calculate the axial stiffness and lateral stiffness of spherical self-balancing fiber reinforced rubber pipes. The inhomogeneous anisotropy of the reinfor… Show more

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Cited by 4 publications

References 17 publications

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Structural design of a balanced cone-spherical fiber-reinforced rubber hose

Cheng,

Gao,

Shuai

et al. 2024

Engineering Optimization

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Structural design of a balanced cone-spherical fiber-reinforced rubber hose

Cheng,

Gao,

Shuai

et al. 2024

Engineering Optimization

View full text Add to dashboard Cite

Structural Design and Mechanical Properties Optimization of a Balanced Fiber-Reinforced Rubber Hose

Cheng,

Gao,

Shuai

et al. 2024

sci adv mater

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This paper focuses on the optimal design of the structure of a balanced fiber-reinforced rubber hose (RH). A multi-spherical RH is proposed. Based on the grid method, the structure optimization design of single-spherical and multi-spherical RHs is performed. According to the constraints, the optimization results of the structural parameters of the RH are solved. Then, combined with the deformation characteristics of the conical RH, the cone-spherical RH is improved based on the spherical RH. The mechanical equilibrium angle and deformation expressions of the cone-spherical RH are deduced. The mechanical model of the balance performance, stiffness, and burst pressure for the cone-spherical RH is constructed. The structural optimization design of double-spherical and double cone-spherical RHs is performed to further reduce the stiffness of the RH based on the multi-spherical RH. Eventually, the correctness of the theoretical model and its optimization results is verified through experiments. The results of this research can provide reference data for future studies in related fields.

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Coefficient of thermal expansion and mechanical properties of modified fiber-reinforced boron phenolic composites

et al. 2022

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Boron phenolic resin is widely used in the aerospace field because of its excellent thermal properties. In this article, nitrile rubber powder was added to phenolic resin to modify fiber-reinforced phenolic resin composites. The results showed that the tensile strength continued to decrease; the elongation ratio increased from 20.01% to 32.04%; and flexural strength and flexural modulus reached the highest values of 188 and 9,401 MPa, respectively. Thermal analysis showed that rubber had little effect on the heat resistance at low temperatures, especially below 350°C. Furthermore, the coefficient of thermal expansion of the composites increased from 8.9 × 10−6 to 1.5 × 10−5 K−1, increasing by nearly 70%. The electron microscopy images showed a tortuous fracture path in modified composites, which indicated that rubber powder–modified phenolic composites had a ductile fracture.

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Axial and lateral stiffness of spherical self-balancing fiber reinforced rubber pipes under internal pressure

Cited by 4 publications

References 17 publications

Structural design of a balanced cone-spherical fiber-reinforced rubber hose

Structural design of a balanced cone-spherical fiber-reinforced rubber hose

Structural Design and Mechanical Properties Optimization of a Balanced Fiber-Reinforced Rubber Hose

Coefficient of thermal expansion and mechanical properties of modified fiber-reinforced boron phenolic composites

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