Tensile Strength of Carbon Fiber/Epoxy Composite Manufactured by the Bladder Compression Molding Method at Variable Curing Temperatures


Antonius Dwi Setyoko(1*), Gesang Nugroho(2)

(1) Department of Mechanical and Industrial Engineering, Universitas Gadjah Mada Jl. Grafika 2, Yogyakarta 55281, Indonesia
(2) Manufacturing Engineering, Politeknik ATMI Surakarta, Jl. Adisucipto/Jl. Mojo no. 1, Karangasem, Laweyan, Surakarta, 57145, Tlp. 0271 714466
(*) Corresponding Author


Corrosion-resistant, high-strength, low-density composite materials are seeing increased applications in a wide variety of products. The composite constituents of matrix and reinforcement require molding technologies and methods to generate products. The bladder compression molding method is an effective method of manufacturing of composite products with a tubular shape, cavity, and/or closed contour. The properties of the composite materials produced are determined by three variables, namely. curing pressure, temperature, and time. This research was conducted to learn the effect of temperature on the mechanical properties of the composite materials produced from the process with the bladder compression molding method. Based on the thickness, tensile strength, and modulus of elasticity of the product from the experiment conducted, the optimal temperature of the process was found to be 120 ºC


bladder compression molding, mechanical property, carbon fiber-epoxy composite

Full Text:



Anderson, J., & Altan, M. (2012). Properties of Composite Cylinders Fabricated by Bladder Assisted Composite Manufacturing . Journal of Engineering Materials and Technology 134, 1-7.

Anderson, J., & Altan, M. C. (2014). Bladder Assisted Composite Manufacturing (BACM): Challenges and Opportunities. Polymer Processing Society Europe-Africa Conference (hal. DOI10.13140/2.1.2139.6169). Tel Aviv: ResearchGate.

Anderson, J., Kelly, A., & Altan, M. (2013). Fabrication of Composite Laminates by VacuumAssisted Resin Transfer Molding Augmented with an Inflatable Bladder. Researchgate, 2-13.

Askeland, D. R., Fulay, P. P., & Wright, W. J. (2010). The Science and Engineering of Materials, Sixth Edition. Stamford, CT 06902: Cengage Learning.

ASM Handbook. (2000). Mechanical Testing and Evaluation, ASM Handbook Vol. 8. Materials Park, OH 44073-0002: ASM International.

DOI: https://doi.org/10.22146/jmpc.51413

Article Metrics

Abstract views : 1218 | views : 1903


  • There are currently no refbacks.