The experiment about the bending behavior of pipe composite based under the low-temperature treatment was carried out. As for the background of this research is that composite material become a suitable design with user need and it has behavior to substitute metal in engineering products. The research aims to investigate the effect of low temperature against to bending strength behavior of pipe from composite epoxy with jute fiber reinforcement. The low-temperature treatment was applied through an immersion process in dry ice as long as 60 minutes to produces a temperature of -33oC. The pipe composite was manufactured in lamination three layers of jute fabric using the vacuum injection molding process (VRTM). Then, the strength of the composite pipe was tested on the three-point bending method according to the ASTM D 790 standard. The testing results show that composite pipe with low-temperature treatment has a flexural strength average of about 76.559 MPa. Meanwhile, the compo-site pipe without treatment shows the strength of flexural average of about 52.435 MPa. They have the strength of flexural inclination is an average of 68%. In addition, the failures of composite in three-point bending test shows a shrank mode on the compression side and flat tearing at tension side due to the material becomes brittle. The conclusion that low-temperature treatment has an effective influence on the pipe composite mechanical properties.

0pt'>

style='mso-spacerun:yes'> ADDIN EN.REFLIST

field-separator'>1 Ngafwan dan Effendi, E. 2015. Analisa kekuatan pipa komposit serat batang pisang polyester yang disusun dua lapis serat 25^o/-25^o terhadap sifat fisis dan mekanis pada temperatur ruang uji 35 ^oc, 45^oc dan 55^oc. Simposium Nasional RAPI XIV - 2015 FT UMS, Surakarta, 268-274.

2 Syamsul Hadi, R.N. Akhsanu Takwin, dan Dani, A. 2016. Uji kekuatan tekan dan kekuatan lentur pipa air pvc. Jurnal logic, 16 (1), 7-13.

3 Kumar, A., Sreekala, K., & Arun, S. 2012. Studies on properties of bio-composites from ecoflex/ramie fabric-mechanical and barrier properties. Journal of Biomaterials and Nanobiotechnology, 03 (3), 396-404.

4 Menshykova, M. & Guz, I.A. 2014. Stress analysis of layered thick-walled composite pipes subjected to bending loading. International Journal of Mechanical Sciences, 88, 289-299.

5 Pamuk, G. 2014. Development of tubular knitted fabric-reinforced composite pipes. Journal of Industrial Textiles, 45 (5), 944-956.

6 Amid, H., Jeddi, A.a.A., Salehi, M., Dabiryan, H., & Pejman, R. 2016. Investigation of circular woven composite preforms for composite pipes. Autex Research Journal, 16 (2), 100-108.

7 Guptaa, M.K., Srivastavaa, R.K., & Bisariaa, H. 2015. Potential of jute fibre reinforced polymer composites: A review. International Journal of Fiber and Textile Research, 5 (3), 30-38.

8 Shubhra, Q.T.H., Alam, A., & Quaiyyum, M.A. 2011. Mechanical properties of polypropylene composites. Journal of Thermoplastic Composite Materials, 26 (3), 362-391.

9 Girijappa, T., Mavinkere Rangappa, Y.G., Parameswaranpillai, & J., Siengchin, S. 2019. Natural fibers as sustainable and renewable resource for development of eco-friendly composites: A comprehensive review. Frontiers in Materials, 6.

10 De Castro, B.D., De Faria, P.E., Vieira, L.M.G., Rubio, C.V.C., Maziero, R., De Matos Rodrigues, P.C., & Rubio, J.C.C. 2020. Recycled green pe composites reinforced with woven and randomly arranged sisal fibres processed by hot compression moulding. Acta Technologica Agriculturae, 23 (2), 81-86.

11 Naidu, A.L. & Rao, P.R. 2016. A review on chemical behaviour of natural fiber composites. International Journal of Chemical Sciences, 14 (4), 2223-2238.

12 Nurazzi, M., Khalina, N., Sapuan, A., Laila, S.D., Rahmah, A., & Hanafee, Z. 2017. A review: Fibres, polymer matrices and composites. Pertanika Journal of Science & Technology, 25 (4).

13 Sanivada, U.K., Marmol, G., Brito, F.P., dan Fangueiro, R. 2020. Pla composites reinforced with flax and jute fibers-a review of recent trends, processing parameters and mechanical properties. Polymers (Basel), 12 (10).

14 Fidelis, A,M.E., Pereira, T.V.C., Gomes, O.D.F.M., De Andrade Silva, F., & Filho, T.R.D. 2013. The effect of fiber morphology on the tensile strength of natural fibers. Journal of Materials Research and Technology, 2 (2), 149-157.

15 Pickering, K.L., Efendy, M.G.A., dan Le, T.M. 2016. A review of recent developments in natural fibre composites and their mechanical performance. Composites Part A: Applied Science and Manufacturing, 83, 98-112.

16 Sature, P. & Mache, A. 2015. Mechanical characterization and water absorption studies on jute/hemp reinforced hybrid composites. American Journal of Materials Science, 5 (3C), 133-139.

17 Dihiaa, S.L., Rachidb, B., & Boualem, S. 2018. Influence of fiber orientation on the behavior of composite pipes subject to internal pressures. Nature & Technology Journal, Vol.A: Fundamental and Engineering Sciences, 18, 77-82.

18 Habibi, M., Selmi, S., Laperrière, L., Mahi, H., & Kelouwani, S. 2019. Post-impact compression behavior of natural flax fiber composites. Journal of Natural Fibers, 17 (11), 1683-1691.

19 Eyvazian, A., Mozafari, H., & Hamouda, A.M. 2017. Experimental study of corrugated metal-composite tubes under axial loading. Procedia Engineering, 173, 1314-1321.

20 Khan, Z.R.M. & Srivastava, S.K. 2018. Development, characterization and application potential of bio-composites: A review. IOP Conference Series: Materials Science and Engineering, 404, 012028.

21 Sebaey, T.A. 2019. Design of oil and gas composite pipes for energy production. Energy Procedia, 162, 146-155.

22 Ighalo, J.O., Adeyanju, C.A., Ogunniyi, S., Adeniyi, A.G., Abdulkareem, S.A. 2020. An empirical review of the recent advances in treatment of natural fibers for reinforced plastic composites. Composite Interfaces, 1-36.

23 Li, S., Guo, X., Li, Q., Ruan, D., & Sun, G. 2020. On lateral compression of circular aluminum, cfrp and gfrp tubes. Composite Structures, 232, 111534.

24 Suresh, G., Srinivasan, T., Meganathan, S., Ramu, P., Ravi, R., Sai Krishnan, G., & Vivek, S. 2020. Experimental analysis of compressive behavior of e-glass fiber reinforced ipn (vinyl ester/polyurethane) composite pipes. IOP Conference Series: Materials Science and Engineering, 988, 012011.

25 Akkus, N., & Kawahara, M. 2000. Bending behaviors of thin composite pipes with reinforcing nodes. Materials Science Research International, 6 (2), 131-135.

26 Graupner, N. & Müssig, J. 2010. Technical applications of natural fibres: An overview. Industrial applications of natural fibres: structure, properties and technical applications, 1, 73-86.

27 Sadat, A. dan Chakraborty, K. 2015. Jute-a biological eixir with multifaceted applications: An overview. International Journal of Research in Pharmaceutical Sciences, 6 (4), 323-332.

28 Sayem, A.S.M., Haider, J., & Sayeed, M.A. 2020. Development and characterisation of multi-layered jute fabric-reinforced hdpe composites. Journal of Composite Materials, 54 (14), 1831-1845.

29 Sápi, Z. & Butler, R. 2020. Properties of cryogenic and low temperature composite materials – a review. Cryogenics, 111, 103190.

30 Vinod, B. & Sudev, L.J. 2019. Study on influence of curing temperature on tensile properties of jute and hemp reinforced hybrid polymer composites. Journal of Physics: Conference Series, 1240, 012029.

31 Vinod, B. & Sudev, L.J. 2019. Investigation on effect of cryogenic temperature on mechanical behavior of jute and hemp fibers reinforced polymer composites. Applied Mechanics and Materials, 895, 76 - 82.

32 Asim, M., Paridah, M.T., Chandrasekar, M., Shahroze, R.M., Jawaid, M., Nasir, M., & Siakeng, R. 2020. Thermal stability of natural fibers and their polymer composites. Iranian Polymer Journal, 29 (7), 625-648.

33 Jirawattanasomkul, T., Likitlersuang, S., Wuttiwannasak, N., Ueda, T., Zhang, D., & Voravutvityaruk, T., 2020. Effects of heat treatment on mechanical properties of jute fiber-reinforced polymer composites for concrete confinement. Journal of Materials in Civil Engineering, 32 (12), 04020363.

34 Zakriya, G.M. & Ramakrishnan, G. 2019. Jute and hollow conjugated polyester composites for outdoor & indoor insulation applications. Journal of Natural Fibers, 16 (2), 185-198.

35 Leblanc, J., 2019. Response of composite materials to dynamic and low temperature environments.

36 Firouzsalari, E., Dizhur, S., Jayaraman, D.K., Chouw, N., & Ingham, J.M. 2020. Flax fabric-reinforced epoxy pipes subjected to lateral compression. Composite Structures, 244, 112307.

"Times New Roman","serif";mso-fareast-font-family:"Times New Roman";mso-ansi-language:

EN-AU;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'>

style='mso-element:field-end'>