Pelayanan pengujian kekuatan pipa HDPE di Laboratorium Kimia Material Departemen Teknik Material dan Metalurgi FTIRS-ITS
DOI:
https://doi.org/10.53088/penamas.v4i1.869Keywords:
HDPE pipe, Materials Chemistry Laboratory, Materials Engineering, Metallurgy FTIRSAbstract
HDPE pipes are widely used in various industries, such as drinking water and sewage infrastructure, petroleum, agriculture, and construction. The advantages of HDPE pipes include corrosion resistance, light weight, easy installation, and low maintenance costs. Checking the quality of HDPE pipes, spesifically from industry that we tested, is important to ensure infrastructure safety, prevent system failure, improve operational efficiency, obtain user satisfaction, and conserve resources. We evaluated HDPE pipes with type PN 12.5 SDR 13.6 from industry in terms of resistance to hydrostatic pressure, tensile strength, and expansion capability. The evaluation was carried out at the Material Chemistry Laboratory of the Department of Material Engineering and Metallurgy FTIRS-ITS ITS in accordance with the standards of SNI 4829.2: 2015, ASTM D 638 M, and SNI 2553: 1999. The results show that HDPE pipes can withstand hydrostatic pressure up to 12 bar without leakage. The average tensile strength is 43.34 MPa with an average elongation of 354%, indicating ductile pipe properties with necking. Pipe expansion was observed to be 0.195%, indicating a good ability of the pipe to undergo expansion.
References
Adjogbe, A., Okoronkwo, C., Igbokwe, J., Ezurike, O., & Oguoma, O. (2019). The Impact of Hydrostatic Pressure Test on the Interstitial Strength of Mild-Steel Pipeline Material. Indian Journal of Science and Technology, 12(43), 1–7. https://doi.org/10.17485/ijst/2019/v12i43/144730
American Society for Testing and Materials. (2016). ASTM D638-14, Standard practice for preparation of metallographic specimens. In ASTM International. https://doi.org/10.1520/D0638-14.1
Badan Standardisasi Nasional. (1991). SNI 06-2553-1991: Metode Pengujian Perubahan Panjang Pipa Pvc Untuk Air Minum Dengan Uji Tungku (SNI 06-2553-1991).
Badan Standardisasi Nasional. (2015). SNI 4829.2:2015: Sistem perpipaan plastik-Pipa polietilena (PE) dan fiting untuk sistem penyediaan air minum-Bagian 2: Pipa (SNI 4829.2:2015).
Diana, L., Ghani Safitra, A., & Nabiel Ariansyah, M. (2022). Analisis Kekuatan Tarik pada Material Komposit dengan Serat Penguat Polimer. Jurnal Kesehatan Dan Masyarakat, 2(2), 2808–6171.
Hosking, S. G., Liu, C. C., & Bayly, M. (2010). The visual search patterns and hazard responses of experienced and inexperienced motorcycle riders. Accident Analysis and Prevention, 42(1), 196–202. https://doi.org/10.1016/j.aap.2009.07.023
Mishra, A. K., & Yadaf, L. P. (2018). Quality Assessment of High Density Polyethylene Pipe in Department of Water Supply and Sewerage. Journal of Advanced Research in Civil and Environmental Engineering, 05(04), 18–33. https://doi.org/10.24321/2393.8307.201803
Rahmantiyoko, A., Sunarmi, S., Rahmah, K., Slamet, D., Kunci-Keselamatan, K., & Kerja, K. (2019). Keselamatan dan Keamanan Kerja Laboratorium. IPTEK Journal of Proceedings Series, 4, 36–38.
Ramadani, R., Prastowo, H., & Fitri, S. P. (2015). Analisa Tegangan pada Vertical Subsea GasPipeline Akibat Pengaruh Arus dan GelombangLaut dengan Metode Elemen Hingga. Jurnal Teknik ITS, 4(2), 15–19.
Suyadi. (2007). Kaji Eksperimen Kekuatan Tarik Produk-Produk Berbahan Plastik Daur Ulang. Tek. Mesin Polines, 104–111.
Tabish Wani, Syed Afsar Quadri Pasha, Sanskar Poddar, & Balaji H V. (2020). A Review on the use of High Density Polyethylene (HDPE) in Concrete Mixture. International Journal of Engineering Research And, V9(05), 861–864. https://doi.org/10.17577/ijertv9is050569
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2024 M. Farian Amrulloh, Tubagus Noor R, Sulistijono Sulistijono, Dian Nafi’, Muhammad Fachri
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
