Pembuatan Atap Galvalum Gelombang Trapesium Dimensi 600x102x3 cm, Tebal 0,3 mm, Kapasitas 50 Lembar/Jam

Authors

  • Irfan Nur Rachmadi Putra Politeknik Negeri Malang
  • Syamsul Hadi Politeknik Negeri Malang
  • Gibran Kurnia Ramadhan Politeknik Negeri Malang
  • Mohammad Rafi Rahman Politeknik Negeri Malang
  • Muhammad Syahrul Pahlevi Politeknik Negeri Malang

DOI:

https://doi.org/10.61132/mars.v4i3.1661

Keywords:

Aluminum Zinc Coated Steel, Dimensions 600x102x3 Cm, Galvalum Roof, SNI 4096:2007, Trapezoidal Wave

Abstract

Less rigid, easy to rust trapezoidal wave galvalum roof as a problem encountered in industrial buildings, warehouses, commercial facilities, and residential homes. The purpose of making a trapezoidal wave galvalum roof with dimensions of 600x102 cm, height 3 cm, thickness 0.30 mm. The manufacturing method includes: design of a trapezoidal wave galvalum roof with dimensions of 600x102 cm, height 3 cm, thickness 0.30 mm; selection including purchase of Aluminum Zinc coated steel (BJLAS) materials; design and manufacture of roll-forming; formation of a trapezoidal wave profile with dimensions of 600x102 cm, height 3 cm; cutting the trapezoidal wave galvalum roof every 6 m; and inspection of quality-dimensions-standards. The result of the manufacture is a trapezoidal wave galvalum roof with dimensions of 600x102 cm, 3 cm high, 0.30 mm thick with a total manufacturing cost of Rp. 328,000/sheet, and a manufacturing duration of 1.2 minutes/sheet, which means that the trapezoidal wave galvalum roof meets the dimensional specifications of SNI BJLAS G550-SNI 4096:2007 and is suitable for application as a roof covering system on medium-span buildings.

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Published

2026-06-30

How to Cite

Irfan Nur Rachmadi Putra, Syamsul Hadi, Gibran Kurnia Ramadhan, Mohammad Rafi Rahman, & Muhammad Syahrul Pahlevi. (2026). Pembuatan Atap Galvalum Gelombang Trapesium Dimensi 600x102x3 cm, Tebal 0,3 mm, Kapasitas 50 Lembar/Jam. Mars: Jurnal Teknik Mesin, Industri, Elektro Dan Ilmu Komputer, 4(3), 117–130. https://doi.org/10.61132/mars.v4i3.1661

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