The provision of insulation on the pipe functions to prevent heat transfer, but the provision of this insulation causes the pipe to be susceptible to damage due to oxidation. In this study, an analysis of damage to insulated pipes will be carried out using a Digital Detector Array (DDA), Computed Radiography (CR), and XRF. Based on the test results, it is known that the image quality using DDA with a voltage of 240 kV produces the most optimal contrast resolution. The results of the thickness dimension measurement using the DDA method on insulated pipes are 3.38 mm, and on insulated pipes with artificial defects are 4 mm. Compared with the CR method, the values are 3.02 mm and 3.94 mm, respectively. The smaller the difference, the more accurate. From the calculation of the ISee software, it is also known that the DDA method can detect a greater number of defects, namely 24, compared to the CR method, which has only 14. The results of the XRF test show that the insulated pipe includes low-carbon steel with a carbon content of 0.057% and 94% ferrum. This high ferrous content contributes to increased X-ray absorption, greatly affecting the images quality.

Insulated pipe; Digital Detector Array; Computed Radiography; X-Ray Fluorescence

Y. Hardika, “Pemilihan bahan baja untuk sistem perpipaan dalam industri migas,” 2017.

U. Utilitas and J. Tengah, “1. PENDAHULUAN Unit utilitas merupakan unit penunjang operasi dalam proses pengolahan minyak yang berfungsi penting dalam penyediaan segala kebutuhan energi dan fluida yang diperlukan seperti air olahan,” no. 2010, pp. 1–7, 2015.

M. W. Silaban, “Pipa Berkarat di Balik Kebocoran Minyak Pertamina di Laut Karawang,” Tempo.co. Accessed: Apr. 23, 2021. [Online]. Available: https://bisnis.tempo.co/read/1455565/pipa-berkarat-di-balik-kebocoran-minyak-pertamina-di-laut-karawang

B. Hanurajie and Suparno, Nondestructive testing Radiography. [s.n] : Jakarta., 2019.

U. Zscherpel et al., "Radiographic evaluation of corrosion and deposits in pipelines: Results of an IAEA co-ordinated research program," 9th Eur. Conf. NDT, no. December, pp. 1–14, 2006.

InternationalStandardOrganistion, “INTERNATIONAL STANDARD Non-destructive testing of welds —,” vol. 2013, 2013.

A. Riska, H. Lubis, P. N. Lhoksuemawe, T. Double, W. Double, and S. A-tig, “Journal of Welding Technology. Volume 4, No. 2, December 2022,” pp. 60–63.

A. Kontras, D. Radiography, and D. Menggunakan, “Gravitasi,” vol. 20, no. 1, pp. 10–18, 2021, doi: 10.22487/gravitasi.v20i1.15521.

G. A. Wiguna, “EFEK PERUBAHAN TEGANGAN (kV) DAN ARUS FILAMEN (mA) PADA TEKSTUR CITRA MIKRO RADIOGRAFI DIGITAL,” J. Pendidik. Teknol. Inf., vol. 1, no. 1, pp. 20–27, 2018, doi: 10.37792/jukanti.v1i1.7.

“ISO 17636-2, Non-destructive testing of welds – Radiographic testing – Part 2: X- and gamma-ray techniques with digital detectors,” vol. 2022, 2022.

U. Ewert, U. Zscherpel, M. Jechow, and B. Redmer, “How to Make an Exposure Chart for Computed Radiography,” 18th World Conf. Nondestruct. Test. , no. April, 2012, [Online]. Available: https://www.ndt.net/article/wcndt2012/workshop/Ewert_WCNDT_Exposure_Diagram_2012_04.pdf

H. M. Harun, M. Musdalifah, and S. Sumarsono, “Faktor Reject Film Radiografi Menggunakan Computed Radiography Di Rs Bhayangkara Makassar,” Lontara J. Heal. Sci. Technol., vol. 3, no. 1, pp. 32–37, 2022, doi: 10.53861/lontarariset.v3i1.268.

P. Brouwer, Theory of XRF. 2010.

A. Tjahjono, Fisika Logam dan Alloy. Tangerang Selatan, 2013.

Xiaohua Gu*, Qinglong Zhao, Shangwen Zhu, Yan Liu, Qingyong Su, Research on the Resourceful and Efficient Recycling Technology of Waste Thermal Insulation Pipe Material, ACS Publication Vol 10/Issue 13, 2025