Effective field testing of concrete structures requires a great deal of rigor and understanding the response and behavior to concrete loads. The bending of the beam tends to be smaller, so reinforcing steel is used to increase the displacement of the beam. However, errors often occur in the implementation so that there is often a decrease in the quality of the concrete. The arrangement of the reinforcement is not in accordance with the requirements for the load received, so it is necessary to create a model according to the load to be applied without conducting multiple trials (trial errors). The abaqus CAE software is a modeling application that belongs to the Finite Element. Modeling reinforced concrete beams in the abaqus application for this study is expected to get results close to experimental tests in the field. namely the comparison between experimental test results of reinforced concrete beams with the results of analysis in the abaqus CAE software. The results of flexure testing of reinforced concrete beams in the field obtained a maximum load value of 106.22 KN with a deflection of 1.126 mm. While the modeling of reinforced concrete beams in the abaqus application obtained a maximum load value of 146.203 KN with a deflection of 4.83 mm.

Andre Renaldi Prameswara (2022). GEDUNG DI KALIMANTAN BARAT Material beton merupakan salah satu material penting yang sering digunakan mengembangkan ilmu dalam pembuatan bulan dan pengujian dilakukan di Sipil Politeknik Negeri Pontianak . Formula ( DMF ) beton K-300 ( fc ’ = Pengujian Beton Analisa Data Pengujian Agregat mengetahui kelayakan dari agregat. 4(3).

Firman, S. (2019). BAB I Latar Belakang Instansi. 1–5. http://repository.stimart-amni.ac.id/613/1/BAB I.pdf

Husni Mubarok. (2019). Finite Element Analysis Perilaku Beton. Finite Element Analysis Perilaku Beton Bertulang Dan Beton Prategang Menggunakan Software Abaqus 6.14.

Malino, L., Wallah, S. E., & Handono, D. B. (2019). Pemeriksaan Kuat Tekan Dan Kuat Tarik Lentur Beton Serat Kawat Bendrat Yang Ditekuk Dengan Variasi Sudut Berbeda. Jurnal Sipil Statik, 7(Juni), 711–722.

Mukrimaa, S. S., Nurdyansyah, Fahyuni, E. F., YULIA CITRA, A., Schulz, N. D., غسان, د., Taniredja, T., Faridli, E. M., & Harmianto, S. (2016). No 主観的å¥åº·æ„Ÿã‚’中心ã¨ã—ãŸåœ¨å®…高齢者ã«ãŠã‘ã‚‹ å¥åº·é–¢é€£æŒ‡æ¨™ã«é–¢ã™ã‚‹å…±åˆ†æ•£æ§‹é€ 分æžTitle. Jurnal Penelitian Pendidikan Guru Sekolah Dasar, 6(August), 128.

Pustaka, T., & Landasan, D. A. N. (2014). Bab 2 tinjauan pustaka dan landasan teori 2.1. Bab Ii, XI(5), 5–13.

Putrianti, P. R., & Setiawan, A. A. (2021). Karakteristik Uji Propertis Dan Campuran Beton Normal. Jurnal Riset Rekayasa Sipil, 5(1), 1. https://doi.org/10.20961/jrrs.v5i1.52251

Runandhani, V., & Bengkalis, P. N. (2022). Pengujian lentur balok beton bertulang dengan penambahan baja ringan.

SURAHMAN, R. (2020). ANALISIS ELEMEN HINGGA PADA BALOK BETON BERTULANG DENGAN PERKUATAN GFRP (Glass Fiber Reinforced Polymer) MENGGUNAKAN SOFTWARE. 8(4), 733–742. http://digilib.unila.ac.id/61551/

Wahyuningtyas, W., Pratama, Y., Krisnamurti, Suyoso, H., & Nurtanto, D. (2021). Modeling Pola Retak Balok Beton BertulangAkibat Beban Lentur. Jurnal Teknik Sipil, 7(1), 53–61. https://journal.unilak.ac.id/index.php/SIKLUS