PEMANFAATAN LIMBAH KOTORAN HEWAN PADA CAMPURAN BETON DI TINJAU DARI KUAT TEKAN
Abstract
Indonesia has a lot of animal waste; this animal waste causes air pollution and becomes a center for the spread of disease. Because cow dung has a silica content of 9.6% per kilogram, silica is the main ingredient in cement, so the study uses cow dung as an additional ingredient in making concrete which will be reviewed from the compressive strength with the proportion of cow dung additives of 0%, 5%, 10% and 15%. This study conducted a normal concrete experiment with a concrete quality of 20 Mpa which was given additional cow dung waste with variations of 0%, 5%, 10% and 15%. Using a cube-shaped test object measuring 15 x 15 x15 at the age of 5 days and will be tested using test objects, testing test objects such as slump testing, and compressive strength to obtain the quality of concrete from the research sample. This study was conducted to produce quality and economical concrete while preventing pollution caused by animal waste by utilizing the waste as an additional ingredient in concrete making. This study used cow dung ash as an additional material of 0%, 5%, 10%, and 15%. The results of this study obtained an average compressive strength of 14.592 MPa for the 0% variation, 14.370 MPa for the 5% variation, 10.22 MPa for the 10% variation, and 9.407 MPa for the 15% variation.
References
Andika, Y., Lisawengen, T., & Mambrak, B. (2022). Pengaruh Plastimen Terhadap Kuat Tekan Beton Pada Berbagai Umur. Jurnal Karkasa, 8(2), 46-49.
Andika, Y., Saputro, I., & Bonde, O. (2021). Studi Eksperimantal Kuat Tekan Beton Menggunakan Material Dari Kali Jodoh. Jurnal Karkasa, 7(1), 22-27.
ASTM – Standart C33. (2003). Standard Spesification for Concrete Aggregates, (ASTM C 33-03). Whest Conshohocken, PA, USA: ASTM International.
D. Mahardika, R. P. Dewanti, and A. Subagyo, “Strategi Green Construction dalam Konstruksi Berkelanjutan Untuk Bangunan Gedung Ramah Lingkungan Dan Ekonomis di Indonesia,” Metta J. Ilmu Multidisiplin, vol. 5, no. 2, pp. 52–61, 2025.
Fawaid & Qudsyi Ainul.(2020). Pengaruh Penambahan Kotoran Sapi sebagai Substitusi Semen terhadap Kuat Tekan Beton. Bogor: library of IPB University
H. Imelda and M. H. Soejachmoen, “Determined Contribution (NDC),” Indones. Res. Inst. Decarbonization, p. 10, 2023.
Hoerudin, D. (2021). Analisa kuat tekan beton K-400 dengan campuran material pengganti semen (slag cement). Jurnal TESLINK: Teknik Sipil Dan Lingkungan, 3(1), 36–44.
Munthe, Sonia Sonita. (2019). Pemanfaatan Limbah Pecahan Beton Sebagai Pengganti Sebagian Agregat Terhadap Kuat Tarik Belah Dengan Fas 0,3 Dan 0,5. Fakultas Teknik Universitas Medan Area.
N. Bertoldo, T. Qureshi, D. Simpkins, A. Arrigoni, and G. Dotelli. (2023). “Concrete with Organic Waste Materials as Aggregate Replacement,” Appl. Sci., vol. 14, no.1, p. 108.
Putri, I. S. A., Sofia, D. A., & Kamal, M. I. H. (2022). Analisis Penggunaan Reclaimed Asphalt Pavement (RAP) Terhadap Kuat Tekan Beton. SEMNASTERA (Seminar Nasional Teknologi Dan Riset Terapan), 4, 380–385
R. R. S. Riwayati and R. Habibi. (2020). “Pengaruh Penambahan Zat Aditif Sika Viscocrete Terhadap Kuat Tekan Mutu Beton K-300 Umur 14 Hari,” Jurnal Tekno Global, vol. 9, no. 2.
SNI 03 – 2834 – 2000 .2000. Tata Cara Pembuatan Rencana Campuran Beton Normal. Badan Standarisasi Nasional
W. A. Prakayuda, A. Halim, and C. Aditya (2021), “Pengaruh Penambahan Damdex Pada Campuran Beton Terhadap Kuat Tekan dan Modulus Elastisitas Beton,” Bouwplank, vol. 1, no. 2.
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