Validitas Beton Mutu Tinggi Menggunakan Komparasi Campuran Bahan Feldspar terhadap Kuat Lentur
DOI:
https://doi.org/10.55606/jurritek.v5i1.6896Keywords:
Compressive Strength, Concrete Mixture, Feldspar Powder, Fine Aggregates, Sustainable ConstructionAbstract
The development of science and technology generally brings positive impacts in terms of convenience in various human activities, but on the other hand, it also leads to negative consequences such as an increase in waste. One of the significant wastes produced from construction activities, including building and house construction, is feldspar, which typically comes from leftover ceramic materials. Feldspar is a type of waste that is difficult to decompose naturally and has no economic value, often accumulating and polluting the environment. Therefore, innovation is needed to utilize this waste to create value. This study aims to use feldspar powder as a replacement for fine aggregates in K-200 grade concrete mixtures. The research method involved mixing feldspar powder in specific proportions as a substitute for sand, followed by a series of tests, including compressive strength and flexural tests, to determine the feasibility and performance of the resulting concrete. The results indicate that the use of feldspar powder as a fine aggregate produces a concrete mixture with satisfactory mechanical characteristics, meeting the K-200 concrete standards. These findings not only provide an alternative environmentally friendly material but also offer a solution to reduce ceramic waste, contributing positively to sustainable construction.
Downloads
References
American Standard Testing Material. (2003). ASTM C33: Standard specification for concrete aggregates. Annual Book of ASTM Standards. USA.
American Standard Testing Material. (n.d.). ASTM C479: Standard specification for chemical admixtures for concrete.
Antoni, & Nugraha, P. (2007). Teknologi beton. Surabaya: Andi Offset.
Arbain, T. (2019). Sifat mekanis beton dengan campuran pasir pantai dan air laut. JTS Teknologi Sipil, 3(1). https://doi.org/10.30872/ts.v3i1.2765
Asik, J., & Zakariah, A. (2018). Kuat tekan dan lentur beton menggunakan pasir Sungai Maulu dan agregat batu gunung putih. Seminar Nasional Hasil Penelitian, 3, 61–64.
Asroni, A. (2010). Balok dan pelat beton bertulang. Yogyakarta: Graha Ilmu.
Asroni, A. (2010). Struktur beton I. Yogyakarta: Graha Ilmu.
ASTM. (n.d.). ASTM C138-77: Uji berat volume beton segar.
ASTM. (n.d.). ASTM C143-78: Tes slump.
Atmaja, S. H., & Irwansyah, M. (2021). Analisa kuat tekan beton menggunakan agregat halus pasir pantai Bunga dan pasir sungai. Batas, 1(1), 9–18. http://jurnal.una.ac.id/index.php/batas
Badan Standardisasi Nasional. (1990). SNI 03-1969-1990: Metode pengujian berat jenis dan penyerapan air agregat halus.
Badan Standardisasi Nasional. (1990). SNI 03-1969-1990: Metode pengujian slump beton.
Badan Standardisasi Nasional. (1990). SNI 03-1974-1990: Metode pengujian kuat tekan beton.
Badan Standardisasi Nasional. (1991). SNI 15-2531-1991: Pengujian berat jenis semen.
Badan Standardisasi Nasional. (1998). SNI 03-4808-1998: Berat isi agregat kasar dan agregat halus.
Badan Standardisasi Nasional. (2000). SNI 03-2834-2000: Tata cara pembuatan rencana campuran beton normal.
Badan Standardisasi Nasional. (2002). SNI 03-2847-2002: Tata cara perhitungan standar beton untuk bangunan gedung.
Badan Standardisasi Nasional. (2004). SNI 15-2049-2004: Semen Portland.
Badan Standardisasi Nasional. (2004). SNI 17-064-2004: Semen Portland pozzolan.
Badan Standardisasi Nasional. (2008). SNI 03-1972-2008: Cara uji slump beton.
Badan Standardisasi Nasional. (2011). SNI 2493-2011: Tata cara pembuatan dan perawatan benda uji di laboratorium.
Citra, K., Zein, S., Andriansyah, W., Tetap, D., Teknik, P., Aceh, U. M., & Sipil, T. (2020). Pengaruh campuran agregat halus alami berupa pasir laut dan pasir pozzolan terhadap kuat tekan beton mutu tinggi. Jurnal Teknik Sipil, 9(2), 98–105. https://doi.org/10.37598/tameh.v9i2.113
Dhana, R. R. (2019). Analisis pengaruh pemakaian material kerikil gunung Kecamatan Mantup dan serat alami eceng gondok terhadap kuat tekan dan kuat lentur beton. CIVILLa, 4(1). https://doi.org/10.30736/cvl.v4i1.309
Hadi, S. (2020). Analisis jenis pasir terhadap kuat tekan beton. Jurnal Kacapuri: Jurnal Keilmuan Teknik Sipil, 3(2), 146. https://doi.org/10.31602/jk.v3i2.4075
Hepiyanto, R., & Firdaus, M. A. (2019). Pengaruh penambahan abu bonggol jagung terhadap kuat tekan beton K-200. UKaRsT, 3(2). https://doi.org/10.30737/ukarst.v3i2.475
Hermawan, R. T. (2017). Digital repository Universitas Jember. Universitas Jember.
Irsyad, M. (2020). Analisis kuat tekan beton dengan serat limbah kaleng sebagai bahan tambah melalui metode wet curing (Skripsi, Universitas Hasanuddin).
Jepri. (2020). Analisa pengaruh penggunaan limbah genteng beton sebagai subtitusi agregat halus terhadap kuat lentur beton FS.47 (Skripsi, Universitas Bina Dharma).
Mahmud, N. M. (2020). Analisis penggunaan pasir pantai Madale sebagai agregat halus terhadap kuat tekan beton (Skripsi, Universitas Sintuwu Maroso).
Man, N., Gaus, A., & Sultan, M. A. (2021). Comparison of compressive strength value of concrete using pumice sand with ordinary sand as fine aggregate. E3S Web of Conferences, 328, 10017. https://doi.org/10.1051/e3sconf/202132810017
Priyono, S. A., & Agustapraja, H. R. (2021). Limbah bata ringan untuk bahan campuran agregat halus terhadap kuat tekan pada beton K250. Jurnal Teknik, 19(1). https://doi.org/10.37031/jt.v19i1.159
Putri, C. P. (2018). Analisa perbandingan kuat tekan beton ringan menggunakan pasir pantai dan sungai dengan abu sekam padi (Skripsi, Universitas Sriwijaya).
Samsudin, & Hartantyo, S. D. (2017). Studi pengaruh penambahan abu sekam padi terhadap kuat tekan beton. Jurnal Teknika, 9(2), 929–935. https://doi.org/10.30736/teknika.v9i2.58
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2025 JURAL RISET RUMPUN ILMU TEKNIK
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
_001.jpg)
