EFFECT OF ADDITIVE ZEOLITE MATERIALS ON THE STRENGTH OF RED BRICK POST BURNING

Prima Eko Agustyawan(1*), Samsul Arif(2),

(1) Civil Engineering Study Program, Faculty of Engineering, Islamic University of Lamongan
(2) Civil Engineering Study Program, Faculty of Engineering, Islamic University of Lamongan
(*) Corresponding Author

Abstract


This research aims to determine how to make bricks with additive Zeolite with a composition of 14%, 16%, 18%, and 20%. This research method using the experimental method, this research concludes that red bricks are added with additive Zeolite with variations in the addition of 14%, 16%, 18%, and 20%. 2 samples were made for each additional percentage of Zeolite Additive, with the mold size according to the fabrication length 21 cm x 10 cm x 5 cm. By going through the drying process for approximately 14 days and burning for approximately 3 days. The resulting increase in compressive strength even though some of the variants experienced a decrease. The addition of the red brick variant with a composition of 0% produces an average compressive strength of 30.95 kg / cm. The 14% variant produces an average compressive strength of 35.71 kg / cm2, the 16% variant produces an average compressive strength of 40.48 kg / cm2, 18% and 20% variants produces an average compressive strength of 33.33 kg / cm2. The highest increase in compressive strength is the 16% variant, with an average compressive strength value of 40.48 kg / cm2

Keywords


Red Bricks; Zeolite Additive Substances; Red Bricks; Compressive Strength;

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P. Lingkungan, “Kata kunci : Inovasi batu bata, limbah plastik, abu sekam padi,” vol. 2, no. 2, pp. 109–114, 2019.

D. A. N. Abu and S. Gergaji, “PENINGKATAN KUALITAS PRODUK BATU BATA MERAH DENGAN,” pp. 175–181.

A. Fernanda, Iswan, and Setyanto, “Studi Kekuatan Pasangan Batu Bata Pasca Pembakaran Menggunakan Bahan Additive Zeolit,” J. Rekayasa Sipil dan Desain, 2012.

jurusan teknik Sipil and Yohanto, “PENDAHULUAN Latar Belakang Sorong merupakan salah satu kota yang terletak di jalur,” no. 27, 2013.

A. B. U. Terbang, “Perbaikan Karakteristik Batu Bata Lempung Dengan Penambahan Abu Terbang,” J. Tek. Sipil Univ. Atma Jaya Yogyakarta, vol. 7, no. 2, pp. 165–179, 2007.

T. Andayono and E. Juliafad, “Karakteristik Batu Bata Campuran Hasil Sedimentasi Penambangan Batu Gamping Area 412,3 Ha Bukit Tajarang,” INVOTEK J. Inov. Vokasional dan Teknol., 2019, doi: 10.24036/invotek.v19i1.581.

K. T. Mueller, R. L. Sanders, and N. M. Washton, “Clay minerals,” eMagRes, 2014, doi: 10.1002/9780470034590.emrstm1332.

A. NISA, “Kesehatan Air Minum,” J. Chem. Inf. Model., pp. 4–26, 2010.

Munasih and T. Priyasmanu, “Batu Bata dengan Campuran Abu Sekam Padi di Desa Saptonegoro, Kecamatan Pakis, Kabupaten Malang,” Ind. Inov., 2016.

B. Singh, “Rice husk ash,” in Waste and Supplementary Cementitious Materials in Concrete: Characterisation, Properties and Applications, 2018.

A. L. Putro and D. Prasetyoko, “Abu Sekam Padi Sebagai Sumber Silika Pada Sintesis Zeolit ZSM-5,” Akta Kim. Indones., 2007.

M. S. Ismail and A. M. Waliuddin, “Effect of rice husk ash on high strength concrete,” Constr. Build. Mater., 1996, doi: 10.1016/0950-0618(96)00010-4.

M. Winterhalter, “Black lipid membranes,” Current Opinion in Colloid and Interface Science. 2000, doi: 10.1016/S1359-0294(00)00063-7.

B. E. D. E. Hegazy, H. A. Fouad, and A. M. Hassanain, “Brick manufacturing from water treatment sludge and rice husk ash,” Aust. J. Basic Appl. Sci., 2012.

P. Lingkungan, “Kata kunci : Inovasi batu bata, limbah plastik, abu sekam padi,” vol. 2, no. 2, pp. 109–114, 2019.

D. A. N. Abu and S. Gergaji, “PENINGKATAN KUALITAS PRODUK BATU BATA MERAH DENGAN,” pp. 175–181.

A. Fernanda, Iswan, and Setyanto, “Studi Kekuatan Pasangan Batu Bata Pasca Pembakaran Menggunakan Bahan Additive Zeolit,” J. Rekayasa Sipil dan Desain, 2012.

jurusan teknik Sipil and Yohanto, “PENDAHULUAN Latar Belakang Sorong merupakan salah satu kota yang terletak di jalur,” no. 27, 2013.

A. B. U. Terbang, “Perbaikan Karakteristik Batu Bata Lempung Dengan Penambahan Abu Terbang,” J. Tek. Sipil Univ. Atma Jaya Yogyakarta, vol. 7, no. 2, pp. 165–179, 2007.

T. Andayono and E. Juliafad, “Karakteristik Batu Bata Campuran Hasil Sedimentasi Penambangan Batu Gamping Area 412,3 Ha Bukit Tajarang,” INVOTEK J. Inov. Vokasional dan Teknol., 2019, doi: 10.24036/invotek.v19i1.581.

K. T. Mueller, R. L. Sanders, and N. M. Washton, “Clay minerals,” eMagRes, 2014, doi: 10.1002/9780470034590.emrstm1332.

A. NISA, “Kesehatan Air Minum,” J. Chem. Inf. Model., pp. 4–26, 2010.

Munasih and T. Priyasmanu, “Batu Bata dengan Campuran Abu Sekam Padi di Desa Saptonegoro, Kecamatan Pakis, Kabupaten Malang,” Ind. Inov., 2016.

B. Singh, “Rice husk ash,” in Waste and Supplementary Cementitious Materials in Concrete: Characterisation, Properties and Applications, 2018.

A. L. Putro and D. Prasetyoko, “Abu Sekam Padi Sebagai Sumber Silika Pada Sintesis Zeolit ZSM-5,” Akta Kim. Indones., 2007.

M. S. Ismail and A. M. Waliuddin, “Effect of rice husk ash on high strength concrete,” Constr. Build. Mater., 1996, doi: 10.1016/0950-0618(96)00010-4.

M. Winterhalter, “Black lipid membranes,” Current Opinion in Colloid and Interface Science. 2000, doi: 10.1016/S1359-0294(00)00063-7.

B. E. D. E. Hegazy, H. A. Fouad, and A. M. Hassanain, “Brick manufacturing from water treatment sludge and rice husk ash,” Aust. J. Basic Appl. Sci., 2012.

I. Sudarsana, I. Made Budiwati, and Y. Angga Wijaya, “KARAKTERISTIK BATU BATA TANPA PEMBAKARAN TERBUAT DARI ABU SEKAM PADI DAN SERBUK BATU TABAS,” J. Ilm. Tek. Sipil, 2011.

M. H. Erna Hastuti, “PENGARUH TEMPERATUR PEMBAKARAN DAN PENAMBAHAN ABU TERHADAP KUALITAS BATU BATA,” J. NEUTRINO, 2012, doi: 10.18860/neu.v0i0.1936.

E. Kawa, M. Bukit, and A. Z. Johannes, “PENENTUAN SIFAT MEKANIS DAN FISIS BATU BATA DENGAN PENAMBAHAN ARANG TEMPURUNG KELAPA ASAL ALOR,” J. Fis. Fis. Sains dan Apl., 2018, doi: 10.35508/fisa.v3i3.605.

A. Alfa, M. Gasali, and R. Yanto, “ANALISA PERBANDINGAN KUAT DESAK BATU BATA,” Selodang Mayang, 2016.

W. Kurniasih, A. Nabiila, S. Nurul Karimah, M. Farhan Fauzan, A. Riyanto, and R. R. Putra, “PEMANFAATAN BATU ZEOLIT SEBAGAI MEDIA AKLIMATISASI UNTUK MENGOPTIMALKAN PERTUMBUHAN ANGGREK BULAN (Phalaenopsis) HIBRIDA,” BIOMA J. Ilm. Biol., 2017, doi: 10.26877/bioma.v6i2.1713.

C. Baerlocher and L. B. McCusker, “Database of Zeolite Structures,” Available at: http://www.iza-structure.org/databases/, 2014.




DOI: http://dx.doi.org/10.30737/ukarst.v4i2.1181

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