Pengaruh Jenis Tanah Terhadap Simpangan Lateral Gedung Beton Bertulang

  • Dermawan Zebua Politeknik Seruyan
  • Leonardus Setia Budi Wibowo Pusat Riset Teknologi Kekuatan Struktur, Badan Riset dan Inovasi Nasional Republik Indonesia
Abstract views: 271 , PDF downloads: 286
Keywords: soil, earthquake, dual system, displacement, reinforced concrete, shear wall

Abstract

As has happened in various cases of earthquakes, the impact caused by each earthquake event varies, because the earthquake shaking that occurs on the ground is not only influenced by the distance and strength of the earthquake, but also by local soil conditions which are related to the amplification phenomenon. earthquake waves are influenced by the type and thickness of the soil/sediment layer above the bedrock. Reinforced concrete storey buildings are designed to withstand both vertical and horizontal loads. The taller the building, the greater the lateral load that will be received by the building structure. In the design of earthquake-resistant structures, the inelastic behavior of the structure is highly expected for the occurrence of earthquake energy dispersion during both moderate and strong earthquakes. In earthquake-prone countries such as Indonesia, it is required to comply with applicable national standards and the structure can still function and be safe from earthquakes affected by the earthquake. The purpose of this study was to determine how much influence the type of soil has on the lateral displacement of a 10-story reinforced concrete building using shear walls in accordance with earthquake building regulations (SNI 1726, 2019) and loading (SNI 1727, 2020). The results obtained that soft soil types have the largest deviation value with a value of 91,831 mm and hard rock soil types have the smallest deviation value with a value of 44,114 mm.

Author Biography

Dermawan Zebua, Politeknik Seruyan

Master of Civil Engineering

References

Cheng, M. Y., Chou, Y., & Wibowo, L. S. B. (2020). Cyclic Response of Reinforced Concrete Squat Walls to Boundary Element Arrangement. ACI Structural Journal, 117(4), 15–24. https://doi.org/10.14359/51725754
Cheng, M. Y., Wibowo, L. S. B., Giduquio, M. B. and Lequesne, R. D. (2021). Strength and Deformation of Reinforced Concrete Squat Walls with High-Strength Materials. ACI Structural Journal, 118(1), 125-137. doi:10.14359/51728082.
Fakhrurrazi, Saidi, T., & Muttaqin M. (2018). Analisis Komparasi Rasio Kapasitas Kolom Gedung Bertingkat Rendah Pada 23 Kabupaten Di Provinsi Aceh Berdasarkan SNI 03-1726- 2002 Dan SNI 03-1726-2012. JARSP: Jurnal Arsip Rekayasa Sipil dan Perencanaan, 1(4), 184-191. https://doi.org/10.24815/jarsp.v1i4.12470
Irsyam M., Dangkua T. D., Kusumastuti D., Kertapati, E. 2007. “Methodology of site specific seismic hazard analysis for important civil structure”. Journal Civil Engineering Dimension 9 (2): 103-112.
Irsyam M., Sengara, I.W., Widiyantoro, S., Natawijaya, D.H., Triyoso, W., Meilano, I., Kertapati, E., Aldiamar, F., Suhardjono, Asrurifak, M, Ridwan, M. 2010. “Ringkasan Hasil Studi Tim Revisi Peta Gempa Indonesia”. Laporan Tim Revisi Peta Gempa Indonesia 2010. Puslitbang Permukiman.
Muslinang Moestopo, Nidiasari. 2010. Kajian Numerik Perilaku Link Panjang Dengan Pengaku Diagonal Badan Pada Sistem Rangka Baja Berpengaku Eksentris, Seminar dan Pameran HAKI.
Nawy, E. G. (2009). Reinforced Concrete (A Fundamental Approach) 6th ed. Pearson Education, Inc.
PPMB-ITB, & PUSKIM. (2021). Desain Spektra Indonesia. http://puskim.pu.go.id/Aplikasi/desain_spektra_indonesia_2021/
Schodek, D. L. and Bechthold, M. (2013). Structures 7th ed. Pearson.
SNI 1726. (2019). Tata Cara Perencanaan Ketahanan Gempa untuk Struktur Bangunan Gedung dan Nongedung. In Badan Standarisasi Nasional.
SNI 1727. (2020). Beban Minimum untuk Perancangan Bangunan Gedung dan Struktur Lain. In Badan Standardisasi Nasional.
SNI 2847. (2019). Persyaratan Beton Struktural untuk Bangunan Gedung dan Penjelasan. In Badan Standarisasi Nasional.
Wibowo, L. S. B., & Zebua, D. (2021). Analisis Pengaruh Lokasi Dinding Geser Terhadap Pergeseran Lateral Bangunan Bertingkat Beton Bertulang 5 Lantai. Ge-STRAM: Jurnal Perencanaan Dan Rekayasa Sipil, 04(01), 16–20. https://doi.org/10.25139/jprs.v4i1.3490
Widodo, 1997, Validasi Parameter Percepatan Tanah dan efek Frekwensi Gempa Terhadap Respon Struktur Bangunan Bertingkat, Journal Teknisia Vol. II, No. 7, pp. 1-15, UII, Yogyakarta.
Zebua, D, Wibowo, L. S. B. (2022). Perbandingan Perpindahan Lateral Gedung Beton Bertulang Dengan Dan Tanpa Dinding Geser. Racic: Rab Construction Research, 7(1), 11-19. https://doi.org/10.36341/racic.v7i1.2399
Zebua, D., & * K. (2022). Performance Evaluation of Highrise Building Structure Based on Pushover Analysis with ATC-40 Method. Applied Research on Civil Engineering and Environment (ARCEE), 3(02), 54–63. https://doi.org/10.32722/arcee.v3i02.4334
Zebua, D., Wibowo, L. S. B., Cahyono, M. S. D., & Ray, N. (2020). Evaluasi Simpangan Pada Bangunan Bertingkat Beton Bertulang berdasarkan Analisis Pushover dengan Metode ATC-40. Ge-STRAM: Jurnal Perencanaan Dan Rekayasa Sipil, 3(2), 53–57. https://doi.org/10.25139/jprs.v3i2.2475
Published
2023-03-30
How to Cite
Zebua, D., & Budi Wibowo, L. S. (2023). Pengaruh Jenis Tanah Terhadap Simpangan Lateral Gedung Beton Bertulang. Ge-STRAM: Jurnal Perencanaan Dan Rekayasa Sipil, 6(1), 7-11. https://doi.org/10.25139/jprs.v6i1.4901
Section
Articles