Perilaku Keruntuhan Balok Beton Mutu Normal Dengan Pengekangan Pada Daerah Tekan

Behavior Of Collapse Of Normal Quality Concrete Beam With Confinement On Pressure Area

Authors

  • Tahan Tahan Universitas Kristen Palangka Raya

DOI:

https://doi.org/10.33084/mits.v8i2.1435

Keywords:

beton mutu normal, beban maksimum, deformasi, variasi jarak sengkang

Abstract

Concrete is a widely used construction material now Compared to other materials such as wood and steel. This is because the constituent material is easy to obtain, has enough strength, good durability, the making process is easy and in terms of economic price affordable. Concrete is Generally classified into two classes, namely normal quality and high quality. Both of them are now widely used in the construction activities. Normal quality concrete has a quality of 20 Mpa up to 58 MPa, while high quality concrete ranges above 58 Mpa. One of the applications in the structures is collapse behavior concrete beams on the normal quality of norm with the confinement on the pressure area. To analyze the effect of collapse behavior of normal quality concrete beams and varied Finite Element Analysis (FEA) by using ANSYS Ed. 9.0 with stirrups variation space in te respective spans (40, 80,120,150) mm and stirrup variation distance in the respective field (40,80,120,125,150,100,75.50) mm with 15/20 beam size. The steel material used has stress power of 400 each Mpa, stirrup stress 200 Mpa, normal quality stress 25 Mpa. Based on manual analysis and FEA the magnitude of ultimate capacity that occurs in the model of the beam with the dense stirrup on the stress area the ultimate moment value will rise both in the moment span area and in the field. The deformation is decreasing and the crack behavior on the pressure area can be minimized

Downloads

Download data is not yet available.

Author Biography

Tahan Tahan, Universitas Kristen Palangka Raya

Lecturer of Civil Engineering, Universitas Kristen Palangka Raya

References

ANSYS Release 11. 2007. Programmer's Manual for ANSYS. ANSYS Incorporations and ANSYS Europe, Ltd. (http://ansys.com diakses tanggal 5 September 2009).

American Concrete Institute (ACI) 1999 SLAB DESIGN In Accordance with ACI 318-77 Supplement To: Design Handbook in Accordance with the strength Design Method ACI PUBLICATION SP-17(73)(S).

Army, B. Perilaku Pelat Lantai Jembatan Beton Komposit Pracetak dan Cast In Place Tanpa Tulangan Geser Horizontal Akibat Beban Statis Terpusat. Jurnal Ilmiah Poli Rekayasa Volume 1, Nomor 2, Maret 2006 ISSN: 1858 - 3709.

Basuki, N. H, 2006 (Eksperimental Model Balok)

Badan Peneliti dan Pengembangan, Departemen Pekerjaan Umum, Standard dan Pedoman Bahan Konstruksi Bangunan dan Rekayasa Sipil. Edisi 2009

Bridge Management System (BMS). 1992. Direktorat Jenderal Bina Marga Departemen Pekerjaan Umum.

Chang. 1998, Bond in Reinforced Concrete Behavior and Design Criteria, ACI Journal January-February 1986.

Chu-Kia Wang Charles G.Salmon Reinforced Concrete Design, Fourth Edition.

Ese Soedarsono HS, Design and Detailing of Flat Slab, 27 February 2002.

http://www.gussuta.com/teknik/perpustakaan-teknik-sipil.html

Jack C. Mc Cormac. Desain Beton Bertulang Edisi Kelima Jilid 2 Penerbit Erlangga Jakarta.

Kodur, V.K.R. Bisby, L.A. Evaluation of Fire Endurance of Concrete Slabs Reinforced With FRP Bars. Journal of Structural Engineering. ASCE. 131 (1). 2005. Pp 34-43 (http://link.aip.org diakses tanggal 4 Agustus 2009).

Mac Gregor, J. G. 1997. “Reinforced Concrete: Mechanics and Design 3rd Ed.” Prentice-Hall International, Inc.

Matsui. 1997. Tinjauan perilaku tegangan lekat pada struktur beton bertulang dengan Metode Semi Beam dan Pull Out

Mulyono, Tri. Teknologi Beton, CV. ANDI OFFSET Yogyakarta Indonesia 2003.

Neville, A. Aitcin, P. C. High Performance Concrete-an overview Journal of Material and Structure. 31. March 1998. pp 111-117.

Parvanova, Sonia. L., et al. 2004. Modeling The Nonlinear Behaviour of R/C Beams With Moderate Shear Span and Without Strirrups Using Ansys. National Science Fund. Bulgaria

Purwono, R . 2005. Tata Cara Perhitungan Struktur Beton Bertulang Tahan Gempa (SN103-1726-2002). Edisi ketiga ITS Press. Surabaya. Indonesia

Purwono, R. Tavio,Iswandi I, I.Gusti Putu R. Tata Cara Perhitungan Struktur Beton Untuk Bangunan Gedung. (SNI 03-2847-2002) Dilengkapi Penjelasan [S-2002]. ITS Press. Surabaya. Indonesia

Park, R., Gamble, W. L. 1993 Reinforced Concrete Slabs

Shah, S. P. Ahmad, S.H. 1994. High Performance Concrete: Properties and Applications. McGraw-Hill Companies, (http://linkinghub.elsevier.com diakses Tanggal 4 Agustus 2009)

Zhenhua, Wu. 2006. Behaviour of High-Strength Concrete Members Under Pure Flexure and Axial - Flexural Loadings. Disertation Civil Engineering North Carolina State University. Raleigh, North Carolina.

Downloads

Published

2020-06-01

How to Cite

Tahan, T. (2020). Perilaku Keruntuhan Balok Beton Mutu Normal Dengan Pengekangan Pada Daerah Tekan: Behavior Of Collapse Of Normal Quality Concrete Beam With Confinement On Pressure Area. Media Ilmiah Teknik Sipil, 8(2), 125–131. https://doi.org/10.33084/mits.v8i2.1435