The Analysis Behaviour of Arched Strip Foundations

https://doi.org/10.24237/djes.2016.09206

Authors

  • Mohammed Ahmed Elaiwi Al- Hamdani Building and Construction Engineering Department, University of Technology, Baghdad

Keywords:

Plain and reinforced concrete, Arched Strip footing, silty clay and silty sand soil, Nonlinear - Finite element

Abstract

The construction of bearing walls structures does not necessarily require for using plane strip reinforce concrete footings. These structures can construct by using present simple arched plain and reinforced concrete strip footings on silty clay and silty sand soil using finite element. This paper aims at analyzing plain and reinforced concrete arched strip footings, as foundation system of bearing walls structures, as an alternative solution to the construction of buildings. The effect of soil type, arched strip footing's height and the bearing walls vertical load on the dimensions and capacity of arched strip footings study in this paper. A numerical model for the non-linear analysis of arched strip footing-soil interaction problem based on the finite and infinite element implement. A computer program develops to model the arched strip footing-soil installation. The material and geometrical non-linearity of the concrete strip footing takes into account the non-linear stress-strain relation of concrete and presence for cracking also considers. In addition, Duncan-Mohr-Coulomb Modified model uses to simulate soil non-linearity. The obtained numerical results were compared with the traditional method in designing of strip footings commonly used by structural engineers.

Design charts propose and presented for structural designers in order to calculate arched P.C & R.C strip footing dimensions according to type of soil and vertical load such strip footings which consider the cost less than traditional bearing walls construction system. The thickness of strip footing expresses in a non-dimensional ratio (t/B), where (B) is the breadth of the strip footing, with three ratios of 0.1, 0.2, and 0.3 respectively. The height of the arched strip footing was expressed in a non-dimensional form (h/B) with three ratios of 0.1, 0.2 and 0.3 respectively. Four different values of vertical load (P = 20t/m', 30t/m', 40t/m' & 50t/m') investigate in the analysis. Two types of soil; silty clay, and silty sand consider in this study to represent the cases of weak and stiff soil. This result leads to exceptionally low cost up to 30% and safe structures than in case of plane strip footing. The present investigation shows some results that the minimum etc. 

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References

R. Roy, K. Bhattacharya and S.C. Dutta, "Behavior of Grid Foundation under static Gravity Loading" IE (I) Journal. Cr. Vol. 85, February 2005.

B.B.K, Huat, T.A. Mohammed, A.A.A. Abang Aly and A.A. Abdullah, "Numerical and field study on triangular shell footing for low rise building" International journal of eng. and technology, vol. 4, no. 2, pp: 194-204, 2007.

S.S. Abdel-Salam, E.A. Elshamy and H.E. ABd-El-Mottaleb, "Analysis of Plain Concrete Strip Footings as a Foundation of Bearing Walls Structures". Ain Shams Journal of Civil Engineering A S J C E, Sept. 2008

Eman A El-Shamy and Sayed abdel- Salam ,"Non Linear Analysis of Arched Strip Footing", Military Technical College. International Conf. on Civil Eng and Arch. Eng, 4th ICCAE Conf. 16-19 May 2002.

Nainan P. Kurian and VM Jayakrishna Devaki, "Analytical Studies on the Geotechnical Performance of Shell Foundations", can. Ceotech. J. 42(2): 562-573, 2005.

Abdel-Salam, S. S., "Analysis of Reinforced Folded Strip Footing", Third Arab Structural Eng. Conf, U.A.E., Vol. 3, 5-8 March ,1989. 7. Adel Hanna and Mohamed Abdel-Rahman "Experimental Investigation of Shell Foundations on Dry Sand". Can Geotech. J. 35(5): 847-857, 1998.

Adel Hanna and Mohamed Abd EL-Rahman, "Ultimate Bearing Capacity of Triangular Shell Strip Footings on Sand". (ASCE) journal of geotechnical engineering, vol. 116, No. 12, Dece. (1990).

Hanaa E. Abd-Elmottaleb, "Earthquake Nonlinear Modeling of R.C. Buildings Including Foundation-Soil Interaction", Ph.D. Thesis, Structural Eng. Dept. Zagazig University,2005.

Smith, I.M. and Groiffiths, D.V., "Programming the Finite Element Method", John Wiley and Sons Inc., New York, 1988.

Duncan, J. M., Byrne, P., Wong, K. S. and Mobry, P., "Strength, Stress-Strain and Bulk Modulus Parameters for Finite Element Analysis of Stresses and Movement in Soil Masses", Report N°. UCB/GT/78-02, Department of Civil Engineering, University of California, Berkeley, Co. 1978.

Duncan, J.M., "Hyperbolic Stress-Strain Relationships. Proc. of Workshop on Limit Equilibrium, Plasticity and Generalized Stress- Strain In Geotech Eng". McGill Univ. May 28- 30,1980.

Angelou, T. A., "Infinite Element-Theory and Applications", J. Computers and Structures, Vol. 41, No. 5, PP. 959-962, 1991. 14. Zeinkiwiez, O.C., "The Finite Element Methods", 3rd Edition, McGraw-Hill, London,1977.

ACI Committee 318M-318RM, “Building Code Requirements for Structural Concrete and Commentary”, American Concrete Institute, Farmington Hills, Michigan, 2011.

Published

2016-06-01

How to Cite

[1]
Mohammed Ahmed Elaiwi Al- Hamdani, “The Analysis Behaviour of Arched Strip Foundations ”, DJES, vol. 9, no. 2, pp. 27–37, Jun. 2016.