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Slope Stability Study of Deep Excavation Pit Slope in Soft Bangkok Clay : Case Study of Comparison between Limit Equilibrium and Finite Element Method

��$ ก�ก�� (Warunee Kakarndee)1

��&��ก��U ��' . (Suttisak Sorralump)2

1�� ก�� ก�� (warunee_bn@hotmail.com) 2./012��3�� 45��1��ก�� ก�� (fengsus@ku.ac.th)

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ABSTRACT : Recently, deep excavation work in Soft Bangkok Clay has been growing fast especially the excavation work to use soil as a material. However, these excavations are mostly done with low standard of practice, many failure sites has been found everywhere. The case study of 15 meters excavation pit in Nonthaburi is used as case study, back analysis has been done to simulate the actual failure of the pit. Three method has been used for the analysis namely :Limit Equilibrium Method (LEM), Finite Element Method (FEM) and Stress Based Method (SBM).The underground water level, water level in pit , soil boring log and laboratory testing results were collected to model the slope. The back analysis results found that the underground water level in the model agrees with the actual water level at time of failure. The main cause of failure is sudden the changing of underground water level. KEYWORDS : Limit Equilibrium Method, Finite Element Method, Stress Based Method, Factor of Safety

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��;��:=�3Jก�:(LEM)

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F.S.=τ

fτStressShear

StrengthShear = (1)

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∑∑

SSF (3)

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Parameters Layer γsat

(kN/m3) γunsat

(kN/m3)

E (kN/m2) ν

c′ (kN/m2)

φ′ (°)

1(4) 17.1 11.5 2,399 0.35 5.2 13.49 2(2.5) 16.1 9.7 6,289 0.33 39.0 6.13 3(3) 16.2 10.1 3,267 0.35 13.4 10.56 4(3) 16.0 9.7 9,973 0.35 10.1 9.97

5(1.5) 17.0 12.0 31,290 0.33 173.3 0 6(1.5) 17.0 12.0 52,610 0.33 213.3 0 7(1.5) 18.0 13.0 56,720 0.33 246.7 0 8(3) 18.0 13.0 60,830 0.2 333.3 0 9(10) 18.0 13.0 82,200 0.3 0.2 40

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7. ��% 1. *�กก�:��-ก&�� +�,��,� �� 0:�� ,� 0� �� ก��0�$j $��,�� 1�.�7,� ��,�� 1�. ��+�,,� �?��06o��'�$+��,�� +�,��,0* 2. ก��0�� ,��.�7,� 6��?��ก��0�� 06o��'�$+��,�� +�,�กก��ก��0�� ,�� 1�.

GWL= -2.4 m

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8. ก�--�ก��'%��ก�� . �+��?F7�*��+�+��$��: ��;ก��6�

*��, �� =-��.�7�� 0��;+7�F��i+��+�,,� �o- � �F �; � *� �� $�z � ��ก� ��4 $��4 � �� ก ��0ก&��6��;��ก� ��ก��?��0/��'��.�7 ��ก��$�z ��*�,�1��+7�� ( Building Code) 61��0��2�� ก�� 8 : +7��0ก��ก��ก��+�,,� ��o,�

9. ��$��ก�' [1] ��ก��6o� ��0��2��j, 2546. +7�F�6'�$,� ��0:��

�� 1��0*7�$�� . ��$�$;6��ก��$�$;: ก��0�$j. [2] ��ก� 270��., 2546. ��ก��0+/�� ,� . 2�� : ก��0�$j [3] Dunn I.S. et al. (1980). Fundamentals of Geotechnical

Analysis. John Wiley & Son,Inc. United State of America. [4] Krahn John. (2004). Stability Modeling with SLOPE/W.

An Engineering Methodology.

[5] Nezar Atalla Hammouri ,Abdallah I. Husein

Malkawi,Mohammad M. A. Yamin. (2008). Stability Analysis of Slopes Using the Finite Element Method and Limiting Equilibrium Approach. Bull Eng Geol Environ, 67:471-478.

[6] Duncan J. (1996). State of the Art:Limit Equilibrium and

Finite Element Analysis of Slopes. J Geotech Geoenviron Eng ASCE, 122(7);578-584.

[7] Zaki A. (1999). Slope Stability Analysis Overview.

University of Toronto.

[8] Lane P,Griffiths D. (2000). Assessment of stability of

slope under drawdown conditions. J Geotech Geoenviron Eng ASCE, 126(5);443-450.

[9] Rocscience Inc. (2001). Application of Finite Element

Method to Slope Stability. University of Toronto. [10] Alkasawneha Wael , Abdallah I. Husein Malkawi b,

Jamal Hassan Nusairat c,Nermeen Albataineh c. (2007). A comparative Study of Various Commercially Available Programs in Slope Stability Analysis.

[11] �� ?�ก��0��;��06 ��06o��'�$+��, ,� (5��6�F�:;). ��ก��ก��61��*�0��;06o��'�$+��, ,� . 6o� ��)�ก��+��F�� 6� +�� 2. �F �;�*��$�z �

��ก��4$��4� ��ก: ��0ก&��6��;. [12] ก7��4 ก�ก7., 2547 ก��-ก&�$%��ก��ก�. ��ก�� ก��6�7�� ,� 0� �� ก��0�$. �� $ �;��33� �, ��0ก&��6��;.

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