Liquefaction of Soil
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Liquefaction of Soil
- 1. Liquefaction of soil By Dr. J.N.Jha Professor Department of Civil Engineering Guru Nanak Dev Engineering College Ludhiana Email: jagadanand@gmail.com
- 2. Chile earthquake 1960 : An island near Valdivia- Mag. 9.5 Large settlements and differential settlements of the ground surface - Compaction of loose granular soil by EQ
- 3. Japan earthquake 1964: Niigata- Mag. 7.5 Settlement and tilting of structures - liquefaction of soil
- 4. Alaska earthquake 1964:Mag. 9.2 Major landslide - combination of dynamic stresses and induced pore water pressure
- 5. Caracas earthquake 1967: Mag. 6.6 Response of building during EQ found to depend on the thickness of soil under the building.
- 10. Site approximately same distance from the zone of energy release
- 12. velop
- 16. Damage potential coefficient varies with building characteristics and soil depth
- 17. Relationship between building characteristics, soil depth and damage potential coefficient (S v /k) Structure Fundamental period Damage intensity (D r ) 2 to 3 storey 0.2 sec Remains same regardless of soil depth 4 to 5 storey 0.4 sec Max. damage intensity expected at soil depth of about 20 to 30 m 10 to 12 storey 1.0 sec Damage intensity expected to increase with soil depth up to 150 m or so 15 to 20 storey Damage intensity even greater for soil depth of 150 to 250 m & relatively low for soil depth up to 80 m or so
- 19. Total stress, Pore water pressure and Effective stress Figure-1 Figure-2 Case Total Pressure Pore Pressure Effective Pressure Figure- 1 475 150 325 Figure- 2 475 250 225
- 23. Influence of soil conditions on liquefaction potential
- 24. Liquefaction Damage: 1964 Niigata, Japan
- 25. Tokachi-oki Earthquake: 2003 The Damage of Sewerage Structures kushiro (Town) Lifted up manhole and gushed soil during liquefaction Lifted up manhole
- 26. The Damage of Sewerage Structures Failure Mode (notice : this is only concept) Replaced Soil (Liquefied) Lift-up Force Crack or Residual Strain Sand Boiling Sand Boiling Manhole Flexible Pipe Rigid Pipe Residual Strain Original Soil (Liquefied)
- 27. The Damage of Embankment Structures Toyokoro Collapsed Embankment
- 28. Place where Embankment was collapsed Abashiri River (1) Shibetsu River (6) Kushiro River (5) Kiyomappu River (2) Tokachi River (66) Under investigation Lateral Spread was observed ( ) : the number of collapsed points Tokachi River The Damage of Embankment Structures
- 29. Toyokoro Liquefied Soil Collapsed Embankment The Damage of Embankment Structures Liquefied Soil
- 30. Failure Mode (notice : this is only concept) Liquefied Stratum Embankment Settlement Land Slide Lateral Spread The Damage of Embankment Structures
- 31. The Damage of Port Structures (at Kushiro Port) Kushiro Settlement behind Quay Wall Trace of Sand Boiling
- 32. Alaska Earthquake ( 1964 )
- 34. Caracas ( 1967 )
- 35. Alaska 2002 Boca del Tocuyo, Venezuela, 1989
- 36. Lateral spread at Budharmora ( Bhuj, 2001 )
- 37. Arial view of kandla port, Marked line sows ground crack and sand ejection (Gujrat Earthquake 2001)
- 38. Adverse effects of liquefaction Most catastrophic ground failure Lateral displacement of large masses of soil Mass comprised of completely liquefied soil or blocks of intact material riding on a layer of liquefied soil Flow develop in loose saturated sand or silts or relatively steep slope (>3 degree) Flow failure
- 43. Soil conditions in Areas where Liquefaction has occurred : Case Study: Niigata Earthquake
- 49. Relationship between depth of pile, ‘N’ of sand at pile tip and Extent of Damage (Zone-C)
- 51. Condition of soil before and after earthquake Relative density (D) of sand with depth before and after earthquake D vs depth of layer of three section charaterized by predominant period T p of microseismic vibrations
- 53. Case Study: Others sites Site Soil Property Standard Penetration Mino-Owari,Tonankai and Fukui Earthquakes D 10 ~ 0.05 to 0.25 mm Uniformity coefficient < 5 <10 (upper 30 ft) Jaltipan Earthquake D 10 ~ 0.01 to 0.1 mm Uniformity coefficient ~2 to 10 Alaska Earthquake D 10 ~ 0.01 to 0.1 mm Uniformity coefficient ~2 to 4 < 20 to 25
- 57. Cross-section(Retaining Geogrid Reinforced cohesionless backfill)
- 58. Field Performance of wall 4 O.P. Fixed in the Wall: To monitor the lateral movement of wall top away from backfill using Electronic Distance Meter for a period of 36 months
- 60. Hyogoken Nambu Earthquake 1995 Height of wall – 4 to 8 m Conventional Retaining Wall – suffered maximum damage Geo-synthetic reinforced soil retaining wall –Performed very well (due to relatively high ductility of the wall)
- 64. SAFETY AGAINST LIQUEFACTION Zone Depth below ground level ‘ N’ value III, II, I Up to 5 m 15 III, II, I Up to 10 m 25 I and II (For important structure) Up to 5 m 10 I and II (For important structure) Up to 10 m 20