Use of DMT in Geotechnical Design with Emphasis on Liquefaction Assessment
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The document discusses the use of the Dilatometer Test (DMT) in geotechnical design, particularly focusing on liquefaction analysis. It covers the key parameters of the DMT, data interpretation, correlations with soil behavior, and the assessment of liquefaction, including a case study of the Chi-Chi earthquake in Taiwan. The conclusions highlight the effectiveness of DMT for estimating soil parameters and its advantages in liquefaction assessment compared to traditional methods.
![7. Settlement Prediction
Predicting the settlement of shallow foundations
(particularly for Sands) is one of the best
applications of DMT.
Calculated by means of expression:
S = [ Δσv/MDMT ] ΔZ
Totani, Marchetti, Monaco &
Calabrese (2001)](https://image.slidesharecdn.com/dmtingeotech-170207060554/85/Use-of-DMT-in-Geotechnical-Design-with-Emphasis-on-Liquefaction-Assessment-19-320.jpg)
![Cyclic Stress Ratio (CSR)
Youd et al. (2001)
rd = [1.0 – 0.00765z] (z ≤ 9.2m)
rd = [1.174 – 0.0267z] (9.2 < z ≤ 23m)
rd = [0.744 – 0.008z] (23 < z ≤ 30m)
rd = 0.5 (z > 9.2m)](https://image.slidesharecdn.com/dmtingeotech-170207060554/85/Use-of-DMT-in-Geotechnical-Design-with-Emphasis-on-Liquefaction-Assessment-29-320.jpg)
![References
Marchetti, S. (1980). "In SituTests by Flat Dilatometer." J. Geotech. Engrg. Div.,
ASCE, 106, No.GT3, 299- 321.
G.Totani, S. Marchetti, P. Monaco & M. Calabrese. Use of Flat DilatometerTest
in Geotechnical Design, Intl. Conf. on In-situ Measurement of Soil Properties
(2001)
Monaco, P., Marchetti, S., Totani, G. and Calabrese, M. (2005). “Sand
liquefiability assessment by Flat DilatometerTest (DMT).” Proc. XVI ICSMGE,
Osaka, 4, 2693-2697
Robertson, P.K., and R.G. Campanella, [1986]. “Estimating liquefaction potential
of sands using the flat plate dilatometer. Geotech.Testing J.,Vol. 9, No. 1, pp. 38–
40.
Tsai,Tung and Lee (2001) . Performance of DMT based liquefaction evaluation
method on case history of Chi-Chi Earthquake
Bambang Setiawan,(2011) “Assessing Liquefaction Potential of Soils Utilizing In-
situTesting” M.ScThesis](https://image.slidesharecdn.com/dmtingeotech-170207060554/85/Use-of-DMT-in-Geotechnical-Design-with-Emphasis-on-Liquefaction-Assessment-49-320.jpg)
Use of DMT in Geotechnical Design with Emphasis on Liquefaction Assessment
- 1. USE OF DMT IN GEOTECHNICAL DESIGN WITH EMPHASIS ON LIQUEFACTION ANALYSIS Presented By: Muhammad Ali Rehman
- 2. Overview Introduction Data Interpretation DMT Correlations Liquefaction Liquefaction Assessment Case Study Conclusions References
- 3. DMT Equipment Layout Test Procedure INTRODUCTION
- 4. Dilatometer Test (DMT) Developed by Professor Silvano Marchetti (Italy). Published test procedure & correlations in 1980. DMT measures the lateral deflection of soil.
- 5. Equipment Layout Fig: General Layout of DMT
- 6. Test Procedure DMT in-situ testing involves expanding membrane by using nitrogen gas.
- 7. The primary way of using DMT results is to interpret them in terms of common soil parameters. DATA INTERPRETATION
- 8. Dilatometer Test Parameters Primary parameters of DMT. Material Index ID = (p1 – p0) / (p0 – u0) Horizontal Stress Index KD = (p1 – p0) / σ´v0 Dilatometer Modulus ED = 34.7 (p1 – p0) Pore-pressure Index UD = (p2 – u0) / (p0 – u0)
- 9. • DMT parameters, ID, KD, and ED are used in subsequent soil analysis. DMT CORRELATIONS
- 10. Correlations Soil Behavior Over-consolidation Relative Density Undrained Shear Strength Constrained Modulus Compression Ratio Settlement Prediction Skin friction of Driven Piles SPT N-value and Dilatometer Modulus
- 11. 1. Behavior of Soil Soil behavior chart introduced by Marchetti et al. (1980). ID<0.6 : Clays 0.6≤ID≤1.8 : Silts ID>1.8 : Sands
- 12. 2. Over-Consolidation Ratio (OCR) Original correlation proposed by Marchetti et al. (1980): OCRDMT = (0.5 x KD)1.56 Confirmed by a comprehensive collection of data by Kamei & Iwasaki (1995) for clays. Finno (1993)
- 13. Over-Consolidation Ratio (OCR) Kamei & Iwasaki (1995) Finno (1993)
- 14. 3. Relative Density Reyna & Chameau (1991) and Tanaka & Tanaka (1998) Robertson & Campanella
- 15. 4. Undrained Shear Strength Marchetti et al. (1980): cu = 0.22 σ'v0 (0.5 KD)1.25
- 16. Undrained Shear Strength Comparison of undrained shear strength by DMT and other tests, at National Research Site, Bothkennar (UK): Nash et al. (1992)
- 17. 5. Constrained Modulus : MDMT Obtained by applying correction factor RM to ED MDMT = RM . ED RM is the function of material index (ID) and horizontal stress index (KD). Increases with KD while ID has lesser effect on the RM value. Generally varies from 1 to 3.
- 18. 6. Compression Ratio Marchetti et al. (1980) Pre-consolidated Clays M = σ’p (2.3/CR) Normally Consolidated Clays M = σ’v (2.3/CR)
- 19. 7. Settlement Prediction Predicting the settlement of shallow foundations (particularly for Sands) is one of the best applications of DMT. Calculated by means of expression: S = [ Δσv/MDMT ] ΔZ Totani, Marchetti, Monaco & Calabrese (2001)
- 20. 8. Skin Friction for Driven Piles in Clay Powell et al. (2001 b), developed a method for the design of piles driven in clay. Method predicts pile skin friction qs, from ID and (p1 - p0): ID < 0.1 : qs /(p1 - p0 ) = 0.5 0.1 < ID < 0.65 : qs /(p1 - p0 ) = -0.73077 ID + 0.575 ID > 0.65 : qs /(p1 - p0 ) = 0.1
- 21. 9. SPT N-value & ED Mayne & Frost
- 22. Introduction Liquefiable Soils Liquefaction Assessment LIQUEFACTION
- 23. Liquefaction “Transformation of coarse grained soil from a solid state into a liquid state” Excessive hydrostatic pressure build-up & reduction of effective stress sudden shock cyclic loading. Devastating effects of structure: Tilting of high rise buildings Ground subsidence Surface rupture Collapse
- 24. Liquefiable Soils Loose granular soils are potentially susceptible to liquefaction. Fine grained soils (such as silts and clays) are non- liquefiable. Andrews & Martin (2000) suggested: Potentially Liquefiable: soils having, CF < 10% & LL < 32% Non-Liquefiable: soils having, CF > 10% & LL ≥ 32%
- 25. Liquefaction Assessment Glaser and Chung (1995): Loose granular soils densify on sampling. Laboratory measurements demonstrate higher cyclic strength In-situ testing is preferred. “Simplified Procedure” for liquefaction assessment, proposed by Seed & Idriss (1971). To evaluate the loading to a soil caused by an earthquake (by CSR) To evaluate the resistance of a soil to triggering of liquefaction (by CRR)
- 26. Liquefaction Assessment Factor of Safety against the occurrence of liquefaction is defined as: FS = CRR7.5 /CSR7.5 If FS < 1, liquefaction will be triggered.
- 27. Cyclic Stress Ratio (CSR) CSR is the measure of intensity of cyclic loading during an earthquake. Obtained by formula, developed by Seed & Idriss (1971): CSR 7.5 = 0.65 (amax / g) . (σv0 / σ’vo) . rd amax is the peak horizontal ground acceleration generated by the earthquake. rd is the stress reduction factor.
- 28. Cyclic Stress Ratio (CSR) Seed & Idriss porposed: rd is the function of stratigraphy and depth. Has a value of 1.0 at ground surface, tends to reduce with depth. Seed and Idriss (1971)
- 29. Cyclic Stress Ratio (CSR) Youd et al. (2001) rd = [1.0 – 0.00765z] (z ≤ 9.2m) rd = [1.174 – 0.0267z] (9.2 < z ≤ 23m) rd = [0.744 – 0.008z] (23 < z ≤ 30m) rd = 0.5 (z > 9.2m)
- 30. Cyclic Resistance Ratio In-situ test Procedures: Standard Penetration Test Cone Penetration Test Shear wave velocity test Dilatometer Test
- 31. DMT Based CRR Evaluation Include: Marchetti (1980) Roberstson & Campnella (1986) Reyna & Chameau (1991) Monaco et al. (2005) Grasso & Maugeri (2006) Monaco & Marchetti (2007) Tsai et al. (2001, 2009)
- 32. DMT Based CRR Evaluation Marchetti (1980) proposed the basic correlation: CRR = (KD/10) Refined by Monaco et al. (2005): CRR7.5 = 0.0107KD 3 − 0.0741KD 2 + 0.2169KD – 0.1306 Grasso & Maugeri (2006) further updated Monaco et al. (2005) model into: CRR7.5 = 0.0908KD 3 − 1.0174KD 2 + 3.8466KD – 4.5369
- 33. DMT Based CRR Evaluation Curves for CRR (Reyna & Chameau 1991) Clean sand is safe against liquefaction for following KD values: Non seismic areas: KD > 1.7 Low seismicity areas : KD > 4.2 Medium seismicity areas: KD > 5.0 High seismicity areas: KD > 5.5
- 34. Performance of DMT Based Liquefaction Evaluation of Chi-Chi Earthquake, Taiwan (1999) by Tsai et al. (2001) Case Study
- 35. Chi-Chi Earthquake 21 September 1999, at 1:47 am, an Earthquake hit Taiwan. 7.6 magnitude Epicenter near Chi-Chi (town in Nantou County) 2400 deaths, 8373 Injuries Damage of US$30 billion. Extensive field investigation after earthquake was conducted by NCREE. In-situ SPT & CPT were performed.
- 36. Collection of SPT Data Liquefaction sites: Wufeng, Nantou, Yuanlin & Zhangbin Total 31 SPT Cases 24 liquefied 7 non-liquefied
- 37. Collection of SPT Data Area Test Number Triggering of Liquefaction Wufeng SPT 9 Yes 1 No Nantou SPT 7 Yes 1 No Yuanlin SPT 8 Yes 5 No
- 38. SPT Based Method Seed et al. established chart for estimating SPT based CRR7.5 : Seed et al. (1985)
- 39. SPT Based Method The CRR7.5 curves were further modified by Youd et al. (2001) and formulated as: CRR7.5 = 𝟏 𝟑𝟒− (𝑵 𝟏) 𝟔𝟎 + (𝑵 𝟏) 𝟔𝟎 𝟏𝟑𝟓 + 𝟓𝟎 (𝟏𝟎 (𝑵 𝟏) 𝟔𝟎 + 𝟒𝟓) 𝟐 − 𝟏 𝟐𝟎𝟎 Valid for (𝑵 𝟏) 𝟔𝟎 < 30 Sandy soils are considered to be non-liquefiable for (𝑵 𝟏) 𝟔𝟎 > 30. Idriss and Boulanger (2006) proposed a new equation: CRR7.5 = Exp (𝑵 𝟏) 𝟔𝟎 14.4 + (𝑵 𝟏) 𝟔𝟎 126 2 − (𝑵 𝟏) 𝟔𝟎 23.6 3 + (𝑵 𝟏) 𝟔𝟎 25.4 4 − 2.8
- 40. DMT Based Method DMT parameters, KD and ED are used to develop DMT based CRR7.5 boundary curves. Two boundary curves, CRR7.5-KD & CRR7.5-ED were established by Tsai et al. (2001), following the existing CRR7.5-(N1)60 curve. Tsai et al. (2001) established the following correlations to develop DMT based CRR7.5 curves. (N1)60-KD (N1)60-ED
- 41. DMT Based Method Tsai et al. (2001): (𝑵 𝟏) 𝟔𝟎 = 0.185KD 3 − 2.75KD 2 + 17KD – 15 (𝑵 𝟏) 𝟔𝟎 = 0.00022ED 3 − 0.02ED 2 + 0.9ED – 3
- 42. DMT Based Method Based on above correlations, Tsai et al. (2001) developed the DMT based CRR7.5 boundary curves. CRR7.5 = Exp 𝑲 𝑫 8.8 3 − 𝑲 𝑫 6.5 2 + 𝑲 𝑫 2.5 − 3.1 CRR7.5 = Exp 𝑬 𝑫 49 3 − 𝑬 𝑫 36.5 2 + 𝑬 𝑫 23 − 2.7
- 43. DMT Based Method
- 44. DMT Based Method CRR curves proposed by Monaco (2005), Grasso & Maugeri (2006) and Tsai (2009)
- 45. CONCLUSION
- 46. Conclusion DMT is relatively quick in-situ method which estimates a number of parameters, that can be effectively used in geotechnical design. DMT is capable of taking into account the soil structure, aging and consolidation effects, which generally influence the liquefaction potential of soil (Tsai et al. 2001). Tsai et al. (2001) study shows that the accuracy of DMT based CRR7.5 curves for Liquefaction assessment is satisfactory. Liquefaction assessment is relatively fast and reliable as compared to SPT, which takes longer time to supplement SPT with lab testing.
- 47. Conclusion However, it is desirable to directly conduct DMTs in the liquefied and non-liquefied areas of earthquake to obtain more KD and ED data of soils for further validating the developed DMT-based liquefaction evaluation method although the results of this study are preliminarily satisfactory
- 48. REFERENCES
- 49. References Marchetti, S. (1980). "In SituTests by Flat Dilatometer." J. Geotech. Engrg. Div., ASCE, 106, No.GT3, 299- 321. G.Totani, S. Marchetti, P. Monaco & M. Calabrese. Use of Flat DilatometerTest in Geotechnical Design, Intl. Conf. on In-situ Measurement of Soil Properties (2001) Monaco, P., Marchetti, S., Totani, G. and Calabrese, M. (2005). “Sand liquefiability assessment by Flat DilatometerTest (DMT).” Proc. XVI ICSMGE, Osaka, 4, 2693-2697 Robertson, P.K., and R.G. Campanella, [1986]. “Estimating liquefaction potential of sands using the flat plate dilatometer. Geotech.Testing J.,Vol. 9, No. 1, pp. 38– 40. Tsai,Tung and Lee (2001) . Performance of DMT based liquefaction evaluation method on case history of Chi-Chi Earthquake Bambang Setiawan,(2011) “Assessing Liquefaction Potential of Soils Utilizing In- situTesting” M.ScThesis