Analysis of a Prefabricated Vertical Drain (PVD) Soil Improvement Project
Year 2022,
Volume: 33 Issue: 1, 11521 - 11541, 01.01.2022
Ahmet Can Mert
,
Akın Önalp
Ersin Arel
Abstract
A settlement analysis has been carried out for several sectors of a rail station yard improved with prefabricated vertical drains (PVD) in Istanbul, Turkey, that exhibited prolonged consolidation beyond the predicted values in certain sectors of the treated zone. Final settlement and End of Primary (EOP) settlement times have been estimated theoretically as well as using the Asaoka graphical procedure. The compliance of settlement-time curves with in-situ measurements and Asaoka solution has been investigated. A geotechnical model was developed for finite element and three-dimensional consolidation analyses. The settlement curves obtained by varying horizontal-vertical permeability coefficient ratio (kh/kv) and in-situ measurements have been compared, and kh/kv values corresponding to 90% degree of consolidation has been computed for all sectors. The effect of drain spacing (sdrain) as well as drain length (Ldrain) on the rate of consolidation have been examined for each sector, keeping the specified ratios constant. The times corresponding to 95% degree of consolidation (t95) have been calculated using the theoretical solution and compared to in-situ measurements. Calculated t95‘s have also been compared to their estimated values by varying the spacing (sdrain) and the length (Ldrain). Additionally, the required intervals of sdrain and Ldrain have been obtained corresponding to the calculated t95 times.
References
- [1] Terzaghi K (1925) Erdbaumechanik. Franz Deuticke, Leipzig and Vienna
- [2] Terzaghi K (1943) Theoretical Soil Mechanics. Wiley, New York
- [3] Biot MA (1941) General Theory of Three-Dimensional Consolidation. Journal of Applied Physics 12: 155-164
- [4] Carillo N (1942) Simple two and three dimensional cases in the theory of consolidation of soils. Journal of Mathematics and Physics 21: 1-5
- [5] Rendulic L (1935) Der hydrodynamische Spannungsausgleich in zentral entwasserten Tonzylindern. Wasserwirtschaft und Technik 2: 250-253, 269-273
- [6] Barron RA (1948) Consolidation of fine-grained soils by drain wells. Transactions of ASCE 113: 718-754
- [7] Richart FE (1959) Review of the theories for sand drains. Transactions of ASCE 124: 709-736
- [8] Kjellman W (1948) Consolidation of fine-grained soils by drain wells. Transactions of ASCE 113, Contribution to the discussion
- [9] Budhu B (2010) Soil Mechanics and Foundations.3rd Ed. John Wiley and Sons, New York
- [10] ASTM D2487 (2017) Standard Practice for Classification of Soils for Engineering Purposes (Unified Soil Classification System), ASTM International, West Conshohocken, PA, www.astm.org
- [11] Hansbo S, Jamiolkowski M, Kok L (1981) Consolidation by vertical drains. Géotechnique 31: 45-66
- [12] Asaoka A (1978) Observational Procedure of Settlement Prediction. Soils and Foundations 18: 87-101
- [13] Hausmann MR (1990) Engineering Principles of Ground Modification. McGraw-Hill, Singapore
- [14] Hansbo S (1983) How to evaluate the properties of prefabricated drains. Proc. 8th European Conference on Soil Mechanics and Foundation Engineering, Helsinki, pp. 621-626
- [15] Miura N, Chai JC, Toyota K (1998) Investigation on some factors affecting discharge capacity of prefabricated vertical drains. Proc. 6th International Conference on Geosynthetics, Atlanta, Georgia, pp. 845-850
- [16] Hansbo S (1987) Design aspects of vertical drains and lime column installation. Proc. 9th Southeast Asian Geotechnical Conference, Bangkok, Thailand, pp. 8-12
- [17] Bergado DT, Asakami H, Alfaro MC, Balasubramaniam AS (1991) Smear effects of vertical drains on soft Bangkok clay. Journal of Geotechnical Engineering 117: 1509-1530
Analysis of a Prefabricated Vertical Drain (PVD) Soil Improvement Project
Year 2022,
Volume: 33 Issue: 1, 11521 - 11541, 01.01.2022
Ahmet Can Mert
,
Akın Önalp
Ersin Arel
Abstract
A settlement analysis has been carried out for several
sectors of a rail station yard improved with prefabricated vertical drains
(PVD) in Istanbul, Turkey, that exhibited prolonged consolidation beyond the
predicted values in certain sectors of the treated zone. Final settlement and
End of Primary (EOP) settlement times have been estimated theoretically as well
as using the Asaoka graphical procedure. The compliance of settlement-time
curves with in-situ measurements and Asaoka solution has been investigated. A
geotechnical model was developed for finite element and three-dimensional
consolidation analyses. The settlement curves obtained by varying
horizontal-vertical permeability coefficient ratio (kh/kv)
and in-situ measurements have been compared, and kh/kv
values corresponding to 90% degree of consolidation has been computed for all
sectors. The effect of drain spacing (sdrain)
as well as drain length (Ldrain)
on the rate of consolidation have been examined for each sector, keeping the
specified ratios constant. The times corresponding to 95% degree of
consolidation (t95) have
been calculated using the theoretical solution and compared to in-situ
measurements. Calculated t95‘s
have also been compared to their estimated values by varying the spacing (sdrain)
and the length (Ldrain).
Additionally, the required intervals of sdrain
and Ldrain have been
obtained corresponding to the calculated t95
times.
References
- [1] Terzaghi K (1925) Erdbaumechanik. Franz Deuticke, Leipzig and Vienna
- [2] Terzaghi K (1943) Theoretical Soil Mechanics. Wiley, New York
- [3] Biot MA (1941) General Theory of Three-Dimensional Consolidation. Journal of Applied Physics 12: 155-164
- [4] Carillo N (1942) Simple two and three dimensional cases in the theory of consolidation of soils. Journal of Mathematics and Physics 21: 1-5
- [5] Rendulic L (1935) Der hydrodynamische Spannungsausgleich in zentral entwasserten Tonzylindern. Wasserwirtschaft und Technik 2: 250-253, 269-273
- [6] Barron RA (1948) Consolidation of fine-grained soils by drain wells. Transactions of ASCE 113: 718-754
- [7] Richart FE (1959) Review of the theories for sand drains. Transactions of ASCE 124: 709-736
- [8] Kjellman W (1948) Consolidation of fine-grained soils by drain wells. Transactions of ASCE 113, Contribution to the discussion
- [9] Budhu B (2010) Soil Mechanics and Foundations.3rd Ed. John Wiley and Sons, New York
- [10] ASTM D2487 (2017) Standard Practice for Classification of Soils for Engineering Purposes (Unified Soil Classification System), ASTM International, West Conshohocken, PA, www.astm.org
- [11] Hansbo S, Jamiolkowski M, Kok L (1981) Consolidation by vertical drains. Géotechnique 31: 45-66
- [12] Asaoka A (1978) Observational Procedure of Settlement Prediction. Soils and Foundations 18: 87-101
- [13] Hausmann MR (1990) Engineering Principles of Ground Modification. McGraw-Hill, Singapore
- [14] Hansbo S (1983) How to evaluate the properties of prefabricated drains. Proc. 8th European Conference on Soil Mechanics and Foundation Engineering, Helsinki, pp. 621-626
- [15] Miura N, Chai JC, Toyota K (1998) Investigation on some factors affecting discharge capacity of prefabricated vertical drains. Proc. 6th International Conference on Geosynthetics, Atlanta, Georgia, pp. 845-850
- [16] Hansbo S (1987) Design aspects of vertical drains and lime column installation. Proc. 9th Southeast Asian Geotechnical Conference, Bangkok, Thailand, pp. 8-12
- [17] Bergado DT, Asakami H, Alfaro MC, Balasubramaniam AS (1991) Smear effects of vertical drains on soft Bangkok clay. Journal of Geotechnical Engineering 117: 1509-1530