1 / 23

Estimation of Uniaxial Compaction Coefficient from GPS Measured Subsidence

Estimation of Uniaxial Compaction Coefficient from GPS Measured Subsidence. by. Dr.PARUL R. Patel Senior Associate Professor Nirma University, Ahmedabad parul.patel@nirmauni.ac.in. Organization of Presentation. Introduction Objectives of the Study

andersoncynthia
Download Presentation

Estimation of Uniaxial Compaction Coefficient from GPS Measured Subsidence

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Estimation of Uniaxial Compaction Coefficient from GPS Measured Subsidence by Dr.PARUL R. Patel Senior Associate Professor Nirma University, Ahmedabad parul.patel@nirmauni.ac.in

  2. Organization of Presentation • Introduction • Objectives of the Study • GPS Field Data Collection & Processing Methodology • Analysis of Results • Estimation of Uniaxial Compaction Coefficient • Conclusions

  3. Land Subsidence Land subsidence is a gradual settling or sudden sinking of the earth's surface with or without horizontal movement Man-made Subsidence Occurs mainly due to • Mining activities • Underground construction activities • Extraction of natural resources like water/gas/oil

  4. Mechanism of Land Subsidence due to Gas Extraction • Weight of overlying sediments partially supported by soil matrix and partially by gas/oil present in pores. • Pressure p declines, and overburden load transferred to soil matrix. • Compaction takes place if soil is compressible • Bowl-shaped depression appears with large displacement at centre.

  5. Effects of Land Subsidence Even Settlement rarely causes any problems but uneven settlement creates problems • Changes in Elevation and Slope of Canals, Drains, Pipe lines etc • Damage to Infrastructure • Failure of Well Casings • Water Intrusion in Coastal Areas • Reduction in Permeability, Loss of Hydrocarbon productivity • Fault Reactivation Resulting in Seismic Activity • Development of Fissures and Sinkholes

  6. Objectives of the Study • Use of GPS technique to monitor subsidence using a case study near Olpad Region, Surat, Gujarat • To identify and study effects of parameters responsible for land subsidence, like, pressure depletion, gas extraction, water level, Uniaxial Compaction Coefficient, Reservoir dimensions • Calculation of Uniaxial Compaction Coefficient

  7. GPS used for Monitoring Subsidence • Ekofisk OilField, 1991-93, • Single Frequency Novtel, Novtel Software used • Groningen Gas Field, 1992-1993, • Dual Frequency, Bernese Software • Coachella Valley, California, 1996-98,Dual Frequency, GP Survey Software • Rafsanjan Plain, Iran, 1998-1999, • Leika, SKIPro Software • Ojiya City, Japan, 1996-98 , • Dual Frequency, Bernese Software • Jakarta, Indonesia, 1997-2001,Dual Frequency, Bernese Software

  8. Reference Network & Monitoring Stations with Reservoir Boundary Deformation Stations with Reference Stations Locations of IGS Stations Deformation Stations and Presumed Reservoir Boundary Details of the Study Area

  9. GPS Monument at Monitoring Station GPS Monument C/S of GPS Monument 4000 ssi Receiver with Choke Ring Antenna

  10. Processing Parameters and Methodology • IGS stations tightly constrained, to get coordinates of all the four reference stations and IITB permanent reference station. • Coordinates of all 27-deformation stations were processed with two reference stations and IITB station by tightly constraining them.

  11. Average Effective Subsidence for May Campaigns Rate of Subsidence 30 mm/year within Reservoir Boundary

  12. Study of Reservoir Pressure and its behaviour May 2004 June 2007 Max. Pressure: 2290 kN/m2 at NSA4 Min. Pressure : 2034 kN/m2 at NSA2 Av. pressure of the reservoir: 2105 kN /m2 Max Pressure: 1336 kN/m2 at NSA2 Min. Pressure: 989 kN/m2 at NSA1 Av. pressure of the reservoir: 1098 kN/m2 Maximum Pressure Depleted on north side More Numbers of Gas Wells Located on North side Maximum Subsidence observed on North side

  13. Relation Between Gas Extraction and Pressure Depletion Linear relation Between Gas Extraction & Average Pressure Pressure is Depleting Continuously with increase in Cumulative Gas Extraction

  14. Relation between Cumulative Effective Subsidence & Cumulative Gas Extraction Linear Relationship is observed to be Suitable with Regression Analysis Correlation Coefficient is Found to be High 0.83 Gas Extraction is the major cause of Subsidence over the Study area

  15. Relation between Water Level and Subsidence Seasonal Change Observed in Water Level and in Ellipsoidal Height Change in Water Level (Four Wells) Change in Ellipsoidal Height (Four Wells) No permanent water depletion observed Net reduction in the average Ellipsoidal Height

  16. LaboratoryMeasured Cm Estimation of Uniaxial Compaction Coefficient (Cm) Cm = 2.7E-05 m2/kN Where, Modulus of Elasticity (E) =2.5E04 kN/m2 (Laboratory Measured) And Poisson’s Ratio (υ) = 0.33 Subsidence = Cm H Δp Subsidence = 953 mm For (Δp = 905 kN/m2, H=39 m) Subsidence Very High Compared to Measured Subsidence (86 mm) Laboratory Measured Cm Value usually overestimated

  17. Average Cm for Four Wells Cm values Ranging from 1.27E-06 m2/kN to 3.70E-06 m2/kN Average Cm Value is 1.84E-06 m2/kN ∆s = (-1.84E-06) (∆p * H) R = 0.73 Cm = 1.84E-06 m2/kN For Barbara Field, Field Measured Cm Values were 2 x 10-7 to 5 x 10-7 m2/kN Laboratory Measured Cm values ranging from 1 x 10-6 to 5 x 10-5 m2/kN Laboratory Measured Cm is more than ten times toField Measured Cm with GPS

  18. Subsidence Prediction based on Cm Calculated using Nucleus of Strain Method (Geertsma, 1978)(Assuming Reservoir Compaction ≠ Subsidence) Subsidence at the Centre of the Reservoir Value of ‘A’ depends on two Dimensionless ratios η=D/R and ρ = r/R D is the Depth of Burial (175 m), R is radius of Reservoir (2500 m), r is the distance of point from centre of the Reservoir (r=0) This Cm value used to predict subsidence from time to time over this reservoir

  19. Conclusions • Effective subsidence over the study area was 86 mm during February 2004 to March 2007 within reservoir boundary • Subsidence is directly related to the amount of gas extracted and resulting pressure. A linear relationships are observed between: • Cumulative gas extraction and average reservoir pressure (R =0.99) • Subsidence and gas extraction ( R = 0.83) • subsidence and pressure depletion ( R = 0.534 to 0.82) • The average compaction coefficient Cm determined from GPS studies (assuming subsidence = compaction) is found to be 1.84E-06 m2/kN. • Subsidence prediction based on field measured is more acceptable than the laboratory measured uniaxial compaction coefficient, as it is always higher by one order of magnitude than the actual measured subsidence in the field. • Estimating Cm (assuming subsidence = compaction) based on GPS measured parameters and Nucleus of Strain Method is found to be 1.95E-06 m2/kN.

  20. Thank You

More Related