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2025 Vol.35, Issue 3 Preview Page

Technical Note

Application of Agarwal’s Method for Analysis of Recovery Data Following Constant Pressure Injection Test in Fractured Rock

암반 정압주입시험-회복자료 분석을 위한 Agarwal 방법 활용 방안

Hangbok Lee1
,
Chan Park1*
이 항복1
,
박 찬1*
1Principal Researcher, Deep Subsurface Storage and Disposal Research Center, Korea Institute of Geoscience and Mineral Resources
1한국지질자원연구원 심층처분환경연구센터 책임연구원
*Corresponding Author
30 June 2025. pp. 194-209
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Abstract

This report introduces the application of Agarwal’s method for analyzing recovery data following constant head injection tests in fractured rock. Agarwal’s method utilizes the concept of equivalent time to transform the pressure recovery curve, which represents the return of the test interval pressure to its initial state after the injection test, into a drawdown curve under constant pumping conditions. This transformed recovery curve can then be applied to various pumping test interpretation methods to estimate the hydraulic conductivity, which represents the in-situ permeability of the rock. Additionally, derivative diagnostic analysis can be used to evaluate the conceptual model of the fractured rock aquifer and groundwater flow patterns, providing a more detailed understanding of fracture network connectivity, flow mechanisms and boundary conditions. This report explains the fundamental principles and concepts of Agarwal’s method and presents case studies of its practical application. The use of Agarwal’s method for recovery data analysis offers an effective approach to overcoming the inherent limitations of field constant pressure injection test, where verification and validation of measured data are often challenging. This method enhances the reliability of hydraulic property estimation and is expected to be applicable across various fractured rock geological environments.

Keywords
Fractured rock
Constant pressure injection test
Recovery data
Agarwal’s method
Equivalent time

본 보고에서는 균열암반 내 정압주입시험 수행 후 회복자료를 분석하기 위한 Agarwal 방법을 소개하였다. Agarwal 방법은 등가시간 개념을 이용하여 정압주입시험 종료 이후에 시험구간의 압력이 원래 상태로 회복되는 수위회복곡선을 일정 양수량 조건의 양수곡선처럼 변환한다. 이렇게 변환된 수위회복곡선은 다양한 양수시험 해석법에 적용하여, 암반의 현지 투수성을 나타내는 수리전도도를 산출할 수 있다. 또한 도함수 진단 분석을 활용하여 암반대수층의 개념모델 및 지하수 흐름 패턴을 평가할 수 있다. 이를 통해, 암반 균열망의 연결성과 유동 메커니즘 및 수리경계 정보를 보다 정밀하게 파악할 수 있다. 본 보고에서는 Agarwal 방법의 기본 원리와 개념을 설명하고, 정압주입 이후 회복시험 관련 실제 적용 연구사례를 기술하였다. Agarwal 방법을 활용한 회복자료 분석은, 측정결과 검증과 타당성 확보가 쉽지 않은 현장 정압주입시험의 고유 한계점을 보완하는 효과적인 방안이 될 수 있다. 이를 통해, 수리특성 도출의 신뢰도를 향상시킬 수 있으며, 다양한 암반지질 환경에서 적용 가능할 것으로 기대된다.

키워드
균열암반
정압주입시험
회복자료
Agarwal 방법
등가시간
References
1

Agarwal, R.G., 1980. A new method to account for producing time effects when drawdown type curves are used to analyze buildup and other test data, SPE 9289, 55th Annual Technical Conference and Exhibition, Dallas, Texas, September, 21-24.

10.2118/9289-MS6902726
2

Almén, K.E., Andersson, J.E., Carlsson, L., Hansson, K., and Larsson, N.Å., 1986, Hydraulic testing in crystalline rock. A comparative study of single-hole test methods, SKB TR-86-27, Stockholm, Sweden, p.179.

3

Andersson, J.E., and Persson, O., 1985, Evaluation of single-hole hydraulic tests in fractured crystalline rock by steady-state and transient methods, SKB TR 845-19, Stockholm, Sweden, p.17.

10.1557/PROC-50-155
4

Bourdet, D., Ayoub, J.A., and Pirard, Y.M., 1989, Use of pressure derivative in well-test interpretations, SPE Formation Evaluation, 4, 293-302.

10.2118/12777-PA
5

Dougherty, D.E., and Babu, D.K., 1984, Flow to a partially penetrating well in a double-porosity reservoir, Water Resources Research, 20(8), 1116-1122.

10.1029/WR020i008p01116
6

Duffield, G.M., 2007, AQTESOLV for windows version 4.5 user's guide, HydroSOLVE, Inc., Reston, USA.

7

Enachescu, C., and Rahm, N., 2007, Method evaluation of single hole hydraulic injection tests at site investigations Oskarshamn, SKB P-07-79, Stockholm, Sweden, p.103.

8

Follin, S., Ludvigson, J.E., and Leven, J., 2011, A comparison between standard well test evaluation methods used in SKB's site investigations and the generalized radial flow concept, SKB P-06-54, Stockholm, Sweden, p.55.

9

Halford, K., Garcia, C.A., Fenelon, J., and Mirus, B.B., 2012, Advanced methods for modeling water-levels and estimating drawdowns with SeriesSEE, an Excel add-in. (Version 1.0: Originally posted December 2012; Version 1.1:July 2016). Reston, VA: Techniques and Methods.

10.2172/1059501
10

Hantush, M.S., and Jacob, C.E., 1955, Non-steady radial flow in an infinite leaky aquifer, American Geophysical Union Transations, 36(1), 95-100.

10.1029/TR036i001p00095
11

Hjerne, C., Ludvigson, J.E., Harrström, J., Olofsson, C., Gokall-Norman, K., and Walger, E., 2013, Single-hole injection tests in boreholes KA2051A01, KA3007A01 and KJ0050F01, SKB P-13-24, Stockholm, Sweden, p.184.

12

Hurst, W., Clark, J.D., and Brauer, E.B., 1969, The skin effect in producing wells, Journal of Petroleum Technology, 21(11), 1483-1489.

10.2118/1854-PA
13

Ji, S.H., Lee, D.H., Yeo, I.W., Park, K.W., and Koh, Y.K., 2014, Derivative-Assisted classification of fractured zones crossing a deep borehole, Ground Water, 52(1), 145-155.

10.1111/gwat.1203523432397
14

Kim, C.S., Lee, E.Y., Bae, D.S., and Kim, K.S., 1993, Flow dimensional analysis for constant pressure injection test, The Journal of Engineering Geology, 3(2), 149-165.

15

Kim, K.S., Kim, C.S., and Bae, D.S., 2002, Estimation of the effective hydraulic conductivity in the granite area as an equivalent continuum medium, The Journal of Engineering Geology, 12(3), 319-332.

16

Lee, H., 2024, Improvement of hydraulic properties by derivative diagnostic analysis in deep fractured rock, Tunnel and Underground Space, 34(6), 647-662.

17

Lee, H., and Park, C., 2024, A study on comparative analysis of hydraulic conductivity in injection and recovery phases of constant pressure injection tests in deep fractured rock, Tunnel and Underground Space, 34(5), 503-526.

18

Ludvigson, J.E., Hansson, K., and Hjerne, C., 2007, Method evaluation of single-hole hydraulic injection tests at site investigations in Forsmark, SKB P-07-80, Stockholm, Sweden, p.162.

19

Martinez-Landa, L., Carrera, J., Niemi, A., and Bensabat, J., 2021, A methodology for the interpretation of aquifer tests: Application to CO2 residual trapping experiments at the Heletz site, International Journal of Greenhouse Gas Control, 112, 103366.

10.1016/j.ijggc.2021.103366
20

Ramos, G., Carrera, J., Gómez, S., Minutti, C., and Camacho, R., 2017, A stable computation of log-derivatives from noisy drawdown data, Water Resources Research, 53, 7904-7916.

10.1002/2017WR020811
21

Renard, P., Glenz, D., and Mejias, M., 2009, Understanding diagnostic plots for well-test interpretation, Hydrogeology Journal, 17, 589-600.

10.1007/s10040-008-0392-0
22

Trabucchi, M., Carrera, J., and Fernàndez-Garcia, D., 2018, Generalizing Agarwal's method for the interpretation of recovery tests under non-ideal conditions, Water Resources Research, 54, 6393-6407.

10.1029/2018WR022684
23

Uraiet, A.A., and Raghavan, R., 1980, Pressure buildup analysis for a well produced at constant bottomhole pressure, Journal of Petroleum Technology, 32(10), 1813-1824.

10.2118/7984-PA
24

Zhang, M., Ji, R., Zhou, Z., Zhao, J., Gou, J., and Chen, H., 2018, IOP Conference Series: Earth and Environmental Science, 170, 022102.

10.1088/1755-1315/170/2/022102
Information
  • Publisher :Korean Society for Rock Mechanics and Rock Engineering
  • Publisher(Ko) :한국암반공학회
  • Journal Title :Tunnel and Underground Space
  • Journal Title(Ko) :터널과 지하공간
  • Volume : 35
  • No :3
  • Pages :194-209
  • Received Date : 2025-05-09
  • Revised Date : 2025-06-05
  • Accepted Date : 2025-06-05
  • DOI :https://doi.org/10.7474/TUS.2025.35.3.194
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