Lithologic Reservoirs ›› 2026, Vol. 38 ›› Issue (3): 190-200.doi: 10.12108/yxyqc.20260317

• PETROLEUM ENGINEERING AND OIL & GAS FIELD DEVELOPMENT • Previous Articles    

Four-dimensional in-situ stress evolution and optimization method for refracturing timing in shale oil reservoir horizontal wells: A case study of Triassic Chang 7 member in Qingcheng Oilfield, Ordos Basin

REN Jiawei1,2(), LI Li3, WANG Deyu1, BAI Xiaohu1, KANG Bo1, BAI Yuen1, BAI Jianwen1, CHEN Junbin2   

  1. 1 Oil & Gas Technology Research Institute, PetroChina Changqing Oilfield Company, Xi’an 710065, China
    2 College of Petroleum Engineering, Xi’an Shiyou University, Xi’an 710065, China
    3 No. 5 Oil Production Plant, PetroChina Changqing Oilfield Company, Xi’an 710018, China
  • Received:2025-09-25 Revised:2025-10-13 Online:2026-05-01 Published:2026-03-18

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Abstract:

Based on the concept of geology-engineering integration, a multi-physics field coupled model of fracture network-seepage-stress applicable to the entire development cycle of shale oil old wells in Qingcheng Oilfield of Ordos Basin was established. Multi-field coupled numerical simulations of refracturing in shale oil horizontal wells were conducted, and a stress recovery index along with an optimization method for refracturing timing was proposed. The results show that: (1) By establishing a seepage model, stress model, and their data interface program, the multi-physics field coupled model of fracture network-seepage-stress was solved by using cross coupling iterative algorithm, with history-matching accuracy of 93%, verifying the accuracy of the model and effectively applying it to the development and production of shale oil reservoirs in Qingcheng Oilfield, Ordos Basin. (2) After six years of production in the target well of Qingcheng Oilfield, the reservoir pressure near hydraulic fractures decreased by 1 MPa, while the maximum and minimum horizontal principal stresses declined by 2.6 MPa and 4.2 MPa, respectively, and the maximum principal stress direction rotated by 84°. Following pre-fracturing energy supplement of 10 000 m³, the maximum principal stress deflection angle decreased from 84° to 20°, resulting in a significant increase in the length and volume of refracturing-induced fractures, and that further proves the importance of implementing pre-fracturing energy supplement. (3) The stress recovery index can be proposed to cha-racterize the degree of in-situ stress recovery during development process of Qingcheng Oilfield, and a stress recovery index of 0.70 was identified as the optimal time for refracturing implementation. The influencing factors of refracturing timing include natural fracture density, matrix permeability, and initial hydraulic fracturing scale.

Key words: shale reservoir, refracturing, four-dimensional geostress, seepage-stress coupling, timing optimization, Chang 7 member, Triassic, Qingcheng Oilfield, Ordos Basin

CLC Number: 

  • TE357.1

Fig. 1

Location of refracturing test area in Qingcheng Oilfield (a) and comprehensive stratigraphic column of Triassic Chang 7 member (b), Ordos Basin"

Fig. 2

Complex fracture morphology in 3D real physical domain (a) and corresponding matrix and fracture grid in the computational domain (b)"

Fig. 3

Calculation process of seepage-stress real-time coupling simulation"

Table 1

Basic parameters of the 3D geological model of Triassic Chang 7 member in Qingcheng Oilfield, Ordos Basin"

属性 数值 属性 数值
有效厚度/m 18 含油饱和度 0.542
油藏埋深/m 1 520 原油黏度/(mPa·s) 7.3
平均孔隙度 0.09 原始地层压力/MPa 15.8
平均渗透率/mD 0.82 原油饱和压力/MPa 5.6
杨氏模量/GPa 21.37 泊松比 0.23
水平最大主应力/MPa 26.0 水平最小主应力/MPa 22.0

Fig. 4

Fracture network-seepage-stress models and historical fitting results of Triassic Chang 7 member in the target well in Qingcheng Oilfield, Ordos Basin"

Fig. 5

Fracture network-seepage-stress model simulated formation pressure distribution profile along the wellbore direction of Triassic Chang 7 member of the target well in Qingcheng Oilfield in Ordos Basin"

Fig. 6

Fracture network-seepage-stress model simulated variation law of horizontal principal stress during the exploitation of Triassic Chang 7 member of the target well in Qingcheng Oilfield in Ordos Basin"

Fig. 7

Fracture network-seepage-stress model simulated variation law of geostress deflection angle during the exploitation of Triassic Chang 7 member of the target well in Qingcheng Oilfield in Ordos Basin"

Fig. 8

Fracture network-seepage-stress model simulated refracturing propagation under long-term injection and production conditions of Triassic Chang 7 member of the target well in Qingcheng Oilfield, Ordos Basin"

Fig. 9

Fracture network-seepage-stress model simulated variation law of geostress after fluid injection and energy supplement of Triassic Chang 7 member of the target well in Qingcheng Oilfield in Ordos Basin"

Fig. 10

Fracture network-seepage-stress model simulated variation law of stress magnitude and direction with diffe-rent injection volume of Triassic Chang 7 member of the target well in Qingcheng Oilfield in Ordos Basin"

Fig. 11

Fracture network-seepage-stress model simulated the fracture propagation law under different supplement fluid volume before fracturing of Triassic Chang 7 member of the target well in Qingcheng Oilfield, Ordos Basin"

Fig. 12

Fracture network-seepage-stress model simulated the relationship of stress recovery index and refracturing transformation volumetric with the level of formation pressure of Triassic Chang 7 member of the target well in Qingcheng Oilfield, Ordos Basin"

Fig. 13

Fracture network-seepage-stress model simulated the variation of stress recovery index with the level of formation pressure under different natural fracture density of Triassic Chang 7 member in the target well in Qingcheng Oilfield, Ordos Basin"

Fig. 14

Fracture network-seepage-stress model simulated the variation of stress recovery index with the level of formation pressure under different matrix permeability of Triassic Chang 7 member of the target well in Qingcheng Oilfield, Ordos Basin"

Fig. 15

Fracture network-seepage-stress model simulated the variation of stress recovery index with the level of formation pressure under different fracture spacing of Triassic Chang 7 member of the target well in Qingcheng Oilfield, Ordos Basin"

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