Your search keyword '"*PETROLEUM reservoirs"' showing total 4 results

1. Integrated optimization of fracture parameters for subdivision cutting fractured horizontal wells in shale oil reservoirs.

Author

Deng, Haiyang, Sheng, Guanglong, Zhao, Hui, Meng, Fankun, Zhang, Haoyi, Ma, Jialing, Gong, Jie, and Ruan, Jiayu

Subjects

*SHALE oils, *HORIZONTAL wells, *PETROLEUM reservoirs, *OIL wells, *HYDRAULIC fracturing, *FLOW simulations

Abstract

Horizontal well with subdivision cutting fracturing technology is a new technical way to improve the efficient development of shale reservoirs. Subdivision cutting fracturing has the characteristics of stronger inter-fracture interference, more variable parameters and constraints. This fracturing technology has no efficient method to optimize the discrete and continuous fracture parameters integrally. A new automatic integrated optimization algorithm is proposed. The algorithm adopts the SPSA nested binary search algorithm to optimize the discrete and continuous fracture parameters. Considering the flow mechanism of multi-scale media in shale reservoirs, a numerical flow simulation model of subdivision cutting fractured horizontal wells is established. Then, taking the NPV as the objective function, a multi-parameter integrated optimization model is established. Make the method apply to a typical test shale reservoir. The optimization results show that the NPV of the optimum fracture parameter combination is 37.69%–57.36% higher than that of the uniform fracture distribution combination. And the optimum fracture combination presents a spindle-like distribution. This method is applied to an actual shale reservoir in Xinjiang to verify the broad application. The fracture parameter combination of two parallel horizontal wells in the reservoir is optimized. The optimization results show that the NPV has been dramatically improved, with an increasing range of 37.94%–96.84%. And the fractures of two adjacent horizontal wells present zipper staggered distribution. The integrated optimization method of fracture parameters can provide theoretical guidance for hydraulic fracturing design. • A new optimization method of SPSA nested binary search algorithm is proposed to realize the integrated optimization of discrete and continuous fracture parameters. • Considering the flow mechanism of multi-scale media in shale reservoirs, an optimization model with NPV as the objective function is established. • The method has a fast convergence speed and a significant increase in NPV, and the optimized fracture parameters combination is in line with the heterogeneous distribution. [ABSTRACT FROM AUTHOR]

Published

2022

2. Experimental and numerical investigation on extra-heavy oil recovery by steam injection using vertical injector -horizontal producer.

Author

Liu, Peng, Zhang, Yunjun, Liu, Pengcheng, Zhou, You, Qi, Zongyao, Shi, Lanxiang, Xi, Changfeng, Zhang, Zhongyi, Wang, Chao, and Hua, Daode

Subjects

*HEAVY oil, *INJECTORS, *PETROLEUM, *TEMPERATURE distribution, *NUMERICAL analysis, *PETROLEUM reservoirs

Abstract

Steam injection is the most popular used method in recovering heavy oil reservoirs. Many researchers were engaged in enhancing oil recovery (EOR) methods by using various well configurations. Laboratory experiments and field applications have verified the feasibility of extra-heavy oil recovery by steam injection using vertical injector -horizontal producer. It was also referred to as a steam assisted gravity drainage (SAGD) process. However, the characteristic of steam chamber growth and production performance during the vertical injector-horizontal producer steam injection process have not been fully understood. In this study, a 3D physical model was constructed to investigate the mechanisms of the steam injection process using vertical injector-horizonal producer. Numerical simulations were also conducted to verify the laboratory experiment and field application. In the aspect of steam chamber growth, the results revealed that three stages were included during the steam injection process. In the aspect of developing mechanisms, it can be divided into steam flooding and gravity drainage stages. Moreover, the results show that about 43.9% of original oil in place (OOIP) was produced in the gravity drainage stage. In addition, subcool showed significant difference in steam flooding and gravity drainage stages. The temperature distribution mode of the horizontal producer was analyzed and proved to be a significant factor that influences the production performance. Sensitivity analysis by using numerical simulation demonstrated that oil viscosity is the dominant factor that impact the production performance. The results guided the development of pilot test area in Xinjiang Oilfield, China. The study can provide a clearer understanding of the vertical injector-horizontal producer steam injection process in recovering heavy oil reservoirs. • The vertical injector- horizontal producer steam injection process was divided into three stages. • The dominant driving forces, steam flooding and gravity drainage, varies in different developing stages. • Production performance at different developing stages were analyzed, and most oil was developed by gravity drainage. • The results were used to guide the development of the pilot test area in Xinjiang Oilfield. [ABSTRACT FROM AUTHOR]

Published

2021

3. Large-scale triaxial experimental investigation of geomechanical dilation start-up for SAGD dual horizontal wells in shallow heavy oil reservoirs.

Author

Wang, Xiaohua, Sun, Xingge, Luo, Chihui, Zhang, Fengshou, and Xu, Bin

Subjects

*PETROLEUM reservoirs, *HEAVY oil, *TIME dilation, *HORIZONTAL wells, *OIL sands, *TIME pressure

Abstract

There are only a few related studies focused on the steam assisted gravity drainage (SAGD) dilation start-up technology (termed as dilation start-up in this paper), especially with true triaxial stress physical modelling experiments in the laboratory. Therefore, in order to better understand the dilation start-up process, four large-scale (1050 mm × 410 mm × 410 mm) true triaxial experiments of SAGD start-up with dual horizontal wells were conducted for the first time by using the oil sands from the Xinjiang oilfield, northwest China. The dilation process characterized by temperature changes at different positions inside the experimental samples was monitored in real time. The performance differences between dilation start-up and conventional start-up were discussed in detail, and the effects of dilation pressure and dilation time on the dilation process were also studied. The experimental results indicate that dilation start-up can significantly reduce the well communication time between injector and producer, and enhance the range of dilation zone and improve the uniformity of dilation zone along the horizontal wellbores. Moreover, we find that dilation pressure is an essential factor influencing the dilation effect. The average communication parameter increases by 5% if dilation pressure increases by 10% whereas the standard deviation of communication parameter decreases. The evolution of dilation zone with time shows that long-time dilation prompts the uniform propagation of dilation zone along the horizontal wellbores. This study provides guidance for the optimization of SAGD dilation start-up in shallow heavy oil reservoirs. • Four large-scale true triaxial experiments of SAGD start-up with dual horizontal wells were conducted. • Dilation process characterized by temperature changes inside the samples was monitored in real time. • Effects of dilation pressure and dilation time on the SAGD dilation start-up were studied. [ABSTRACT FROM AUTHOR]

Published

2021

4. The application of geomechanical SAGD dilation startup in a Xinjiang oil field heavy-oil reservoir.

Author

Sun, Xingge, Xu, Bin, Qian, Genbao, and Li, Biao

Subjects

*PETROLEUM reservoirs, *HEAVY oil, *RESERVOIRS, *OIL fields, *NEW business enterprises, *SHALE gas reservoirs, *WATER use

Abstract

Steam-assisted gravity drainage (SAGD) methods have been widely applied in oil-sands exploitation globally. SAGD processes are effective only after thermal and hydraulic communication between the injector and producer has been established during the start-up operation of the well pair. The geomechanical SAGD dilation startup has been considered a promising technology that can enhance permeabilities of heavy-oil reservoirs and reduce thermal conformance time. However, limited studies have focused on the practical operational procedures of geomechanical SAGD dilation startup. This paper presents the application of SAGD dilation startup technology in a shallow super heavy-oil reservoir in the Karamay oil field, China. The general reservoir geology and geomechanical characteristics were investigated and used to propose a practical approach to determine dilation initiation pressure. We also summarize the SAGD well completions and geomechanical SAGD dilation startup procedures. A case study using a real SAGD well is presented and analyzed. We then share the field operation procedures and results after dilation startup. The objective of the research was to reduce the steam circulation time and achieve uniform thermal conformance along the SAGD well. Our field results highlight the promising potential of using water injection to create a dilated zone and dramatically enhance reservoir permeability. The performance of SAGD dilation startup in the Karamay oil field is evaluated by comparing the cumulative oil production rate with those from SAGD wells using conventional startup. • The geomechanical properties of Karamay heavy oil reservoirs are characterized. • A practical approach to determine dilation initiation pressure for SAGD startup is proposed. • A field case study of geomechanical SAGD dilation startup is presented and analyzed. [ABSTRACT FROM AUTHOR]

Published

2021