Your search keyword '"Peng, Chengyong"' showing total 5 results

1. A New Approach to a Fracturing Sweet Spot Evaluation Method Based on Combined Weight Coefficient Method—A Case Study in the BZ Oilfield, China.

Author

Jiang, Mao, Peng, Chengyong, Wu, Jianshu, Wang, Zongyong, Liu, Yi, Zhao, Bingjin, and Zhang, Yan

Subjects

ANALYTIC hierarchy process, HYDRAULIC fracturing, METHODS engineering, GEOLOGICAL modeling, STATISTICAL correlation

Abstract

The Sha3 member of the BZ Oilfield in Bohai Sea represents a typical ultra-low permeability thin interbedding reservoir. Hydraulic fracturing is an effective method for increasing oil and gas production. However, the complex geological conditions make it difficult to screen out the optimal frac spot. Consequently, the design of hydraulic fracturing exhibits certain limitations. A novel method for evaluating sweet spots is proposed, based on a refined geological reservoir model that considers the varying degrees of influence that geological and engineering factors have on fracturing effectiveness. This method utilizes grey correlation and hierarchical analysis to quantify and characterize the weight coefficients of each factor, ultimately leading to a combined weight coefficient approach. The results indicate that permeability and fracturing scale are the primary factors that impact the post-frac production of the BZ oilfield, with their respective combined weights being 0.33 and 0.25. The average weight for geological factors is 0.18, while for engineering factors it is 0.15. This suggests that geological factors have a greater influence on production than engineering factors. Furthermore, the correlation coefficient between the dual sweet spot index and the production is 0.96, indicating a strong positive correlation between the two variables. After comparing the predicted and actual production of each well, it was determined that the anastomosis rate is 80%. This finding holds significant guiding significance for selecting the optimal fracturing spot. [ABSTRACT FROM AUTHOR]

Published

2024

2. Numerical Investigation of Hydraulic Fractures Vertical Propagation Mechanism for Enhanced Tight Gas Recovery.

Author

Wu, Jianshu, Fan, Baitao, Wu, Guangai, Peng, Chengyong, Chen, Zhengrong, Yan, Wei, Xiao, Cong, Liu, Wei, Wu, Mingliang, and Zou, Lei

Subjects

ELASTIC modulus, CRACK propagation (Fracture mechanics), HYDRAULIC fracturing, FRACTURING fluids, GAS reservoirs

Abstract

Hydraulic fracturing stands as a pivotal technological approach for enhanced tight gas recovery. This paper investigates the influences of geological and engineering parameters on the vertical extension mechanism of hydraulic fractures. In addition, the feasibility and effectiveness of fracture height prediction method and various fracture height control techniques have been examined. The results indicate that the height of hydraulic fractures decreases with an increase in the thickness of the barrier layers, the stress difference between the barrier and reservoir layers, the difference in tensile strength, and the difference in fracture toughness, whereas it increases with the increasing of difference in elastic modulus between the barrier and reservoir layers. Compred with the difference in Poisson's ratio, the volume of fracturing fluid, discharge rate, and fluid viscosity have little impactd. The influence of these factors on fracture height, in descending order, is stress difference between barrier and reservoir layers, fracturing fluid viscosity, fracturing discharge, fracturing fluid volume, barrier layer thickness, tensile strength difference between barrier and reservoir layers, elastic modulus difference between barrier and reservoir layers, Poisson's ratio difference between barrier and reservoir layers. Furthermore, based on typical geomechanic and reservoir parameters of the target area, a fracture height prediction workflow has been developed. Engineering practice has proven the reliability of fracture height prediction method. The results of this study provide theoretical support and guidance for predicting fracture morphology, controlling fracture height in the hydraulic fracturing development of the tight gas reservoir, and optimizing fracturing process design. [ABSTRACT FROM AUTHOR]

Published

2024

3. Evaluation of Tight Sandstone Mechanical Properties and Fracability: An Experimental Study of Reservoir Sand−Stones from Lufeng Sag, Pearl River Mouth Basin, Northern South China Sea

Author

Peng, Chengyong, primary, Zhou, Jun, additional, Wu, Jianshu, additional, Jiang, Mao, additional, Zhang, Hao, additional, Yin, Biao, additional, Liu, Shanyong, additional, and Zhang, Yan, additional

Published

2023

4. Application of Artificial Intelligence in Prediction of Wellbore Stability Using Well Logging and Drilling Data

Author

Wu, Juntao, additional, Liu, Wei, additional, Lin, Hai, additional, Liu, Hailong, additional, and Peng, Chengyong, additional

Published

2023

5. Model for fracture initiation and propagation pressure calculation in poorly consolidated sandstone during waterflooding

Author

Sun, Jin, Deng, Jingen, Yu, Baohua, and Peng, Chengyong

Published

2015