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Xinjiang Oil & Gas    2024, 20 (1): 0-0.   Abstract （88）      PDF （13817KB）（331）       Knowledge map    Save Related Articles | Metrics

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Research Progress on Capture of CO2 by Alcohol Amine Absorption Method YANG Tianmeng, YANG Fan, REZEY Rehemtuli, GOU Guolei, LI Xiuhui, HOU Junwei Xinjiang Oil & Gas    2024, 20 (1): 52-60.   DOI: 10.12388/j.issn.1673-2677.2024.01.007 Abstract （279）      PDF （3625KB）（314）       Knowledge map    Save CO2 capture，utilization，and storage are the main technologies to cope with the greenhouse climate，achieve the strategic goal of carbon peak and neutralization，lead the transformation and upgrading of the global energy system，and promote the green and sustainable development of energy. The chemical absorption methods have the characteristics of high absorption efficiency and large processing capacity，most suitable for large-scale carbon capture in various industries. Among them，the alcoho lamine method is the most widely used and the most effective. After absorbing CO2，the alcoholamine solution becomes an alcoholamine-rich solution，which can be recovered by desorption treatment for cyclic utilization. However，in the process of CO2 capture by the existing alkanolamine absorbent，there are some disadvantages such as high energy consumption and great loss of absorbent，and it is necessary to improve the alcoholamine absorber to realize high absorption efficiency and a feasible process with low regeneration energy consumption. To solve the problems of large loss of absorbent and low regeneration rate，a new mixed alcoholamine absorber was developed for improvement. For the problem of high energy consumption for regeneration，the traditional thermal desorption process is improved and microwave desorption technology is selected. This paper introduces the mechanism and characteristics of CO2 absorption by alcoho lamine method，summarizes the basis for improving the mixed alcoholamine absorber，and expounds on the principle and characteristics of CO2 capture through microwave-assisted alcoholamine，providing a reference for industrial carbon capture and environmental protection. Reference | Related Articles | Metrics

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Research Status and Development Proposal of ROP Improvement Technology with Percussion Rock-Breaking Method LI Gensheng, MU Zongjie, TIAN Shouceng, HUANG Zhongwei, SUN Zhaowei Xinjiang Oil & Gas    2024, 20 (1): 1-12.   DOI: 10.12388/j.issn.1673-2677.2024.01.001 Abstract （170）      PDF （7836KB）（182）       Knowledge map    Save Enhancing the rate of penetration （ROP） is crucial for optimizing the efficiency of oil and gas development and deep exploration in China and ensuring national energy security. The percussion rock-breaking drilling technology has been applied in oil fields at home and abroad，resulting in significant improvements in ROP. Further research efforts are expected to address the technical challenges of low drilling footage and limited ROP enhancements encountered during deep exploration of hard rock formations with high temperature and pressure. This paper presents and analyzes the practice and development trends of the drill bit percussion rock-breaking drilling technology assisted by axial percussion，torsional percussion，and axial-torsional coupled percussion. It illustrates that the percussion-assisted drill bit rock-breaking mechanism is the core of percussion rock-breaking ROP improvement technology. This paper also reviews the scientific advancements made by domestic and overseas research scholars in physical experiments，theoretical modeling，and numerical simulation of percussion-assisted drill bit rock-breaking. In addition，it offers relevant proposals for the development of percussion rock-breaking ROP improvement technology，i.e. advancing research on material structure optimization design，intelligent control，integration of multiple technologies，and optimization of well applications. This is expected to provide valuable insights for enhancing the drilling efficiency in energy development of our country. Reference | Related Articles | Metrics

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Research and Application Progress of Nanofluid for Enhanced Oil Recovery LIANG Tuo, YANG Changhua, ZHANG Yanjun, LI Pan, QU Ming, HOU Jirui Xinjiang Oil & Gas    2023, 19 (4): 29-41.   DOI: 10.12388/j.issn.1673-2677.2023.04.004 Abstract （172）      PDF （5519KB）（168）       Knowledge map    Save In view of the limitations of traditional polymer and surfactant solutions in enhancing oil recovery，such as low viscosity retention and large adsorption loss，this paper examines the potential use of nanofluids for enhanced oil recovery and discusses recent research in this field. First，the synthesis of nanomaterials is described，and the methods used for evaluation of the stability of nanofluids in enhanced oil recovery in the field are summarized. Second，six mechanisms by which nanofluids enhance oil recovery are reviewed. These are：reducing interfacial tension，changing wettability，reducing crude viscosity，improving foam stability，structural disjoining pressure，and reducing pressure and increasing injection. Third，the use of nanofluids for enhanced oil recovery in the field is investigated. The “bottleneck” issues that limit the large-scale application of nanofluids in oilfields are also described. For example，there are currently no nanofluid flooding systems available for efficient development of unconventional reservoirs. Furthermore，there has been insufficient theoretical and technical discussion and research. More integrated research is required on inter-related matters such as the development of nanofluids containing two-dimensional nanosheets，determination of the mechanisms for enhanced oil recovery，and field pilot testing of the process. Finally，a direction for the practical introduction and application of nanofluids is proposed. Reference | Related Articles | Metrics

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Research Progress on the Mechanisms and Control Methods of Casing Deformation in Shale Gas Horizontal Wells#br# YIN Aobo , LI Jun, , LIAN Wei , ZHANG Hui Xinjiang Oil & Gas    2025, 21 (1): 50-60.   DOI: 10.12388/j.issn.1673-2677.2025.01.006 Abstract （33）      PDF （3254KB）（131）       Knowledge map    Save Significant casing deformation （CD） occurs during multi-stage fracturing of shale gas horizontal wells，which reduces the ratio of recovered reservoirs and increases operation costs. Based on a comprehensive review of global research on this issue，a comparative analysis of the current status of casing deformation in shale gas horizontal wells was conducted. With the casing deformation data from Changning-Weiyuan，Luzhou，and Weirong blocks，the distribution patterns of casing deformation in terms of time，space，and morphology were summarized. The influences of engineering factors such as casing and cement sheath types，cementing quality，fracturing and perforation parameters，and thermal stresses，as well as geological factors such as reservoir heterogeneity and reservoir slip，on casing deformation，were analyzed. The analysis results indicate that while engineering factors can increase casing stresses，they are unlikely to cause casing deformation. Among geological factors，reservoir slip induced by natural fractures and faults activated during multi-stage fracturing is the main controlling factor leading to significant casing deformation. To address this issue，various control methods were summarized，including optimizing casing and cement sheath parameters，improving cementing quality，selecting appropriate fracturing and perforation parameters，optimizing wellbore trajectory，and controlling reservoir slip. Additionally，it was proposed to enhance the understanding of formations and improve prediction accuracy of reservoir slip. The research findings provide references for casing integrity design and control during the fracturing process. Reference | Related Articles | Metrics

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The Lost Circulation Mechanism in Formations Prone to Lost Circulation at Misui Block in Changqing Oilfield PENG Lei, LUO Jiangwei, ZHAO Hongbo, LE Lu, BIAN Jing, DONG Jingnan Xinjiang Oil & Gas    2023, 19 (4): 10-19.   DOI: 10.12388/j.issn.1673-2677.2023.04.002 Abstract （124）      PDF （8824KB）（98）       Knowledge map    Save Rich in natural gas resources，Misui Block is a key strategic area for accelerating the production of Changqing Oilfield. However，the frequent occurrence of lost circulation in recent years has seriously restricted improvement of cost-efficiency. Therefore，to curb the occurrence of well lost circulation，the lost circulation mechanism in this area has been studied through multi-scale quantitative experiment on rock physical property，microelectrode imaging logging observation and geo-mechanical profile analysis of wells. The results show that the thief zones in Misui Block are mainly in Liujiagou and Shiqianfeng Formations，which have large numbers of micro- and nano-scale fractures. The average calculated dynamic Yang's modulus of the cores from these formations are 17.94 GPa and 8.47 GPa，respectively，and the average dynamic Poisson's ratios are 0.394 and 0.064，respectively. The clay mineral content of Liujiagou Formation is more than 50%，and the brittle mineral content of Shiqianfeng Formation is as high as 72%. The imaging logging map shows that the area contains tensile fractures. The single well geo-mechanical profile reveals a low-pressure area in the thief zone，where the density of drilling fluid is 1.18 g/cm3. Finally，analysis shows that the high contents of clay and brittle minerals in the formation caused both hydration fractures and structural fractures，with low formation pressure causing drilling fluid to flow into natural fractures，eventually resulting in lost circulation. The research results not only reveal the lost circulation mechanism at Misui Block，but also provide technical guidance for selecting plugging methods and reducing well lost circulations at Misui Block. Reference | Related Articles | Metrics

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Study on the Law of Wellbore Alkali-Salt Deposition in Fengcheng Formation  of Mahu Sag#br# WU Dingying , PU Di, , ZHENG Miao , YIN Jianyu , LUO Pingya , GUO Yongjun, Xinjiang Oil & Gas    2023, 19 (3): 42-48.   DOI: 10.12388/j.issn.1673-2677.2023.03.007 Abstract （89）      PDF （1744KB）（93）       Knowledge map    Save The post-frac flowback and production of the alkali-salt layers of Fengcheng Formation in Mahu Sag suffer from wellbore salt deposition，but the salt deposition law remains unclear. Therefore，through static and dynamic salt precipitation evaluation experiments，the reservoir conditions affecting the salt precipitation rate and the impacts of flow rate and gas production on wellbore salt deposition in the production process are investigated to clarify the wellbore salt deposition law. The results show that the three typical salts，with their solubility from most to least sensitive to temperature，are sodium carbonate，sodium bicarbonate and sodium chloride. Moreover，the boundary conditions （total salinity and ion composition） and salt crystal types of salt crystal precipitation are defined for composite salt solutions with different compositions. Under the same salinity，the precipitation degrees of composite salts with different compositions are between those of the individual salt，and the priority orders of salt precipitation are sodium bicarbonate，sodium carbonate and sodium chloride，which is consistent with the change of solubility of various salts with temperature. With the increasing flow rate and gas production，the salt deposition first grows and then declines. The salt deposition peaks in the case of the daily liquid production of 40 m3/L and the gas-liquid ratio of 200 m3/L.The study on the salt deposition law in alkali-salt wells helps to set reasonable drainage parameters，delay the salt deposition during flowback，ensure the smooth completion of formation testing after fracturing，and provide a theoretical basis for on-site salt prevention measures in the later production from Fengcheng Formation alkali-salt layers. Reference | Related Articles | Metrics

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Xinjiang Oil & Gas    2023, 19 (3): 0-.   Abstract （91）      PDF （13819KB）（91）       Knowledge map    Save Related Articles | Metrics

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Practice and Understanding of Volume Fracturing Technology for Horizontal Wells in Jimsar Shale Oil Reservoir XU Jiangwen, WANG Mingxing, WANG Junchao, SUN Haoran, WANG Liang Xinjiang Oil & Gas    2024, 20 (3): 23-30.   DOI: 10.12388/j.issn.1673-2677.2024.03.003 Abstract （119）      PDF （790KB）（86）       Knowledge map    Save Addressing Jimsar shale oil reservoir，this study aims to enhance fracture-controlled reserves by conducting theoretical research and technical practices. Focused on four key aspects—fracture network design，construction，proppant effectiveness，and the enhancement of in-situ oil mobility，three generations of technological advancements have been realized. Fundamental theories regarding the effective propagation of hydraulic fracture in thin interlayers and key technologies such as multi-cluster fracturing within a stage and the use of cost-effective materials have been mastered. An integrated horizontal well volume fracturing technology system centered on fracture-matrix matching，precise stimulation，multi-scale proppant support，and CO2 prepad injection has been developed. The key technical indicators of fracturing have reached the advanced domestic level，supporting the large-scale and efficient development of Jimsar shale oil. In 2023，the oil production of Jimsar shale oil surpassed 60×104 t，with a consecutive annual production increase of 10×104 t in the block for three years. This achievement has provided robust technical support for the establishment of China's first national continental shale oil demonstration zone by 2025 and serves as a reference for optimizing shale oil development technologies in other regions of China. Reference | Related Articles | Metrics

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Fracture Propagation Law of Hydraulic Fracturing in High-Salinity Reservoir of Fengcheng Formation in Mahu #br# PAN Liyan, HAO Lihua, LIU Kaixin, SUN Xize, ZHU Zhenlong, ZHAO Yanxin, Xinjiang Oil & Gas    2023, 19 (4): 20-28.   DOI: 10.12388/j.issn.1673-2677.2023.04.003 Abstract （95）      PDF （2886KB）（83）       Knowledge map    Save The high salt content of Fengcheng Formation in Mahu leads to high operating pressures, difficulty in fracture propagation when penetrating salt layers, and increased difficulty in adding proppant. True triaxial fracturing experiments are carried out on equivalent salt-bearing rock samples prepared according to similarity criteria, and fracture propagation in salt-bearing reservoirs is numerically simulated using the finite element and cohesive element methods. The influence of salt content, viscosity, pump rate, and other factors on fracture propagation is explored. The results show that the fracture opening pressure of salt-bearing reservoirs is greater than that of conventional sandstone reservoirs, and their plasticity is stronger. The existence of pure salt interlayers hinders the longitudinal propagation of fractures. The lower the fluid viscosity , the stronger the dissolution of the salt-bearing reservoir and the lower the operating pressure. The higher the pump rate, the higher the fracturing friction and the operating pressure. In field, high viscosity fluid (120 mPa·s) with clean water and high pump rate （5 m3/min per single cluster） have been adopted to achieve effective penetration into pure salt barriers and form wider fractures. These results have important guiding significance for the stimulation of salt-bearing reservoirs in Mahu area. Reference | Related Articles | Metrics

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Current Status and Suggestions for Drilling Technology of CNPC Continental Shale Oil Reservoirs Xinjiang Oil & Gas    2024, 20 (3): 1-14.   DOI: 10.12388/j.issn.1673-2677.2024.03.001 Abstract （191）      PDF （2045KB）（79）       Knowledge map    Save Shale oil with medium to high maturity is the key field for China's shale oil strategic breakthrough，and strengthening the exploration and development of continental shale oil is an important way to ensure the security of national energy supply. The technical progress of shale oil drilling in Ordos，Junggar and Songliao Basins by China National Petroleum Corporation （CNPC） was introduced in detail，including large platform factory-like well placement，horizontal well casing program optimization，"one-run drilling" in separate well sections，high-performance drilling fluids for horizontal wells，integrated geological steering and other key technologies. By benchmarking against advanced shale oil drilling technologies in North America，the gap and development trend of shale oil drilling in China were analyzed in terms of well placement and wellbore configuration，geological-engineering integration and steering technology，supporting technology for accelerating rates of penetration （ROP），drilling fluid and cementing supporting technology. Development suggestions，such as continuously promoting large platform factory-like operations，optimizing wellbore configurations，integrating ROP acceleration technologies，strengthening research on geological-engineering integration，and accelerating the research and development of new-generation steering tools，were proposed in order to achieve the goals of ROP acceleration，cost reduction，and efficiency improvement in continental shale oil drilling，and moreover，the engineering goals of the shale oil revolution. Reference | Related Articles | Metrics

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Numerical Simulation of the Pressure Law of Energy Charging and Permeability Enhancement in Low Permeability Reservoirs ZHU Zheng, DANG Hailong, CUI Pengxing, DANG Kaiyan, BAI Pu, ZHAO Yining Xinjiang Oil & Gas    2023, 19 (4): 56-62.   DOI: 10.12388/j.issn.1673-2677.2023.04.007 Abstract （103）      PDF （6406KB）（75）       Knowledge map    Save A number of problems have been experienced with water injection in Yanchang Oilfield，such as high-pressure injection failure，poor flooding effect，and rapid increase of water cut during injection. An innovative method for energy charging and permeability enhancement is proposed to address these issues. Numerical reservoir simulation is used to study the evolution of fractures，matrix pressure，and bottom hole pressure propagation during injection and well shut in. The influence of injection volume on fracturing effect is also analyzed. It is found that，during the injection stage，rapid injection of fluid increases the pressure in the fracture，with the injected fluid passing through the main fracture to the tips of the fractures. The pressure increase mainly occurs around the fracture itself，with little change in the matrix pressure. In shut in stage，as shut in time increases，the matrix pressure in the fracture and near-fracture zone initially decreases rapidly and then tends to become stable after a certain time. If the distance from the fracture is more than 30 m，the matrix pressure first increases and then decreases with the increase of shut in time. The bottom hole pressure also declines rapidly in the early stage of shut in with the rate of decline slowing in the later stage. The greater the injection volume，the higher the formation energy. Analysis of the effect of energy charging and permeability enhancement in field applications for low permeability reservoirs shows remarkable increases in pressure and oil production. This provides a valuable reference for the development of energy charging and permeability enhancement in similar reservoirs. Reference | Related Articles | Metrics

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Analysis of the Effects for Reamer Size under Different Operation Conditions：a Case Study of Well H101 in the Southern Margin of Junggar Basin GAN Quan, ZHANG Maolin, ZHANG Chen, WEI Qiang, LI Bingqing, ZHANG Dong Xinjiang Oil & Gas    2023, 19 (3): 10-20.   DOI: 10.12388/j.issn.1673-2677.2023.03.002 Abstract （114）      PDF （5579KB）（74）       Knowledge map    Save The determination of the reamer size（the desirable reamed borehole size） is a global challenge for research on reaming in drilling. To ensure smooth drilling and cementing of reamed borehole sections，an in-depth case study of Well H101 drilled in the southern margin of Junggar Basin was performed to identify the affecting patterns of the reamed borehole size on drilling，tripping and cementing operations. The requirements for the reamer size were analyzed from perspectives of the drilling tool bending deformation，pump rate optimization，BHA vibration，swab and surge pressure during tripping and fluid density window，surge pressure of running liners，equivalent circulating density（ECD） during cementing，and wellbore integrity incorporating wellbore curvature，and the impacts of changes in casing sizes on cementing of the reamed borehole section were investigated. Finally，the above analyses were combined with a mathematical statistical approach to comprehensively determine the reamer size. The determined reamer size was applied to Well H101 and analogous wells in the southern margin of Junggar Basin，which were all found with smooth drilling operations after reaming，and moreover，Well H101 delivered a daily penetration of 101 m for the reamed borehole section. The presented method and strategy for the reamer size optimization incorporate more factors and are more reliable. They provide important references for determining the reamer size of to-be-reamed wells.  Reference | Related Articles | Metrics

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A Machine Learning-Based Bridging Particle Size Recommendation Method for Lost Circulation Control LIU Fan, LIU Yushuang, ZHANG Zhen, LI Yongjian, LIU Ce, MA Zhihu, Xinjiang Oil & Gas    2024, 20 (1): 13-20.   DOI: 10.12388/j.issn.1673-2677.2024.01.002 Abstract （93）      PDF （3565KB）（68）       Knowledge map    Save Lost circulation is a key technical challenge in oil and gas exploration，and bridge plugging is the most commonly used method for lost circulation control. As an important parameter，the size of bridging particles directly affects the plugging. At present，the size selection mainly relies on experience，lacking a scientific and effective method. In light of this，this paper investigates a particle size recommendation method for lost circulation control based on machine learning algorithms. The basic data used for this method are well-logging，mud logging，and lost circulation control data from 126 completed wells in Kuqa piedmont area of Tarim Basin. The input layer adopts 23 main parameters screened based on the Pearson algorithm，and the output layer is in 4 bridging particle size ranges of 0-750 μm，750-1 500 μm，1 500-4 000 μm and＞4 000 μm. 10 commonly used machine learning algorithms are trained and tested to determine the accuracy of three types of datasets：well logging data，mud logging data，and combination of the former two types. It is found that the scores of each algorithm for the well logging + mud logging dataset are generally higher than those for the well logging and mud logging datasets. For the combined dataset，the support vector machine and extremely randomized trees algorithms have the highest F1 scores of above 0.9. The bridging particle size recommendation model based on the support vector machine and extremely randomized trees algorithms is validated twice on a well in Kuqa piedmont area. The predicted results of bridging particle size of the two algorithm models are consistent with the actual bridging effect in the field. This method exhibits good application prospects in the scientific optimization of bridging particle size. Reference | Related Articles | Metrics

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Non-Uniform Perforation to Balance Multi-Cluster Fractures Propagation and Parameter Optimization SHENG Mao , DENG Chao , LI Jie , GU Mingzhe , WANG Tianyu , TIAN Shouceng, Xinjiang Oil & Gas    2024, 20 (3): 54-63.   DOI: 10.12388/j.issn.1673-2677.2024.03.007 Abstract （109）      PDF （5659KB）（68）       Knowledge map    Save Multi-cluster perforation staged fracturing of horizontal well has become one of the key technologies for completion and stimulation in unconventional oil and gas reservoirs. However，the fractures of the central perforation clusters in each fracturing stage are significant affected by stress interference from the fractures of heel and toe clusters，leading to substantial propagation resistance of the central cluster fractures. This is a major cause of the unbalanced propagation of multi-cluster fractures. This study optimized the design of non-uniform perforation distribution pattern between clusters to regulate the perforation parameters，balance the fluid distribution among clusters，mitigate the stress interference between fractures，and promote the balanced propagation of fractures. Therefore，a multi-stage，multi-cluster fracture propagation model that accounts for stress superposition between stages/clusters was established. The model was used to compare and analyze the fracture propagation patterns and mechanisms of spindle-shaped，sloped and uniform perforating patterns. The difference in fracture length and height propagation morphology was utilized to assess the equilibrium of fracture propagation. The perforation distribution pattern was optimized，and an orthogonal test was designed to refine the parameters of non-uniform perforation distribution pattern. The findings indicate that under typical shale oil reservoir conditions，the spindle-shaped perforation pattern achieves the best fracture propagation equilibrium，followed by uniform pattern and then the sloped pattern. The mechanism is that，with the spindle-shaped perforation pattern，the clusters at both ends have a perforation friction 1.4~16.7 times greater than that of the central clusters，reducing the stress interference from the heel and toe fractures on the central-cluster fractures. This results in an increased fluid inflow distribution in the central clusters，enhancing the fracture propagation equilibrium by 17.2 % compared to the uniform pattern. Conversely，the sloped perforation pattern，with over 35% of the holes concentrated at the toe cluster and accounting for 49.3 % of the fluid inflow，exerts a significant squeezing effect on the central cluster fractures，which is counterproductive to achieving a balanced fracture propagation. The optimization of the spindle-shaped perforation parameters reveals that an fracture propagation equilibrium is achieved with a total of 49 holes，a perforation diameter of 10 mm，and an end-cluster perforation proportion of 24.5%. The research results are expected to offer an effective approach for the design of non-uniform perforation in multi-cluster fracturing for unconventional oil and gas reservoirs.  Reference | Related Articles | Metrics

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Development Status of Wellbore Integrity Inspection Technology for Deep Strata and Deep Wells SONG Xuefeng , LI Zhibin, , LIU Jinming , WANG Jiangshuai , DING Yida , QIAN Xuesen Xinjiang Oil & Gas    2024, 20 (4): 8-18.   DOI: 10.12388/j.issn.1673-2677.2024.04.002 Abstract （128）      PDF （2630KB）（64）       Knowledge map    Save As the development of oil and gas resources is continuously advancing toward deep water areas，deep and ultra-deep strata，complex geology and extreme wellbore conditions pose great challenges to the safe and stable production of oil and gas wells. Conventional wireline logging technology and casing packer leak detection technology can meet the technical requirements of wellbore integrity inspection，but they both require to shutdown wells and the costs of joint inspection are high. In recent years，the application of fiber optic sensing in petroleum industry has become increasingly widespread，opening up new ideas for real-time monitoring of wellbore integrity. By systematically summarizing the current development status of wellbore integrity inspection，the following prospects are made：（1） Permanently or semi-permanently placing optical cables in oil wells enables monitoring the temperature field，pressure field，stress field，sound waves，vibration，and fluids inside the wellbore in real time to provide direct data for evaluating the integrity status of oil and gas wells.（2） Fiber optic sensing technologies such as DTS and DAS are characterized by continuous，real-time and distributed measurement，for which it is preferred to place them during the well construction to deliver full lifecycle monitoring of oil and gas wells. However，the overall cost of fiber optic laying is relatively high，and the fiber optic layout method needs to consider the impact of pipe string insertion and cementing perforation operations. The fiber optic winding method and light source scattering type also have an impact on optical signal transmission and signal-to-noise ratio. Corresponding measures need to be taken to optimize the signal-to-noise ratio，improve the measurement accuracy and stability of the sensor.（3） Processing of fiber optic signals mostly relies on empirical methods determining the signal range in accordance with laboratory simulation experiments. However，considerable differences exist between the laboratory environment and the downhole environment. Therefore，it is still necessary to conduct wellbore experiments and establish measurement interpretation models based on the actual wellbore environment. Reference | Related Articles | Metrics

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Key Technologies and Practice of Shale Oil Cost-Effective Development in Jimsar Sag，Junggar Basin QI Hongyan, WU Chengmei, HU Ke, CHEN Yiwei, XU Tianlu, WANG Yongjiao Xinjiang Oil & Gas    2024, 20 (3): 15-22.   DOI: 10.12388/j.issn.1673-2677.2024.03.002 Abstract （97）      PDF （2526KB）（61）       Knowledge map    Save Xinjiang Jimsar Shale Oil Demonstration Area is the first national-level continental shale oil demonstration project，located in Jimsar Sag，Junggar Basin，China. The target layer is Permian Lucaogou Formation. After ten years of exploration and development，with the obtained abundant production and geological data of the reservoir and deepened geological understanding，the corresponding exploration and development technologies become fairly mature. The fine 3D seismic survey with broadband excitation and well-surface integrated acquisition improves the geological understanding. The fine characterization and classification evaluation techniques of shale oil sweet spots provide a basis for development deployment. The comprehensive mud logging technology of "gold targets" improves the target-layer drilling ratio that is fundamental for delivering high stable production from horizontal wells. The customized fracturing technology of "complex fracture networks" provides an effective means for the efficient development of shale oil. The production capacity of horizontal wells is fully exploited by the flowback and production scheme optimization technique. The marketization has greatly reduced costs and improved both quality and efficiency. The cost-effective development technology system of Jimsar shale oil provides references for the efficient exploration and development of shale oil in China. Reference | Related Articles | Metrics

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Multi-Field Coupling Analysis of Wellbore Instability in Hutubi Anticline While Using Water-Based Drilling Fluid SONG Xianzhi, GUO Yong, XIANG Dongmei, JU Pengfei, TAN Qiang, LIU Wei Xinjiang Oil & Gas    2023, 19 (4): 1-9.   DOI: 10.12388/j.issn.1673-2677.2023.04.001 Abstract （107）      PDF （3894KB）（60）       Knowledge map    Save Complex problems，such as HTHP，wellbore collapse，and lost circulation were encountered during drilling Hutubi Anticline. The fabric，mechanical properties，and in-situ stress state of the troublesome medium-deep shale formation were analyzed to determine the countermeasures necessary to stabilize the borehole and reduce risk. A multi-field calculation model for collapse pressure was established linking mechanical factors，drilling fluid chemistry，and fluid seepage. The mechanism of wellbore instability when using water-based drilling fluid in the middle-deep shale formation of Hutubi anticline was identified. The results indicate that the montmorillonite content of the illite-smectite mixed layers in the mudstone in Paleogene Anjihaihe-Ziniquanzi Formation （which collapses readily） exceeds 35%. The formation exhibits moderate expansion and high dispersion，with water expansion rate and recovery rate both being less than 10%. The formation strength also shows anisotropic properties. The mudstone in Cretaceous Hutubihe-Qingshuihe Formation shows reduced swelling and increased hardness and brittleness. Hutubi Anticline is subject to significant tectonic stress，with the maximum horizontal principal stress being equivalent to nearly 2.50 g/cm3，which is higher than the overburden pressure. Applying the multi-field coupling model indicates that the main causes of wellbore instability are seepage of drilling fluid along cracks，hydration of mudstone after contact with drilling fluid，and insufficient effective mechanical support of drilling fluid for the wellbore. The collapse pressure calculated using the multi-field coupling model is 0.05-0.25 g/cm3 higher than when only considering mechanical factors. It was established that the wellbore can be kept stable by maintaining the sealing ability of the drilling fluid to the fractured formation，preventing contact with easily hydrated mudstone during drilling，and increasing the density of the drilling fluid to slightly higher than the collapse pressure. Reference | Related Articles | Metrics

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Development of Viscosity Reducer for High Density Water-Based Drilling Fluid and Its Application#br# DENG Zhengqiang , OU Meng , BAI Hailong , JING Yujuan , HUANG Ping , SHAO Ping Xinjiang Oil & Gas    2023, 19 (3): 33-37.   DOI: 10.12388/j.issn.1673-2677.2023.03.005 Abstract （177）      PDF （548KB）（55）       Knowledge map    Save One of the main reasons for rheology out-of-control of high density water-based drilling fluid is the increase of inferior solid phase content. Inferior solid phase is dispersed in high density water-based drilling fluid，which enhances the system architecture，resulting in increased drilling fluid viscosity and higher shearing force. Based on the principle of viscosity reduction by competitive adsorption，WNTHIN，a low molecular weight polymer viscosity reducer was synthesized with 2-acrylamide-2-methylpropanesulfonic acid，styrene，maleic anhydride，N and N-dimethylacrylamide in a molar ratio of 1∶2∶1∶1.Test results of the viscosity reducer show that WNTHIN can significantly reduce the viscosity and shearing force of high density potassium polysulfonate water-based drilling fluid with a density of 2.40 g/cm3，with plastic viscosity reduced by 42.85%，static shearing force reduced by 51.35%，and the recommended WNTHIN dosage addition is 1.5%. The field application of WNTHIN in a well in Penglai Gas Field showed improved rheology of high density potassium polysulfonate water-based drilling fluid. The plastic viscosity dropped from 58 mPa·s to 30 mPa·s，the yield point dropped from 29 Pa to 14 Pa，and the 10 min static shearing force dropped from 28 Pa to 16 Pa. The performance of the high density water-based drilling fluid has been improved to meet the technical requirements for safe drilling in deep wells.  Reference | Related Articles | Metrics

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Analysis of Factors Affecting the Productivity of Radial Multilateral Horizontal Wells in Low Permeability Reservoirs SUN Xize, YU Tianxi, Anivar·SHAYIMU, ZHENG Weijie, DING Kebao Xinjiang Oil & Gas    2023, 19 (3): 49-56.   DOI: 10.12388/j.issn.1673-2677.2023.03.008 Abstract （88）      PDF （3945KB）（55）       Knowledge map    Save Radial multilateral horizontal well technology can be used to improve the productivity of low permeability reservoirs by drilling multilateral branches in the oil intervals of horizontal wellbores，which increases the oil displacement area. However，the factors affecting the productivity of radial multilateral horizontal wells are not clear and，to date，there has been little research on methods of prediction. This paper describes a numerical model for radial multilateral horizontal wells，using numerical simulation software COMSOL，and its application in evaluating the influence of factors such as reservoir and well type on well production. The mathematical model was solved using the finite element method and radial horizontal well output predicted using the material balance method. The focus of the study is to analyze the effects of changes in radial multilateral well parameters and formation heterogeneity on production behavior and transient pressure distribution. The results show that branch length has a significant effect on productivity，effectively expanding the control area. The number of branches，their angles，and formation heterogeneity，are found to be the principal controlling factors. Reference | Related Articles | Metrics

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Settling Plugging Technology for Severe Lost Circulation at the Salt Bottom of Tarim Piedmont Zone LIU Fengbao, YIN Da, WEI Tianxing, WU Hongyu, WANG Ziwu Xinjiang Oil & Gas    2024, 20 (4): 1-7.   DOI: 10.12388/j.issn.1673-2677.2024.04.001 Abstract （78）      PDF （990KB）（53）       Knowledge map    Save High-pressure gypsum salt beds and low-pressure clastic rock target beds are commonly developed in the piedmont zone of Tarim Basin，and the pressure difference between these two stratigraphic systems generally exceeds 20 MPa. Because of the inaccuracy of geological stratigraphic determination during drilling，it is highly likely to drill through the gypsum salt bed into the target bed and then trigger severe lost circulation. To solve the problem of severe lost circulation at the salt bottom of Tarim piedmont zone，this paper evaluates the performance parameters of plugging materials such as pressure-bearing capacity and settling velocity，identifies the optimal conditions （velocity and mass） of oil- and water- based drilling fluid （OBM and WBM） settling plugging pills respectively，and finally develops the high density large pressure difference settling plugging technology specialized for OBM and WBM，based on the known mechanism of the severe lost circulation problem （drilling induced communication between high and low pressure formations） and the principle of the "bottle plug" plugging practice. Specifically，optimal plugging pills are expected to form in the case of OBM with a oil-water ratio of 50：50 and ES of 200-300 V or WBM with 0.2% XC + 0.2% demulsifier + plugging agents. The developed settling plugging technology has been successfully tested in three wells in Tarim piedmont zone，and Well DB1302 was found with a pressure bearing capacity of 30 MPa，demonstrating excellent application performance. Reference | Related Articles | Metrics

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Simulation and Countermeasures  of Casing Erosion at Downhole Decoupled Sandblaster During Fracturing WANG Feiwen, LI Junzhi, XIANG Zhipeng, CHEN Rui, ZHAO Yunfeng, MOU Yisheng Xinjiang Oil & Gas    2023, 19 (3): 57-65.   DOI: 10.12388/j.issn.1673-2677.2023.03.009 Abstract （74）      PDF （4659KB）（51）       Knowledge map    Save During long-time fracturing，the high speed proppant-carrying fluid flowing will cause serious erosion for downhole tools and casings. Therefore，it is important to understand the flow field distribution inside the tool and the casing erosion pattern during fracturing，propose improvement measures，optimize fracturing parameters，and protect wellbore integrity. A finite element mechanical model of casing erosion at the decoupled sandblaster during fracturing was developed，and a systematic analysis and study of erosion in an ultra-deep well was conducted. The results show that without sheath protection，the erosion rate of the casing at the outlet reaches 1.46×10-3 kg/（m2·s），with a casing thickness reduction of 1.35 mm，which decreases the casing strength，and the pipe string with erosion defect is more prone to stress concentration. After the sheath is added，the wall thickness reduction of the casing caused by erosion is significantly lower than that of the working condition without sheath protection. The finite element model developed allows a complete and quantitative study and analysis on all the points near the outlet of the sandblaster. The safety window of wall thickness thinning of the eroded sheath under different injection rate of fracturing fluid and proppant ratio was predicted. The safety window can quantitatively provide guidance for the operators to ensure effective protection of the casings and prevent casing erosion by controlling the injection rate and proppant ratio. The study is of great significance to parameter optimization and wellbore protection during fracturing. Reference | Related Articles | Metrics

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Xinjiang Oil & Gas    2025, 21 (1): 0-.   Abstract （123）      PDF （13664KB）（51）       Knowledge map    Save Related Articles | Metrics

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Performance Evaluation of the Cement Sheath in Jimsar Shale Oil Wells WANG Dian, LI Jun, ZHANG Wei, LIAN Wei Xinjiang Oil & Gas    2023, 19 (4): 49-55.   DOI: 10.12388/j.issn.1673-2677.2023.04.006 Abstract （93）      PDF （1588KB）（50）       Knowledge map    Save Hydraulic fracturing technology is an important method for increasing the production capacity of shale oil wells. The mechanical behavior of well cement sheath during fracturing has an important impact on the safety and efficiency of production. Based on the cement slurry system in Jimsar region，a cement specimen maintenance mold was designed as well as a cement bonding strength test program，maintaining the standard cylindrical specimen of cement and the set cement bond specimen. The uni/triaxial compression experiments were then carried out as well as the cyclic loading experiments and bonding strength experiments under simulated well bottom conditions to investigate the rules governing damage and destruction of cement bodies and cementing interface. The results show that under uniaxial compression，the set cement has significant elastic-brittle characteristics and that macroscopic cracks are formed in the cement body when it is damaged.The average Young's modulus of cement is 3.054 GPa and the average Poisson's ratio is 0.127. Under triaxial conditions，the strength and plasticity of the cement sheath are enhanced. During cyclic loading，there is a bilinear accumulation of cementite plastic deformation，with the amount of plastic deformation being positively correlated with the peak load. The plastic strain after 20 cycles increased from 0.24% to 2.46% when the peak load increased from 22.7 MPa to 53.2 MPa. The cement bonding strength is lower than 1 MPa，which is much lower than the body strength，and the bonding interface is a natural mechanical weak zone，representing a risk point for wellbore seal failure. Reference | Related Articles | Metrics

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Xinjiang Oil & Gas    2023, 19 (4): 0-0.   Abstract （54）      PDF （13358KB）（50）       Knowledge map    Save Related Articles | Metrics

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Research Status of Wellbore Stabilization Drilling Fluid Materials in Complex Shale Formations HUANG Xianbin, , ZHANG Xuehao, , YUAN Zhenhang, , ZHANG Yang, Xinjiang Oil & Gas    2024, 20 (3): 46-53.   DOI: 10.12388/j.issn.1673-2677.2024.03.006 Abstract （96）      PDF （1203KB）（50）       Knowledge map    Save In response to the frequent wellbore instability issues encountered during drilling operations in complex shale formations，the drilling fluid technologies aimed at wellbore stabilization have been developed at home and abroad. These include shale hydration inhibition，formation pore plugging，and chemical wall strengthening techniques. Despite these advancements，existing methods have limitations in curbing the surface hydration of shale，and the effect of rapid plugging and wall strengthening agent is considerably reduced under high temperature conditions，making it challenging to address wellbore instability. This paper offers a comprehensive review of the research work on drilling fluid materials for wellbore stability in complex shale formations. By analyzing the current state of research，it elucidates the mechanism of various drilling fluid materials，including shale hydration inhibitors，plugging agents，and chemical wall strengthening agents. It also discusses the strengths and limitations of different types of wellbore stabilization materials. This paper highlights the need for fundamental theoretical research into shale hydration，the development of novel nanomaterials that are stable and effective under high temperature and high salinity conditions，and the establishment of evaluation methods for chemical wall strengthening agents that can simulate downhole conditions. These areas are identified as key focal points and challenges for future research in the field of drilling fluid materials and technologies for wellbore stabilization in complex shale formations. This paper concludes with an outlook on the future development directions for these technologies and materials. Reference | Related Articles | Metrics

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The Principles and Field Application of Double Throttling Technology in Mahu Oilfield YAO Tianqi, XUE Liang, WANG Dian, XIN Xiaozhi, XU Xiaohui, CHI Ming Xinjiang Oil & Gas    2023, 19 (4): 63-68.   DOI: 10.12388/j.issn.1673-2677.2023.04.008 Abstract （69）      PDF （1160KB）（48）       Knowledge map    Save A high gas-bearing well in Mahu  Oilfield suffers from hydrate freezing blockage，which results in considerable fluctuation in gas and liquid production. The surface gathering and transportation capacity is also limited. A double throttling technology is proposed to address this problem. Throttling nozzles are installed downhole and at the wellhead to control hydrates and regulate production. PIPESIM software was used to calculate the temperatures and pressure distribution in tubing and nozzles under double throttling condition. Thus，the principles of hydrate freezing prevention，wellhead production regulation，and discharge for blockage prevention were studied. Double throttling was carried out 51 times in 20 wells and its field application effects was analyzed. 5 test wells were designed to adopt the double throttling technology and thus the average cleaning interval of hydrate in production wells with serious freezing blockage problems was more than doubled. The field application results show that downhole throttle ratio is the core parameter of the double throttling process design. Reducing downhole throttling ratio improves the capacity of hydrate freezing and blockage prevention. Increasing downhole throttling ratio improves the production regulation ability of wellhead nozzle. For high gas production wells，a low downhole throttling ratio design can achieve good hydrate freezing blockage prevention results. For high liquid production wells，a high throttling ratio allows both effective wellhead production regulation and hydrate freezing prevention. This provides a solid theoretical basis for more efficient development of Mahu Oilfield. Reference | Related Articles | Metrics

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CO2 Flooding Connectivity Characteristics of the Strong Water-Sensitive Conglomerate Reservoir in Xinjiang Oilfield CHEN Shengen, XU Jinshan, ZHANG Xin, WANG Rui, ZHANG Liwei, LI Haifu Xinjiang Oil & Gas    2024, 20 (1): 44-51.   DOI: 10.12388/j.issn.1673-2677.2024.01.006 Abstract （96）      PDF （2075KB）（47）       Knowledge map    Save Clarifying the connectivity characteristics between injection and production wells in CO2 flooding reservoirs can provide essential support for the subsequent implementation of CO2 flooding technology to improve sweep efficiency. With a strong water-sensitive conglomerate reservoir in Xinjiang Oilfield as the research object，this paper specifies the key parameters for determination of injection and production connectivity through the analysis of injection and production data. It designs the evaluation coefficient C after presetting the proportion of key parameters，and confirms the connectivity between injection and production wells under different ranges of C value，thus establishing a connectivity evaluation method for the strong water-sensitive conglomerate reservoir. This method can be used to judge weak，medium，or strong connectivity between injection and production wells in this area and analyze the main controlling factors of different connectivity characteristics to form targeted treatment measures. The study shows that the key parameters for determination of injection and production connectivity are oil production rate，tubing pressure，and the gas component of production wells. When the C value is greater than 8，the injection and production wells have strong connectivity；between 3 and 8，the injection and production wells have medium connectivity；and when less than 3，the injection and production wells have weak connectivity. According to the statistical injection and production data of the whole area and the C value，the connectivity between injection and production wells in the block presents two apparent characteristics. First，the connectivity between injection and production wells has directionality. The medium and strong connectivity is mainly northwest，but the local connectivity has specific differences，primarily affected by the structure and early water flooding. Second，the connectivity has regional characteristics and is better in the northeast region of the block center. Among the 22 wells in the area，14 wells show strong connectivity，accounting for 63.6%，mainly affected by the difference in formation permeability and the amount of carbon injection. According to the results of injection and production connectivity，it is suggested to implement classified management of the various connected wells in the area，huff and puff for wells with weak connectivity in the marginal area，small-scale fracturing for wells with weak connectivity in the core area，and channeling sealing and profile control for wells with strong connectivity. This study can provide a reference for the efficient development of strong water-sensitive conglomerate reservoirs by CO2 flooding after water injection. Reference | Related Articles | Metrics

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Development and Evaluation of Block Silicone Oil Anti-Water Blocking Agent JIN Jiafeng, DENG Yan, HUANG Xianbin, WANG Jintang, LIU Kesong Xinjiang Oil & Gas    2023, 19 (3): 38-41.   DOI: 10.12388/j.issn.1673-2677.2023.03.006 Abstract （80）      PDF （597KB）（47）       Knowledge map    Save To prevent the water block damage induced by any extraneous fluid's invasion during drilling and completion operations in low-permeability gas reservoirs，a high-performance anti-water blocking agent（FWB），which is composed of hydrogen-rich block silicone oil and some additives such as organosilicon surfactant and deformer，was developed for low-permeability gas reservoirs. The infrared spectroscopy was used to characterize the molecular structure of the block silicone oil，and a series of tests，which include surface tension test，contact angle test，core imbibition test，permeability recovery ratio test，and drilling fluid compatibility test，were conducted to comprehensively evaluate the performance of this anti-water blocking agent. The test results show that，at the mass concentration of 1%，it can dramatically reduce the surface tension of the aqueous phase to 22.28 mN/m，increase the contact angle of the aqueous phase from 29° to 120°，decrease the core imbibition amount by 69.2%，and improve the permeability recovery ratio to 89.3%，and that it has good compatibility with drilling fluids. This anti-water blocking agent can significantly reduce the water block damage during drilling and completion operations and provide effective protection for low-permeability oil and gas reservoirs.  Reference | Related Articles | Metrics

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Xinjiang Oil & Gas    2024, 20 (4): 0-0.   Abstract （38）      PDF （13678KB）（47）       Knowledge map    Save Related Articles | Metrics

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Micro-Scale Visualization of Enhanced Oil Recovery by Micro-Emulsion Chemical Flooding ZHU Zhehan, HE Fen, YANG Zhenhang, WANG Chen, YU Wenqiang, ZHOU Yi Xinjiang Oil & Gas    2024, 20 (2): 79-.   DOI: 10.12388/j.issn.1673-2677.2024.02.010 Abstract （66）      PDF （3447KB）（45）       Knowledge map    Save Chemical flooding plays an important role in improving oilfield recovery. The micro-emulsion system has been widely studied and applied owing to its unique properties. In this experiment，the alcohols with carbon numbers less than five were selected as cosurfactants to optimize the performance of the micro-emulsion system. The dynamic oil displacement process，morphology and distribution of residual oil and displacement performance of micro-emulsion flooding were visualized using microfluidic technology. Firstly，the mass fractions of isopropanol and n-butanol in the cosurfactants were optimized，followed by the optimization of NaCl mass fractions. Ultimately，microscopic visual displacement experiments were conducted with the optimal micro-emulsion formulation. The results show that the optimal micro-emulsion formulation is as follows：an fixed oil-water ratio of 1∶1，5 wt% SDS，8 wt% n-butanol and 3 wt% NaCl as the optimum. The corresponding ultimate oil recovery is 98.8%，and the residual oil saturations are 0.15% and 1.05% in the high- and low- permeability zones，respectively. NaCl can change the polarity of water to reduce interfacial tension. The combination of n-butanol with surfactants and NaCl can greatly reduce interfacial tension and modify the wettability of the microfluidic chip，leading to promoted oil detachment and enhanced mobility of residual oil. Using microfluidic technology to study the in situ emulsification and dynamic displacement process of micro-emulsions provides effective theoretical guidance and technical support for efficient development of reservoir residual oil. Reference | Related Articles | Metrics

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Design of Shaped Cutter PDC Bit for Deep Hard Plastic Mudstone LIU Wei, FENG Chaochao, WAN Xuxin, ZHANG Zengbao, WEI Jiusen, GAO Deli Xinjiang Oil & Gas    2023, 19 (3): 1-9.   DOI: 10.12388/j.issn.1673-2677.2023.03.001 Abstract （113）      PDF （7535KB）（45）       Knowledge map    Save With oil and gas exploration and development approaching the deep-burial，deep-water and unconventional fields，the encountered formations become increasingly complex. Deep mudstone formations exhibit strong hard plastic characteristics during drilling，resulting in difficulties in penetrating of cutters into formations and low rates of penetration （ROP）. Given the challenge of improving ROP in hard plastic mudstone，rock-breaking simulation tests of PDC （Polycrystalline Diamond Compact） cutters were conducted for hard plastic formations，and the rock-breaking effects of various shaped cutters were analyzed. The results indicated that the 3D-shaped cutter exhibits the best rock-breaking efficiency and certain durability: it delivers a maximum ROP improvement of 116.4% in the hard plastic mudstone in Shengli Luojia Oilfield. Furthermore，a staggered cutter arrangement design，combining axe-shaped and 3D-shaped cutters，was proposed for drilling deep and complex formations，like sand-mudstone interbedding formations，which delivers the highest ROP increment of  215.7% in Yongjin Oilfield in Junggar Basin. Additionally，potential measures for enhancing ROP in hard plastic mudstone were discussed. The design principles of "sharp breakthrough，plane advancing and intensive scraping with small-diameter cutters" are recommended to improve the drilling efficiency. The research findings provide valuable insights for optimizing the design of PDC bits for hard plastic mudstone. Reference | Related Articles | Metrics

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Energy Conservation and Consumption Reduction Technology of Gas Extraction System in Hutubi Gas Storage MA Zenghui, ZHAO Yida, CHEN Ligang, HE Lin, ZHU Huan, BAI Bofeng Xinjiang Oil & Gas    2024, 20 (1): 88-94.   DOI: 10.12388/j.issn.1673-2677.2024.01.011 Abstract （101）      PDF （1756KB）（44）       Knowledge map    Save Given the current situation that some operating parameters of the gas extraction system in Hutubi gas storage deviate from the optimal value to cause low energy-saving efficiency，the energy efficiency of the gas extraction system is analyzed through pinch analysis and exergy analysis methods. A simulation study is performed based on HYSYS software，giving rise to the scheme of energy conservation and consumption reduction. The scheme mainly includes the selection of the gas-gas heat exchanger，the optimization of the glycol-rich liquid inlet temperature，the optimization of the reflux ratio of the regenerator，and the optimization of the phase-change furnace. The calculation model between the inlet pressure and J-T valve back pressure and the theoretical KA value of the gas-gas heat exchanger is established to optimize the selection of the heat exchanger. The optimum inlet temperature of the glycol-rich liquid is determined to be 67 ℃，and the reflux ratio of the regenerator is 0.06. During the operation of the top condenser of the regenerator，the consumption of glycol can be reduced by 84.6%. The energy consumption of the system can be reduced by 9.0% by using the waste heat of the exhaust gas from the regenerator to preheat the external transmission gas. This optimization scheme effectively reduces the total energy consumption of the gas extraction system with minimum alteration. Reference | Related Articles | Metrics

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Application and Prospect of LiDAR Technology in Seismic Acquisition of Complex Mountainous Areas#br# XU Wenrui , WANG Liye , WEI Chencheng , QIN Xin , LIU Yiyan , PENG Xiao Xinjiang Oil & Gas    2025, 21 (1): 1-9.   DOI: 10.12388/j.issn.1673-2677.2025.01.001 Abstract （55）      PDF （12113KB）（44）       Knowledge map    Save The southern piedmont belt of Junggar Basin is rich in oil and gas resources. However，seismic exploration is faced with such problems as high implementation difficulties，low efficiency，high risks and high costs of field acquisition，due to the highly undulating surface conditions and complex underground structures. Therefore，the LiDAR technology was introduced to improve quality and efficiency in seismic acquisition. The functions of mountain excitation type division，mountain shot point pre-design，fine surface survey design，mountain vehicle navigation design and risk classification can be rapidly completed through the "far-looking" functionality of LiDAR images and high precision elevation data. With the application of this technology in mountain seismic acquisition，vibroseis has access into mountains，which effectively improves the excitation ratio of vibroseis in mountainous areas and the efficiency of field acquisition operations to improve quality and efficiency in the field. Looking ahead，it is believed that the LiDAR technology will play a greater role in seismic acquisition operations in complex mountainous areas. The high precision coordinates and elevation models of LiDAR images are expected to replace traditional measurement processes in field acquisition. The high resolution coordinates and elevations can improve the accuracy of surface modeling inversion. Rapid construction of digital outcrop models can be delivered with high definition imaging and digital elevation platforms. This technology promotes the upgrading of seismic exploration processes，the implementation of efficient exploration in mountainous areas，and data improvement for complex moutainous structures. Reference | Related Articles | Metrics

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Film-Forming Plugging Reservoir Protection Technology in Tangdong Evaluation and Appraisal Wells#br# ZHUO Lvyan , ZHAO Cheng , ZHANG Yi , Wang Yingbo , Dou Shuming , Wang Chao Xinjiang Oil & Gas    2023, 19 (3): 26-32.   DOI: 10.12388/j.issn.1673-2677.2023.03.004 Abstract （82）      PDF （697KB）（43）       Knowledge map    Save Tangdong Block of Dagang Oilfield has complex geology. The main target layers are the third member of Dongying Formation and Shahejie Formation. The target layers are deeply buried and rather thick, and the damage mechanisms between the reservoirs are very different. The applications of fine calcium carbonate and plugging agents for drilling fluids in reservoir damage prevention present insufficient performance for exploration and appraisal wells in this block, due to the low technical adaptiveness to the reservoirs and inferior practice management. The core permeability recovery rate for the reservoirs is only 67.5%. According to the core sensitivity evaluation and casting thin section analysis results of Well Tangdong 9X6, a reservoir protection technology system was developed for the drilling of the Tangdong exploration and appraisal wells, according to the potential damage factors. The protection system adopts the film-forming plugging reservoir protection technology and combines the applications of the single-well multi-layer/multi-point design method. The efficient implementation of the developed technology system is ensured with the help of refined technology implementation management and high-quality real-time evaluation. The film-forming plugging reservoir protection technology was applied to five wells in this block. The dynamic fluid loss of drilling fluids was reduced by 25.7%, and the permeability recovery rate was increased by 13.1%.  All the five wells met the geological expectations. Two wells have delivered high production, with initial daily production of 61.3 t and 101.1 t, respectively, which indicates good performance. Reference | Related Articles | Metrics

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Use of Metaverse Technology Clusters and Quantum Computing in CCUS：Research Status and Trends#br# LUO Ling , LI Yichang , WEI Liyao Xinjiang Oil & Gas    2023, 19 (3): 86-94.   DOI: 10.12388/j.issn.1673-2677.2023.03.013 Abstract （109）      PDF （2713KB）（42）       Knowledge map    Save The metaverse represents the next generation of internet and is also an immersive virtual world connected to the real world on which it is having a profound effect. It is capable，for example，of real time rendering of digital twin scenarios and high-precision simulations that follow the laws of physics. Carbon Capture，Utilization，and Storage （CCUS） has come to be regarded as a critical core technology for China to achieve its double carbon goal. Compared with conventional Carbon Capture and Storage （CCS） technology，it offers tangible economic benefits and practical operability. The metaverse can energize every aspect of CCUS. However，current CCUS engineering technology is not standardized，which means high industrialization costs. Our analysis of the current development status of CCUS technology at home and abroad reveals that machine learning based on supervised and unsupervised algorithms can play a huge role in CO2 capture using adsorption techniques；in particular on the selection of adsorbent materials. In addition，process simulation and optimization using quantum computing offers a lower cost option for CO2 capture than the technologies currently in use. This paper proposes an intelligent，integrated，on and offline management system—using metaverse technology clusters （particularly machine learning）—as a vision for the future to solve the industrialization issues facing CCUS and help to achieve its large scale application. Related Articles | Metrics

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Status and Development Trend of Molten Salt Thermal Storage Technology Based on Photothermal Technology DUAN Shengnan, MA Nengliang, CHEN Xiangyu, DUAN Zidan, CHEN Bairong, WANG Zhiqiang Xinjiang Oil & Gas    2024, 20 (2): 87-.   DOI: 10.12388/j.issn.1673-2677.2024.02.011 Abstract （121）      PDF （1771KB）（42）       Knowledge map    Save In addressing the problems of intermittency and instability in the conventional utilization of solar energy，this paper introduces the research progress of the photothermal technology applied in photothermal power generation and direct solar thermal utilization for stable solar heat supply by employing heat storage systems，and summarizes the classification methods and application scenarios of current heat storage technologies. This study reviews the technical principles and research progress of the mainstream molten salt heat storage systems （carbonate，chloride，fluoride and nitrate），pointing out the advantages and technical problems of different molten salt thermal storage systems. Aiming at the core of the molten salt thermal storage technology，it summarizes the research status and process flow of photothermal technology in different scenarios. This paper also generalizes the development trends of molten salt thermal storage systems in the photothermal field. First，suitable heat collection modes are selected according to application scenarios，and the capacity configuration and coordination control of solar heat collection and molten salt thermal storage are optimized. Second，molten salt with lower melting points，wider liquid temperature range，and low corrosion is developed to improve the applicability of molten salt thermal storage. Third，the operation safety and stability of the molten salt energy storage system can be ensured while costs are lowered. This provides a reference for the future application and development of the molten salt thermal storage technology. Reference | Related Articles | Metrics

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Calculation of Casing Collapse Strength under Zipper Fracturing in Platform Wells LI Jun, , ZHANG Xiaojun , LIAN Wei , ZHANG Juncheng , LIU Gonghui Xinjiang Oil & Gas    2024, 20 (3): 37-45.   DOI: 10.12388/j.issn.1673-2677.2024.03.005 Abstract （69）      PDF （4873KB）（42）       Knowledge map    Save With the extensive applications of new technologies such as zipper fracturing in shale oil and gas development，the casing is subjected to both the multi-stage cyclic internal pressure and the external non-uniform compressive load caused by zipper fracturing operations. Given this，this paper analyzes the variation law of casing collpase strength under multi-stage cyclic load and zipper fracturing of platform wells via the multi-stage cyclic load experiments and numerical simulations. The calculation method of the casing comprehensive collapse strength coefficient under multi-stage fracturing is developed and applied to a casing-deformed well in  Xinjiang Oilfield. The results show that the casing collapse strength decreases linearly with the number of load cycles under cyclic loading. Zipper fracturing results in the non-uniform stress distribution around the well，and the casing collapse strength nearly linearly decreases with the increasing stress non-uniformity. Under the combined effects of internal and external loads，the casing collapse strength drops by more than 15%，which increases risks of casing deformation. The calculation method of casing callopase strength in platform wells proposed in this paper provides calculation guidance for the prevention of casing deformation in fracturing practice. Reference | Related Articles | Metrics

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Numerical Simulation of Nitrogen-Assisted VHSD Development in Old Super-Heavy Oil Reservoirs WANG Pan, LIU Yang, LIANG Xiangjin, ZHENG Aiping, QIN Ninghan, FENG Zhijun Xinjiang Oil & Gas    2024, 20 (1): 38-43.   DOI: 10.12388/j.issn.1673-2677.2024.01.005 Abstract （79）      PDF （4553KB）（40）       Knowledge map    Save Changing over to Vertical-Horizonal well Steam Drive （VHSD） development pattern is becoming an important means for improving block production rate and recovery rate in old super-heavy oil reservoirs. Nitrogen-assisted VHSD can increase energy and pressure and form a heat insulating top layer，effectively solving the problems of pressure maintenance，low displacement pressure，and low steam chamber temperatures following huff-puff operations in old heavy oil reservoirs，saving steam volume，improving oil production levels and oil-steam ratio，and reducing carbon consumption. This paper examines a VHSD development unit in the Ninth Block of Karamay Oilfield. Numerical simulation is used to determine the influences of different parameters （nitrogen injection timing，injection pattern，injection amount） on pressure and energy increase，and on the establishment of heat insulating layers. Variations in recovery rates and accumulated injection-production indicators during VHSD development are also analyzed. The results show that nitrogen injection by slug can help to build a heat insulating layer in the initial stages of the transition to displacement and drainage. In field tests of this nitrogen-assisted VHSD approach，the oil-steam ratio of the study well group was increased by 0.025，and daily oil production was increased by 0.7 t，which are favorable results. This study provides a technical reference for efficient development using nitrogen-assisted VHSD in similar old heavy oil reservoirs. Reference | Related Articles | Metrics

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Concentrated Solar Steam Generation Technology Enables Low Carbon Shallow Super-Heavy Oil Production FAN Yuxin, LI Hongzhou, DUAN Shengnan, GU Pengcheng, REN Ning Xinjiang Oil & Gas    2023, 19 (4): 82-87.   DOI: 10.12388/j.issn.1673-2677.2023.04.011 Abstract （117）      PDF （1762KB）（40）       Knowledge map    Save PetroChina Xinjiang Oilfield Company is carrying out a pilot test of concentrated solar power direct steam generation，in conjunction with existing gas-fired steam boilers，to produce low-carbon，high-quality steam for super-heavy oil production using SAGD technology. This has exemplary significance for the integration of oil and gas field exploration and development using renewable energy technology. Under the double carbon initiative，Xinjiang Oilfield is facing the challenge of reducing natural gas consumption and CO2 emission while maintaining super-heavy oil production. Through combining solar energy concentrating and heating technology，green electricity + electrode molten salt heating technology，and high-temperature heat storage technology，renewable energy supply configuration schemes for different scenarios are proposed for the use of steam injection in shallow heavy oil exploitation，which will provide a specific road map and solution for the scale application of concentrating solar power technology in the heavy-oil operation areas of Xinjiang Oilfield. The schemes will reduce self-consumption of natural gas and provide low-cost steam，and has guiding significance for low carbon，sustainable exploration and development of heavy-oil fields. Reference | Related Articles | Metrics