Mechanism of gas pressure action during the initial failure of coal containing gas and its application for an outburst inoculation

Faced with the continuous occurrence of coal and gas outburst(hereinafter referred to as“outburst”)disasters,as a main controlling factor in the evolution process of an outburst,for gas pressure,it is still unclear about the phased characteristics of the coupling process with in situ stress,which induce coal damage and instability.Therefore,in the work based on the mining stress paths induced by typical outburst accidents,the gradual and sudden change of three-dimensional stress is taken as the background for the mechanical reconstruction of the disaster process.Then the true triaxial physical experiments are conducted on the damage and instability of coal containing gas under multiple stress paths.Finally,the response characterization between coal damage and gas pressure has been clarified,revealing the mechanism of action of gas pressure during the initial failure of coals.And the main controlling mechanism during the outburst process is elucidated in the coupling process of in situ stress with gas pressure.The results show that during the process of stress loading and unloading,the original gas pressure enters the processes of strengthening and weakening the action ability successively.And the strengthening effect continues to the period of large-scale destruction of coals.The mechanical process of gas pressure during the initial failure of coals can be divided into three stages:the enhancement of strengthening action ability,the decrease of strengthening action ability,and the weakening action ability.The entire process is implemented by changing the dominant action of in situ stress into the dominant action of gas pressure.The failure strength of coals is not only affected by its original mechanical strength,but also by the stress loading and unloading paths,showing a particularly significant effect.Three stages can be divided during outburst inoculation process.That is,firstly,the coals suffer from initial damage through the dominant action of in situ stress with synergy of gas pressure;secondly,the coals with spallation of structural division are generated through the dominant action of gas pressure with synergy of in situ stress,accompanied by further fragmentation;and finally,the fractured coals suffer from fragmentation and pulverization with the gas pressure action.Accordingly,the final broken coals are ejected out with the gas action,initiating an outburst.The research results can provide a new perspective for deepening the understanding of coal and gas outburst mechanism,laying a theoretical foundation for the innovation of outburst prevention and control technologies.

Evaluation and Application of Flowback Effect in Deep Shale Gas Wells

The pivotal areas for the extensive and effective exploitation of shale gas in the Southern Sichuan Basin have recently transitioned from mid-deep layers to deep layers.Given challenges such as intricate data analysis,absence of effective assessment methodologies,real-time control strategies,and scarce knowledge of the factors influencing deep gas wells in the so-called flowback stage,a comprehensive study was undertaken on over 160 deep gas wells in Luzhou block utilizing linear flow models and advanced big data analytics techniques.The research results show that:(1)The flowback stage of a deep gas well presents the characteristics of late gas channeling,high flowback rate after gas channeling,low 30-day flowback rate,and high flowback rate corresponding to peak production;(2)The comprehensive parameter AcmKm1/2 in the flowback stage exhibits a strong correlation with the Estimated Ultimate Recovery(EUR),allowing for the establishment of a standardized chart to evaluate EUR classification in typical shale gas wells during this stage.This enables quantitative assessment of gas well EUR,providing valuable insights into production potential and performance;(3)The spacing range and the initial productivity of gas wells have a significant impact on the overall effectiveness of gas wells.Therefore,it is crucial to further explore rational well patterns and spacing,as well as optimize initial drainage and production technical strategies in order to improve their performance.

Influential factors and control of water inrush in a coal seam as the main aquifer

In this paper, a combination of field measurement, theoretical analysis and numerical simulation were used to study the main control factors of coal mine water inrush in a main aquifer coal seam and its control scheme. On the basis of revealing and analyzing the coal seam as the main aquifer in western coal mine of Xiao Jihan coal mine, the simulation software of PHASE-2D was applied to analyze the water inflow under different influencing factors. The results showed that water inflow increases logarithmically with the coal seam thickness, increases as a power function with the permeability coefficient of the coal seam, and increases linearly with the coal seam burial depth and the head pressure; The evaluation model for the factors of coal seam water inrush was gained by using nonlinear regression analysis with SPSS. The mine water inrush risk evaluation partition within the scope of the mining field was obtained,through the engineering application in Xiao Jihan coal mine. To ensure the safe and efficient production of the mine, we studied the coal mine water disaster prevention and control measures of a main aquifer coal seam in aspects of roadway driving and coal seam mining.

Geological Factors Controlling the Accumulation and High Yield of Marine-Facies Shale Gas: Case Study of the Wufeng-Longmaxi Formation in the Dingshan Area of Southeast Sichuan, China

The main geological factors controlling the accumulation and yield of marine-facies shale gas reservoirs are the focus of the current shale gas exploration and development research.In this study,the Wufeng-Longmaxi Formation in the Dingshan area of southeast Sichuan was investigated.Shale cores underwent laboratory testing,which included the evaluation of total organic carbon(TOC),vitrinite reflectance(Ro),whole-rock X-ray diffraction(XRD),pore permeability,and imaging through field emission scanning electron microscopy(FE-SEM).Based on the results of natural gamma ray spectrum logging,conventional logging,imaging logging,and seismic coherence properties,the exploration and development potential of shale gas in the Dingshan area have been discussed comprehensively.The results showed that(1)layer No.4(WF2-LM4)of the Wufeng-Longmaxi Formation has a Th/U ratio<2 and a Th/K ratio of 3.5–12.Graptolites and pyrite are relatively abundant in the shale core,indicating sub-high-energy and low-energy marine-facies anoxic reducing environments.(2)The organic matter is mainly I-type kerogen with a small amount of II1-type kerogen.There is a good correlation among TOC,Ro,gas content,and brittle minerals;the fracturing property(brittleness)is 57.3%.Organic and inorganic pores are moderately developed.A higher pressure coefficient is correlated with the increase in porosity and the decrease in permeability.(3)The DY1 well of the shale gas reservoir was affected by natural defects and important latestage double destructive effects,and it is poorly preserved.The DY2 well is located far from the Qiyueshan Fault.Large faults are absent,and upward fractures in the Longmaxi Formation are poorly developed.The well is affected by low tectonic deformation intensity,and it is well preserved.(4)The Dingshan area is located at the junction of the two sedimentary centers of Jiaoshiba and Changning.The thickness of the high-quality shale interval(WF2-LM4)is relatively small,which may be an important reason for the unstable production of shale gas thus far.Based on the systematic analysis of the geological factors controlling high-yield shale gas enrichment in the Dingshan area,and the comparative analysis with the surrounding typical exploration areas,the geological understanding of marine shale gas enrichment in southern China has been improved.Therefore,this study can provide a useful reference for shale gas exploration and further development.

Energy-limiting factor for coal and gas outburst occurrence in intact coal seam

This research reviewed the mechanics and gas desorption properties of intact coal,and tested the crushing work ratios of different intact coals,and then,studied the stress conditions for the failure or crushing of intact coal and the gas demand for the pulverization of intact coal particles.When a real-life outburst case is examined,the required minimum stress for intact coal outburst is estimated.The study concludes that the crushing work ratios of three intact coal samples vary from 294.3732 to 945.8048 J/m^(2).For the real-life case,more than 2300 MJ of transport work is needed,and 10062.09,7046.57 and 5895.47 m^(3) of gas is required when the gas pressure is 1,2 and 3 MPa,respectively.The crushing work exceeds the transport work and even reaches 13.96 times of the transport work.How to provide such an enormous crushing work is an energy-limiting factor for the outburst in intact coal.The strain energy is needed for the crushing work,and the required minimum stress is over 54.35 MPa,even reaching 300.44 MPa.These minimum stresses far exceed the in-situ vertical and horizontal stresses that can be provided at the 300–700 m mining depth range.

Effectiveness analysis of methane-drainage by deep-hole controlled pre-splitting blasting for preventing coal and gas outburst

In the study of the application effectiveness of deep-hole controlled pre-splittingblasting technology,it was found through laboratory micro test and field study on a mine insouth China that under the technology,coal masses produce many irreversible cracks.Afterblasting,the nearer the distance from blasting hole,the larger the BET surface areaand volume ratio of the infiltration pore are;they increased by 11.47%and 5.73%,respectively.The coefficient of air permeability is increased 4 times.After 3 months,the gasdrainage rate was increased by 66%.In the first 15 days,the cumulative pumped gas was1.93 times of blasting before.The average absolute gas emission decreased by 63.46%.Experimental results show that deep-hole controlled pre-splitting blasting not only preventscoal and gas outburst,but also gives good economic results.

Natural Gas Types,Distribution Controlling Factors,and Future Exploration in the Western Qaidam Basin

The Paleogene and Neogene oil and gas in the western Qaidam basin have a regular distribution in three concentric zones from the edge to the center of the basin. Natural gas mainly occurs in the inner zone, and the gas-oil ratio of the northern area of the basin is significantly higher than that of the southern area. Large amounts of carbon isotope data of natural gas, plotted in X- shaped and comprehensive identification diagrams for the southern area and northern area, respectively, were used to identify the types of natural gas. The large-scale distribution of natural gas is highly consistent with the Ro values of major source rocks, but is poorly correlated with the type of organic matter. This indicates that the main controlling factor of natural gas distribution is organic matter maturity, and the kerogen types act as the basis for the formation of different types of natural gas. Paleouplifts and squeezed anticlines near hydrocarbon generation depression centers, which are major natural gas-rich regions, control the migration directions of natural gas, while hydrocarbon migration pathways and fault systems connecting gas sources are the most important factors for natural gas reservoir formation in the inner basin. Therefore, favorable zones for natural gas distribution can be predicted on the basis of the distribution of thermal evolution and the gas generation intensity of major source rocks as well as the structural map. The Shizigou-Youshashan- Yingdong-Dawusi, Youquanzi -Kaitemilike - Youdunzi, and Xiaoliangshan - Nanyishan - Dafengshan structural belts are favorable zones for natural gas accumulation. This study has important theoretical and practical significance for future natural gas exploration.

Controlling factors of marine shale gas differential enrichment in southern China

Based on the exploration and development practice of marine shale gas in Fuling, Weiyuan, Changning, Luzhou and Southeast Chongqing in southern China, combined with experiments and analysis, six factors controlling differential enrichment of marine shale gas are summarized as follows:(1) The more appropriate thermal evolution and the higher the abundance of organic matter, the higher the adsorption and total gas content of shale will be.(2) Kerogen pyrolysis and liquid hydrocarbon cracking provide most of the marine shale gas.(3) The specific surface area and pore volume of organic matter rich shale increased first and then decreased with the increase of thermal evolution degree of organic shale. At Ro between 2.23% and 3.33%, the shale reservoirs are mainly oil-wet, which is conducive to the enrichment of shale gas.(4) The thicker the roof and floor, the higher the shale gas content. The longer the last tectonic uplift time and the greater the uplift amplitude, the greater the loss of shale gas will be.(5) The buried depth and dip angle of the stratum have different controlling and coupling effects on shale gas in different tectonic positions, resulting in two differential enrichment models of shale gas.(6) The effective and comprehensive matching of source, reservoir and preservation conditions determines the quality of shale gas accumulation. Good match of effective gas generating amount and time, moderate pore evolution and good preservation conditions in space and time is essential for the enrichment of shale gas.

Differences and controlling factors of composite hydrocarbon accumulations in the Tazhong uplift, Tarim Basin, NW China

Based on three-dimensional seismic interpretation, structural and sedimentary feature analysis, and examination of fluid properties and production dynamics, the regularity and main controlling factors of hydrocarbon accumulation in the Tazhong uplift, Tarim Basin are investigated. The results show that the oil and gas in the Tazhong uplift has the characteristics of complex accumulation mainly controlled by faults, and more than 80% of the oil and gas reserves are enriched along fault zones. There are large thrust and strike-slip faults in the Tazhong uplift, and the coupling relationship between the formation and evolution of the faults and accumulation determine the difference in complex oil and gas accumulations. The active scale and stage of faults determine the fullness of the traps and the balance of the phase, that is, the blocking of the transport system, the insufficient filling of oil and gas, and the unsteady state of fluid accumulation are dependent on the faults. The multi-period tectonic sedimentary evolution controls the differences of trap conditions in the fault zones, and the multi-phase hydrocarbon migration and accumulation causes the differences of fluid distribution in the fault zones. The theory of differential oil and gas accumulation controlled by fault is the key to the overall evaluation, three-dimensional development and discovery of new reserves in the Tazhong uplift.

Study on comprehensive gas control techniques and practice in coal mines

The origins and main control methods of gas in coal seams were introduced cursorily, and the processes that need to be done in controlling gas, which includes prediction of gas emissions, drainage systems, the means of prevention of gas outbursts, and some suggestions were put forward. The characteristic of different gas emissions and the corresponding counter measures were presented, and ＆ case study of simultaneous extraction of coal and gas in Xieyi Coal Mine was carried out by coal mining and gas extraction without coal-pillar. The field application shows that gas drainage ratio in panel 5121（0） averages about 90% and reaches as high as 95~/0, which will give beneficial references to gas control in coal mines.

RESEARCH ON DEEP COAL SEAM MINING FLOOR STARTA WATER BURSTING INFLUENCED FACTORS BASED ON ANALYTIC HIERACHY PROCESS

Deep coal seam mining floor strata water bursting is a complicate nonlinear system, whose factors are coupling and influencing themselves. It built the analytic structure model for deep coal seam mining floor strata water bursting, the judgment matrix was found by the expert scoring method, the contribution weights of the influenced factors were given out by the equation analytic process. The thirteen controlling factors and five main controlling factors were put award by analyzing weights, so the result was basically conform to the field practice. The expert scoring method and analytic process can convert the objective fact to the subjective cognition, so it is a method that can turn the qualitative into the quantitative. This can be relative objectively and precisely to study the question of many factors and grey box.

大宁—吉县区块深部煤层气富集主控因素分析及地质工程甜点区评价

精准评价和合理优选煤层气地质工程甜点区是翔实制定勘探开发一体化方案的基础。本文聚焦大宁—吉县区块深部石炭系本溪组8^(#)煤层,充分利用研究区煤心描述、分析化验、测录井、地震及开发动态等资料,通过研究区深部8^(#)煤层的各种资料系统整理和深入剖析,从煤层顶底板岩性、厚度、构造、沉积环境及煤岩特征等方面,系统探讨了深部煤层气富集的主控因素,并建立了地质工程甜点区评价标准,进而划分了研究区的地质工程甜点区。研究结果表明,煤层气富集主要受顶底板岩性、构造及煤岩特征等影响,沉积环境对煤层气富集的影响多体现在顶底板岩性组合及封闭性等特征上;研究区评价出地质一类、工程一类有利区411.5 km^(2),资源量1 038.75×10^(8) m^(3);地质二类、工程一类有利区596.2 km^(2),资源量1 192.4×10^(8) m^(3);地质二类、工程二类有利区287.4 km^(2),资源量574.5×10^(8) m^(3)。

鄂尔多斯盆地上古生界煤系烃源岩三环萜烷成因探讨

【目的】鄂尔多斯盆地煤系烃源岩发育,其饱和烃中三环萜烷含量丰富,但其三环萜烷分布模式在研究区表现出较大的差异性,因此探讨其差异性的主控因素具有重要意义。【方法】利用气相色谱和色谱—质谱分析技术,对鄂尔多斯盆地上古生界26个煤系烃源岩样品饱和烃进行了详细地剖析。【结果】根据三环萜烷(TT)的分布特征将研究区烃源岩样品划分为三种不同类型的分布模式。Ⅰ类烃源岩以C_(19)TT为主峰,C_(19)TT、C_(20)TT、C_(21)TT含量逐渐减小的变化趋势,同时该类样品中Pr/Ph比值高,介于1.19~3.84,平均值为2.99、C_(24)四环萜烷含量也较丰富,C_(24)四环萜烷/C_(26)TT比值介于2.39~32.54,平均值为9.80、C_(28)三环萜烷和C_(29)三环萜烷缺失,这类样品主要是腐殖煤和炭质泥岩,揭示出湖沼相沉积环境之特征;与之相反的Ⅱ类烃源岩的三环萜烷以C_(23)TT为主峰,C_(19)TT、C_(20)TT、C_(21)TT含量是逐渐增大的,而Pr/Ph比值低,比值主要介于0.34~0.90,平均值为0.61、C_(24)四环萜烷含量不丰富,C_(24)四环萜烷/C_(26)TT比值主要介于0.42~0.77,平均值为0.54、C_(28)三环萜烷和C_(29)三环萜烷含量丰富,这类样品除了煤系泥岩之外还有腐殖煤和炭质泥岩,其沉积环境与Ⅰ类烃源岩迥然不同;Ⅲ类烃源岩的三环萜烷分布介于Ⅰ类和Ⅱ类烃源岩之间,一方面三环萜烷的主峰碳为C_(23)TT,另一方面C_(19)TT、C_(20)TT、C_(21)TT相对含量又依次降低并呈阶梯状分布的特征,此外Pr/Ph比值为2.07、C_(24)四环萜烷/C_(26)TT比值为3.53,两者均介于Ⅰ类烃源岩和Ⅱ类烃源岩之间。【结论】随着烃源岩热演化程度的增加,三环萜烷的总量展示了逐渐增大的变化趋势,但不同类型烃源岩的三环萜烷分布模式并没有发生明显变化,说明研究区煤系烃源岩三环萜烷的不同分布模式受有机质热演化程度影响较小,而主要受控于沉积环境和母质类型。

古城矿区富油煤赋存特征及主控因素分析

以前期煤田勘查成果为基础,选取4^(#)、8^(#)和9^(-1#)煤为研究对象,通过原煤焦油产率分级划分,研究了各煤层的富油煤赋存特征;从镜惰比(V/I)、H/C原子比、挥发分产率及灰成分指数等方面,探讨了富油煤的时空分布规律及主控因素。结果表明:各煤层焦油产率主要分布在9.02%~11.43%;平面上,4^(#)、8^(#)煤多为富油煤,高油煤零星分布;9^(-1#)煤以富油煤为主,局部分布高油煤;垂向上,自上而下煤层焦油产率呈增大趋势。煤层焦油产率与挥发分产率、氢元素含量均呈正相关,与灰分产率负相关,与灰成分中CaO含量呈弱正相关。煤层镜质体反射率为0.723%~0.733%,变质程度中等,生油潜力较大,含腐泥型母质为生油提供了物质基础,温暖、潮湿的气候环境和较深覆水或闭塞条件下的还原环境有利于富油煤形成。

南华北盆地鹿邑凹陷上古生界煤系地层砂岩储层特征

鹿邑凹陷上古生界煤系砂岩储层特征认识不清,制约该区天然气藏相关研究和勘探部署。本文综合运用岩心观察、薄片鉴定、扫描电镜、压汞和声发射试验等分析方法查明砂岩储层特征,并阐释储层发育影响因素。结果表明,砂岩储层岩性以细-中粒、细粒岩屑石英砂岩为主,成岩作用类型多样,压实和胶结作用对储层破坏明显,溶解及破裂作用对储层贡献较大。储层属超低孔、超低渗的致密储层,储集空间类型以溶孔、晶间微孔、裂缝、少量剩余原生孔和铸模孔组合为主。孔隙结构分为3类,Ⅰ类的孔隙结构和物性最好,但发育规模小;Ⅱ类和Ⅲ类的发育规模大,但孔隙结构和物性差。储层发育受多种因素影响,构造背景决定其长期处于中-深埋藏环境;沉积微相控制其发育位置;压实作用导致储层原始孔隙度降低22.01%;多期次矿物胶结使储层更加致密化;含有机酸流体是促使不稳定组分溶解形成次生孔隙的主要因素;破裂作用极大程度地改善储层渗透性,但发育局限。该认识对煤系地层非常规天然气藏的研究具有促进作用,也可为鹿邑凹陷相关勘探工作的部署提供基础参考。

陕西煤矿冲击地压发生规律与分类防治

随着煤炭资源开采区域不断向西部以及深部转移,西部地区冲击地压矿井数量呈井喷式增长。陕西省作为煤炭大省,煤炭开发供应规模稳居全国前列,但冲击地压灾害尤为突出,为了有效遏制本地区煤矿冲击地压频繁发生势头,并为类似条件矿区冲击地压防治提供借鉴,通过分析陕西煤矿10年来的24座矿井、85起冲击地压案例,基本厘清了冲击地压发生规律,并开展了基于主控因素的分类防治研究。研究结果表明:陕西省煤矿冲击地压具有灾害矿井集中、灾害程度严重、多灾害叠加影响显著、防治难度大等特点;冲击地压监测技术、防治技术与地方法规建设历程几乎同步,达到了起步晚,起点高,示范效应强的结果;基于冲击地压主控因素,将陕西省冲击地压划分为3大类,分别为:坚硬顶板主导型、地质构造主导型和宽煤柱主导型,并针对主控因素提出弱化坚硬顶板、转移煤柱高集中应力、释放构造应力的防治方法。通过10年来的工程实践,不断优化矿井开采设计,探索煤层厚硬顶板千米顺层钻孔区域压裂新技术,加大防冲卸压技术的落实,冲击地压显现逐年减少,成果显著。

吐哈盆地大南湖矿区富油煤赋存特征及主控因素分析

为揭示吐哈盆地大南湖矿区富油煤的赋存特征及主控因素,选取大南湖矿区3号、7号和25号煤层为研究对象,通过分析煤岩煤质和焦油产率特征,对大南湖矿区富油煤赋存特征进行研究;结合显微煤岩组分、H/C原子比、镜惰比、灰成分等方面,研究影响大南湖矿区富油煤赋存的主要因素。研究结果表明,大南湖矿区3号、7号和25号煤层以镜质组为主,总体属中水分、特低灰低灰分、高挥发分煤;各煤层富油煤资源均在矿区边缘零星分布。煤焦油产率与镜质组、壳质组、氢元素含量、H/C原子比、灰成分指数呈正相关,与惰质组含量呈负相关。在潮湿、覆水的还原环境以及较低的煤化程度条件下,越有利于富油煤的形成和赋存。

珠江口盆地惠北地区煤系烃源岩新认识与勘探实践

珠江口盆地恩平组煤系烃源岩因分布主控因素认识不清、发育规模不明确,导致勘探潜力被忽视。以煤系烃源岩发育区惠北地区作为研究靶区,利用地震、钻井和地化等资料,系统分析了煤系烃源岩分布主控因素,据此确定煤系烃源岩发育规模和资源潜力,从而有效指导勘探。研究表明:①纵向上,从恩四段到恩一二段沉积期,惠北地区古气候温暖湿润,古水深逐渐变浅,古构造活动强度逐渐减弱,恩一二段和恩三段有利于煤层的发育和聚集,恩四段沉积期煤层不发育;②横向上,受古沉积条件的控制,煤系烃源岩主要分布于惠州14洼北部缓坡带辫状河三角洲河道间的河漫沼泽和洼陷带滨浅湖内的湖沼范围内。基于煤系烃源岩分布规律,预测惠北地区煤系烃源岩资源量约2亿方油当量,带动了惠北地区周边勘探,也展示了珠江口盆地煤系烃源岩勘探前景。

煤层气井煤粉产出规律特征及主控因素研究

针对沁水盆地柿庄南区块煤层气井产粉严重的问题,连续采集20口煤层气井煤粉溶液样品,在实验室测试获取了煤粉浓度、煤粉粒径、煤粉形态和主要成分等煤粉产出特征。通过系统研究煤粉产出特征的影响因素,发现煤粉浓度和煤体结构的相关系数R^(2)为0.707,具有较强的相关性;水平井的煤粉浓度平均值为2.85g/L,定向井的煤粉浓度平均值为0.36g/L,相差了8倍;煤体结构是煤粉产出的主控地质因素,井型是主控工程因素。研究成果为柿庄南区块煤层气产粉规律研究和控粉措施提供了实验数据和理论指导。

建新煤矿4^(-2)煤层瓦斯赋存规律及瓦斯富集区域判定

为了获得建新煤矿4^(-2)煤层的瓦斯赋存规律以及主控因素,从煤岩层特征以及煤层瓦斯含量入手,讨论地质构造、顶底板岩性、煤层厚度、煤层埋深及煤层底板标高各种因素对瓦斯含量的影响,明晰建新煤矿4^(-2)煤层瓦斯赋存的主控因素。研究结果显示,建新煤矿4^(-2)煤层的瓦斯含量与煤层厚度呈线性正相关,煤层的厚度直接影响着瓦斯含量的大小,煤层越厚,其瓦斯含量越大;煤层瓦斯含量与埋深呈正相关,随埋深的增加而逐渐增加;瓦斯含量与底板标高呈负相关关系。基于对建新煤矿4304工作面瓦斯含量的现场实测及分析,绘制瓦斯赋存规律等值线图,得到工作面瓦斯富集区。