PDC钻头综合受力模型的试验研究

模拟钻头上的切削齿的不同的切削断面形状、重叠切削状态及磨损状态,利用PDC切削齿对多种岩样进行了切削试验,研究了切削面积、接触弧长、切削齿后倾角、岩石抗钻强度、切削齿磨损高度等因素对PDC切削齿受力的影响规律。结果表明,切削面积相同情况下切削齿受力随接触弧长、岩石可钻性极值、切削齿磨损高度分别呈线性,幂函数和指数函数趋势变化;切削齿受力最小的后倾角在5～10°区间内。引入弧长系数、磨损高度系数,建立了PDC切削齿综合受力模型。根据力的平衡原理,推导得出完整的PDC钻头受力计算模型,为PDC钻头优化设计和合理使用提供了理论依据。     

锥形聚晶金刚石复合片齿破岩特征与机制研究

锥形聚晶金刚石复合片(polycrystalline diamond compact,PDC)齿是一种具有较强抗冲击性和耐磨性的新型PDC齿,在坚硬、强研磨性和软硬交错地层中取得了非常好的钻井提速效果。为了揭示锥形齿破碎硬岩机制,开展锥形齿破碎花岗岩试验与数值模拟研究,分析了切削深度和前倾角对锥形齿切削力和破岩比能的影响规律,采用高速摄像机和透明K9玻璃观测了锥形齿作用下岩屑形成过程及微裂纹萌生与扩展过程,通过数值模拟分析了破岩过程中岩石应力响应与损伤演化特性,结合对切削槽和大尺寸块体岩屑表面形貌及断口微观特征分析,建立了锥形齿破碎花岗岩机制模型。结果表明,锥形齿破碎花岗岩的过程可以分为挤压成核和块体崩裂两个阶段,前倾角对岩石破碎过程影响较小,切削深度的影响显著;锥形齿周围的裂纹主要由压实核、纵向裂纹和横向裂纹组成,纵向裂纹和横向裂纹扩展的最大深度分别为切削深度的6.69倍和4.53倍;齿尖周围压应力集中,岩石发生压剪破坏,压应力区外围形成弧形条带状拉应力区,并在齿尖及压应力区边界处诱导出拉伸微裂纹;微裂纹向齿前扩展形成弧形拉伸主裂纹,发生块体岩屑崩裂,提高破岩效率,向岩石内部扩展劣化...     

复合片钻头钻进时机械钻速和碎岩功耗的研究

关于复合片钻头钻进大理岩和花岗岩时机械钻速和碎岩功率消耗同规程参数的关系,用实验设计方法进行了试验研究,得出了机械钻速和碎岩功耗与钻压、钻头转速及冲洗液量关系的数学模型;提出了碎岩绝对功耗和相对功耗的概念,而相对碎岩功耗是个更为重要的概念,求出了大理岩相对碎岩功耗最小时的最优钻进规程参数值。     

新型锥形PDC齿犁削破岩理论研究

目前关于锥形PDC齿的研究主要集中于数值模拟、现场及室内试验,而关于其切削力学特性的理论分析未见相关报道。通过数值模拟阐述了锥形PDC齿拉伸剪切破岩机理,以及切削载荷分布特性;根据能量平衡原理,推导了锥形PDC齿切削载荷理论公式。结果表明,相比于常规PDC齿,锥形PDC齿破岩过程更加稳定,其切削载荷受岩石性质、齿的形状参数、切削深度以及切削角度的影响,且切削载荷随着锥顶半径、切削角度以及吃入岩石深度的增加而增加。研究成果可为锥形PDC齿及钻头的设计提供理论支撑。      

关于复合片钻头钻进工艺的试验研究

用试验设计方法研究了复合片钻头钻进时机械钻速、碎岩功耗、钻头磨损与规程参数的关系,求出了它们的最优值以及与其相应的钻进规程最优值。     

Numerical Studies on Chip Formation in Drag-Pick Cutting of Rocks

A two dimensional non-linear finite element simulation model has been developed using a mathematical model for progressive rock failure for understanding the mode and sequence of rock failure under a drag pick cutter. Rock cutting simulation has also been done using linear elastic modeling using local stability factor contouring. It has been observed from the simulation results that during negative rake angle cutting the chipping occurs by shear failure of the elements. Whereas, in positive rake angle cutting, some elements were observed to fail in shear and some under tension. The predicted peak cutting force using the developed models was found to be up to 25% higher than the experimental values. The effect of input parameters such as rake angle, flank wear, depth of cut and rock properties on the predicted peak cutting force has been studied, verified from earlier experimental studies and compared with some earlier proposed theories on rock cutting. The elastic stress analysis model based on the stability factor contouring method has also been found to be an effective tool to bracket the expected peak cutting force for a given operational and rock parameters but failed to simulate the effect of pick geometry (rake angle) correctly. The non-linear simulation model using progressive rock element failure is superior to elastic linear stress analysis model by simulating the correct trends for all the rock and machining parameters.     

复合片钻头钻进规程参数的试验研究

操作规程是决定一种钻进方法成功与否的三大因素之一。本文通过对两种具有代表性的中硬岩石（细砂岩和石灰岩）进行实尺寸钻进试验,探讨和揭示了新型钻岩工具复合片钻头（Polycrystalline-diamond-compact bits）钻进工艺规程与各项参数的相互关系和变化规律,从碎岩比功的角度为合理选择工艺规程提供了依据。     

基于Drucker-Prager准则的扩孔器单齿正交切削岩土三维力学模型

扩孔器是定向穿越扩孔钻进阶段进行岩土切削的主要工具,合理的结构设计是提高扩孔时效、降低工程复杂问题出现几率的主要手段,且由于扩孔阶段是决定定向穿越工程工期的最主要阶段,因此,对扩孔器切削齿的切削效率进行深入研究是非常必要的。从单齿正交切削岩土的机制入手,综合考虑岩土与切削齿面之间的接触摩擦及岩土剪切区的剪切作用,分析了单齿正交切削岩土的力学特征,基于能够考虑中间主应力对岩土破坏影响的Drucker-Prager强度准则,推导了单齿正交切削岩土的主切削力与主切削力矩计算公式;在利用有限元计算程序对所推导公式进行验证的基础上,优选了剪切角计算模型,获得了不同岩土材料时的主切削力解析解,并分析了不同齿前角对主切削力的影响规律,从而获得单齿正交切削岩土的最优齿前角,为进一步研究扩孔器整体结构设计并针对不同岩土介质设计出适应性更强的扩孔器结构奠定基础。     

组构对自然休止角影响的试验研究

利用自制的模型试验装置,通过在不同方位沉积散体颗粒生成堆积体,研究不同沉积组构特征对自然休止角的影响,以及通过在母堆积体底部设置漏孔以生成子堆积体,研究堆积体内部结构对自然休止角的影响。研究发现,母堆积体休止角? 和子堆积体休止角? 随着沉积面倾角? 的增大（0° → 90°）呈现先减小后增大的趋势,子堆积体休止角? 则先增大后减小,且最小和最大值的分布区间正好互余,分别为? = 30°～45°和? = 45°～60°。当漏孔位置从左至右靠近母堆坡脚时,? 先增大后减小,? 则单调增大。基于模型的分析和推导,发现当沉积面与潜在滑动面越接近平行,休止角越小,越偏离,休止角则越大,并从细观上合理解释了?、? 和? 在特殊角度区间出现最大或最小值的原因。最后,提出了散粒堆积体的扰动分区模型,并以此为基础阐释了漏孔位置（堆积体内部结构）对休止角? 和? 的影响机制。     

Grain boundary energy as a clue to mineral segregations — A preliminary study

Dihedral angles between two grains of quartz and one of pyrrhotite, sphalerite resp. hematite are measured at triple junctions. An approach to equilibrium is noted. The sulphides have dihedral angles greater than 120 ° and the oxide less than 120 °. No significant influence of sphalerite composition on dihedral angle can be proved. It is concluded that the average grain boundary energy between two grains of quartz is smaller than that between quartz and a sulphide but greater than that between quartz and hematite. Sulphide — biotite interfaces are found to be parallel to the biotite cleavage. Parallelism is concluded to meet a requirement of minimum grain boundary energy. Assuming random distribution of grains, the interfacial area between sulphides and transparent minerals is found to be too small in comparison with that between sulphides. The sulphide clustering, observed and inferred, is suggested to depend on a combination of grain boundary energy and epitaxial growth, but may to some extent be inherited from the ore-generation stage.