井简内旋转管柱动力学分析

井筒内细长管柱是石油工程中特有结构,考虑旋转管柱可能在任意井深和井眼圆周方向上与井筒产生随机碰撞接触,建立了旋转管柱动力学模型,并采用动力间隙元和空间梁单元、Newmark法进行动力学分析.经B3-4-P31等井的应用表明,该方法所设计的抽油杆柱能够在井下安全可靠工作,避免了抽油杆柱发生脱断、偏磨事故.     

用于聚合物驱油的抽油杆动力学分析

聚驱井与水驱井相比杆管偏磨更加严重,聚驱井采出液的法向力是加剧偏磨 的重要因素之一. 根据非牛顿流体力学理论,采用上随体Maxwell模型,建立了法向力计算 模型,确定了井筒内法向力的分布规律,并将此法向力施加在抽油杆的瞬态动力学 模型中; 考虑实际边界条件,采用有限元法对聚驱抽油杆进行了分析计算. 并对FU081801 井模拟计算进行验证,模拟结果与作业检测结果吻合较好,证明了该方法的可行性. 通过此 方法可预测出聚驱井杆管的偏磨位置以及聚合物浓度对抽油杆偏磨的影响程度.     

抽油杆和油管材料在油田污水介质中的摩擦磨损性能研究

以油田污水作为润滑介质，利用MG-200型高速高温摩擦磨损试验机考察了45“钢抽油杆同表面喷焊不同厚度耐磨涂层的J55油管配副时的摩擦磨损性能，采用扫描电子显微镜观察了抽油杆试样磨损表面形貌．结果表明，在油管试样表面引入适当厚度的喷焊耐磨涂层可以显著提高摩擦副的耐磨性能，并在一定程度上降低摩擦系数，从而有利于减小抽油杆同油管之间的摩擦力，提高抽油杆和油管的使用寿命；45“钢抽油杆试样同J55油管试样配副时主要发生粘着磨损，而同表面涂覆耐磨涂层的J55油管试样配副时粘着磨损明显减轻；J55油管试样在常温和60℃下的磨损率相近，而45“钢抽油杆试样在60℃下的磨损率稍大，这可能是由于60℃下粘着磨损有所加剧并发生轻微腐蚀磨损所致．当耐磨涂层过厚时，其减摩抗磨作用显著减弱，故应当适当控制油管表面耐磨涂层的厚度，以充分发挥其减摩抗磨作用。     

旋转圆管湍流的大涡模拟数值研究

采用大涡模拟（LES）方法,并结合动力学亚格子尺度应力（SGS）模型,通过数值求解柱坐标系下的滤波Navier-Stokes方程,研究了绕管轴旋转圆管内的湍流流动特性.为验证计算的可靠性,以及动力学SGS模型对于旋转湍流的适用性,将大涡模拟计算所得的结果,与相应的直接模拟（DNS）结果和实验数据进行了对比验证,吻合良好.进一步对旋转圆管湍流的物理机理进行了探讨,研究了湍流特性随旋转速率的变化规律.当旋转速率增加时,湍流流动有层流化的发展趋势.基于湍动能变化的关系,分析了旋转效应对湍流脉动生成的抑制作用.     

井筒内杆管柱双层接触有限元分析及应用

构造双层多向接触间隙元描述细长油管柱与内外杆管柱的随机接触摩擦问 题,与空间梁单元相结合,采用变刚度与等刚度交替方式求解,得出抽油杆柱与油管柱以及 油管柱与套管柱的接触状态、接触位置、摩阻力大小以及抽油杆柱与油管柱在任意井深处的 广义内力、应力和变形. 三口井算例表明,抽油杆柱与油管柱的井口悬重误差低 于10{\%}, 能够为抽油杆和油管柱设计和失效分析提供可靠的计算方法和理论依据.     

一种旋转载体用角速率传感器模型

提出了一种利用旋转载体自身的旋转作为驱动，从而敏感旋转载体横滚或俯仰的角速率传感器模型，并运用陀螺力学理论建立传感器的动力学方程、求得解析解，对传感器进行动力学误差分析。     

抽油杆疲劳裂纹形状比变化规律

采用断裂力学方法研究了抽油杆杆体疲劳裂纹形状比在扩展过程中的变化规律，证明无论初始形状如何，抽油杆杆体疲劳裂纹形状比在扩展过程中趋于同一个稳定数值．通过裂纹扩展实验对直径为15．9mm的抽油杆疲劳裂纹形状比进行了实验测定，发现其裂纹形状比迅速靠近0．78．     

分层有杆抽油系统诊断模型的反问题计算法

建立了分层有杆抽油系统的诊断模型 ,研究了在实心抽油杆与空心抽油杆的界面处空心泵对应力波的影响 ,给出了抽油杆柱不同杆段的波动方程的显示差分格式 ,提出了一种诊断模型的反问题计算法。用此算法可在缺少一个边界条件的情况下求解诊断模型 ,获得抽油系统各个工况下抽油杆柱任意截面的受力状态 ,从而可绘制出分层有杆抽油系统的空心泵示功图和管式泵示功图。将此算法与模式识别技术相结合就可对分层有杆抽油系统的故障进行诊断。     

复合材料柱管撞击分析中的有限元方法

建立了复合材料柱管结构在撞击状态下的有限元分析模型，考虑了撞击大变形引起的几何非线性、撞击接触的非线性、纤维树脂复合材料的各向异性及材料的物理非线性．给出了利用该有限元方法分析玻璃环氧柱管撞击吸能特性，并与试验进行了比较，得到了较好的吻合结果，表明该有限元方法是有效的．此外，还讨论了纤维的铺设角度对复合材料管的吸能性能的影响．     

高速喷流下的柔性旋转火箭发射系统瞬态响应

对于柔性旋转火箭发射系统，考虑高速燃气喷流作用下的系统耦合振动．建立发射系统动力学模型，数值计算发射管流场结构，确定系统瞬态响应和燃气流冲击对火箭发射姿态的影响，更加真实地模拟柔性旋转火箭的发射动力学环境．     

定向井有杆抽油系统动态性能分析方法

由于杆管间库仑摩擦的影响,定向井有杆泵抽油系统动态参数预测模型是一个非线性的偏微分方程,求解复杂。鉴于此,提出了一种新的分析方法。该方法以定向井有杆抽油系统中的抽油杆柱作为研究对象,根据三次样条插值模拟得到的定向井的井眼轨迹,利用静力有限元法计算出了油管对抽油杆柱的支反力,进而得出了杆柱与油管之间的库仑摩擦力;给出了杆柱单元的受力分析;建立了有限元形式的杆柱系统动力学方程并利用状态空间法对其进行了数值求解,获得了悬点示功图。文末给出了两口油井的预测实例,并将预测结果与实测结果进行了对比。对比结果表明本文所提的分析方法是正确和有效的。     

结构力学分析方法在南海水平井钻进预测中的应用

本文探讨了结构力学分析方法-非线性有限元性在预测水平井钻进中的工程应用,在钻探水平井尤其是大位移水平井中,事先较准确地预测出钻柱的钻进扭矩及钻头前进的方向,是取得水平井成功的关键条件之一。利用非线性有限元理论,着重分析了水平井实际钻进中的钻柱大变形非线性及钻柱与井壁的接触非线性问题,并导出了一套非线性有限元钻柱力学模式,在此基础上编制了一套非线性力学计算程序软件,并在海洋石油南海西部石油公司一个钻井平台水平井钻井进行了五口井的实际验证,获得了一些有启迪性的结论。     

高效的三维曲梁单元

三维井眼中延伸数千米的三维细长圆截面钢钻柱应力分析问题是一个复杂的力学问题,通常使用有限元数值分析方法对其进行受力分析。而在进行有限元分析时,现有的圆弧曲粱单元和空间直粱单元在几何上都不能很好地模拟三维曲线形状的钻柱。为了确保计算精度．其单元划分势必不能过大,结果是计算时间长,收敛性差。为了解决这一问题,显然必须构建一种新的较有效的曲梁单元。基于自然坐标系,依据圆截面空间曲粱单元节点有6个自由度——3个线位移和3个角位移,利用包含全部刚体位移模式和常应变的形函数,忽略剪切变形,假设变形后的梁轴线的弯曲曲率改变为线性变化,建立起了保证收敛性的具有12个自由度的有初始曲率和挠率的圆截面空间曲梁的有限元模型。为了证明给出的有限元模型的高效性,分析了几个静态问题,并与现有文献中的解析解或数值结果进行了比较。基于所给出的结果,可望该有限元模型可以作为分析三维空间曲粱结构的有效工具。     

Entropy generation of radial rotation convective channels

The exchange of heat between two fluids is established by radial rotating pipe or a channel. The hotter fluid flows through the pipe, while the cold fluid is ambient air. Total length of pipe is made up of multiple sections of different shape and position in relation to the common axis of rotation. In such heat exchanger the hydraulic and thermal irreversibility of the hotter and colder fluid occur. Therefore, the total entropy generated within the radial rotating pipe consists of the total entropy of hotter and colder fluid, taking into account all the hydraulic and thermal irreversibility of both fluids. Finding a mathematical model of the total generated entropy is based on coupled mathematical expressions that combine hydraulic and thermal effects of both fluids with the complex geometry of the radial rotating pipe. Mathematical model follows the each section of the pipe and establishes the function between the sections, so the total generated entropy is different from section to section of the pipe. In one section of the pipe thermal irreversibility may dominate over the hydraulic irreversibility, while in another section of the pipe the situation may be reverse. In this paper, continuous analytic functions that connect sections of pipe in geometric meaning are associated with functions that describe the thermo-hydraulic effects of hotter and colder fluid. In this way, the total generated entropy of the radial rotating pipe is a continuous analytic function of any complex geometry of the rotating pipe. The above method of establishing a relationship between the continuous function of entropy with the complex geometry of the rotating pipe enables indirect monitoring of unnecessary hydraulic and thermal losses of both fluids. Therefore, continuous analytic functions of generated entropy enable analysis of hydraulic and thermal irreversibility of individual sections of pipe, as well as the possibility of improving the thermal–hydraulic performance of the rotating pipe consisting of n sections. Analytical modeling enabled establishing of a mathematical model of the total generated entropy in a radial rotating pipe, while the generated entropy of models with radial rotating pipe were determined by experimental testing, with comparisons of the achieved results.     

Control of vortex breakdown in a closed cylinder with a small rotating rod

Effective control of vortex breakdown in a cylinder with a rotating lid was achieved with small rotating rods positioned on the stationary lid. After validation with accurate measurements using a novel stereoscopic particle image velocimetry (SPIV) technique, analysis of numerical simulations using a high-order spectral element method has been undertaken. The effect of a finite length rod creates additional source terms of vorticity as the rod rotates. These additional source terms and their spatial locations influence the occurrence of the vortex breakdown.     

井筒内受压杆管后屈曲能量法分析与实验研究

目前不少理论力学教材都涉及刚体平面运动动力学方程的教学内容,但有些教材在叙述上有许多值得商榷之处.对这一重要的基本概念,本文提出作者的思考,供理论力学教学的教师与学过此内容的学生讨论.     

Control of vortex breakdown in a closed cylinder with a rotating lid

The flow within a closed cylinder with a rotating lid is considered as a prototype for fundamental studies of vortex breakdown. Numerical simulations for various parameter values have been carried out to reproduce the known effect of a thin rotating rod positioned along the center axis as well as analyze the influence of local vorticity sources. As expected, the results show that the breakdown bubbles in the steady axisymmetric flow can be affected dramatically, i.e., fully suppressed or significantly enhanced, by rotating the rod. The main contribution of this article is to show that the observed behavior can be explained by the vorticity generated by the rod locally near the rotating lid and near the fixed lid, as analogous behavior is caused by the introduction of local vorticity sources in the flow without a rod. Moreover, we describe the influence on the breakdown bubbles of the vorticity sources by an analytical model. In addition to improving our understanding, this finding should also open the door to other types of flow control devices capable of generating localized vorticity.     

Method of equilibrium differential equation for analysis of strength of large deflection drill string

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Numerical analysis of the developing fluid flow in a circular duct rotating steadily about a parallel axis

A numerical analysis of the flow pattern in the inlet region of a circular pipe rotating steadily about an axis parallel to its own is presented. Both finite cell and finite element methods are used to analyse the problem and they give qualitatively similar results which show that a swirling fluid motion is induced in the pipe inlet region. The analyses show that the direction of swirl is opposite to that of the pipe rotation when viewed along the flow axis and that its magnitude depends on the speed of pipe rotation and throughflow Reynolds number. Neither numerical analysis predicts the marked upturn in friction factor (or pressure drop) which has been observed experimentally. However, a dependence on the pipe inlet boundary conditions is demonstrated.