Analysis of impact pressure,rock-breaking effect,and ground vibration induced by the disposable CO_(2)fracturing tube

The technology of expansion fracturing with liquid CO_(2)(EFLCO_(2))has attracted increasing attention due to reduced vibration and damage.The disposable fracturing tube has been developed and is gradually replacing the Cardox tube.However,there is a lack of impact pressure testing of disposable tubes under real working conditions,selection of gas explosion design parameters,and systematic analysis of blasting vibration.This limitation has constrained the widespread application of disposable fracturing tubes in engineering.A joint monitoring of the pressure-time curves in the disposable tubes and boreholes was conducted.The rock-breaking effect of varying hole spacing parameters in the EFLCO_(2)design was analyzed,and a systematic study was carried out on the vibration peak value,frequency,and energy characteristics.The results show that(1)the pressure distribution characteristics,stress peak value,and duration in the disposable tubes are different from those of Cardox tubes,which show multi-peak distribution,low-pressure peak value,and short duration.The correlation between the pressure in the disposable tube,filling pressure,and liquid CO_(2)weight is established,and a theoretical calculation method for the borehole wall pressure is proposed;(2)The hole spacing in rocks of different hardness is suggested;and(3)At the same scale distance,the peak particle velocity(PPV)caused by EFLCO_(2)(PPVCO_(2))is significantly smaller than that caused by blasting(PPVexplosive).The ratio of PPVexplosive to PPVCO_(2)is a power function related to scale distance,and a distance-related zonality exist in this relationship.The frequency composition of the vibration signal caused by EFLCO_(2)is relatively simple with a narrow frequency band.Its PPV and energy are mainly concentrated in the low-frequency band.This research contributes to the optimization of disposable fracturing tubes,gas explosion design,and vibration hazard control.

Investigation of the Vibration Behavior of Fluidelastic Instability in Closely Packed Square Tube Arrays

Flow-induced vibrations in heat exchanger tubes have led to numerous accidents and economic losses in the past. Fluidelastic instability is the most critical flow-induced vibration mechanism in heat exchangers. Both experimental and computational studies conducted to determine fluidelastic instability were presented in this paper. In the experiment, a water channel was built, and a closely packed normal square tube array with a pitch-to-diameter ratio of 1.28 was tested, and significant fluidelastic instability was observed. A numerical model adopting large-eddy simulation and moving mesh was established using ANSYS CFX, and results showed good agreement with the experimental findings. The vibration behaviors of fluidelastic instability were discussed, and results showed that the dominant vibration direction of the tubes changed from streamwise to transverse beyond a critical velocity. A 180° phase lag between adjacent tubes was observed in both the experiment and simulations. Normal and rotated square array cases with pitch-to-diameter ratios of 1.28 and 1.5 were also simulated. The results of this study provide better insights into the vibration characteristics of a square tube array and will help improve the fundamental research and safety design of heat exchangers.

Linear and nonlinear torsional free vibration of functionally graded micro/nano-tubes based on modified couple stress theory

The linear and nonlinear torsional free vibration analyses of functionMly graded micro/nuno-tubes （FGMTs） are analytically investigated based on the couple stress theory. The employed non-classical continuum theory contains one material length scale parameter, which can capture the small scale effect. The FGMT model accounts for the through-radius power-law variation of a two-constituent material. Hamilton＇s principle is used to develop the non-classical nonlinear governing equation. To study the effect of the boundary conditions, two types of end conditions, i.e., fixed-fixed and fixed-free, are considered. The derived boundary value governing equation is of the fourthorder, and is solved by the homotopy analysis method （HAM）. This method is based on the Taylor series with an embedded parameter and is capable of providing very good approximations by means of only a few terms, if the initial guess and the auxiliary linear operator are properly selected. The analytical expressions are developed for the linear and nonlinear natural frequencies, which can be conveniently used to investigate the effects of the dimensionless length scale parameter, the material gradient index, and the vibration amplitude on the natural frequencies of FGMTs.

Vibration Response and Stress Analysis of Planar Elastic Tube Bundle Induced by Fluid Flow

Flow?induced vibration plays a positive role on heat transfer enhancement. Meanwhile, it is also a negative factor for fatigue strength. Satisfying the fatigue strength is the primary prerequisite for heat transfer enhancement. This paper numerically studied the flow?induced vibration of planar elastic tube bundle based on a two?way fluid–structure interaction(FSI) calculation. The numerical calculation involved the unsteady, three?dimensional incompressible governing equations solved with finite volume approach and the dynamic balance equation of planar elastic tube bundle solved with finite element method combined with dynamic mesh scheme. The numerical approach was verified by comparing with the published experimental results. Then the vibration trajectory, deformation and stress contour of planar elastic tube bundle were all studied. Results show that the combined movement of planar elastic tube bundle represents the agitation from inside to outside. The vibration of out?of?plane is the main vibration form with the typically sinusoidal behavior because the magnitude of displacement along the out?of?plane direction is the 100 times than the value of in?plane direction. The dangerous point locates in the innermost tube where the equivalent stress can be utilized to study the multiaxial fatigue of planar elastic tube bundle due to the alternating stress concentration. In the velocity range of 0.2-3 m/s, it is inferred that the vibration amplitude plays a role on the stress response and the stress amplitude is susceptible to the fluid velocity. This research paves a way for studying the fatigue strength of planar elastic tube bundle by flow?induced vibration.

水声材料声振特性的驻波管测量方法

提出了一种基于驻波管的测量方法,以获得水声材料在静水压条件下的声学和振动特性参数。设计了带有气压补偿功能的低频发射换能器,作为驻波管的声源,通过水柱将换能器的平面活塞振动耦合到水面下的被测样品。在被测样品背衬上安装加速度计,测量样品背面振速;同时在管壁中嵌入一对水听器,测量水柱声压。导出样品声波入射面的振速和声压,进而计算出样品前表面和背衬面之间的振速传递系数(去耦系数)、样品的输入阻抗和声压反射系数。建立低频驻波管测试系统,声管尺寸为内径300 mm、外径600 mm、高3 m,工作频率范围100~1000 Hz,利用水层样品和多层穿孔橡胶样品开展了实验研究。实验结果显示,测量数据与仿真计算数据吻合较好,验证了测量方法的有效性。

管束结构的阻尼控制型流弹失稳特性研究

尽管自2012年SONGS事故以来,流弹失稳对管束结构的危害性和重要性再次引起了重点关注,但对导致这种不稳定现象的根本因素仍未确定。为进一步研究流弹失稳的基本物理机制,以压水堆蒸汽发生器通常采用的平行三角形管束为对象,基于开源CFD(computational fluid dynamics)工具OpenFOAM,同时耦合管的动力学方程,求解具有移动边界的非定常Navier-Stokes(uRANS)方程,建立了研究阻尼控制型不稳定机制的数值模型,进而预测管束的流固耦合振动,揭示影响阻尼控制型不稳定机制的关键参数和流动响应;重点讨论了不同质量阻尼参数下,系统的响应特性、能量输入与耗散,升力与位移间的相干性、相位差、相关系数,升力的频谱特性,主导激励机理。进一步揭示了管束流弹系统中占主导地位的激励机理和关键流动现象,有助于理解管束与流体之间的相互作用机理,同时为工程中使用开源CFD工具OpenFOAM预测流弹失稳行为提供了参考。

考虑“筒中筒”耦合作用的深水隔水管柱与钻柱碰摩运动规律

深水钻井时,旋转钻柱与海洋环境力作用下发生振动的隔水管柱易发生接触,造成钻柱与隔水管柱的碰撞或者摩擦。为了解隔水管柱与钻柱间的运动状态,减轻两者间碰摩,保证作业安全性,提出了一种模拟深水隔水管柱-钻柱组成的“筒中筒”耦合系统模型,通过分析二者间的位移与接触力,实现海洋深水钻井作业时隔水管柱与钻柱的耦合动力学模拟的建立。模拟结果表明,考虑隔水管柱与钻柱接触的情况下,海流作用和涡激作用对钻柱的动力学特征具有较大影响;海流速度增加,隔水管柱弯曲程度变大,隔水管柱的振动特征会限制钻柱运动;井口转速增加对钻柱的涡动特征影响小,但会增大钻柱与隔水管柱内壁的接触力,增大钻柱与隔水管柱的失效风险。该理论为海洋深水钻井摩阻分析提供了新的借鉴。

超声振动辅助磨削CFRP复合材料薄管撕裂损伤研究

针对碳纤维增强复合材料(CFRP)薄管超声振动辅助磨削过程中存在撕裂损伤且形成原因不明确的问题,通过对M55J和T300复合材料薄管开展超声振动辅助磨削试验,探究了超声振幅、进给量及主轴转速对磨削力和撕裂尺寸的影响规律,通过对磨削过程的受力分析和对最大未变形切屑厚度的计算,分析了撕裂位置的形成原因和撕裂尺寸的变化规律。结果表明:磨削力随超声振幅的增大而减小,随进给量的增大而增大,与主轴转速的关联性较小;撕裂易出现于CFRP薄管内壁,其长度与高度随超声振幅的增大而减小,随进给量的增大而增大,随主轴转速的增大而减小。

海上移动平台直升机甲板圆管支撑结构安全评估

圆管支撑结构是海上移动式平台直升机甲板设计的重要部分,由于海上恶劣的风浪环境,使结构整体受风载荷的影响较大.现有直升机甲板圆管支撑结构的安全评估内容主要集中于圆管的静强度分析,缺乏风振响应分析,文中以海洋石油163平台直升机甲板为例,研究圆管支撑结构的静力和动力载荷输入,通过有限元强度分析和理论经验公式计算对比静力、风载荷作用下直升机甲板圆管支撑结构的受力情况,考虑风振涡激效应的准静态分析,在此基础上提出了直升机甲板圆管支撑结构的安全评估方法,探究了风载荷对结构整体安全的影响.

基于神经网络的输电塔钢管构件涡激振动幅值预测方法

输电塔中长细比较大的钢管构件容易发生低风速下的涡激振动,鉴于传统风洞试验和数值模拟研究方法存在的成本高、周期长的局限,该文提出了一种基于神经网络的输电塔钢管构件涡激振动幅值高效预测方法。为获取训练模型所需的数据集,发展了适用于任意插板形式、几何尺寸的钢管构件涡激振动响应分析方法;结合多种神经网络模型(BPNN、PSO-BPNN、RBFNN、GRNN)以及性能评价指标,建立了基于神经网络的输电塔钢管构件涡激振动幅值预测方法;通过算例对某C型插板和十字型插板钢管构件涡激振动幅值进行了预测。研究表明:通过与试验结果的对比,验证了该文输电塔钢管构件涡激振动响应分析方法的准确性,对于C型和十字型插板钢管构件VIV幅值的相对误差分别为3.84%和5.87%,利用该方法可为神经网络模型提供可靠样本;通过7折10次交叉验证优化超参数后的4种神经网络模型,均表现出较好的预测精度;相比之下,GRNN在C型插板和十字型插板钢管构件算例中均呈现出最佳的泛化能力,其R2值分别为0.989和0.992;采用GRNN方法可以较好地预测C型和十字型插板钢管构件在不同质量阻尼比参数下的VIV幅值,且在计算效率上相比于CFD方法具有明显的优势。

加装螺旋导流板的双层铜管换热器传热性能分析

为提高螺旋铜管(SCT)换热器的综合传热性能,通过在换热器内加装螺旋形导流板,采用双向流固耦合计算方法,分析了不同入口流速和导流板安装位置下对换热器内部双层SCT的振动和传热性能的影响。数值结果表明:双层SCT换热器外层SCT的振动强度明显高于内层;无振动时内层SCT的传热系数高于外层,有振动时外层SCT的传热系数高于内层;随着入口流速增加,内外层SCT的振幅均增大,传热系数提高;导流板的安装位置会直接影响SCT的振动和传热特性,且在SCT呈现最大振动强度和最佳传热性能时的安装位置并不相同;对比振动强化传热参数Q PEC和综合传热性能因子R JF发现,双层SCT换热器的Q PEC和R JF均高于单层,两螺旋导流板分别安装在换热器的左、下位置时,Q PEC最大,安装在换热器的左、上位置时,R JF最大且比安装在左、下位置时最高增大了7.99%。该研究可为高性能SCT换热器的设计提供理论和数据支撑。

振动作用下平直翅片管结霜初期微液滴运动过程数值模拟

平直翅片管换热器在低温高湿环境中工作极易发生结霜现象,造成能耗增加、故障率升高,而对结霜初期的微液滴施加振动作用可以加速微液滴的滑落过程从而达到抑制结霜的效果。对结霜前期微液滴的生长过程进行数值模拟分析,并通过文献值验证了数值模拟的可靠性,然后利用不同时刻的微液滴数据,通过数值模拟的方式,研究不同振动频率作用下微液滴的运动特性,最后搭建试验平台进行验证。研究结果发现,不同体积的微液滴对应的最优振动频率有所不同,当微液滴体积较小时,较高的振动频率使微液滴在基管壁面来回振荡,不易滑落,当微液滴体积较大时,较高的振动频率有利于微液滴克服壁面摩擦力,有利于液滴滑落。

工件振动辅助管电极电解加工方孔仿真与试验研究

为解决管电极电解加工方孔过程中因流场分布不均造成加工质量差等问题,提出一种工件振动辅助管电极电解加工方孔的方法。流场仿真结果表明,工件振动辅助电解加工能够在加工间隙内不同位置产生明显的脉动流场,改善加工间隙内的电解液流动状态,有效消除传统电解加工方孔中加工间隙内存在的“死水”区,从而有利于电解产物的排出,提升电解加工的稳定性。同时开展试验研究,结果表明,采用工件振动辅助管电极电解加工可以提升方孔加工的轮廓精度和表面质量,并且采用脉冲电流可以进一步提升方孔的加工质量。最终采用振幅0.04 mm、振频20Hz、脉冲占空比80%、脉冲频率5000 Hz、进给速度1.5 mm/min,加工出平均宽度1.218 mm、宽度标准偏差0.026 mm、侧壁表面粗糙度0.703μm的方孔。

射孔管柱动力学特性研究

射孔管柱受射孔弹爆炸冲击载荷易发生变形甚至断裂,保障管柱承载安全性是射孔作业的关键,现有射孔管柱力学分析模型简化条件过多,计算精度有待提高。以射孔爆轰载荷计算方法为基础,根据欧拉-伯努利空间梁理论和间隙元理论,利用有限元方法建立了射孔管柱三维冲击动力学模型,并利用Generalized-α法对模型进行了求解,以实测数据对模型精度进行了验证。以现场实际作业数据为基础,对射孔管柱的动力学特性和安全性进行了分析评估。结果表明,射孔爆轰载荷会使射孔管柱发生剧烈的纵向、横向振动;射孔弹装药量越高对射孔管柱的冲击作用越强烈,油管的振动幅度越大;增加射孔管柱长度可以减小管柱应力;油管壁厚对管柱的动力学行为和安全性能有较大影响。

悬浮隧道管体运动对锚索涡激振动的影响

根据锚索式悬浮隧道的运动特性,将锚索假设为两端铰接的非线性梁模型,在海流作用下,锚索会产生顺流向与横流向的涡激振动。当海流方向和管体轴向存在夹角时,管体运动可简化为作用在锚索上部端点的质点运动,并将质点运动沿锚索坐标系方向逐一分解。根据Hamilton原理建立锚索三向振动方程,并通过Galerkin方法和Runge-Kutta方法对该方程进行求解,选取典型悬浮隧道的结构进行数值分析。结果表明:当锚索上部端点的输入频率与锚索固有频率的比值为整数时,锚索会发生共振现象;如上部端点除锚索轴向方向外的某一方向质点运动与锚索振动方向一致,则锚索在该方向上的振动会出现显著变化,而对另一方向振动的影响较小;在多数情况下,锚索振动平衡位置的偏离与上部端点所输入的运动频率有紧密联系,但与幅值联系不大。

垂直井内上击器解卡过程中钻柱振动数学模型的建立与求解及动态解卡力分析

对于油气井内解卡过程中的钻柱振动情况及动态解卡力,目前还没有有效的分析方法。该研究建立了垂直井内上击器解卡过程中考虑钻井流体阻尼的钻柱振动数学模型,并进行了求解,分析了几个主要因素对动态解卡力的影响。首先,介绍了上击器解卡过程中钻柱振动的三个阶段:(1)拉伸储能阶段,对钻柱进行静力学分析;(2)泄压阶段,结合拉伸储能阶段的计算结果,通过特征函数展开法与拉普拉斯变换求解了泄压阶段的钻柱振动数学模型;(3)撞击阶段,引入了将钻柱-钻柱轴向撞击的强非线性问题转化为多段钻柱振动的线性问题的求解思路,通过紧差分方法对撞击阶段的钻柱振动数学模型进行求解,获得了钻柱中的弹性波传播规律以及动态解卡力。其次,建立了与三个阶段相应的数学模型并求解。然后,采用该模型计算了无阻尼情况下的荷载场与动态解卡力,经低通滤波处理后的计算结果与相应条件下的解析解以及ABAQUS软件所得结果均有较好的吻合,验证了该工况下解法的准确性。最后,分析了震击启动拉力、上击器位置、钻井流体黏度、以及芯轴有效距离对动态解卡力的影响。所得结论对使用震击解卡的作业过程具有一定的指导意义。

碳纤维圆管增强超弹多孔结构振动特性研究

随着船舶工业技术的快速发展,对动力系统隔振装置提出了更加苛刻的要求,现有的橡胶阻尼材料虽然具备良好的减振效果,但仍然存在着质量大、力学承载性能和吸能性能不足等问题,针对上述背景,将橡胶阻尼材料与力学性能优异的碳纤维圆管相结合设计出了一种兼具轻质、抗冲、隔振的碳纤维圆管增强超弹多孔结构,并在前期的研究中已验证了该结构具有优异的抗冲吸能表现。在此基础上,通过试验结合数值表征的方法研究了该结构的振动行为和减振性能,揭示碳纤维圆管对结构固有振动特性和减振性能的影响规律。结果发现,相比无增强结构,填充碳纤维圆管的超弹多孔结构可在增强结构整体刚度的同时实现减振性能的显著提升;试验结果验证了所建立结构数值模型的可靠性,对比不同增强结构的仿真与试验发现随着碳纤维圆管厚度的增加,结构固有频率呈现先增大后减小的趋势;研究结果可为设计新型轻质高刚度高阻尼结构提供参考。

用于高温管道的二重动力吸振器设计及力学性能试验

针对传统减振支撑难以解决核电机组中小支管的无规则振动问题,设计了一种基于金属橡胶材料的环形二重三向动力吸振器,其中质量块总质量为0.084 kg,矩形弹簧和金属橡胶固定在质量块与工装夹具之间。首先,构建二重动力吸振器动力学模型。其次,利用质量感应法确定小支管的等效质量,并结合定点理论优化吸振器刚度、阻尼比。最后,对小支管二重动力吸振器系统进行谐响应仿真分析。仿真结果表明:二重动力吸振器对X、Y、Z 3个方向的吸振效果均大于95%。分别对有无安装二重动力吸振器的小支管进行激振试验,正弦激励幅值为5 N,频率为0~150 Hz。数据表明,二重动力吸振器对于小支管主要振动方向Y、Z吸振效果达到95%以上,X方向的吸振效率达到75%以上。

空间脉冲管制冷机自适应主动减振控制技术

采用自适应主动减振控制器驱动制冷机压缩机,通过自适应窄带滤波控制算法使脉冲管制冷机50 Hz微振动力由0.21 N减为0.05 N,100 Hz微振动力由0.26 N减为0.04 N,150 Hz微振动力由0.9 N减为0.04 N,200 Hz微振动力由0.97 N减为0.02 N,250 Hz微振动力由0.69 N减为0.0 6 N。测试结果表明自适应主动减振控制对压缩机轴向前五阶具有明显的减振效果。

旋流条件下螺旋弹性铜管振动强化传热性能分析

为了充分利用流体诱导螺旋弹性铜管(helical elastic copper tube,HECT)振动增强传热,以获得更高综合传热性能的HECT换热器装置,基于安装正向螺旋引流板的螺旋弹性铜管(helical elastic copper tube-forward spiral baffle,HECT-FSB)换热器和逆向螺旋引流板的螺旋弹性铜管(helical elastic copper tube-reverse spiral baffle,HECT-RSB)换热器,采用双向-流固耦合法,研究了旋流条件下入口流速(U_(in))对HECT振动强化传热性能的影响。研究表明:U_(in)在计算范围内增加,HECT的振幅增大、传热系数提高,HECT换热器的进出口压降增大、PEC(performance evaluation criteria)值减小;HECT-RSB换热器的HECT振幅和传热系数、进出口压降明显高于HECT-FSB换热器。HECT-FSB换热器的PEC值高于HECT-RSB换热器,振动强化传热性能更佳,当U_(in)=0.3 m/s时,PEC值高出了9.00%。HECT-RSB换热器的综合传热性能因子JF值最大,综合传热性能最佳,与已发表文献中的换热器相比,U_(in)在计算范围内综合传热性能因子JF值平均提升了2.7%。该研究可为HECT换热器装置综合性能的提升提供技术支撑。