全尺寸隔水管在复杂应力状态下的力学特性试验研究

为对隔水管在复杂应力状态下的力学特性进行试验研究,研制了能够模拟高液压环境下管柱力学行为的特殊试验装置——深水管柱力学模拟试验系统,并借助该系统对全尺寸隔水管在受内外压条件下进行了力学特性模拟试验。结果表明:试验系统运行良好,能够有效地按照要求进行加载、卸载。试验中通过对隔水管试件进行内外压加载,同时对系统两端的轴向活塞加压,消除了由于内外压产生的轴向力,实现了在内外压条件下的隔水管力学特性模拟试验。通过在管柱外壁粘贴电阻应变片,得到了其真实径向应变与环向应变随内外压变化的关系曲线,并通过分析计算得到了试件的真实应力状态。由于隔水管加工制造等方面的误差,真实的应变数据、应力状态与理论推导结果并不重合。为了提高深水作业的安全性与经济性,可以借用试验结果对理论推导值进行修正,也说明了用试验方法进行隔水管力学特性研究的重要性。该试验系统为深水作业管柱等的模拟试验提供了一个良好的平台,能够有效降低深水钻采作业的风险,提高深水钻采作业的经济性与安全性,具有较高的推广应用价值。     

Micro‐Raman study of exfoliated Bi2Sr2CaCu2O8+δ single crystals with different thicknesses

Exfoliated Bi₂Sr₂CaCu₂O_8+δ (Bi‐2212) single crystals were prepared by micromechanical cleavage of bulk Bi‐2212 single crystals on SiO₂/Si substrates. Room temperature micro‐Raman spectra were collected using a 532‐nm laser source. The evolutions of the spectra of A_1g (Bi), A_1g (Sr), and A_1g (O_Bi) Raman modes with different thicknesses of the samples were studied. The refractive index of Bi‐2212 single crystal was obtained by studying the intensity evolutions based on the interference effect. The observed wavenumber shifts of the A_1g (Bi), A_1g (Sr), and A_1g (O_Bi) modes were analyzed. Copyright © 2011 John Wiley & Sons, Ltd.     

Mechanical systems in the quantum regime

Mechanical systems are ideal candidates for studying quantum behavior of macroscopic objects. To this end, a mechanical resonator has to be cooled to its ground state and its position has to be measured with great accuracy. Currently, various routes to reach these goals are being explored. In this review, we discuss different techniques for sensitive position detection and we give an overview of the cooling techniques that are being employed. The latter includes sideband cooling and active feedback cooling. The basic concepts that are important when measuring on mechanical systems with high accuracy and/or at very low temperatures, such as thermal and quantum noise, linear response theory, and backaction, are explained. From this, the quantum limit on linear position detection is obtained and the sensitivities that have been achieved in recent opto- and nanoelectromechanical experiments are compared to this limit. The mechanical resonators that are used in the experiments range from meter-sized gravitational wave detectors to nanomechanical systems that can only be read out using mesoscopic devices such as single-electron transistors or superconducting quantum interference devices. A special class of nanomechanical systems is bottom-up fabricated carbon-based devices, which have very high frequencies and yet a large zero-point motion, making them ideal for reaching the quantum regime. The mechanics of some of the different mechanical systems at the nanoscale is studied. We conclude this review with an outlook of how state-of-the-art mechanical resonators can be improved to study quantum mechanics.     

In situ three‐dimensional reciprocal‐space mapping during mechanical deformation

Mechanical deformation of a SiGe island epitaxically grown on Si(001) was studied by a specially adapted atomic force microscope and nanofocused X‐ray diffraction. The deformation was monitored during in situ mechanical loading by recording three‐dimensional reciprocal‐space maps around a selected Bragg peak. Scanning the energy of the incident beam instead of rocking the sample allowed the safe and reliable measurement of the reciprocal‐space maps without removal of the mechanical load. The crystal truncation rods originating from the island side facets rotate to steeper angles with increasing mechanical load. Simulations of the displacement field and the intensity distribution, based on the finite‐element method, reveal that the change in orientation of the side facets of about 25° corresponds to an applied pressure of 2–3 GPa on the island top plane.     

Uniform Approximation of Entire Functions of Slow Growth on Compact Sets

In the present paper, we study the polynomial approximation of entire functions of several complex variables. The characterizations of generalized order and generalized type of entire functions of slow growth are obtained in terms of approximation and interpolation errors.     

基于Copula理论的装甲车辆齿轮传动箱系统的可靠性分析

应用Copula函数研究了某型装甲车辆齿轮传动箱的系统可靠性问题,得出了系统的可靠度函数和失效率,并与独立性下的可靠度函数进行比较,通过分析两种方法下可靠度的变化趋势,得出基于Copula函数的可靠度函数更接近于实际情况.     

对小麦发育后期茎秆抗倒性问题的研究

针对小麦发育后期茎秆抗倒伏性问题,首先运用了数理统计与分析的相关知识,建立了各品种小麦的抗倒伏指数模型并对其进行了求解;其次,通过建立相关性系数模型并结合SPSS软件分析研究了抗倒伏指数与茎秆外部形态特征之间的关系;然后,建立了以抗倒伏能力最强和经济系数最大为目标的双目标优化模型来确定不同单穗重小麦的理想株型结构;最后,建立了基于力学分析的小麦茎秆抗倒伏性能的综合评价模型与抗倒伏风速模型.     

小麦发育后期茎秆抗倒伏问题研究

围绕小麦抗倒伏问题,综合运用数据预处理、相关性分析、数据拟合、数理方程、微分方程等方法,根据已有的抗倒伏模型,进行了模型修正,运用修正的模型,计算了六种小麦的倒伏指数,计算结果与试验结论基本吻合,并从生活常识的角度对模型的合理性进行论证,在对小麦茎秆性状相关性分析中,讨论了小麦最优性状特征,得出不同穗重下的最优株型结构,在考虑麦穗自重的前提下,进行力矩分析,运用最小势能原理进行理论推导,建立茎秆抗倒伏数理方程模型,并从数值计算和图形分析两个方面对模型的合理性进行了论证.     

应用于高速转子系统的金属橡胶阻尼环动力特性分析

针对金属橡胶构件的非线性特性及结构不同时弹性阻尼力学性能不同的特点, 利用实验和理论相结合的方法建立了金属橡胶构件迟滞回线边界变形过程力学模型, 推导了不同相对密度金属橡胶构件非线性迟滞恢复力表达式. 分析了简谐激励载荷作用下金属橡胶阻尼环动力学特性, 对该阻尼环进行了实验研究, 研究了存在预变形情况下阻尼环的弹性阻尼性能, 实验和理论分析结果基本一致, 为该种阻尼环的实际应用奠定了理论基础. 关键词： 金属橡胶构件 力学模型 非线性迟滞恢复力     

第一性原理研究bct-C4碳材料的强度性质

本文采用第一性原理方法,分析了bct-C4碳材料的力学性质,尤其是抗压强度性质,并在研究中分析了在压缩过程中bct-C4碳的 键长随压缩应变的变化规律.计算结果表明, bct-C4碳材料不仅具有优秀的弹性性质和硬度性质,也具有优秀的强度特性, 其沿[100]晶向的抗压强度高于金刚石6.9%.本文的工作表明, bct-C4碳是一种高强度的碳同素异形体, 可以用于压缩包括金刚石在内的各种物质,并可用于研究物质在高压下的结构变化以及力、电学等性质. 同时,作为一范例,本文研究同样可以为寻找力学性质超越金刚石的物质提供参照.