A generalized multi-field coupling approach and its application to stability and deformation control of a high slope

Human activities, such as blasting excavation, bolting, grouting and impounding of reservoirs, will lead to disturbances to rock masses and variations in their structural features and material properties. These engineering disturbances are important factors that would alter the natural evolutionary processes or change the multi-field interactions in the rock masses from their initial equilibrium states. The concept of generalized multi-field couplings was proposed by placing particular emphasis on the role of engineering disturbances in traditional multi-field couplings in rock masses. A mathematical model was then developed, in which the effects of engineering disturbances on the coupling-processes were described with changes in boundary conditions and evolutions in thermo-hydro-mechanical （THM） properties of the rocks. A parameter, d, which is similar to damage variables but has a broader physical meaning, was conceptually introduced to represent the degree of engineering disturbances and the couplings among the material properties. The effects of blasting excavation, bolting and grouting in rock engineering were illustrated with various field observations or theoretical results, on which the degree of disturbances and the variations in elastic moduli and permeabilities were particularly focused. The influences of excavation and groundwater drainage on the seepage flow and stability of the slopes were demonstrated with numerical simulations. The proposed approach was further employed to investigate the coupled hydro-mechanical responses of a high rock slope to excavation, bolting and impounding of the reservoir in the dam left abutment of Jinping I hydropower station. The impacts of engineering disturbances on the deformation and stability of the slope during construction and operation were demonstrated.

MULTI-FIELD COUPLING BEHAVIOR OF SIMPLY-SUPPORTED CONDUCTIVE PLATE UNDER THE CONDITION OF A TRANSVERSE STRONG IMPULSIVE MAGNETIC FIELD

In order to study the multi-field coupling mechanical behavior of the simply-supported conductive rectangular thin plate under the condition of an externally lateral strong impulsive magnetic field, that is the dynamic buckling phenomenon of the thin plates in the effect of the magnetic volume forces produced by the interaction between the eddy current and the magnetic fields, a FEM analysis program is developed to characterize the phenomena of magnetoelastic buckling and instability of the plates. The critical values of magnetic field for the three different initial vibrating modes are obtained, with a detailed discussion made on the effects of the lengththickness ratio a/h of the plate and the length-width ratio a/b as well as the impulse parameter on the critical value BOcr of the applied magnetic field.

Mechanism of hybrid-magnetic-circuit multi-couple motor

Discusses the interval between laminations in a permanent magnet inductor motor which makes the air gap magnetic field produced by the permanent magnet very uneven in the axial direction, and limits the performance of a motor. Proposes a hybrid magnetic circuit multi couple motor to compensate for the uneven air gap magnetic field, thereby improving the performance of a motor.

ANALYSES ON NONLINEAR COUPLING OF MAGNETO-THERMO-ELASTICITY OF FERROMAGNETIC THIN SHELL—I:GENERALIZED VARIATIONAL THEORETICAL MODELING

Based on the generalized variational principle of magneto-thermo-elasticity of the ferromagnetic elastic medium, a nonlinear coupling theoretical modeling for a ferromagnetic thin shell is developed. All governing equations and boundary conditions for the ferromagnetic shell are obtained from the variational manipulations on the magnetic scalar potential, temperature and the elastic displacement related to the total energy functional. The multi-field couplings and geometrical nonlinearity of the ferromagnetic thin shell are taken into account in the modeling. The general modeling can be further deduced to existing models of the magneto-elasticity and the thermo-elasticity of a ferromagnetic shell and magneto-thermo-elasticity of a ferromagnetic plate, which are coincident with the ones in literature.

煤矿矿井水水质形成及演化的水动力场-水化学场-微生物场耦合作用与数值模拟

煤矿矿井水的水质形成与演化过程机理复杂,受水动力场、水化学场和微生物场等多场作用影响显著。深入研究并揭示煤矿矿井水水质形成机理与演化趋势、阐明采空区封闭后矿井水的多场耦合作用机制是矿井水污染防控与修复的理论基础。以鄂尔多斯盆地某煤矿采空区为水文地质原型,在前期研究的基础上,进一步建立了煤矿采空区积水水位回升、蓄满后水动力-水化学-微生物场(HCB)多场耦合室内相似模拟和数值模型。采空区水动力场研究结果表明基质-裂隙双孔隙模型能有效模拟采空区水位回升过程,模拟误差为9.9%,其模拟精度远高于理论预测和单孔隙模型。水化学场模拟结果与试验较为吻合,SO_(4)^(2-)、HCO_(3)-和p H模拟相对误差分别为3.0%、21.0%和6.2%,模拟结果较为可靠。模拟结果显示采空区蓄水过程中水岩反应和微生物作用不明显;而蓄满后水动力几乎停滞,但水化学场和微生物场较为活跃,2号煤和3号煤层中黄铁矿的氧化反应使得SO_(4)^(2-)质量浓度提升约24.6%;后期采空区水环境演化为弱酸性、厌氧还原条件,微生物降解作用凸显,将SO_(4)^(2-)有一定的“自净”能力。通过调整微生物代谢速率常数,可将SO_(4)^(2-)降解比例提高到61.6%。实际工程场景中可通过补充碳源、人工建立密闭厌氧环境等强化手段实现这一目标。将多场耦合室内试验和数值模拟技术拓展到煤矿采空区积水水质形成与演化规律研究,研究结论可为煤矿区矿井水污染防治提供指导。

电爆炸金属桥箔早期过程中电磁-热-力多物理场耦合建模与分析

金属桥箔的电爆炸过程对电炮、冲击片雷管等的性能影响极为关键。这一过程中物质性质变化、几何构型和动力学过程非常复杂,早期的大量理论模拟工作均采用极为简化的物理模型。为此,建立了描述爆炸箔早期行为的三维电磁-热-固体力学耦合求解全物理模型,模拟爆炸箔在大电流加载下的早期受热膨胀过程,并对早期膨胀过程中桥箔上的磁场、电流、温度等演化进行分析,观察到电流在构型和电阻率两种因素影响下的角扩散和线扩散现象,模拟得到的桥区温度场分布与参考文献中的实验图像及模拟结果定性符合。

浏览器/服务器架构场地土-水系统中有机污染物多场耦合模拟与可视化系统

场地土壤—地下水系统(土—水系统)中有机污染驱动机制复杂,污染物时空分布的预测与可视化是科学、规范开展土水污染绿色低碳修复管控的前提。基于WebGIS地理信息系统基础平台,嵌入有机污染“多相流场—温度场—化学场”多场耦合模拟与Cesium可视化技术,自主开发浏览器/服务器(Browser/Server,B/S)架构的场地土—水系统有机污染物时空分布模拟与可视化系统。本系统可应用于场地土—水系统中有机污染调查与监测数据的集成管理、有机污染物时空分布图形化建模和多场耦合污染过程的场景可视化表达,与场地污染物实测数据相比,系统模拟误差小于30%,可为场地进一步开展有机污染风险评估、精准防控和综合管理提供信息化平台。

球状风化花岗岩类土质边坡土-岩界面优势流潜蚀特性研究

受降雨作用,球状风化花岗岩类土质边坡的土-岩差异风化界面极易演化为优势渗流通道而发生渗流潜蚀,进而加速该类边坡的变形失稳,然而当前有关其渗流潜蚀作用特征、细颗粒迁移规律等的研究仍鲜见开展。基于多孔介质非饱和渗流理论,综合考虑细颗粒运移、潜蚀启动响应与非饱和渗流的耦合关系,提出一种可准确描述土-岩界面渗流潜蚀过程的数值计算框架。采用有限元方法,构建优势流作用下非饱和花岗岩残积土的渗流潜蚀模型,并以均质土柱的渗流潜蚀过程为参考,系统研究3种典型土-岩界面埋藏状态下的优势流潜蚀特性。结果表明:球状风化花岗岩类土质边坡的土-岩界面与基质渗透性存在高度差异性,湿润锋形成向下凹陷的渗透漏斗,且随着降雨的持续,湿润锋的凹陷程度愈发明显;细颗粒流失程度与土-岩界面的埋藏状态相关,其中下填土体工况的优势流潜蚀最为显著,其界面处甚至出现超孔隙水压力,最不利于该类边坡的稳定性。研究成果可为降雨条件下球状风化花岗岩类土质边坡稳定性的准确评价提供科学依据。

弯管内外表面腐蚀缺陷力学-电化学相互作用规律研究

为进一步研究弯管内外表面腐蚀缺陷力学-电化学(M-E)相互作用规律,建立基于多物理场耦合的弯管内外表面含腐蚀缺陷的三维模型,研究内压和缺陷几何形状对M-E相互作用规律及对弯管的影响。研究结果表明:当弯管内外表面存在腐蚀缺陷时,弯管内侧的M-E效应更强,增加应力和腐蚀的增长速率,使内侧更容易发生失效;当缺陷几何增长时,应力在缺陷长度和宽度方向上增长,腐蚀主要在缺陷长度方向上增长;外表面缺陷附近的应力和腐蚀增长规律基本一致,而内表面缺陷附近的应力增长较腐蚀增长更为复杂。研究结果可为含腐蚀缺陷弯管评估模型的完善以及管道系统完整性的管理提供理论参考。

The Large Sky Area Multi-Object Fiber Spectroscopic Telescope (LAMOST)

The Large Sky Area Multi-Object Fiber Spectroscopic Telescope (LAMOST, also called the Guo Shou Jing Telescope) is a special reflecting Schmidt telescope. LAMOST’s special design allows both a large aperture (effective aperture of 3.6 m–4.9 m) and a wide field of view (FOV) (5°). It has an innovative active reflecting Schmidt configuration which continuously changes the mirror’s surface that adjusts during the observation process and combines thin deformable mirror active optics with segmented active optics. Its primary mirror (6.67m×6.05 m) and active Schmidt mirror (5.74m×4.40 m) are both segmented, and composed of 37 and 24 hexagonal sub-mirrors respectively. By using a parallel controllable fiber positioning technique, the focal surface of 1.75 m in diameter can accommodate 4000 optical fibers. Also, LAMOST has 16 spectrographs with 32 CCD cameras. LAMOST will be the telescope with the highest rate of spectral acquisition. As a national large scientific project, the LAMOST project was formally proposed in 1996, and approved by the Chinese government in 1997. The construction started in 2001, was completed in 2008 and passed the official acceptance in June 2009. The LAMOST pilot survey was started in October 2011 and the spectroscopic survey will launch in September 2012. Up to now, LAMOST has released more than 480 000 spectra of objects. LAMOST will make an important contribution to the study of the large-scale structure of the Universe, structure and evolution of the Galaxy, and cross-identification of multiwaveband properties in celestial objects.

力-热场耦合无氟碱酸法石墨提纯试验研究

为了提升碱酸法制备高纯石墨品位,降低环境污染,本试验以萝北石墨浮选精矿为原料,研究了力-热场耦合无氟碱酸法对石墨的提纯效果。结果表明,在NaOH用量为250 kg/t,碱熔温度为750℃,碱融时间为60 min,HCl用量为300 kg/t,酸浸温度为85℃,酸浸时间为4 h的条件下,进行两段超声:第1段为360 W超声强度,80℃温度下洗涤30 min(碱熔后);第2段为180 W超声强度,70℃温度下洗涤20 min(酸浸后),最终制备出的高纯石墨固定碳含量高达99.973%,Si含量为101μg/g,Al含量为31μg/g,Fe含量为29μg/g。

基于磁-流-热耦合的高速开关阀动态特性

为确保高速开关阀动态特性满足其工作性能要求,建立了高速开关阀磁-流-热多场耦合模型,综合考虑电磁驱动力和负载力进行阀开关过程的瞬态计算,并对阀芯位移特性、流场特性进行了系统的仿真研究。通过高速开关阀空载位移试验对建立的多场耦合模型进行了验证,同时开展了高速开关阀在极端温度下的动态特性试验。试验结果表明,建立的多场耦合模型能够较为准确地描述高速开关阀工作过程中的动态变化,为其特性分析提供了研究方法;高速开关阀在2种极端油液温度条件下响应速度较室温略慢。

COMSOL Multiphysics在锂离子电池中的应用

作为一种具有前景的能量存储系统,锂离子电池需要进一步提高能量密度、功率密度、可靠性和循环稳定性,以满足不断增长的大型能源存储、电动汽车和便携式电子设备需求。当前对锂离子电池的实验研究仍然面临多个挑战,这些挑战包括电解液的导电性和安全性、高能量负极的沉积-剥离机制的优化、高能量正极的循环电压和容量维持、高电流条件下的界面极化和容量释放,以及在极端电流-温度-针刺条件下的热失控管理等问题。这些问题涉及到电-化-力-热等多个场的耦合作用,需要进行协同优化处理。COMSOL Multiphysics提供了一种可行的工具,通过求解多物理场耦合的连续方程,能够同时考虑载流子浓度、电流密度、电-化学势、温度、应力/应变和几何形态等综合信息的演化。本文概述了该工具在锂离子电池的电解液、负极和正极设计等方面的研究,并聚焦于多场耦合对电池性能的综合影响、多场耦合模拟方法以及理论模拟与实验表征的结合。最后,本文对理论与实验联合研究中的多场和多尺度问题进行了展望。

基于毛细芯热管的换流变阀侧套管电-热-流场优化研究

换流变压器阀侧套管在运行期间内部发热严重,电场分布极不均匀,在高温与复合电压作用下,又进一步导致电场畸变。鉴于热管良好的散热与均温性能,将套管与毛细芯热管相结合,提出换流变压器阀侧套管热管散热技术。搭建了热管套管的多物理场仿真模型,分析了电容芯体的轴向、径向温度与电场分布,进一步改变毛细芯孔隙率大小、热管填充工质种类与套管故障类型,研究孔隙率与工质对热管传热性能的影响以及套管故障情况下热管的有效性。仿真结果表明,引入热管后,套管内径向温度与电场最大值分别降低了41.06%、30.12%,轴向温度与电场分布更加平均。当热管工质为去离子水,孔隙率为0.75时热管的传热性能最好。即便套管发生过热故障,热管仍可降低热点温度,减小电场畸变。

基于流-固-损伤全耦合模型的裂隙型岩溶突涌水数值模拟

岩溶地区隧道建设频遇突涌水灾害,裂隙型突涌水勘察与预测难度极大、致灾风险高。为揭示裂隙型岩溶突涌水机理与明确前兆信息,基于流-固-损伤耦合模型对裂隙型岩溶突涌水致灾机理与临界条件展开研究。通过公式推演与多场耦合数值分析得到以下结论:建立了完整的流-固-损伤耦合裂隙型岩溶突涌水致灾机理数学模型,并论证其可行性与合理性;分析了不同溶腔水压工况下,隧道拱顶围岩位移演化规律。结果表明,裂隙型岩溶突涌水与富水溶腔水压高度相关;分析了临界突水条件下围岩特性,提出了缓慢增长段-快速增长段-位移失控段的三阶段裂隙型岩溶突涌水围岩位移演化规律。

400 kW永磁同步电机磁-流-热耦合特性分析

为准确分析大功率永磁同步电机运行时的温升特性,对400 kW,9 000 r/min的大功率永磁同步电机进行磁-流-热多物理场耦合分析。首先,对电机进行结构设计,分析其空载及负载的运行特性。其次,将损耗作为热源加载到温度场中,采用流热耦合,计算冷却流道中的冷却液对电机温度的影响。最后,考虑电机材料的温度特性对热性能的影响,提出双向耦合的方法,将电机磁场损耗实际分布加载到温度场中,再将绕组和永磁体温度变化情况反代至电磁场,通过有限元方法实现电机磁-流-热多物理场耦合。结果表明,双向耦合方法下,绕组的温升比单向耦合高6.27%,永磁体温升增加2.27%,提高了该类电机损耗和温升计算精度。

电-热-流多物理场耦合作用下脐带缆温度场及载流量计算研究

脐带缆被誉为连接水下生产系统和上部设施的“神经生命线”,准确分析其温度场分布和载流量是安全开展海洋油气勘探和开采任务的关键保障。不同于传统海缆,脐带缆因结构复杂、功能多样,在位运行时存在复杂的电-热-流多物理场耦合效应,传统解析法难以确定其温度场分布和载流量。本文基于有限元软件Comsol建立脐带缆电-热-流多物理场耦合截面精细模型,通过控制变量法研究3种典型敷设方式、环境等因素对导体温度和稳态载流量的影响。结果表明:当电流较小时,影响脐带缆截面温度和稳态载流量的主导因素是管中液体温度;导体温度的变化趋势能够反映稳态载流量的变化情况;直埋时,埋设深度与外界流体温度的增加皆会削弱脐带缆的散热能力;平铺时,海水流动会明显降低脐带缆温度,在低流速下,流速增加对脐带缆的降温效果十分显著,但高流速的海水会在紧贴脐带缆的表面形成具有温度梯度的边界层,使热量的传递受到限制,降温效果反而不明显;绝缘老化对脐带缆整体温度分布的影响较小,但会影响截面最高温度。

1×××/7×××系铝合金液-固铸轧复合模拟研究

结合双辊立式铸轧机设备和技术参数,通过流-固耦合的方法进行了变参数正交模拟研究,揭示了1×××系铝液浇铸温度和铸轧速度对铸轧复合区内温度场、流场的影响。研究结果表明,最优铸轧参数区间为浇铸温度670~690℃、铸轧速度12~13 m/min。浇铸温度越高、铸轧速度越快越容易发生漏液,反之容易发生轧卡。

镍电沉积界面层流/气泡-形核生长模拟研究

为探明镍电沉积过程中电沉积基体/电沉积液界面低流速层流场内电沉积副反应产生的气泡演变规律、Ni^(2+)浓度场变化和镍晶体形核及生长特点,建立了电场、低流速层流场、浓度场、气泡/沉积液/镍晶体多相场的气泡/层流-镍晶体形核生长模型,并利用有限元方法计算该模型。结果表明,当形核前的气泡从镍基体脱附到浓度扩散层边界时,在气泡脱附位置周围气泡迎流区和背流区的基体表面镍以瞬时形核方式形核,当离开Ni^(2+)浓度扩散层后,其产生的低Ni^(2+)浓度区与层流对流和Ni^(2+)扩散作用使镍晶体沿Ni^(2+)流动最大方向择优生长,在气泡迎流区的枝晶高度最高。与此不同,形核后的气泡从镍基体脱附到浓度扩散层边界时,气泡产生的涡流只能使已经形核的晶体不均匀生长;当离开Ni^(2+)浓度扩散层后,随后镍晶体以枝晶形式生长,沿Ni^(2+)流动最大方向枝晶的生长速度最快。

电磁-结构场耦合下变压器绕组漏磁场和变形仿真研究

电力变压器发生短路故障时会产生巨大的电动力,为研究电力变压器短路故障时的绕组变形情况以及影响绕组变形的因素,文中基于变压器多物理场耦合理论,搭建了三相变压器的有限元模型,通过MATLAB/Simulink平台仿真变压器发生短路时的短路电流,将该电流作为电磁场仿真的激励,计算出绕组的漏磁场和电动力分布,再采用电磁-结构场耦合的方法分析绕组的形变量大小和应力分布;运用相关理论分析不同温度条件对绕组变形的影响。结果表明,在辐向上,高压绕组受到向外膨胀的辐向电动力,中压和低压绕组受到向中间压缩的辐向电动力,在轴向上,各绕组均受到从端部向中间压缩的电动力,温度越高,绕组铜的杨氏模量越小,相同电动力作用下绕组变形量越大。研究结果对提高变压器抗短路能力具有一定的参考意义。