Application and Analysis of Computer Virtual Simulation Technology in Three-dimensional Animation Production

With the continuous promotion of computer technology, the application system of virtual simulation technology has been further optimized and improved, and has been widely used in various fields of social development, such as urban construction, interior design, industrial simulation and tourism teaching. China's three-dimensional animation production started relatively late, but has achieved good results with the support of related advanced technology in the process of development. Computer virtual simulation technology is an important technical support in the production of three-dimensional animation. In this paper, firstly, the related content of computer virtual simulation technology was introduced. Then, the specific application of this technology in the production of three-dimensional animation was further elaborated, so as to provide some reference for the improvement of the production effect of three-dimensional animation in the future.

Dynamic Reliability Assessment of Heavy Vehicle Crossing a Prototype Bridge Deck by Using Simulation Technology and Health Monitoring Data

Overloads of vehicle may cause damage to bridge structures,and how to assess the safety influence of heavy vehicles crossing the prototype bridge is one of the challenges.In this report,using a large amount of monitored data collected from the structural health monitoring system(SHMS)in service of the prototype bridge,of which the bridge type is large-span continuous rigid frame bridge,and adopting FEM simulation technique,we suggested a dynamic reliability assessment method in the report to assess the safety impact of heavy vehicles on the prototype bridge during operation.In the first place,by using the health monitored strain data,of which the selected monitored data time range is before the opening of traffic,the quasi dynamic reliability around the embedded sensor with no traffic load effects is obtained;then,with FEM technology,the FEM simulation model of one main span of the prototype bridge is built by using ANSYS software and then the dynamic reliability when the heavy vehicles crossing the prototype bridge corresponding to the middle-span web plate is comprehensively analyzed and discussed.At last,assuming that the main beam stress state change is in the stage of approximately linear elasticity under heavy vehicle loads impact,the authors got the impact level of heavy vehicles effects on the dynamic reliability of the prototype bridge.Based on a large number of field measured data,the dynamic reliability value calculated by our proposed methodology is more accurate.The method suggested in the paper can do good for not only the traffic management but also the damage analysis of bridges.

Computational fluid dynamics simulations of respiratory airflow in human nasal cavity and its characteristic dimension study

To study the airflow distribution in human nasal cavity during respiration and the characteristic parameters of nasal structure, three-dimensional, anatomically accurate representations of 30 adult nasal cavity models were recons- tructed based on processed tomography images collected from normal people. The airflow fields in nasal cavities were simulated by fluid dynamics with finite element software ANSYS. The results showed that the difference of human nasal cavity structure led to different airflow distribution in the nasal cavities and variation of the main airstream passing through the common nasal meatus. The nasal resistance in the regions of nasal valve and nasal vestibule accounted for more than half of the overall resistance. The characteristic model of nasal cavity was extracted on the basis of characteristic points and dimensions deduced from the original models. It showed that either the geometric structure or the airflow field of the two kinds of models was similar. The characteristic dimensions were the characteristic parameters of nasal cavity that could properly represent the original model in model studies on nasal cavity.

Numerical simulations and comparative analysis of two- and three-dimensional circulating fluidized bed reactors for CO2 capture

Carbon dioxide(CO2),the main gas emitted from fossil burning,is the primary contributor to global warming.Circulating fluidized bed reactor(CFBR)is proved as an energy-efficient method for post-combustion CO2 capture.The numerical simulation by computational fluid dynamics(CFD)is believed as a promising tool to study CO2 adsorption process in CFBR.Although three-dimensional(3D)simulations were proved to have better predicting performance with the experimental results,two-dimensional(2D)simulations have been widely reported for qualitative and quantitative studies on gas-solid behavior in CFBR for its higher computational efficiency recently.However,the discrepancies between 2D and 3D simulations have rarely been evaluated by detailed study.Considering that the differences between the 2D and 3D simulations will vary substantially with the changes of independent operating conditions,it is beneficial to lower computational costs to clarify the effects of dimensionality on the numerical CO2 adsorption runs under various operating conditions.In this work,the comparative analysis for CO2 adsorption in 2D and 3D simulations was conducted to enlighten the effects of dimensionality on the hydrodynamics and reaction behaviors,in which the separation rate,species distribution and hydrodynamic characteristics were comparatively studied for both model frames.With both accuracy and computational costs considered,the viable suggestions were provided in selecting appropriate model frame for the studies on optimization of operating conditions,which directly affect the capture and energy efficiencies of cyclic CO2 capture process in CFBR.

Research on the Dynamic Simulation System of Maize Growth

Dynamic simulation system of maize growth is developed by the physiological and ecological model,morphological structure model,computer science and virtual reality technology,to improve the level of precise operation of maize production.The computer graphics algorithms,virtual reality technology,animation design and information integration technology are applied to maize production by this system.establishment of dynamic simulation system of maize growth is conducive to raise level of precise operation in maize production.The system also can assist the relevant production research and testing,to reduce cost and improve efficiency.

A computational particle fluid-dynamics simulation of hydrodynamics in a three-dimensional full-loop circulating fluidized bed: Effects of particle-size distribution

A computational particle fluid-dynamics model coupled with an energy-minimization multi-scale(EMMS)drag model was applied to investigate the influence of particle-size distribution on the hydrodynamics of a three-dimensional full-loop circulating fluidized bed.Different particle systems,including one monodisperse and two polydisperse cases,were investigated.The numerical model was validated by comparing its results with the experimental axial voidage distribution and solid mass flux.The EMMS drag model had a high accuracy in the computational particle fluid-dynamics simulation of the three-dimensional full-loop circulating fluidized bed.The total number of parcels in the system(Np)influenced the axial voidage distribution in the riser,especially at the lower part of the riser.Additional numerical simulation results showed that axial segregation by size was predicted in the two polydisperse cases and the segregation size increased with an increase in the number of size classes.The axial voidage distribution at the lower portion of the riser was significantly influenced by particle-size distribution.However,radial segregation could only be correctly predicted in the upper region of the riser in the polydisperse case of three solid species.

Simulation of flow pattern at rectangular lateral intake with different dike and submerged vane scenarios

A comprehensive understanding of the sediment behavior at the entrance of diversion channels requires complete knowledge of threedimensional(3 D) flow behavior around such structures. Dikes and submerged vanes are typical structures used to control sediment entrainment in the diversion channel. In this study, a 3 D computational fluid dynamic(CFD) code was calibrated with experimental data and used to evaluate flow patterns, the diversion ratio of discharge, the strength of secondary flow, and dimensions of the vortex inside the channel in various dike and submerged vane installation scenarios. Results show that the diversion ratio of discharge in the diversion channel is dependent on the width of the flow separation plate in the main channel. A dike perpendicular to the flow with a narrowing ratio of 0.20 doubles the ratio of diverted discharge in addition to reducing suspended sediment input to the basin, compared with a no-dike situation, by creating the outer arch conditions. A further increase in the narrowing ratio decreases the diverted discharge. In addition, increasing the longitudinal distance between consecutive vanes(Ls) increases the velocity gradient between the vanes and leads to a more severe erosion of the bed, near the vanes.

Towards full predictions of temperature dynamics in McNary Dam forebay using OpenFOAM

Hydroelectric facilities impact water temperature; low velocities in a reservoir increase residence time and enhance heat exchange in surface layers. In this study, an unsteady three-dimensional model was developed to predict the temperatm＇e dynamics in the McNary Dam forebay. The model is based on the open-source code OpenFOAM. RANS equations with the Boussinesq approximation were used to solve the flow field. A： realizable k-ε model that accounts for the production of wind turbulence was developed. Solar radiation and convective heat transfer at the free surface were included. The result of the model was compared with the field data collected on August 18, 2004. Changes in diurnal stratification were adequately predicted by the model. Observed vertical and lateral temperature distributions were accurately captured. Results indicate that the model can be used as a numerical tool to assess structural and operational alternatives to reduce the forebay temperature.

Observation and computer simulation of multicomponent chemical short-range order (MCSRO) for the bulk metallic glasses

The atomic configuration of chemical short-range order (CSRO) for the Zr-base metallic glasses was investigated by using nano-diffraction and high resolution transmission electronic microscopy (HRTEM) technology with a beam size of 0.5 nm. It is il- lustrated that the pattern of atomic configuration of CSRO might have various compound counterparts because of the chemical inter- action of bonding atoms. Some atomic configuration of MCSRO is similar to the icosahedral structure with 10-fold symmetry of very weak spots. In deed, the nano-beam technology could clearly detect the evolution of atomic configuration in nanometer scale during the transformation from the metallic melt to the primary crystallization. The local atomic configuration of CSRO is also investigated by molecular dynamics simulation (MD) for the Zr2Ni compound in a wider temperature range. The CSRO in the melt could be pic- torially demonstrated as distorted coordination polyhedron of the compound structure and/or the structure similar to cubo-octahedron analogs. The MD simulation illustrates that the atomic packing of long-range order disappears just above the melting point, but the chemical interaction of bonding atoms still exists that leads to form the various CSRO with the atomic configuration similar to stable or metastable unit cell of Zr2Ni compound. The icosahedral polyhedron became more abundance as the overheating temperature was raised.

Dynamic simulation of differential accumulation history of deep marine oil and gas in superimposed basin:A case study of Lower Paleozoic petroleum system of Tahe Oilfield,Tarim Basin,NW China

According to the complex differential accumulation history of deep marine oil and gas in superimposed basins,the Lower Paleozoic petroleum system in Tahe Oilfield of Tarim Basin is selected as a typical case,and the process of hydrocarbon generation and expulsion,migration and accumulation,adjustment and transformation of deep oil and gas is restored by means of reservoine-forming dynamics simulation.The thermal evolution history of the Lower Cambrian source rocks in Tahe Oilfield reflects the obvious differences in hydrocarbon generation and expulsion process and intensity in different tectonic zones,which is the main reason controlling the differences in deep oil and gas phases.The complex transport system composed of strike-slip fault and unconformity,etc.controlled early migration and accumulation and late adjustment of deep oil and gas,while the Middle Cambrian gypsum-salt rock in inner carbonate platform prevented vertical migration and accumulation of deep oil and gas,resulting in an obvious"fault-controlled"feature of deep oil and gas,in which the low potential area superimposed by the NE-strike-slip fault zone and deep oil and gas migration was conducive to accumulation,and it is mainly beaded along the strike-slip fault zone in the northeast direction.The dynamic simulation of reservoir formation reveals that the spatio-temporal configuration of"source-fault-fracture-gypsum-preservation"controls the differential accumulation of deep oil and gas in Tahe Oilfield.The Ordovician has experienced the accumulation history of multiple periods of charging,vertical migration and accumulation,and lateral adjustment and transformation,and deep oil and gas have always been in the dynamic equilibrium of migration,accumulation and escape.The statistics of residual oil and gas show that the deep stratum of Tahe Oilfield still has exploration and development potential in the Ordovician Yingshan Formation and Penglaiba Formation,and the Middle and Upper Cambrian ultra-deep stratum has a certain oil and gas resource prospect.This study provides a reference for the dynamic quantitative evaluation of deep oil and gas in the Tarim Basin,and also provides a reference for the study of reservoir formation and evolution in carbonate reservoir of paleo-craton basin.

通信对抗接收机建模与Simulink动态仿真

针对通信对抗系统中超外差接收机的建模仿真问题,以Matlab中的Simulink软件包作为工具建立基于Simulink仿真平台的超外差接收机的仿真模型,给出频率为5kHz的调幅信号的动态仿真实例,并得到各关健点的仿真波形图和频域图,实验结果证明了该建模方法的有效性。

Static and dynamic finite element analysis of 304 stainless steel rod and wire hot continuous rolling process

Three-dimensional finite element models were developed to analyze 304 stainless steel rod and wire hot continuous rolling process with the help of MSC.Marc software. The entire 30-pass deformation process and the actual parameters of production line were taken into account. Static and dynamic procedures were used to study the continuous rolling process with the aid of the thermo-mechanical coupled FEM of elastic-plasticity. The properties of billets, such as deformation, temperature field and rolling force, were mainly discussed. The simulation results of temperature agree well with the measured values. Comparisons of the analysis results obtained using static implicit method and dynamic implicit method were presented. It is shown that static implicit procedure is more accurate than dynamic implicit procedure and is able to simulate the rolling process with a lower speed, such as a roughing mill. Whereas, dynamic analysis shows a higher efficiency than static analysis and is fit for simulating the rolling process with a higher speed, such as a finishing mill.

基于动态模拟技术的混动车辆发动机电控单元检测系统设计

电控单元是混动车辆发动机中的重要组成部分,对于发动机以及混动车辆的行驶性能产生直接影响,为保证电控单元的运行正常,利用动态模拟技术,优化设计了混动车辆发动机电控单元检测系统;改装温度、转速等传感器设备以及信号处理器设备,调整系统电路的连接方式,实现硬件系统的优化;利用动态模拟技术模拟混动车辆发动机电控过程,结合不同故障类型下电控单元的运行特征,设置系统的检测标准;采集电控单元输出信号,从时域和频域两个方面提取信号特征,最终通过特征匹配确定电控单元状态、故障类型以及故障位置,实现系统的电控单元检测功能;综合混动车辆发动机的3种运行场景,通过系统测试实验得出结论:与传统检测系统相比,优化设计系统的漏检率和误检率分别降低了2.59%和2.05%,由此证明优化设计系统具有良好的检测功能。

89钻杆自动排放机械手设计与研究

为了解决目前人工辅助完成陆地钻台立柱存取存在排放工作劳动强度大、安全性低等问题,以KV3000钻井平台为大环境、89钻杆组成的立柱为研究对象,设计了钻杆自动排杆机械手。首先,对钻井过程中存取立柱的动作及时序过程进行分析;其次,采用动力学仿真分析方法对自动排放机械手进行干涉检查和行程检验,并针对核心零部件进行有限元分析。结果表明:研究装置可顺利完成钻杆存取工作,实现立柱在立柱盒与井口之间的位置转换,加速度均为线性,变化比较平稳,整体无较大波动;核心零部件最大变形为0.15167 mm,最大应力为59.875 MPa,均在允许范围。设备结构合理、运动轨迹规划合理、核心受力部件满足使用要求,提高了钻井作业过程中的自动化程度和安全性,为钻井作业钻杆自动排放提供了解决方案。

叠合盆地深层海相油气差异富集历史的动态模拟——以塔河油田下古生界含油气系统为例

以塔里木盆地塔河油田下古生界含油气系统为例,针对叠合盆地深层海相油气复杂的差异富集历史,采用成藏动力学模拟方法进行深层油气的生排烃、运聚和调整改造的历史恢复。研究表明:①塔河油田下寒武统烃源岩的热演化史反映出不同构造带的生排烃过程及其强度具有明显不同,是导致深层油气相态差异的主要原因。②走滑断裂和不整合面等构成的复合输导体系控制深层油气早期运移聚集和后期调整,中寒武统台内膏盐岩阻止深层油气的垂向运聚,致使深层油气呈现明显的“断控”特征,其中北东向走滑断裂带和深层油气运移低势区叠加有利于汇聚成藏,且主要沿北东向走滑断裂带呈串珠状分布。③成藏动态模拟揭示“源-断-缝-膏-保”时空配置控制塔河深层油气的差异富集,奥陶系经历多期充注、垂向运聚、侧向调整改造的成藏历史,深层油气一直处于运移聚集和逸散的动态平衡中。④油气残留量统计显示塔河油田深层奥陶系鹰山组和蓬莱坝组仍具有较好的勘探开发潜力,超深层中上寒武统具有一定的油气资源前景。研究为塔里木盆地深层油气的动态定量评价提供了参考依据,也可以为古老克拉通盆地碳酸盐岩相关油气成藏演化的研究提供借鉴。

虚拟现实技术在城市景观设计中的动态仿真

针对城市景观设计中动态仿真的效率不高、精确度不足的问题,提出基于虚拟现实技术的城市景观动态仿真模型。以Mongo DB数据库为依据构建城市景观虚拟现实动态仿真模型的整体框架,并结合Open GL进行城市景观的三维设计。为保证城市景观动态仿真的准确度,结合Rank变换进行城市景观单元匹配以及相机参数优化。通过相对误差以及仿真模型的性能测试,基于虚拟现实技术的城市景观动态仿真模型准确度更高,相应时间较快。通过改进模型能够有效提高城市景观设计的动态仿真质量,提升工作效率。

BIM技术在建筑装饰工程项目管理中的应用研究

为提高项目管理水平,加快工程进度并控制其施工成本,引进BIM技术,以某建筑装饰工程项目为例,开展工程管理方法的设计研究。根据视图、基准面、构件、注释、主体结构五个核心要素,创建基于BIM技术的建筑装饰工程项目3D信息模型;将建立的建筑装饰工程项目3D信息模型作为参照,通过录入、深化节点信息,进行建筑装饰工程项目施工的动态模拟;在工程施工前对机械进行动力学仿真,对机械的运行路径、作业人员的作业区域等进行最优选择,实现对装饰设备管线碰撞与冲突的检测;使用Project软件,将工程施工中的进度数据录入4D模型中,通过创建计划数据,实现对工程项目的综合管理。实例应用结果证明:按照提出的方法进行建筑装饰工程项目的管理,不仅可以提高工程的进度,还可以使工程项目支出控制在预期范围内,避免项目建设出现超预算等问题。

微流控视觉伪装系统实验设计及流动特性分析

自然界中变色龙能够根据背景颜色的变化实时改变皮肤颜色,实现自适应伪装。提出了一种利用微流控视觉伪装系统控制有色液体在伪装薄膜的微流道内循环以实现动态伪装的变色龙皮肤模拟实验。对采用非线性、超弹性材料的伪装薄膜进行了静态力学特性实验。选择适当的应变能密度函数拟合实验数据,得到合理的模型参数。通过单、双向流固耦合仿真模型比较微流控视觉伪装系统的液体流动特性以及流量对压力、速度分布的影响,并通过实验验证微流道内液体流动压力损失特性仿真结果,从而确定系统功率,为微流控视觉伪装系统设计提供可靠依据。微流控视觉伪装系统实验及对微流道内液体的仿真分析有效拓展了传统实验教学内容及方法。

基于磁流体稳定性提升的电解槽母线改造研究

磁场是电解槽磁流体稳定性的决定性因素,本文对铝电解槽的磁流体稳定性进行研究,通过采用自均衡网络化母线技术降低电解槽垂直磁场,改造后的垂直磁场平均降低47.5%,且四个象限磁场强度分布均匀。通过瞬态磁流体模型及流动场稳定性分析验证,500s左右后电解槽可自行恢复稳定状态,界面变形减小1.2cm,证明采用自均衡网络化母线技术后的电解槽自平衡能力及抗波动能力均得到增强,从而节省直流电耗150kWh/t-Al。

基于CFD模拟的混合式住宅小区布局对风环境改良的研究

文章旨在探讨衡阳市住宅小区的风环境问题,并提出优化方案。通过对该市不同季节的气象数据和现存建筑的模拟分析,研究发现建筑布局和围合形式对风环境有着显著的影响。因此,作者提出了针对冬季和夏季不同风向的方案,以改善住宅小区内部的风环境。本研究采用计算流体动力学CFD(Computational Fluid Dynamics)模拟技术模拟住宅小区周边的风环境,并控制改良后的模拟方案中的变量,以验证所提出的优化方案的可行性,同时对比分析不同方案的效果。结果表明,合理的调整建筑布局能显著优化其周围的风环境,改善通风并缓解局部风速过快的问题。证明CFD技术在未来住宅小区的规划上能提供更科学合理的方案。希望本研究能为未来同类型研究提供参考。