抛光瓷砖毕业设计外文文献翻译

What is circulating fluidized bed boiler?∙Fluidized Bed Reactors : High temperature systems for labs: Excellent mass and heat transfer∙Fluidized Bed Dryer for porboiled, paddy,corn,coffee,beans,jusmin etc.∙Fluid Bed Processor: Powder Coater Granulator Drying/Granulating/Coating Answer:CIRCULATING FLUIDIZED BED (CFB) BOILERTECHNOLOGY...a unique type of technology that converts various sources of fuel into energyDuring normal operation CFB technology does not utilize higher temperature gas, coal or oil burners in its furnace; instead it utilizes fluidization technology to circulate the fuel source as they burn in a low-temperature combustion process. The low burningtemperature minimizes the formation of nitrogen. The fuel is recycled over and over which results in high efficiency for fuel burning, capturing certain gaseous emissions, andtransferring the fuel's heat energy into high-quality steam used to produce power. The vigorous mixing, long burning time, and low-temperature combustion process allow CFBs to cleanly burn virtually any combustible material. CFBs capture and control gaseous emissions as required by the EPA during the conversion process generally eliminating the need to add additional emission control equipment.CFB technology has proven to be very capable of converting fuels with substantially lower BTU (British Thermal Unit) heating values such as waste coal.Simply put, by suspending (circulating) low quality fuel in air, it could be ignited and swirl inside the boiler like a fluid --- hence the "fluidized bed" part of the name. By circulating the burning fuel in a tall boiler-furnace until all of the available carbon is converted to energy, even a low BTU source such as coal refuse can be effectively and efficiently utilized.Accordingly even coal refuse that had been randomly discarded and unused for decades could now be used and converted into viable alternative energy....coal that had never been considered as "useful fuel" prior to the development of CFB Technology.CFB units are inherently designed and have proven over time to cleanly convert low BTU fuels into viable alternative energy.。

华南理工大学广州学院本科生毕业设计(论文）翻译英文原文名Review of Vibration Analysis Methods for Gearbox Diagnostics and Prognostics中文译名对变速箱振动分析的诊断和预测方法综述学院汽车工程学院专业班级车辆工程七班学生姓名刘嘉先学生学号201130085184指导教师李利平填写日期2015年3月15日英文原文版出处：Proceedings of the 54th Meeting of the Society for Machinery Failure Prevention Technology, Virginia Beach，V A, May 1-4，2000，p. 623-634译文成绩：指导教师(导师组长）签名：译文：简介特征提取技术在文献中有描述;然而，大多数人似乎掩盖所需的特定的预处理功能。

一些文件没有提供足够的细节重现他们的结果，并没有一个全面的比较传统的功能过渡齿轮箱数据。

常用术语,如“残差信号”,是指在不同的文件不同的技术.试图定义了状态维修社区中的常用术语和建立所需的特定的预处理加工特性。

本文的重点是对所使用的齿轮故障检测功能。

功能分为五个不同的组基于预处理的需要。

论文的第一部分将提供预处理流程的概述和其中每个特性计算的处理方案。

在下一节中，为特征提取技术描述，将更详细地讨论每一个功能。

最后一节将简要概述的宾夕法尼亚州立大学陆军研究实验室的CBM工具箱用于齿轮故障诊断。

特征提取概述许多类型的缺陷或损伤会增加机械振动水平。

这些振动水平，然后由加速度转换为电信号进行数据测量。

原则上,关于受监视的计算机的健康的信息被包含在这个振动签名。

因此，新的或当前振动签名可以与以前的签名进行比较,以确定该元件是否正常行为或显示故障的迹象。

在实践中，这种比较是不能奏效的。

由于大的变型中,签名的直接比较是困难的。

相反,一个涉及从所述振动署名数据特征提取更多有用的技术也可以使用。

毕业设计外文翻译粉碎WC-Co 陶瓷子弹核心的临界厚度学生姓名： 学号：0901064122学 院：专 业：指导教师：2013年06月杨雄斐 机电工程学院 弹药工程与爆炸技术 王坚茹粉碎WC-Co陶瓷子弹核心的临界厚度P. J. Hazell1 and C. J. Roberson21P. J.哈泽尔,C. J.罗伯逊工程系统部，斯温顿SN68LA Shriven ham克兰菲德大学，英国皇家军事科学学院，英国2弗兰克·惠特尔爵士国防部高级材料有限公司，商务中心，大中央路，英国CV213XH 在本文中，7.62毫米×51毫米FFV轮组成的碳化钨芯（1550 HV）和铜镀金外壳在氮化硅，二硼化钛，碳化钨和硅碳化硅陶瓷中发射。

特别感兴趣的是在陶瓷的厚度需要改变的渗透机制下，在渗透过程中，从一个完整的弹体到破碎的弹体，最后，完全支离破碎。

似乎在粉碎陶瓷核心厚度所需的声阻抗粉碎存在相关性。

陶瓷的硬度的效果不太显着。

粉碎核心的临界厚度的存在表明，它的冲击应力的大小不仅赋予给核心，但持续时间的冲击应力是在粉碎这些相对较脆的核心。

简介已经有相当多的研究，多年来什么样的陶瓷性质决定其弹道导弹的性能。

然而，它已清晰的，从经已出版的数据的财富中，证明没有一个单一的可以用来确定投射弹者的电阻的渗透参数。

例如，早期的工作由詹姆斯[1]显示，多晶氧化铝曼斯陶瓷及其弹性极限和层裂强度弹道每间不存在相关性。

在这种情况下，1/4规模的钨的APFSDS棒被分配到包括三个25毫米的砖氧化铝由半无限RHA堆栈支持的目标中。

这些结果说明了陶瓷作为一个相对较高的负荷率将强烈期望强度与弹道性能。

小型武器弹药的攻击，以及其他的研究表明，硬度是一个重要因素，并确定粉碎的陶瓷弹丸，从而减少它的动能密度[2,3]。

钢芯对于许多小型武器的威胁在于陶瓷的硬度，因此不可避免地加强弹芯的硬度，因此，相对薄的部分烧结或什至反应键合的陶瓷材料可以附着到一个适当的背衬的重量提供高效率，成本有效的装甲解决方案。

瓷砖⾏业专业英语1，polished tile,抛光砖，2，porcelain super white matt 超⽩哑光抛光砖3，soluble salt /Color-penetrated 渗花砖（抛光砖的⼀种，较cheap）4，Semi polished 半抛光5，Matt polished 哑抛6，salt and pepper 带斑点的渗花砖7，polished crystal tile 抛晶砖8，rustic / antique tile仿古砖9，glazed porcelain 釉⾯瓷质砖10，full body 通体砖11，floor tile 地转12， wall tile 墙⾯砖13，interior wall tile 内墙砖14，exterior wall tile 外墙砖15，indoor floor tile 室内地砖，16， outdoor tile 室外地砖17，plaza tile / plaza stone⼴场砖 paving tile18，unglazed tile ⽆釉砖19，endurable / wearable 耐磨砖20，ceramics glaze tile 瓷砖21，mosaic 马赛克22，border / decorative border tile 腰线23，Angle tile ⾓砖(⽡)24，Stoneware tile 炻质砖25，Embossed tile 浮雕瓷砖, 雕纹花砖26，完全玻化砖 polished tile27，⾦⽟⽯ polished mosaic28，精⼯钻 fine granule⼆、规格（Specification）1，Nominal size /SPAN>名义尺⼨/公称尺⼨2，Work size /Manufacturing size: ⼯作尺⼨/加⼯尺⼨3，Shade number ⾊号4，Thickness /SPAN>厚度5，Caliber /SPAN>尺码6，Weight per unit/SPAN>每块砖重量7，Unit per box /SPAN>每箱数量8，Area per box:每箱砖的⾯积9，Net weight per box :每箱净重10，Gross weight per box:每箱⽑重11，Boxes per pallet:每托箱数12，M? per pallet:每托砖的⾯积13，Weight per pallet:每⼀托的重量14，Neutral packing / standard packing 中性包装（neutral box 中性纸箱）五、陶瓷机械（Machinery）1，Kiln 窑2，Tunnel 隧道窑3，Flat printing machine平板印花机4，Silk screen printing 丝⽹印刷5，Roller printing machine 辊筒印花机6，Tile press 磁砖压制机7，Ball mill 球磨机8，Compensator 釉线储胚机9，Pressing turn-over flat form 压砖翻转平台10，Glaze supply machine 加釉机11，Glazing bell assemble the diagram 钟罩淋釉器12，Edge cleaner 洗边机 13，Polishing machine 磨光机抛光机三、技术参数(Technical parameter / Technical )1，Water absorption:吸⽔率2，Modulus of breakage (MPa):断模系数3，Breakage pressure(N)：破坏强度4，Breaking strength (N): 抗裂强度5，Modulus of rupture (N/mm?):破裂系数6，PEI - Abrasion Resistance:抗磨损性7，Side：边长偏差8，Thickness：厚度偏差9，Surface flatness / Surface smoothness：表⾯平整度10，Straightness of sides：边直度11，Rectangularity:直⾓度12，Warpage (%):翘曲13，Adrasion resistance / wearing strength / 14，scratch-resistance : 耐磨性15，Mohs hardness:莫⽒硬度16，Resistance to thermai shock耐急冷急热17，Frost resistance:抗冻性18，Chemical resistance: 耐⽇⽤化学品游泳池药⽤盐19，Acid and alkali resistance / Acid and alkali solutions 耐酸碱性20，Brightness / Glossy: 光泽度21，Temperature shock resistance 抗热震性21，Center curvature, related to diagonal (%):中⼼曲率，关于对⾓线22，Edge curvature related to the corresponding work size (%):边曲率，关于实际尺⼨23，Coefficient or linear thermal expansion:24，Moisture expansion - (mm/m):湿膨胀25，Stain resistance:抗污性26，Slip resistance: 防滑性四, 缺陷名称（Defect）1，坯裂：crack on body出现在坯体上的裂纹。

On the Filter Size of DMM for Passive Scalarin Complex FlowYang Na1, Dongshin Shin2, and Seungbae Lee31 CAESIT, Dept. of Mechanical Engineering, Konkuk University,Hwayang-dong 1, Gwangjin-gu, Seoul 143-701, Koreayangna@konkuk.ac.kr2 Dept. of Mechanical Engineering, Hong-Ik University,Seoul 121-791, Koreadsshin@wow.hongik.ac.kr3 Dept. of Mechanical Engineering, Inha University,Inchon 402-751, Koreasbaelee@inha.ac.krAbstract. Effect of filter size of dynamic mixed model combined with a boxfilter on the prediction of passive scalar field has been investigated in complexflow. Unlike in the simple channel flow, the result shows that the model per-formance depends on the ratio of test to grid filter widths.1 IntroductionThe role of large eddy simulation (LES) in most of engineering applications involving turbulent flows increases everyday. Since direct numerical simulation (DNS) is re-stricted to a relatively low Reynolds number due to the resolution requirement for the length-scale in dissipation range, it is currently less attractive as an engineering tool and LES becomes more popular as a reasonably accurate and at the same time less expensive methodology.Even though the significant development has been made to the LES modeling for the prediction of velocity field, relatively much less effort has been done in the calcu-lation of passive scalar transport in spite of its obvious practical importance and this fact is reflected in the difficulty of predicting the passive scalar field with satisfactory accuracy using current LES models. The difficulty of investigating passive scalar transport is possibly due to the fact that errors associated with LES models embedded in a velocity field reduces the accuracy in the prediction of passive scalar in a way not clearly understood. Consequently, more effort should be devoted to the development of LES methodology for more accurate and reliable approach for the design of ther-mal system.The present work mainly intended to examine the performance of dynamic mixed model (DMM, Zang et. al. [1]) for passive scalar transport in complex flow (Na [2]). An exhaustive number of LES models has been reported in the literature but DMM was chosen here for the following two reasons: (1) From the perspective of large eddy simulation of engineering flows, computations based on finite difference formulations are certainly of great interest. Thus, DMM with finite difference formulations, which1128 most conveniently use filters in physical space, were considered and tested for turbu-lent channel flows; (2) DMM has been known to produce good results in a wide range of turbulent flows.The dynamic mixed model extended to passive scalar transport will be briefly ex-plained and its characteristics are discussed in the case of turbulent channel flow with wall injection.2 Mathematical Formulation2.1 Dynamic Mixed Model for Passive ScalarThe filtered governing equations for the LES of a passive scalar T for incompressi-ble flows are given as follow:0i iu x ∂=∂, (1) ()(2)i i j ij ij j i ju p u u S t x x x ντ∂∂∂∂+=−+−∂∂∂∂, (2)()()j j j j j T T u T q t x x x α∂∂∂∂+=−∂∂∂∂. (3) where the grid-filtering operation is denoted by an overbar. The effect of unresolved subgrid scales is represented by the following residual stress tensor ij τ and residual scalar flux vector j q .ij i j i j u u u u τ=−, (4)j j j q Tu Tu =−. (5)Only two terms ij τ and j q in equations (1)-(3) should be obtained through the ap-propriate LES models. Details of how to calculate ij τ and j q using DMM approach are explained in Lee & Na [3] and will not be repeated here.In order to discretize the grid-scale and the test-scale filters, a box filter in physical space was employed. After the model coefficients S C and T C are computed through the least-squares approach, they are averaged locally in space within the test-filtering volume as suggested by Zang et. al [1].For the actual computation using DMM, the only adjustable parameter is the ratio of test to grid filter width, i /α=∆∆. Two commonly used definitions of theY. Na, D. Shin, and S. Lee1129effective filter width are (1) i i i 1/32/3/(/)2x z x z∆∆=∆∆∆∆=and (2) i /∆∆ = i i 1/2(/)2x z x z ∆∆∆∆=. The value of α=2 is known to be the optimal choice in the simulation of a turbulent channel flow using a sharp cutoff filter (Germano et al. [4]), but optimal value is likely to depend on the types of grid and test filters used. Thus, the investigation of effect of α on the prediction of passive scalar is the main objec-tive of the present study. The sensitivity of the numerical results to the choice of α was examined for two different values of α (2 and 2/32) in a channel with wallinjection for Pr=1.2.2 Computational DomainIn order to test DMM for a passive scalar field, an incompressible flow between two parallel walls driven by the wall injection was considered. Figure 1 shows a schematic diagram of three-dimensional computational domain. The streamwise extent of the domain is L x =26h and the spanwise extent is L z =6.5h, where h is the half channel height. In terms of wall units (based on the friction velocity at inlet of the computational domain), the domain size is approximately equivalent to 3850 in the streamwise, 296 in the wall-normal, and 963 in the spanwise directions. The Reynolds number based on inlet bulk velocity and half-channel height was set to 2250.The turbulent structures originated from the flat channel region are lifted by the ac-tion of wall injection applied from the location of x=13.4h and this induces a strong mixing layer away from wall. In turn, this formation of strong shear layer causes more turbulent structures to grow in space (Figure 2) and thus, the flow experiences veryrapid changes in the mean flow direction.Fig. 1. Flow geometry and computational domain for the test of passive scalar using DMM On the Filter Size of DMM for Passive Scalar in Complex Flow1130Fig. 2. Turbulent structures generated in a region with a strong injection applied at the wall2.3 Boundary ConditionNo-slip boundary condition was used along the walls except in the region where con-stant blowing was applied (x/h >13.4). The strength of the wall injection, ε, defined by the ratio of injected velocity to the inlet bulk velocity, was set to 0.05, representing a quite strong injection. It remained constant along both upper and lower walls and the spatial variation of ε was not considered. The bottom wall was cooled (w T −) and the top wall was heated (w T ) at the same rate so that both walls were maintained at constant temperature.The flow was assumed to be homogeneous in the spanwise direction which allows transform method. The adequacy of the computational domain size and the periodic boundary condition in the spanwise direction was assessed Na [2].3 Results and DiscussionThe effect of α on the performance of DMM for passive scalar was investigated in a channel with wall injection. The computation was done with 1296565××grids. The impact of the injected vertical flow on the turbulent boundary layer is accompa-nied by the lifted shear layer and this adds complexity to flow. Mass conservation leads to a streamwise acceleration or strong inhomogeneity in the middle of the chan-nel. As shown in Figure 2, the flow is characterized by the formation of increasingly stronger streamwise vortices as it moves downstream. This feature of getting more and more turbulent structures in the streamwise direction is thought to be associated with the growing lifted shear layer.It would be useful to investigate the effect of α in this type of complex flow to in-vestigate the range of model’s utility. For the purpose of comparison, DNS with 513257257××grids were also performed and the data were filtered in physical space to get the filtered statistics.Y. Na, D. Shin, and S. Lee1131Fig. 3.Time-averaged temperature (passive scalar) profiles at several streamwise locationsFig. 4. Root-mean square temperature (passive scalar) profiles at several streamwise locations Figure 3 shows the comparison of mean temperature profiles at several streamwise locations. Note that the location of x/h=9 is in the simple channel flow. It is clear that the mean temperature is not sensitive to the value of αupstream of wall injection. Even though a priori test results suggest the sensitivity of α, this sensitivity does not clearly appear in an actual LES. As the flow moves downstream, however, the choice of 2α= produces much better prediction. Thus, it would be interesting to investi-gate what feature of DMM generates the difference in the presence of wall injection.A similar behavior can also be found in the rms profiles shown in Figure 4.As mentioned earlier, the resolution may play an important role in the present flow due to the strong shear layer formed away from wall. As a first step of the research, On the Filter Size of DMM for Passive Scalar in Complex Flow1132 65 grids were used in the vertical direction in which explicit filtering is not done. However, in order to generalize the effect of α, a more careful examination on the resolution should be carried out in the future.4 SummaryThe dynamic mixed model extended to the prediction of passive scalar transport was tested in a channel with injection. Since the optimal value of αand its range of utility is likely to depend on the flow, DMM was tested in a strong shear layer generated by the strong wall injection.A close investigation of the results suggests that the performance of the model showed sensitivity to the size of the effective filter width ratio unlike in a simple channel flow. Overall, the value of 2α= produced a better mean and rms passive scalar statistics for the flow under investigation. However, more work for a variety of complex flows will be required in order to determine the model’s range of utility of DMM in its current form.AcknowledgementThis work was supported by grant No. R01-2004-000-10041-0 from the Basic Research Program of the Korea Science & Engineering Foundation.References1. Zang, Y., Street R. L. and Koseff, J. R.: A Dynamic Mixed Subgrid-scale Model and itsApplication to Turbulent Recirculating Flows, Phys. Fluids, A 5, vol. 12 (1993) 3186-3196.2. Na, Y.: Direct Numerical Simulation of Turbulent Scalar Field in a Channel with Wall In-jection. Numerical Heat Transfer, Part A (2005) 165-181.3. Lee, G. and Na, Y.: On the Large Eddy Simulation of Temperature Field Using DynamicMixed Model in a Turbulent Channel, Trans. KSME B, Vol. 28, No. 10, (2004) 1255-1263.4. Germano, M. , Piomelli, U., Moin P. and Cabot W. H.: A Dynamic Subgrid-scale EddyViscosity Model, Phys. Fluids, A 3, vol. 7 (1991) 1760-1765.Y. Na, D. Shin, and S. Lee。

ROOM-AND-PILLAR METHOD OF OPEN-STOPE MINING空场采矿法中的房柱采矿法Chapter 1.A Classification of the Room-and-Pillar Method of Open-Stope Mining第一部分，空场采矿的房柱法的分类OPEN STOPING空场采矿法An open stope is an underground cavity from which the initial ore has been mined. Caving of the opening is prevented (at least temporarily) by support from the unmined ore or waste left in the stope,in the form of pillars,and the stope walls (also called ribs or abutments). In addition to this primary may also be required using rockbolts , reinforcing rods, split pipes ,or shotcrete to stabilize the rock surface immediately adjacent to the opening. The secondary reinforcement procedure does not preclude the method classified as open stoping.露天采场台阶是开采了地下矿石后形成的地下洞室。

通过块矿或采场的支柱和（也称为肋或肩）采场墙形式的废料的支持来（至少是暂时的）预防放顶煤的开幕。

除了这个，可能还需要使用锚杆，钢筋棒，分流管，或喷浆，以稳定紧邻开幕的岩石表面。

毕业设计(论文)外文资料翻译学院：艺术学院专业：环境设计姓名：学号：外文出处: The Swedish Country House附件： 1.外文资料翻译译文；2.外文原文附件1：外文资料翻译译文室内装饰简述一室内装饰设计要素1 空间要素空间的合理化并给人们以美的感受是设计基本的任务。

要勇于探索时代、技术赋于空间的新形象，不要拘泥于过去形成的空间形象。

2 色彩要求室内色彩除对视觉环境产生影响外，还直接影响人们的情绪、心理。

科学的用色有利于工作，有助于健康。

色彩处理得当既能符合功能要求又能取得美的效果。

室内色彩除了必须遵守一般的色彩规律外，还随着时代审美观的变化而有所不同。

3 光影要求人类喜爱大自然的美景，常常把阳光直接引入室内，以消除室内的黑暗感和封闭感，特别是顶光和柔和的散射光，使室内空间更为亲切自然。

光影的变换，使室内更加丰富多彩，给人以多种感受。

4 装饰要素室内整体空间中不可缺少的建筑构件、如柱子、墙面等，结合功能需要加以装饰，可共同构成完美的室内环境。

充分利用不同装饰材料的质地特征，可以获得千变完化和不同风格的室内艺术效果，同时还能体现地区的历史文化特征。

5 陈设要素室内家具、地毯、窗帘等，均为生活必需品，其造型往往具有陈设特征，大多数起着装饰作用。

实用和装饰二者应互相协调，求的功能和形式统一而有变化，使室内空间舒适得体，富有个性。

6 绿化要素室内设计中绿化以成为改善室内环境的重要手段。

室内移花栽木，利用绿化和小品以沟通室内外环境、扩大室内空间感及美化空间均起着积极作用。

二室内装饰设计的基本原则1 室内装饰设计要满足使用功能要求室内设计是以创造良好的室内空间环境为宗旨，使室内环境合理化、舒适化、科学化；要考虑人们的活动规律处理好空间关系，空间尺寸，空间比例；合理配置陈设与家具，妥善解决室内通风，采光与照明，注意室内色调的总体效果。

2 室内装饰设计要满足精神功能要求室内设计的精神就是要影响人们的情感，乃至影响人们的意志和行动，所以要研究人们的认识特征和规律；研究人的情感与意志；研究人和环境的相互作用。

毕业设计外文资料翻译（二）外文出处：Jules Houde 《Sustainable development slowed down by bad construction practices and natural and technological disasters》2、外文资料翻译译文混凝土结构的耐久性即使是工程师认为的最耐久和最合理的混凝土材料，在一定的条件下，混凝土也会由于开裂、钢筋锈蚀、化学侵蚀等一系列不利因素的影响而易受伤害。

近年来报道了各种关于混凝土结构耐久性不合格的例子。

尤其令人震惊的是混凝土的结构过早恶化的迹象越来越多。

每年为了维护混凝土的耐久性，其成本不断增加。

根据最近在国内和国际中的调查揭示，这些成本在八十年代间翻了一番，并将会在九十年代变成三倍。

越来越多的混凝土结构耐久性不合格的案例使从事混凝土行业的商家措手不及。

混凝土结构不仅代表了社会的巨大投资，也代表了如果耐久性问题不及时解决可能遇到的成本，更代表着，混凝土作为主要建筑材料，其耐久性问题可能导致的全球不公平竞争以及行业信誉等等问题。

因此，国际混凝土行业受到了强烈要求制定和实施合理的措施以解决当前耐久性问题的双重的挑战，即：找到有效措施来解决现有结构剩余寿命过早恶化的威胁。

纳入新的结构知识、经验和新的研究结果，以便监测结构耐久性，从而确保未来混凝土结构所需的服务性能。

所有参与规划、设计和施工过程的人，应该具有获得对可能恶化的过程和决定性影响参数的最低理解的可能性。

这种基本知识能力是要在正确的时间做出正确的决定，以确保混凝土结构耐久性要求的前提。

加固保护混凝土中的钢筋受到碱性的钝化层(pH值大于12.5)保护而阻止了锈蚀。

这种钝化层阻碍钢溶解。

因此，即使所有其它条件都满足(主要是氧气和水分)，钢筋受到锈蚀也都是不可能的。

混凝土的碳化作用或是氯离子的活动可以降低局部面积或更大面积的pH值。

当加固层的pH值低于9或是氯化物含量超过一个临界值时，钝化层和防腐保护层就会失效，钢筋受腐蚀是可能的。

毕业设计(论文)外文资料翻译学院：机械工程学院专业：机械设计制造及其自动化姓名：崔涛学号： 090501614外文出处： Robotics and Computer-IntegratedManufacturing 25 (2009) 73-80 附件： 1.外文资料翻译译文；2.外文原文。

附件1：外文资料翻译译文科学指南机器人和计算机集成制造25（2009）73–80一个外旋轮线专用的固定循环数控铣床Sotiris L. Omirou a, , Andreas C. Nearchou b——弗雷德里克大学机械工程系，尼科西亚，塞浦路斯，塞浦路斯——希腊帕特雷大学工商管理系发表于2006年9月20日，修改更新从2007年7月23日到2007年9月10日。

摘要提出了一个加工外旋轮线边界的特定的铣床组策略，该方法适用于被集成到一个控制器的数控铣床，对于旋转式内燃发动机（汪克尔），旋转活塞泵和一般外旋轮线形外壳的加工设计特别有用。

方案可以提供较高的精度，其中铣机是通过利用数控插补算法实现的，表面质量控制，是通过粗加工和精加工来实现，整个加工任务可以被编程在一块。

最后，该方法的有效性通过仿真试验验证所产生的刀具路径来实现。

关键词：数控；程序加工；刀具路径生成；偏移曲线；外旋轮线1介绍智能周期提供了一种数控机床来完成重复使用的G / M代码语言的新的加工操作的编程方法。

从本质上讲，智能周期是一个指令被预先设定并永久存储的集机控制器。

它们的使用，消除了许多编程的繁琐需要，减少了编程时间，并简化了整个编程过程。

所有数控加工控制是智能的，这些固定循环可以执行一定的代码，输入任何所需的变量信息。

钻，反钻，深孔钻或槽的加工是标准智能循环应用的例子。

然而，标准智能循环在数量和能力有限，无法容纳复杂的几何形状的日益增加的应用需求。

在加工一个外旋轮线构造特征的情况下，不能用标准智能循环处理。

尽管有其重要的加工应用，现代数控系统仍缺乏类似的专用智能周期。

毕业设计（论文)外文资料翻译系别：专业：班级:姓名：学号:外文出处:附件： 1. 原文; 2。

译文2013年03月附件一：A Rapidly Deployable Manipulator SystemChristiaan J。

J。

Paredis, H. Benjamin Brown，Pradeep K. KhoslaAbstract:A rapidly deployable manipulator system combines the flexibility of reconfigurable modular hardware with modular programming tools，allowing the user to rapidly create a manipulator which is custom-tailored for a given task. This article describes two main aspects of such a system，namely，the Reconfigurable Modular Manipulator System （RMMS)hardware and the corresponding control software。

1 IntroductionRobot manipulators can be easily reprogrammed to perform different tasks, yet the range of tasks that can be performed by a manipulator is limited by mechanicalstructure。

Forexample，a manipulator well-suited for precise movement across the top of a table would probably no be capable of lifting heavy objects in the vertical direction. Therefore，to perform a given task,one needs to choose a manipulator with an appropriate mechanical structure.We propose the concept of a rapidly deployable manipulator system to address the above mentioned shortcomings of fixed configuration manipulators。

毕业设计外文文献翻译Graduation design of foreign literature translation 700 words Title: The Impact of Artificial Intelligence on the Job Market Abstract:With the rapid development of artificial intelligence (AI), concerns arise about its impact on the job market. This paper explores the potential effects of AI on various industries, including healthcare, manufacturing, and transportation, and the implications for employment. The findings suggest that while AI has the potential to automate repetitive tasks and increase productivity, it may also lead to job displacement and a shift in job requirements. The paper concludes with a discussion on the importance of upskilling and retraining for workers to adapt to the changing job market.1. IntroductionArtificial intelligence (AI) refers to the development of computer systems that can perform tasks that typically require human intelligence. AI has made significant advancements in recent years, with applications in various industries, such as healthcare, manufacturing, and transportation. As AI technology continues to evolve, concerns arise about its impact on the job market. This paper aims to explore the potential effects of AI on employment and discuss the implications for workers.2. Potential Effects of AI on the Job Market2.1 Automation of Repetitive TasksOne of the major impacts of AI on the job market is the automation of repetitive tasks. AI systems can perform tasks faster and moreaccurately than humans, particularly in industries that involve routine and predictable tasks, such as manufacturing and data entry. This automation has the potential to increase productivity and efficiency, but also poses a risk to jobs that can be easily replicated by AI.2.2 Job DisplacementAnother potential effect of AI on the job market is job displacement. As AI systems become more sophisticated and capable of performing complex tasks, there is a possibility that workers may be replaced by machines. This is particularly evident in industries such as transportation, where autonomous vehicles may replace human drivers, and customer service, where chatbots can handle customer inquiries. While job displacement may lead to short-term unemployment, it also creates opportunities for new jobs in industries related to AI.2.3 Shifting Job RequirementsWith the introduction of AI, job requirements are expected to shift. While AI may automate certain tasks, it also creates a demand for workers with the knowledge and skills to develop and maintain AI systems. This shift in job requirements may require workers to adapt and learn new skills to remain competitive in the job market.3. Implications for EmploymentThe impact of AI on employment is complex and multifaceted. On one hand, AI has the potential to increase productivity, create new jobs, and improve overall economic growth. On the other hand, it may lead to job displacement and a shift in job requirements. To mitigate the negative effects of AI on employment, it is essentialfor workers to upskill and retrain themselves to meet the changing demands of the job market.4. ConclusionIn conclusion, the rapid development of AI has significant implications for the job market. While AI has the potential to automate repetitive tasks and increase productivity, it may also lead to job displacement and a shift in job requirements. To adapt to the changing job market, workers should focus on upskilling and continuous learning to remain competitive. Overall, the impact of AI on employment will depend on how it is integrated into various industries and how workers and policymakers respond to these changes.。

建筑工程毕业设计外文翻译英文原文The effects of surface preparation on the fracture behavior ofECC/concrete repair systemToshiro Kamada a,*, Victor C. Li ba Department of Civil Engineering, Gifu University, Yanagido, Gifu 501-1193, Japanb Advanced Civil Engineering Materials Research Laboratory, Department of Civil and Environmental Engineering,University of Michigan, Ann Arbor, Michigan, MI 48109-2125, USAReceived 7 July 1999; accepted 15 May 2000AbstractThis paper presents the influence of surface preparation on thekink-crack trapping mechanism of engineered cementitious composite (ECC)/concrete repair system. In general,surfacepreparation of the substrate concrete is considered essential to achieve a durable repair. In thisexperiment, the ``smooth sur face’’ system showed more desirable behavior in the crack pattern and the crack widths than the ``rough surface’’ system. This demonstrates that the smooth surface system is preferable to the rough surface system, from the view point of obtaining durable repair structure. The special phenomenon of kink-crack trapping which prevents the typical failuremodes of delamination or spalling in repaired systems is best revealed when the substrate concrete is prepared to have a smooth surface prior to repair. This is in contrast to the standard approach when the substrate concrete is deliberately roughened to create better bonding to the new concrete. Ó 2000 Elsevier Science Ltd. All rights reserved.Keywords: ECC repair system; Kink-crack trapping mechanism; Surface preparation; Durable repair1. IntroductionEngineered cementitious composites (ECCs) [1,2] are high performance fiber-reinforced cement based composite materials designed with micromechanical principles. Micromechanicalparameters associated with fiber, matrix and interface are combined to satisfy a pair of criteria, the first crack stress criterion and steady state cracking criterion [3] to achieve the strain hardening behavior. Micromechanics allows optimization of the composite for high performance while minimizing the amount of reinforcing fibers (generally less than 2-3%). ECC has a tensile strain capacity of up to 6% and exhibits pseudo-strain hardening behavior accompanied by multiple cracking. It also has high ultimate tensile strength (5-10 MPa), modulus of rupture (8-25 MPa), fracture toughness (25-30 kJ/m2) and compressive strength (up to 80 MPa) and strain (0.6%). A typical tensile stress-strain curve is shown in Fig. 1. ECC has its uniqueness not only insuperior mechanical properties in tension or in relatively small amount ofchopped fiber usage but also in micromechanical methodology in material design.The use of ECC for concrete repair was proposed by Li et al. [4], and Lim and Li [5]. In theseexperiments, specimens representative of an actual repair system - bonded overlay of a concrete pavement above a joint, were used. It was shown that the common failure phenomenona ofspalling or delamination in repaired concrete systems were eliminated. Instead, microcracksemanated from the tips of defects on the ECC/concrete interface, kinked into and subsequently were arrested in the ECC material (see Fig. 2, [5]). The tendency for the interface crack to kink into the ECC material depends on the competing driving force for crack extension at differentorientations, and on the competing crack extension resistance along the interface and into the ECC material. A low initial toughness of ECC combined with a high Mode II loading configuration tends to favor kinking. However, if the toughness of ECC remains low after crack kinking, this crack will propagate unstably to the surface, forming a surface spall. This is the typically observed phenomenon associated with brittle concrete and even fiber-reinforced concrete (FRC). In the case of ECC, the kinked crack is trapped or arrested in the ECC material, dueto the rapidly rising toughness of the ECC material. Conceptually, the ECC behaves like a material with strong R-curve behavior, with lowinitial toughness similar to that of cement (0.01 kJ/m2) and high plateau toughness (25-30 kJ/m2). After kinked crack arrest,additional load can drive further crackextension into the interface, followed by subsequent kinking and arrest.Details of the energetics of kink-crack trapping mechanism can befound in [5]. It was pointed out that this kink-crack trapping mechanism could serve as a means for enhancing repaired concrete system durability.In standard concrete repair, surface preparation of the substrate concrete is considered critical in achieving a durable repair [6]. Inthe study of Lim and Li [5], the ECC is cast onto a diamond saw cut surface of the concrete. Hence, the concrete surface is smooth and is expected as a result to produce a low toughness interface. Higherinterface roughness has been associated with higher interface toughnessin bi-material systems [7].In this paper, this particular aspect of the influence of surface preparation on the kink-crack trapping phenomenon is investigated. Specifically, the base concrete surfaces were prepared by threedifferent methods. The first surface was obtained as cut surface byusing a diamond saw (smooth surface), similar to that used in theprevious study [5]. The second one was obtained by applying a lubricanton the smooth surface of the concrete to decrease the bond between thebase concrete and the repair material. This surface was applied only in one test case to examine the effect of weak bond of interface on the fracture behavior of the repaired specimen. The third surface was prepared with a portable scarifier to produce a roughened surface (rough surface) from a diamond saw-cut surface.Regarding the repair materials, the water/cement ratio of ECC was varied to control its toughness and strength. Thus, two different mixtures of ECC were used for the comparison of fracture behavior in both smooth and rough surface case. Concrete and steel fiber-reinforced concrete (SFRC) were also used as control repair materials instead of ECC.2. Experimental procedure2.1. Specimens and test methodsThe specimens in this experiment were designed to induce a defect in the form of aninterfacial crack between the repair material and the base concrete, as well as a joint in thesubstrate. Fig. 3 shows the dimensions of the designed specimen and the loading configuration, and these were the same as those of the previous experiment [5]. This loading condition can provide a stable interface crack propagation condition, when the crack propagates along the interface [8].In this experiment, concrete, SFRC and ECC (with two different W/C ratios) were used as therepair materials. Table 1 illustrates the combinations of the repair material and the surface condition of test specimens. The numbers of specimens are also shown in Table 1. Only in the concrete overlay specimens, a special case where lubricant was smeared on the concrete smooth surface was used.The mix proportions of materials are shown in Table 2. Ordinary mixture proportions wereadopted in concrete and SFRC as controls for comparisons with ECC overlay specimens. The steel fiber for SFRC was ``I.S fiber’’, straight with indented surfaceand rectangular cross-section (0.5* 0.5 mm2), 30 mm in length. An investigation using a steel fiber with hooked ends had already been performed in the previous study [5]. Polyethylene fiber (Trade name Spectra 900) with 19 mm length and 0.038 mm diameter was used for ECC. The elastic modulus, the tensile strength and the fiber density of Spectra 900 were 120 GPa, 2700 MPa and 0.98 g/cm3, respectively. Two different ECCs were used with different water/cement ratios. The mechanical properties of the base concrete and the repair materials are shown in Table 3. The tensile strain capacity of the ECC materials are not measured, but are estimated to be in excess of 3% based on test results of similar materials [2].An MTS machine was used for loading. Load and load point displacement were recorded. The loading rate in this experiment was0.005 mm/s. After the final failure of specimens, interface crack (extension) lengths were measured at both (left and right) sides of a specimen as the distance from a initial notch tip to a propagated crack tip along the interface between the base concrete and the repair material.2.2. Specimen preparationMost of the specimen preparation procedures followed those of the previous work [5]. The base concrete was prepared by cutting a concrete block (see Fig. 4(a)) into four pieces (see Fig. 4(b)) using a diamond saw. Two out of the four pieces were usedfor one smooth surface repairspecimen. In order to make a rough surface, a cut surface was roughened uniformly with ascarifier for 30 s. To prepare a repair specimen in the form of an overlay system, a repair material was cast against either the smooth surface or the rough surface of the base concrete blocks (see Fig. 5). Special attention was paid both to maintain cleanliness and to provide adequate moisture on the base concrete surface just before the casting. In two of the concrete overlay specimens, lubricant was sprayed on the smooth surface just before concrete casting. The initial notch and joint were made by applying a smooth tape on the base concrete before casting the repair materials(see Fig. 4(c)).The specimens were cured for 4 weeks in water. Eventually, the base concrete was cured for a total of 8 weeks, and repair materials were cured for 4 weeks in water. The specimens were dried for 24 h before testing.3. Results and discussion3.1. Comparison of the ECC overlay system with the control systemsFig. 6 shows the representative load-deflection curves in each test case. The overall peak load and deflection at peak load are recorded in Table 4. In the ECC overlay system, the deflections at peak load, which reflect the system ductility, are considerably larger than those of both theconcrete overlay (about one order of magnitude higher) and the SFRC overlay system (over five times). These results show good agreement with the previous results [5]. Moreover, it is clear fromFig. 6 that the energy absorption capacity in the ECC overlay system is much enhanced when it is compared with the other systems. This significant improvement in ductility and in energyabsorption capacity of the ECC overlay system is expected to enhance the durability of repaired structures by resisting brittle failure. The ECC overlay system failed without spalling ordelamination of the interface, whereas, both the concrete and SFRC overlay systems failed by spalling in these experiments (Fig. 7).3.2. Influence of surface preparationBoth in the concrete overlay system and the SFRC overlay system, the peak load and thedeflection at peak load do not show significant differences between smooth surface specimen and rough surface specimen (Table 4). Thetypical failure mode for both overlay systems (for smooth surface) is shown in Fig. 7. In the concrete overlay specimen with lubricant on the interface, delamination between repair concrete and substrate occurred first, followed by a kinked crack which propagates unstably to the surface of the repair concrete. On the other hand, in the concrete overlay system without lubricant, the initial interface crack kinked out from the interface into the repair concrete with a sudden load drop, without any interface delamination. The fractured halves of the specimens separated completely in both smooth surface specimens and rough surfacespecimens. In the SFRC overlay system, the initial interface crack also kinked out into the SFRC and the load decreased gradually in both surface conditions of specimen. In all these repairsystems, a single kink-crack always leads to final failure, and the influence of surface preparation is not reflected in the experimental data. Instead, only the fracture behavior of the repair material (concrete versus SFRC) are revealed in the test data. These specimen failures are characterized bya single kinked crack with immediate softening following elastic response.。

Title:The Poetics of City and Nature：T oward a New Aesthetic for Urban DesignJournal Issue：Places, 6（1)Author:Spirn，Anne WhistonPublication Date:10-01—1989Publication Info：Places，College of Environmental Design, UC BerkeleyCitation:Spirn,AnneWhiston.(1989).ThePoeticsofCityandNature：T owardaNewAestheticforUrban Design。

Places，6（1)，82。

Keywords:places，placemaking,architecture,environment，landscape，urbandesign，publicrealm,planning, design，aesthetic, poetics，Anne Whiston SpirnThe city has been compared to a poem, a sculpture, a machine. But the city is more than a text，and more than an artistic or technological. It is a place where natural forces pulse and millions of people live—thinking,feeling，dreaming,doing。

An aesthetic of urban design must therefore be rooted in the normal processes of nature and of living.I want to describe the dimensions of such an aesthetic。