机械结构设计外文文献翻译、中英文翻译、机械设计外文翻译
2011届毕业设计外文翻译
结构设计
系、部:机械系
学生姓名:李衍
指导教师:康煜华职称副教授
专业:机械设计制造及其自动化
班级:机本0704班
完成时间:2011年6月
结构设计
Augustine J.Fredrich
摘要:结构设计是选择材料和构件类型,大小和形状以安全有用的样式承担荷载。一般说来,结构设计暗指结构物如建筑物和桥或是可移动但有刚性外壳如船体和飞机框架的工厂稳定性。设计的移动时彼此相连的设备(连接件),一般被安排在机械设计领域。
关键词:结构设计;结构分析;结构方案;工程要求
Abstract: Structure design is the selection of materials and member type ,size, and configuration to carry loads in a safe and serviceable fashion .In general ,structural design implies the engineering of stationary objects such as buildings and bridges ,or objects that maybe mobile but have a rigid shape such as ship hulls and aircraft frames. Devices with parts planned to move with relation to each other(linkages) are generally assigned to the area of mechanical .
Key words: Structure Design ;Structural analysis ;structural scheme ;Project requirements
Structure Design
Structural design involved at least five distinct phases of work: project requirements, materials, structural scheme, analysis, and design. For unusual structures or materials a six phase, testing, should be included. These phases do not proceed in a rigid progression , since different materials can be most effective in different schemes , testing can result in change to a design , and a final design is often reached by starting with a rough estimated design , then looping through several cycles of analysis and redesign . Often, several alternative designs will prove quite close in cost, strength, and serviceability. The structural engineer, owner, or end user would then make a selection based on other considerations.
Project requirements. Before starting design, the structural engineer must determine the criteria for acceptable performance. The loads or forces to be resisted must be provided. For specialized structures, this may be given directly, as when supporting a known piece of machinery, or a crane of known capacity. For conventional buildings, buildings codes adopted on a municipal, county , or , state level provide minimum design requirements for live loads (occupants and furnishings , snow on roofs , and so on ). The engineer will calculate dead loads (structural and known, permanent installations ) during the design process.
For the structural to be serviceable or useful , deflections must also be kept within limits ,since it is possible for safe structural to be uncomfortable “bounce”Very tight deflection limits are set on supports for machinery , since beam sag can cause drive shafts to bend , bearing to burn out , parts to misalign , and overhead cranes to stall . Limitations of sag less than span /1000 ( 1/1000 of the beam length ) are not uncommon . In conventional buildings, beams supporting ceilings often have sag limits of span /360 to avoid plaster cracking, or span /240 to avoid occupant concern (keep visual perception limited ). Beam stiffness also affects floor “bounciness,” which can be annoying if not controlled. In addition , lateral deflection , sway , or drift of tall buildings is often held within approximately height /500 (1/500 of the building height ) to minimize the likelihood of motion discomfort in occupants
of upper floors on windy days .
Member size limitations often have a major effect on the structural design. For example, a certain type of bridge may be unacceptable because of insufficient under clearance for river traffic, or excessive height endangering aircraft. In building design, ceiling heights and floor-to-floor heights affect the choice of floor framing. Wall thicknesses and column sizes and spacing may also affect the serviceability of various framing schemes.
Materials selection. Technological advances have created many novel materials such as carbon fiber and boron fiber-reinforced composites, which have excellent strength, stiffness, and strength-to-weight properties. However, because of the high cost and difficult or unusual fabrication techniques required , they are used only in very limited and specialized applications . Glass-reinforced composites such as fiberglass are more common, but are limited to lightly loaded applications. The main materials used in structural design are more prosaic and include steel, aluminum, reinforced concrete, wood , and masonry .
Structural schemes. In an actual structural, various forces are experienced by structural members , including tension , compression , flexure (bending ), shear ,and torsion (twist) . However, the structural scheme selected will influence which of these forces occurs most frequently, and this will influence the process of materials selection.
Tension is the most efficient way to resist applied loads ,since the entire member cross section is acting to full capacity and bucking is not a concern . Any tension scheme must also included anchorages for the tension members . In a suspension bridge , for example ,the anchorages are usually massive dead weights at the ends of the main cables . To avoid undesirable changes in geometry under moving or varying loads , tension schemes also generally require stiffening beams or trusses.
Compression is the next most efficient method for carrying loads . The full member cross section is used ,but must be designed to avoid bucking ,either by making the member stocky or by adding supplementary bracing . Domed and arched
buildings ,arch bridges and columns in buildings frames are common schemes . Arches create lateral outward thrusts which must be resisted . This can be done by designing appropriate foundations or , where the arch occurs above the roadway or floor line , by using tension members along the roadway to tie the arch ends together ,keeping them from spreading . Compression members weaken drastically when loads are not applied along the member axis , so moving , variable , and unbalanced loads must be carefully considered.
Schemes based on flexure are less efficient than tension and compression ,since the flexure or bending is resisted by one side of the member acting in tension while the other side acts in compression . Flexural schemes such as beams , girders , rigid frames , and moment (bending ) connected frames have advantages in requiring no external anchorages or thrust restrains other than normal foundations ,and inherent stiffness and resistance to moving ,variable , and unbalanced loads .
Trusses are an interesting hybrid of the above schemes . They are designed to resist loads by spanning in the manner of a flexural member, but act to break up the load into a series of tension and compression forces which are resisted by individually designed tension and have excellent stiffness and resistance to moving and variable loads . Numerous member-to-member connections, supplementary compression braces ,and a somewhat cluttered appearance are truss disadvantages .
Plates and shells include domes ,arched vaults ,saw tooth roofs , hyperbolic paraboloids , and saddle shapes .Such schemes attempt to direct all force along the plane of the surface ,and act largely in shear . While potentially very efficient ,such schemes have very strict limitations on geometry and are poor in resisting point ,moving , and unbalanced loads perpendicular to the surface.
Stressed-skin and monologue construction uses the skin between stiffening ribs ,spars ,or columns to resist shear or axial forces . Such design is common in airframes for planes and rockets, and in ship hulls . it has also been used to advantage in buildings. Such a design is practical only when the skin is a logical part of the design and is never to be altered or removed .
For bridges , short spans are commonly girders in flexure . As spans increase
and girder depth becomes unwieldy , trusses are often used ,as well as cablestayed schemes .Longer spans may use arches where foundation conditions ,under clearance ,or headroom requirements are favorable .The longest spans are handled exclusively by suspension schemes ,since these minimize the crucial dead weight and can be erected wire by wire .
For buildings, short spans are handled by slabs in flexure .As spans increase, beams and girders in flexure are used . Longer spans require trusses ,especially in industrial buildings with possible hung loads . Domes ,arches , and cable-suspended and air –supported roofs can be used over convention halls and arenas to achieve clear areas .
Structural analysis . Analysis of structures is required to ensure stability (static equilibrium ) ,find the member forces to be resisted ,and determine deflections . It requires that member configuration , approximate member sizes ,and elastic modulus ; linearity ; and curvature and plane sections . Various methods are used to complete the analysis .
Final design . once a structural has been analyzed (by using geometry alone if the analysis is determinate , or geometry plus assumed member sizes and materials if indeterminate ), final design can proceed . Deflections and allowable stresses or ultimate strength must be checked against criteria provided either by the owner or by the governing building codes . Safety at working loads must be calculated . Several methods are available ,and the choice depends on the types of materials that will be used .
Pure tension members are checked by dividing load by cross-section area .Local stresses at connections ,such as bolt holes or welds ,require special attention . Where axial tension is combined with bending moment ,the sum of stresses is compared to allowance levels . Allowable : stresses in compression members are dependent on the strength of material, elastic modulus ,member slenderness ,and length between bracing points . Stocky members are limited by materials strength ,while slender members are limited by elastic bucking .
Design of beams can be checked by comparing a maximum bending stress to
an allowable stress , which is generally controlled by the strength of the material, but may be limited if the compression side of the beam is not well braced against bucking .
Design of beam-columns ,or compression members with bending moment ,must consider two items . First ,when a member is bowed due to an applied moment ,adding axial compression will cause the bow to increase .In effect ,the axial load has magnified the original moment .Second ,allowable stresses for columns and those for beams are often quite different .
Members that are loaded perpendicular to their long axis, such as beams and beam-columns, also must carry shear. Shear stresses will occur in a direction to oppose the applied load and also at right angles to it to tie the various elements of the beam together. They are compared to an allowable shear stress. These procedures can also be used to design trusses, which are assemblies of tension and compression members. Lastly, deflections are checked against the project criteria using final member sizes.
Once a satisfactory scheme has been analyzed and designed to be within project criteria, the information must be presented for fabrication and construction. This is commonly done through drawings, which indicate all basic dimensions, materials, member sizes, the anticipated loads used in design, and anticipated forces to be carried through connections.
结构设计
结构设计包含至少5个不同方面的工作:工程要求,材料,结构方案,分析和设计。对于不一般的结构或材料,又包含一个方面:试验。这些方面不是严格按步骤进行,因为不同材料在不同方案大多数是有效的,试验会导致设计变更,最终设计由初步估计设计开始,然后经过分析和再设计几个循环后完成。通常,可替代的设计证明在费用,强度和使用性上十分接近。结构工程师,业主或最后住户基于其它的考虑选择一种。
工程要求。在开始设计前,结构工程师必须决定容易接受的执行标准。必须提供承担的荷载或力。对于一些专门结构,当支持一台已知载重的机器或起重机时,这可能直接给出,对于普通建筑物,采用市政,县,州的建筑规范,提供了设计所需活载(人群荷载和设备,屋顶雪荷载,等等)的最小值。工程师将计算出设计期间的恒载(结构和已知永久性设备)。
对要正常使用的结构,也必须控制其挠度,因为安全的结构可能会存在令人不安的振动。机器的支座有严格的变形限制,因为梁下沉会导致驱动轴弯曲,烧毁,部件错位和上面的吊车熄火。挠度限制在跨度/1000 (梁长的1/1000)以下是很普通的。在传统建筑里,支持板的梁挠度限制在跨度1/360以避免粉刷开裂或跨度1/240以避免人的担忧(保持在可感知的变动范围内)。梁的刚度也影响板“振动”,如果不能控制会令人很头疼。另外,高层建筑的侧面变形,位移或摇摆通常限定在高度/500(建筑物高度的1/500)里,把在有风的日子里上面楼层的人移动的不舒服降到最小。构件尺寸在结构设计里起主要作用。例如,由于下面留作水上交通的净空不够或过高威胁到飞机的特定类型的桥是不可接受的。在建筑设计里,天花板高度和楼板之间高度影响楼板框架的选择。墙厚和柱子尺寸和跨度也影响不同框架方案的适用性。
选择材料。技术的进步创造了许多新材料,如碳纤维加强复合材料和硼纤维加强复合材料,它们都具有极好的强度,刚度和强度重量比特性。然而,由于费用高和非通常的制造要求,它们仅用在有限特殊领域。强化玻璃合成物如玻璃纤
维是很普遍,但被限制应用在小荷载情况下。用在结构设计上的主要材料更多是普通的,包括钢材,铝,钢筋混凝土,木材,砌体。
结构方案。在一个实际方案里,结构构件承担很多力,包括拉,压,弯,剪和扭。然而所选择的方案将会影响这些力产生的概率,也会影响材料选择过程。
抗拉是有效的承担荷载的方法,整个构件的横截面性能得到发挥,并且不涉及到弯曲变形。任何抗拉方案必须也对抗拉构件的锚固。例如,在悬索桥里,锚固体通常是位于主要绳索尾段的强大自重。为了避免在荷载移动或变形时有不期望的几何变形,抗拉方案通常要求是刚性梁和桁架。
抗压是另一个很有效的承担荷载方法。全部杆件截面发挥了作用,但是设计时必须避免弯曲,或者是做成粗短构件或者是增加附加支撑。圆顶和拱形建筑,拱桥和柱是很普遍的建筑方案。拱产生了必须抵挡住的水平外推力。这靠设计合适的基础或建在车道或楼板的上面的拱解决,靠沿着车道用抗拉构件把两端的拱连接起来,阻止他们拉开。当荷载不是作用在构件轴线上时,抗压构件显著地被削弱。所以,必须认真考虑移动,变化和不平衡的荷载。
基于受弯的方案的效率比受拉和压低,因为弯曲是靠构件一边受拉另一边受压来抵抗。受弯方案如主梁,次梁,刚架和受弯框架在外部锚固或推力限制,与一般基础不同,靠内部刚度阻挡可移动,变化和不平衡的荷载的情况下有利。
桁架是上面方案的混合体。它们设计成荷载横跨在受弯构件上,但是分解成一系列拉力和压力,由抗拉和抗压构件承担。桁架方案设计时不需要特殊锚固或推力的限制,并且有很好的刚度抵抗移动或变化的荷载。大量的构件之间连结和抗压构件的附加支撑,看起来有点杂乱,这就是桁架的不利处。
板和壳包括圆顶,拱顶,有齿屋顶,双曲抛物面和马鞍形。这样的方案把所有的力直接作用在平板表面并且作用有巨大的剪力。尽管可能效率很高,但是这样的方案对几何有严格的限制,并且在移动,和不平衡垂直作用在表面的荷载的能力很弱。
薄壳结构和硬壳结构利用加劲肋,梁之间的壳板抵抗剪力和轴向力。这样的设计在飞机机体和火箭,船体方面很普遍。它在建筑方面也是有利的。这样的设计仅仅在壳是设计的逻辑部分并且永远不会被替代和移除时才实际些。
对于桥梁,短跨是很普遍受弯的梁。当跨度增加和梁高变得很大时,通常用
桁架和斜拉结构。更长跨时也许用拱,要考虑基础条件和净空要求。最长的跨靠悬索方案处理,因为这可把关键性的自重降到最小并且能索连索地建造起来。
对于桥,短跨靠板承担弯矩。当跨度增加时,主梁和次梁被用来承担弯曲。更长的跨要求用桁架,尤其是在工业建筑有吊车荷载时,圆顶,拱和悬索和充气屋顶被用在传统的大厅和竞技场里以获得净面积。
结构分析。结构分析要求确定稳定性(静力平衡),构件承担的力和变形。它需要构件形状,大概尺寸,已知或假设的材料特性。分析包括:平衡,应力,应变和弹性模量,线形,塑性和弯曲和板截面。很多方法可以完成分析过程。
最终设计。一旦结构分析完成(如果分析是正确的,只用几何方法;反之附加构件尺寸和材料假设)。最终设计可以进行,必须对照业主或政府建筑规范标准来检查变形和允许应力或极限强度。必须计算工作荷载下的安全性。一般方法是可行的,依据所使用的材料类型做出选择。
纯抗拉构件检查横截面应力。特别注意螺栓孔或焊接处的应力。拉弯构件中,用应力之和与分析应力作比。受压构件中的允许应力取决于构件强度,弹性模量,长细比和支点间距离。粗短构件由材料强度决定,然而长细构件由弹性弯曲决定。
梁的设计由对于最大弯曲应力和允许应力来检验,通常由材料强度控制,但是如果受压一边没有侧向支撑就会被限制。
梁,柱或有弯矩的受压构件的设计必须考虑两项。首先,当构件由于承受弯矩而弯曲时,轴力会增加弯曲量,实际上,轴压放大了原始弯矩。其次,对于柱和梁的允许应力是不同的。
承受垂直于长轴的荷载的构件。如梁和梁——柱,也必须承担剪力。剪应力和荷载的方向相反并且在其右边,把梁的不同部分连接起来。它们与允许剪应力作对比。这些步骤也能用来设计由受拉和受压构件组成的桁架。最后,用工程标准检验变形,使用最后的构件。
一旦被分析和在工程标准内的设计方案是令人满意的,必须提出制造和建立信息。通过作图,指明所以基本尺寸,材料和构件大小。设计中预期荷载和节点承担的预期力。
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不是说富于想象力的结构设计就能够创造出伟大建筑。正相反,有许多例优美的建筑仅得到结构工程师适当的支持就被创造出来了,然而,如果没有天赋甚厚的建筑师的创造力的指导,那么,得以发展的就只能是好的结构,并非是伟大的建筑。无论如何,要想创造出高层建筑真正非凡的设计,两者都需要最好的。 虽然在文献中通常可以见到有关这七种体系的全面性讨论,但是在这里还值得进一步讨论。设计方法的本质贯穿于整个讨论。设计方法的本质贯穿于整个讨论中。 抗弯矩框架 抗弯矩框架也许是低,中高度的建筑中常用的体系,它具有线性水平构件和垂直构件在接头处基本刚接之特点。这种框架用作独立的体系,或者和其他体系结合起来使用,以便提供所需要水平荷载抵抗力。对于较高的高层建筑,可能会发现该本系不宜作为独立体系,这是因为在侧向力的作用下难以调动足够的刚度。 我们可以利用STRESS,STRUDL 或者其他大量合适的计算机程序进行结构分析。所谓的门架法分析或悬臂法分析在当今的技术中无一席之地,由于柱梁节点固有柔性,并且由于初步设计应该力求突出体系的弱点,所以在初析中使用框架的中心距尺寸设计是司空惯的。当然,在设计的后期阶段,实际地评价结点的变形很有必要。 支撑框架 支撑框架实际上刚度比抗弯矩框架强,在高层建筑中也得到更广泛的应用。这种体系以其结点处铰接或则接的线性水平构件、垂直构件和斜撑构件而具特色,它通常与其他体系共同用于较高的建筑,并且作为一种独立的体系用在低、中高度的建筑中。
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框架结构设计外文翻译
毕业设计(论文)外文资料翻译 系:机械工程系 专业:土木工程 姓名: 学号: 外文出处:Design of prestressed (用外文写) concrete structures 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 8-2简支梁布局 一个简单的预应力混凝土梁由两个危险截面控制:最大弯矩截面和端截面。这两部分设计好之后,中间截面一定要单独检查,必要时其他部位也要单独调查。最大弯矩截面在以下两种荷载阶段为控制情况,即传递时梁受最小弯矩M G的初始阶段和最大设计弯矩M T时的工作荷载阶段。而端截面则由抗剪强度、支承垫板、锚头间距和千斤顶净空所需要的面积来决定。所有的中间截面是由一个或多个上述要求,根它们与上述两种危险截面的距离来控制。对于后张构件的一种常见的布置方式是在最大弯矩截面采用诸如I形或T形的截面,而在接近梁端处逐渐过渡到简单的矩形截面。这就是人们通常所说的后张构件的端块。对于用长线法生产的先张构件,为了便于生产,全部只用一种等截面,其截面形状则可以为I形、双T形或空心的。在第5 、 6 和7章节中已经阐明了个别截面的设计,下面论述简支梁钢索的总布置。 梁的布置可以用变化混凝土和钢筋的办法来调整。混凝土的截面在高度、宽度、形状和梁底面或者顶面的曲率方面都可以有变化。而钢筋只在面积方面有所变化,不过在相对于混凝土重心轴线的位置方面却多半可以有变化。通过调整这些变化因素,布置方案可能有许多组合,以适应不同的荷载情况。这一点是与钢筋混凝土梁是完全不同的,在钢筋混凝土梁的通常布置中,不是一个统一的矩形截面便是一个统一的T形,而钢筋的位置总是布置得尽量靠底面纤维。 首先考虑先张梁,如图 8-7,这里最好采用直线钢索,因为它们在两个台座之间加力比较容易。我们先从图(a)的等截面直梁的直线钢索开始讨论。这样的布置都很简单,但这样一来,就不是很经济的设计了,因为跨中和梁端的要求会产生冲突。通常发生在跨度中央的最大弯矩截面中的钢索,最好尽量放低,以便尽可能提供最大力臂而提供最大的内部抵制力矩。当跨度中央的梁自重弯矩M G相当大时,就可以把c.g.s布置在截面核心范围以下很远的地方,而不致在传递时在顶部纤维中引起拉应力。然而对于梁端截面却有一套完全不同的要求。由于在梁端没有外力矩,因为在最后的时刻,安排钢索要以c.g.s与 c.g.c在结束区段一致,如此同样地获得克服压力分配的方法。无论如何,如果张应力在最后不能承受,放置 c.g.s.
机械类毕业设计外文文献翻译
沈阳工业大学工程学院 毕业设计(论文)外文翻译 毕业设计(论文)题目:工具盒盖注塑模具设计 外文题目:Friction , Lubrication of Bearing 译文题目:轴承的摩擦与润滑 系(部):机械系 专业班级:机械设计制造及其自动化0801 学生姓名:王宝帅 指导教师:魏晓波 2010年10 月15 日
外文文献原文: Friction , Lubrication of Bearing In many of the problem thus far , the student has been asked to disregard or neglect friction . Actually , friction is present to some degree whenever two parts are in contact and move on each other. The term friction refers to the resistance of two or more parts to movement. Friction is harmful or valuable depending upon where it occurs. friction is necessary for fastening devices such as screws and rivets which depend upon friction to hold the fastener and the parts together. Belt drivers, brakes, and tires are additional applications where friction is necessary. The friction of moving parts in a machine is harmful because it reduces the mechanical advantage of the device. The heat produced by friction is lost energy because no work takes place. Also , greater power is required to overcome the increased friction. Heat is destructive in that it causes expansion. Expansion may cause a bearing or sliding surface to fit tighter. If a great enough pressure builds up because made from low temperature materials may melt. There are three types of friction which must be overcome in moving parts: (1)starting, (2)sliding, and(3)rolling. Starting friction is the friction between two solids that tend to resist movement. When two parts are at a state of rest, the surface irregularities of both parts tend to interlock and form a wedging action. To produce motion in these parts, the wedge-shaped peaks and valleys of the stationary surfaces must be made to slide out and over each other. The rougher the two surfaces, the greater is starting friction resulting from their movement . Since there is usually no fixed pattern between the peaks and valleys of two mating parts, the irregularities do not interlock once the parts are in motion but slide over each other. The friction of the two surfaces is known as sliding friction. As shown in figure ,starting friction is always greater than sliding friction . Rolling friction occurs when roller devces are subjected to tremendous stress which cause the parts to change shape or deform. Under these conditions, the material in front of a roller tends to pile up and forces the object to roll slightly uphill. This changing of shape , known as deformation, causes a movement of molecules. As a result ,heat is produced from the added energy required to keep the parts turning and overcome friction. The friction caused by the wedging action of surface irregularities can be overcome
机械图纸中英文翻译汇总
近几年,我厂和英国、西班牙的几个公司有业务往来,外商传真发来的图纸都是英文标注,平时阅看有一定的困难。下面把我们积累的几点看英文图纸的经验与同行们交流。 1标题栏 英文工程图纸的右下边是标题栏(相当于我们的标题栏和部分技术要求),其中有图纸名称(TILE)、设计者(DRAWN)、审查者(CHECKED)、材料(MATERIAL)、日期(DATE)、比例(SCALE)、热处理(HEAT TREATMENT)和其它一些要求,如: 1)TOLERANCES UNLESS OTHERWISE SPECIFIAL 未注公差。 2)DIMS IN mm UNLESS STATED 如不做特殊要求以毫米为单位。 3)ANGULAR TOLERANCE±1°角度公差±1°。 4)DIMS TOLERANCE±0.1未注尺寸公差±0.1。 5)SURFACE FINISH 3.2 UNLESS STATED未注粗糙度3.2。 2常见尺寸的标注及要求 2.1孔(HOLE)如: (1)毛坯孔:3"DIAO+1CORE 芯子3"0+1; (2)加工孔:1"DIA1"; (3)锪孔:锪孔(注C'BORE=COUNTER BORE锪底面孔); (4)铰孔:1"/4 DIA REAM铰孔1"/4; (5)螺纹孔的标注一般要表示出螺纹的直径,每英寸牙数(螺矩)、螺纹种类、精度等级、钻深、攻深,方向等。如: 例1.6 HOLES EQUI-SPACED ON 5"DIA (6孔均布在5圆周上(EQUI-SPACED=EQUALLY SPACED均布) DRILL 1"DIATHRO' 钻1"通孔(THRO'=THROUGH通) C/SINK22×6DEEP 沉孔22×6 例2.TAP7"/8-14UNF-3BTHRO' 攻统一标准细牙螺纹,每英寸14牙,精度等级3B级 (注UNF=UNIFIED FINE THREAD美国标准细牙螺纹) 1"DRILL 1"/4-20 UNC-3 THD7"/8 DEEP 4HOLES NOT BREAK THRO钻 1"孔,攻1"/4美国粗牙螺纹,每英寸20牙,攻深7"/8,4孔不准钻通(UNC=UCIFIED COARSE THREAD 美国标准粗牙螺纹)
机械毕业设计外文翻译---装载机发展概况
外文资料翻译 学生姓名: 专业班级:机械设计制造及其自动化04级2班指导教师: 2008年6月
装载机发展概况 Abstract This paper have discussed s.s. ZL-50 type fork-lift truck mainly overall fictitious prototype design as well as some kinds of typical schoolwork operating modes imitate and emulate , include equipment and the overall parts needed build mould. In this design course, have applied ADAMS software and the software of PRO/ENGINEER. ADAMS software is used in the emulation of some kinds of schoolwork operating modes, and the software of PRO/ENGINEER is used to build mould mainly. Through the simulated emulation for some kinds of overall schoolwork operating modes, can see relatively distinctly the overall possible condition in actual schoolwork course that met , can in time modify , have reduced actual design time , have raised production efficiency. The innovation of this design Zhi is in in, imitate and have emulated fork-lift truck the 3 kinds of typical schoolwork operating mode in actual schoolwork, is effect again have imitated in actual schoolwork the hydraulic impact of use, so when being helpful to solve actual loading, the actual problem of meeting the stock that is hard to uninstall can so raise production efficiency. Key words: Fork-lift truck 、fictitious prototype , build mould, emulation, optimization、production efficiency Loader Development China's modern 20 wheel loaders began in the mid-1960s of the Z435. The aircraft as a whole rack, rear axle steering. After years of hard work, the attraction was the world's most advanced technology wheel loader on the basis of the successful development of the power of 162 KW of shovel-fit wheel loaders, stereotypes for Z450 (later ZL50), and in 1971 December 18, formally appraised by experts. Thus the birth of China's first articulated wheel loader, thus creating our industry loader formation and development history. Z450-type loader with hydraulic mechanical transmission, power shift, Shuangqiaoshan drive, hydraulic manipulation, articulated power steering, gas oil Afterburner brake wheel loaders, and other modern, the basic structure of the world's advanced level for the time . Basically represent the first generation of wheeled loading the basic structure. The aircraft in the overall performance of dynamic, and insertion force a rise of power and flexibility, manipulation of light, the higher operating efficiency of a series of advantages. 1978, Heavenly Creations by the Department in accordance with the requirements of machinery, worked out to LIUGONG Z450-based type of wheel loaders series of standards. The development of standards, with reservations Z