資源目錄里展示的全都有，所見即所得。下載后全都有,請(qǐng)放心下載。原稿可自行編輯修改=【QQ：401339828 或11970985 有疑問(wèn)可加】 機(jī)0405 11號(hào) 馬吟川 指導(dǎo)老師：許寶杰 THE DESIGN OF PARALLEL KINEMATIC MACHINE TOOLS USING KINETOSTATIC PERFORMANCE CRITERIA http://arxiv.org/ftp/arxiv/papers/0705/0705.1038.pdf 1. INTRODUCTION Most industrial machine tools have a serial kinematic architecture, which means that each axis has to carry the following one, including its actuators and joints. High Speed Machining highlights some drawbacks of such architectures: heavy moving parts require from the machine structure high stiffness to limit bending problems that lower the machine accuracy, and limit the dynamic performances of the feed axes. That is why PKMs attract more and more researchers and companies, because they are claimed to offer several advantages over their serial counterparts, like high structural rigidity and high dynamic capacities. Indeed, the parallel kinematic arrangement of the links provides higher stiffness and lower moving masses that reduce inertia effects. Thus, PKMs have better dynamic performances. However, the design of a parallel kinematic machine tool (PKMT) is a hard task that requires further research studies before wide industrial use can be expected. Many criteria need to be taken into account in the design of a PKMT. We pay special attention to the description of kinetostatic criteria that rely on the conditioning of the Jacobian matrix of the mechanism. The organisation of this paper is as follows: next section introduces general remarks about PKMs, then is explained why PKMs can be interesting alternative machine tool designs. Then are presented existing PKMTs. An application to the design of a small-scale machine tool prototype developed at IRCCyN is presented at the end of this paper. 2. ABOUT PARALLEL KINEMATIC MACHINES 2.1. General Remarks The first industrial application of PKMs was the Gough platform (Figure 1), designed in 1957 to test tyres1. PKMs have then been used for many years in flight simulators and robotic applications2 because of their low moving mass and high dynamic performances. Since the development of high speed machining, PKMTs have become interesting alternative machine tool designs3, 4. Figure 1. The Gough platform In a PKM, the tool is connected to the base through several kinematic chains or legs that are mounted in parallel. The legs are generally made of either telescopic struts with fixed node points (Figure 2a), or fixed length struts with gliding node points (Figure 2b). Along with high-speed cutting's unceasing development, the traditional tandem type organization constructs the platform the structure rigidity and the traveling carriage high speed becomes the technological development gradually the bottleneck, but the parallel platform then becomes the best candidate object, but was opposite in the tandem engine bed, the parallel working platform had the following characteristic and the merit: (1) structure is simple, the price is low The engine bed mechanical spare part number is series connected constructs the platform to reduce largely, mainly by the ball bearing guide screw, the Hooke articulation, the ball articulation, the servo electrical machinery and so on common module is composed, these common modules may by the special factory production, thus this engine bed's manufacture and the inventory cost are much lower than the same function's traditional engine bed, easy to assemble and the transporting. (2) structure rigidity is high Because used closeness structure (closed-loop structure) to enable it to have high rigid and the high speed merit, its structural load streamline was short, but shouldered decomposes pulls, the pressure also to withstand by six connecting rods, by materials mechanics' viewpoint, when the external force was certain, the bracket quantity's stress and the distortion were biggest, the both sides inserted the (build-in) next best, came is again both sides Jan supports (simply-supported), next was the bearing two strength structure, what the stress and the distortion were smallest was the tensity two strength structure, therefore it had the high rigidity. Its rigidity load ratio is higher than traditional the numerically-controlled machine tool. (3) processing speed is high, the inertia is low If the structure withstands the strength will change the direction, (will be situated between tensity and pressure), two strength components will be most save the material the structure, but it will move to the moving parts weight to reduce to lowly and simultaneously will actuate by six actuating units, therefore machine very easy high speed, and will have the low inertia. (4) working accuracy is high Because it for the multiple spindle parallel organization composition, six expandable pole poles long alone has an effect to cutting tool's position and the posture, thus does not have the traditional engine bed (i.e. connects engine bed) the geometrical error accumulation and the enlargement phenomenon, even also has the being uniform effect (averaging effect); It has the hot symmetrical structural design, therefore the thermal deformation is small; Therefore it has the high accuracy merit. (5) multi-purpose flexible Is convenient as a result of this engine bed organization simple control, easily according to processing object, but designs it the special purpose machine, simultaneously may also develop the general engine bed, with realizes the milling, boring, processings and so on grinding, but may also provide the essential measuring tool to compose it the measuring engine, realizes engine bed's multi-purpose. This will bring the very big application and the market prospect, has the very broad application prospect in the national defense and the civil aspect. (6) service life is long Because the stress structure is reasonable, the moving part attrition is small, and does not have the guide rail, does not have the iron filings either the refrigerant enters the guide rail interior to cause it to scratch, the attrition or the corrosion phenomenon. (7) Stewart platform suits in the modular production Regarding the different machine scope, only need change the connecting rod length and the contact position, maintains also easily, does not need to carry on part's remaking and to adjust, only need the new organization parameter input. (8) transformation coordinate system is convenient Because does not have the entity coordinate system, the engine bed coordinate system and the work piece coordinate system transform depend on the software to complete completely, is convenient. When the Stewart platform applies in the engine bed and the robot, may reduce the static error (, because high rigidity), as well as dynamic error (because low inertia). But Stewart the platform inferiority lies in its working space to be small, and it has the singular point limit in the working space, but the serial operation platform, the controller meets time the singular point, accountant will figure out the actuation order which the drive is unable to achieve to create the ning error, but the Stewart platform will lose the support partial directions in the strange position the strength or moment of force ability, will be unable to complete the constant load object. Figure 2a. A bipod PKM Figure 2b. A biglide PKM 2.2. Singularities The singular configurations (also called singularities) of a PKM may appear inside the workspace or at its boundaries. There are two types of singularities5. A configuration where a finite tool velocity requires infinite joint rates is called a serial singularity. A configuration where the tool cannot resist any effort and in turn, becomes uncontrollable, is called a parallel singularity. Parallel singularities are particularly undesirable because they induce the following problems: - a high increase in forces in joints and links, that may damage the structure, - a decrease of the mechanism stiffness that can lead to uncontrolled motions of the tool though actuated joints are locked. Figures 3a and 3b show the singularities for the biglide mechanism of Fig. 2b. In Fig. 3a, we have a serial singularity. The velocity amplification factor along the vertical direction is null and the force amplification factor is infinite. Figure 3b shows a parallel singularity. The velocity amplification factor is infinite along the vertical direction and the force amplification factor is close to zero. Note that a high velocity amplification factor is not necessarily desirable because the actuator encoder resolution is amplified and thus the accuracy is lower. Figure 3a. A serial singularity Figure 3b. A parallel singularity 2.3. Working and Assembly Modes A serial (resp. parallel) singularity is associated with a change of working mode6 (resp. of assembly mode). For example, the biglide has four possible working modes for a given tool position (each leg node point can be to the left or to the right of the intermediate position corresponding to the serial singularity, Fig. 4a) and two assembly modes for a given actuator joint input (the tool is above or below the horizontal line corresponding to the parallel singularity, Fig. 4b). The choice of the assembly mode and of the working mode may influence significantly the behaviour of the mechanism5. Figure 4a. The four working modes Figure 4b. The two assembly modes 3. PKMs AS ALTERNATIVE MACHINE TOOL DESIGNS 3.1. Limitations of Serial Machine Tools Today, newly designed machine tools benefit from technological improvements of components such as spindles, linear actuators, bearings. Most machine tools are based on a serial architecture (Figure 5), whose advantage is that input/output relations are simple. Nevertheless, heavy masses to be carried and moved by each axis limit the dynamic performances, like feed rates or accelerations. That is why machine tools manufacturers have started being interested into PKMs since 1990. 3.2. PKMs Potentialities for Machine Tool Design The low moving mass of PKMs and their good stiffness allow high feed rates (up to 100 m/min) and accelerations (from 1 to 5g), which are the performances required by High Speed Machining. PKMs are said to be very accurate, which is not true in every case4, but another advantage is that the struts only work in traction or compression. However, there are many structural differences between serial and parallel machine tools, which makes it hard to strictly compare their performances. 3.3. Problems with PKMs a) The workspace of a PKM has not a simple geometric shape, and its functional volume is reduced, compared to the space occupied by the machine7, as we can see on Fig. 5 Figure 5. Workspace sections of Tricept 805 b) For a serial mechanism, the velocity and force transmission ratios are constant in the workspace. For a parallel mechanism, in contrast, these ratios may vary significantly in the workspace because the displacement of the tool is not linearly related to the displacement of the actuators. In some parts of the workspace, the maximal velocities and forces measured at the tool may differ significantly from the maximal velocities and forces that the actuators can produce. This is particularly true in the vicinity of THE DESIGN OF PKMT USING KINETOSTATIC PERFORMANCE CRITERIA 5 singularities. At a singularity, the velocity, accuracy and force ratios reach extreme values. c) Calibration of PKMs is quite complicated because of kinematic models complexity8. 4. EXISTING PKMT DESIGNS In this section will be presented some existing PKMTs. 4.1. Fully Parallel Machine Tools What we call fully parallel machine tools are PKMs that have as many degrees of freedom as struts. On Fig. 7, we can see a 3-RPR fully parallel mechanism with three struts. Each strut is made of a revolute joint, a prismatic actuated joint and a revolute joint. Figure 6. 3-RPR fully parallel mechanism Fully PKMT with six variable length struts are called hexapods. Hexapods are inspired by the Gough Platform. The first PKMT was the hexapod “Variax” from Giddings and Lewis presented in 1994 at the IMTS in Chicago. Hexapods have six degrees of freedom. One more recent example is the CMW300, a hexapod head designed by the Compagnie Mécanique des Vosges (Figure 7) . Figure 7. Hexapod CMW 300 (perso.wanadoo.fr/cmw.meca.6x/6AXES.htm) Fully parallel machine tools with fixed length struts can have three, four or six legs. The Urane SX (Figures8 and 13) from Renault Automation is a three leg machine, whose tool can only move along X, Y and Z axes, and its architecture is inspired from the Delta robot9, designed for pick and place applications. The Hexa M from Toyoda is a PKMT with six fixed length struts (Figure 9). Figure 8. Renault automation Urane SX (from “Renault Automation Magazine”, n° 21, may 1999) Figure 9. Toyoda Hexa M (www.toyodakouki. co.jp) 4.2. Other Kinds of PKMT The Tricept 805 is a widely used PKMT with three variable length struts (Figures 5 and 10). The Tricept 805 has a hybrid architecture: a two degrees of freedom wrist serially mounted on a tripod architecture. Another non fully parallel MT is the Eclipse (Figure 11) from Sena Technology10, 11. The Eclipse is an overactuated PKM for rapid machining, capable of simultaneous five faces milling, as well as turning, thanks to the second spindle. Figure 10. Tricept 805 from Neos robotics (www.neosrobotics.com) Figure 11. The Eclipse, from Sena Technology (macea.snu.ac.kr/eclipse/homepage.html) 5. DESIGNING A PKMT 5.1. A Global Task Given a set of needs, the most adequate machine will be designed through a set of design parameters like the machine morphology (serial, parallel or hybrid kinematic structure), the machine geometry (link dimensions, joint orientation and joint ranges), the type of actuators (linear or rotative motor), the type of joints (prismatic or revolute), the number and the type of degrees of freedom, the task for which the machine is designed. These parameters must be defined using relevant design criteria. 5.2. Kinetostatic Performance Criteria are Adequate for the Design of PKMTs The only way to cope with problems due to singularities is to integrate kinetostatic performance criteria in the design process of a PKMT. Kinetostatic performance criteria evaluate the ability of a mechanism to transmit forces or velocities from the actuators to the tool. These kinetostatic performance criteria must be able to guaranty minimum stiffness, accuracy and velocity performances along every direction throughout the workspace of the PKMT. To reach this goal, we use two complementary criteria: the conditioning of the Jacobian matrix J of the PKMT, called conditioning index, and the manipulability ellipsoid associated with J12. The Jacobian matrix J relates the joint rates to the tool velocities. It also relates the static tool efforts to the actuator efforts. The conditioning index is defined as the ratio between the highest and the smallest eigenvalue of J. The conditioning index varies from 1 to infinity. At a singularity, the index is infinity. It is 1 at another special configuration called isotropic configuration. At this configuration, the tool velocity and stiffness are equal in all directions. The conditioning index measures the uniformity of the distribution of the velocities and efforts around one given configuration but it does not inform about the magnitude of the velocity amplification or effort factors. The manipulability ellipsoid is defined from the matrix (J JT)-1. The principal axes of the ellipsoid are defined by the eigenvectors of (J JT)-1 and the lengths of the principal axes are the square roots of the eigenvalues of (J JT)-1. The eigenvalues are associated with the velocity (or force) amplification factors along the principal axes of the manipulability ellipsoid. These criteria are used in Wenger13, to optimize the workspace shape and the performances uniformity of the Orthoglide, a three degree of freedom PKM dedicated to milling applications (Figure 12). Figure 12. A section of Orthoglide’s optimised workspace 5.3. Technical Problems If the struts of the PKMT are made with ballscrews, the PKMT accuracy may suffer from struts warping due to heating caused by frictions generated by ballscrews. This problem is met by hexapods designers that use ballscrews. Thus, besides manufacturing inaccuracies, the calibration of a PKMT will have to take into account dimensions variations due to dilatation. A good thermal evacuation can minimise the effects of heating. In case PKMT actuators are linear actuators, magnetic pollution has to be taken into account so that chips clearing out is not obstructed. One technique, used by Renault Automation for the Urane SX, is to isolate the tool from the mechanism. At last, choosing fixed length or variable length struts influence the behaviour of the machine. Actuators have to be mounted on the struts in case of variable length struts, which increases moved masses. Fixed length struts do not have this problem, and furthermore allow the use of linear actuators, that bring high dynamic performances. 6. CONCLUSIONS The aim of this article was to introduce a few criteria for the design of PKMTs, which may become interesting alternatives for High Speed Machining, especially in the milling of large parts made of hard material, or for serial manufacturing operations on aeronautical parts. Kinetostatic criteria seem to be well adapted to the design of PKMTs, particularly for the kinematic design and for the optimisation of the workspace shape, with regard to performances uniformity. The kinetostatic criteria have been used for the design of the Orthoglide, a three-axis PKMT developed at IRCCyN. A small scale prototype is under development. A five-axis PKMT will be derived from the Orthoglide. 設(shè)計(jì)并聯(lián)機(jī)床 使用kinetostatic標(biāo)準(zhǔn) 的表現(xiàn) http://arxiv.org/ftp/arxiv/papers/0705/0705.1038.pdf 1 介紹 多數(shù)工業(yè)機(jī)床有一個(gè)串行運(yùn)動(dòng)學(xué)架構(gòu)，這意味著每個(gè)軸進(jìn)行下列工作時(shí)，包括其執(zhí)行機(jī)構(gòu)和聯(lián)接點(diǎn)高速加工突出了一些弊端，例如架構(gòu)：較重的運(yùn)動(dòng)部件需要從機(jī)械結(jié)構(gòu)高剛度，以限制彎曲問(wèn)題，即降低機(jī)床精度，并限制動(dòng)態(tài)表現(xiàn)的曲線。 這就是為什么并聯(lián)機(jī)床吸引了越來(lái)越多的研究人員和公司，因?yàn)樗鼈儞?jù)稱提供了單獨(dú)的優(yōu)勢(shì)，如高結(jié)構(gòu)剛度和高動(dòng)態(tài)的能力。事實(shí)上，并聯(lián)安排的聯(lián)系，可提供更高的剛度和較低的誤差，減少慣性的影響。因此，并聯(lián)機(jī)床有更好的動(dòng)態(tài)性能。然而，設(shè)計(jì)一個(gè)并聯(lián)機(jī)床是一個(gè)艱巨的任務(wù)，在進(jìn)一步的研究之前，廣泛地在工業(yè)用途中的調(diào)研，是必不可少的。 許多標(biāo)準(zhǔn)要考慮到在設(shè)計(jì)一個(gè)并聯(lián)機(jī)床。我們要特別注意描述并聯(lián)機(jī)床標(biāo)準(zhǔn)依賴于現(xiàn)有的雅可比矩陣的機(jī)制。該組織的這份文件具體內(nèi)容如下：未來(lái)介紹總論約并聯(lián)機(jī)床，那就是解釋了為什么并聯(lián)機(jī)床是不可替代機(jī)床的設(shè)計(jì)。一個(gè)設(shè)計(jì)中的應(yīng)用了一次小規(guī)模的機(jī)床樣機(jī)研制irccyn。 2 關(guān)于并聯(lián)機(jī)床 2.1 總論 第一次工業(yè)應(yīng)用并聯(lián)機(jī)床是The Gough平臺(tái)（圖1 ） 設(shè)計(jì)于1957年，以測(cè)試tyres1 。并聯(lián)機(jī)床當(dāng)時(shí)已使用多年，在飛行模擬器和機(jī)器人applications2因?yàn)樗麄兊牡鸵苿?dòng)質(zhì)量和高動(dòng)態(tài)表演。由于發(fā)展的高速切削加工，并聯(lián)機(jī)床已成為有趣的替代機(jī)床。 圖1 The Gough platform 隨著高速切削的不斷發(fā)展，傳統(tǒng)串聯(lián)式機(jī)構(gòu)構(gòu)造平臺(tái)的結(jié)構(gòu)剛性與移動(dòng)臺(tái)高速化逐漸成為技術(shù)發(fā)展的瓶頸，而并聯(lián)式平臺(tái)便成為最佳的候選對(duì)象，而相對(duì)于串聯(lián)式機(jī)床來(lái)說(shuō)，并聯(lián)式工作平臺(tái)具有如下特點(diǎn)和優(yōu)點(diǎn)： (1) 結(jié)構(gòu)簡(jiǎn)單、價(jià)格低 機(jī)床機(jī)械零部件數(shù)目較串聯(lián)構(gòu)造平臺(tái)大幅減少，主要由滾珠絲杠、虎克鉸、球鉸、伺服電機(jī)等通用組件組成，這些通用組件可由專門廠家生產(chǎn)，因而本機(jī)床的制造和庫(kù)存成本比相同功能的傳統(tǒng)機(jī)床低得多，容易組裝和搬運(yùn)。 (2) 結(jié)構(gòu)剛度高 由于采用了封閉性的結(jié)構(gòu)(closed-loop structure)使其具有高剛性和高速化的優(yōu)點(diǎn)，其結(jié)構(gòu)負(fù)荷流線短，而負(fù)荷分解的拉、壓力由六只連桿同時(shí)承受，以材料力學(xué)的觀點(diǎn)來(lái)說(shuō)，在外力一定時(shí)，懸臂量的應(yīng)力與變形都最大，兩端插入(build-in)次之，再來(lái)是兩端簡(jiǎn)支撐(simply-supported)，其次是受壓的二力結(jié)構(gòu)，應(yīng)力與變形都最小的是受張力的二力結(jié)構(gòu)，故其擁有高剛性。其剛度重量比高于傳統(tǒng)的數(shù)控機(jī)床。 (3) 加工速度高，慣性低 如果結(jié)構(gòu)所承受的力會(huì)改變方向，(介于張力與壓力之間)，兩力構(gòu)件將會(huì)是最節(jié)省材料的結(jié)構(gòu)，而它的移動(dòng)件重量減至最低且同時(shí)由六個(gè)致動(dòng)器驅(qū)動(dòng)，因此機(jī)器很容易高速化，且擁有低慣性。 (4) 加工精度高 由于其為多軸并聯(lián)機(jī)構(gòu)組成，六個(gè)可伸縮桿桿長(zhǎng)都單獨(dú)對(duì)刀具的位置和姿態(tài)起作用，因而不存在傳統(tǒng)機(jī)床(即串聯(lián)機(jī)床)的幾何誤差累積和放大的現(xiàn)象，甚至還有平均化效果(averaging effect)；其擁有熱對(duì)稱性結(jié)構(gòu)設(shè)計(jì)，因此熱變形較?。还仕哂懈呔鹊膬?yōu)點(diǎn)。 (5) 多功能靈活性強(qiáng) 由于該機(jī)床機(jī)構(gòu)簡(jiǎn)單控制方便，較容易根據(jù)加工對(duì)象而將其設(shè)計(jì)成專用機(jī)床，同時(shí)也可以將之開發(fā)成通用機(jī)床，用以實(shí)現(xiàn)銑削、鏜削、磨削等加工，還可以配備必要的測(cè)量工具把它組成測(cè)量機(jī)，以實(shí)現(xiàn)機(jī)床的多功能。這將會(huì)帶來(lái)很大的應(yīng)用和市場(chǎng)前景，在國(guó)防和民用方面都有著十分廣闊的應(yīng)用前景。 (6) 使用壽命長(zhǎng) 由于受力結(jié)構(gòu)合理，運(yùn)動(dòng)部件磨損小，且沒(méi)有導(dǎo)軌，不存在鐵屑或冷卻液進(jìn)入導(dǎo)軌內(nèi)部而導(dǎo)致其劃傷、磨損或銹蝕現(xiàn)象。 (7) Stewart平臺(tái)適合于模塊化生產(chǎn) 對(duì)于不同的機(jī)器加工范圍，只需改變連桿長(zhǎng)度和接點(diǎn)位置，維護(hù)也容易，無(wú)須進(jìn)行機(jī)件的再制和調(diào)整，只需將新的機(jī)構(gòu)參數(shù)輸入。 (8) 變換座標(biāo)系方便 由于沒(méi)有實(shí)體座標(biāo)系，機(jī)床座標(biāo)系與工件座標(biāo)系的轉(zhuǎn)換全部靠軟件完成，非常方便。 Stewart平臺(tái)應(yīng)用于機(jī)床與機(jī)器人時(shí)，可以降低靜態(tài)誤差(因?yàn)楦邉傂?，以及動(dòng)態(tài)誤差(因?yàn)榈蛻T量)。而Stewart平臺(tái)的劣勢(shì)在于其工作空間較小，且其在工作空間上有著奇異點(diǎn)的限制，而串聯(lián)工作平臺(tái)，控制器遇到奇異點(diǎn)時(shí)，將會(huì)計(jì)算出驅(qū)動(dòng)裝置無(wú)法達(dá)成的驅(qū)動(dòng)命令而造成控制誤差，但Stewart平臺(tái)在奇異位置會(huì)失去支撐部分方向的力或力矩的能力，無(wú)法完成固定負(fù)載對(duì)象。 在并聯(lián)機(jī)床，工具是以底座作為支撐做伸縮性運(yùn)動(dòng)，下圖為伸縮運(yùn)動(dòng)簡(jiǎn)圖。一