大型軸齒輪專用機(jī)床設(shè)計(jì)圖,大型,齒輪,專用,機(jī)床,設(shè)計(jì)圖 攀枝花學(xué)院 機(jī) 電 工 程 學(xué)院學(xué)生 畢業(yè)設(shè)計(jì)(論文) 題 目：大型軸齒輪專用機(jī)床設(shè)計(jì) 指導(dǎo)教師：周 汝 忠（教授） 學(xué)生姓名：肖 靜 年級專業(yè)：2001級機(jī)械設(shè)計(jì)制造及自動化 2005年 6 月 17 日 摘要：結(jié)合機(jī)電一體化的需要，設(shè)計(jì)以單片機(jī)作為控制系統(tǒng)的X-Y型工作臺。通過對X-Y型工作臺機(jī)械結(jié)構(gòu)設(shè)計(jì)和控制電路接口的設(shè)計(jì)，闡述了機(jī)電一體化設(shè)計(jì)中的共性和關(guān)鍵技術(shù)。這種工作臺通常與整機(jī)設(shè)計(jì)成一個整體，其形狀，尺寸，結(jié)構(gòu)因機(jī)器類型不同而有較大差異，但其工作原理有著共同點(diǎn)。 關(guān)鍵詞：X-Y數(shù)控十字滑臺；機(jī)電一體化；單片機(jī) Abstract : Combine mechanical-electrical integration’s need, design a Model X-Y workingbench with one-chip computer as the of the control system. Though describing the workingbench mechanical’s design of structure and interface of the control circuit to Model X-Y, have explained generality in the design of mechanical-electrical integration and its key technology. This kind of workingbench is usually designed with the complete machine into a whole , its form , size, there is a greater difference because types of the machine are different in the structure, but its operation principle has common point. Keywords: X-Y numerical control cross slippery platform; The mechanical-electrical integration; One-chip computer 計(jì)算機(jī)輔助制造 1.緒論 當(dāng)今的工業(yè)的競爭已經(jīng)是真正意義上的國際市場競爭。 高效的運(yùn)輸網(wǎng)絡(luò)建立了一個我們每天都要參與的 “世界市場”。 對于任何工業(yè)化國家要參與這個市場競爭，就必須采用一種適時的方式為其客戶提供經(jīng)濟(jì)、優(yōu)質(zhì)的產(chǎn)品。將產(chǎn)品設(shè)計(jì)和過程設(shè)計(jì)進(jìn)行集成的重要性，在產(chǎn)品系統(tǒng)被怎么強(qiáng)調(diào)都不為過。但是， 即使一種設(shè)計(jì)最終被落實(shí)， 制造業(yè)者一定愿意通過允許最后的工程設(shè)計(jì)變化，而沒有通過影響裝運(yùn)進(jìn)度表，或者改變產(chǎn)品質(zhì)量來適應(yīng)他們的用戶。 大多數(shù)美國的生產(chǎn)公司基于趨向計(jì)算機(jī)輔助設(shè)計(jì)（CAD）/計(jì)算機(jī)輔助制（CAM）和CIM為他們的制造系統(tǒng)提供靈活性。今天，計(jì)算機(jī)用于制造已經(jīng)很平?！，F(xiàn)在不僅為零件生產(chǎn)設(shè)計(jì)制造系統(tǒng)，而且為零件從一臺機(jī)器運(yùn)送到另一臺機(jī)器的命令順序設(shè)計(jì)了制造系統(tǒng)，如圖（1），它還包含一個經(jīng)濟(jì)區(qū)域的制造經(jīng)濟(jì)計(jì)劃在美國和其他國家，手工產(chǎn)品總是還有一些市場的，此外真正的工業(yè)產(chǎn)品對于特殊的“one-of-a-kind”技術(shù)項(xiàng)目還是需要的?！皁ne-of-a-kind”通過大量的貨物來表明、各種各樣的工業(yè)需要各種各樣的加工方法。 有些系統(tǒng)將看起來像我們的祖父母曾經(jīng)工作過的工廠，而其它則呈現(xiàn)出一種未來派的情景。在后文中，我們將展開討論柔性制造系統(tǒng)。 圖（1） 2.柔性制造系統(tǒng) 柔性制造系統(tǒng)（FMS）像人們通常知道的那樣的，能使用一個可編程的制造系統(tǒng)自動地生產(chǎn)各種各樣的產(chǎn)品。 自從亨利·福特率先提出并且使流水生產(chǎn)線實(shí)現(xiàn)現(xiàn)代化，我們就已經(jīng)能自動執(zhí)行多種生產(chǎn)的生產(chǎn)。 不過，改變這些系統(tǒng)甚至只作較小的變動，這些產(chǎn)品的生產(chǎn)都會變得相當(dāng)繁重。 當(dāng)其他機(jī)器或者零部件要經(jīng)過修理或者廢棄，以適應(yīng)這種蕭蕭的變化，整個機(jī)器才可能被引進(jìn)到系統(tǒng)。 在今天的競爭性市場里，能適應(yīng)客戶的各種變化是很必要的。傳統(tǒng)的制造系統(tǒng)以特征可劃分為以下兩種： 1.加工車間類型系統(tǒng)能生產(chǎn)多種產(chǎn)品，但是費(fèi)用高。 2.流水線能以合理費(fèi)用生產(chǎn)能大量產(chǎn)品， 但是僅局限于幾種不同零件的生產(chǎn)。 數(shù)控(NC)和機(jī)器人技術(shù)的時代已經(jīng)來臨，這為我們提供了在最小準(zhǔn)備時間里，使機(jī)器的程序重新調(diào)定。NC機(jī)床和機(jī)器人是重新可編程序的制造系統(tǒng)的基本物理組成部分。 2.1.柔性制造系統(tǒng)的設(shè)備 2.1.1機(jī)床 為了滿足柔性制造系統(tǒng)定義的要求，該系統(tǒng)的基本工藝應(yīng)實(shí)現(xiàn)自動化。因?yàn)樽詣踊仨毷强删幊痰模赃m應(yīng)不同的產(chǎn)品要求，而易于改變，以及通用機(jī)床必須執(zhí)行這些工藝。計(jì)算機(jī)數(shù)控（CNC）車削中心、計(jì)算機(jī)數(shù)控（CNC）加工中心、及機(jī)器人工作站構(gòu)成了這些設(shè)備。這些機(jī)器不僅僅是易于重新編程，同時也適應(yīng)置于刀具存儲系統(tǒng)及刀具更換器中的不同刀具。通常CNC加工中心備有60多把或更多刀具（銑刀、鉆頭、鏜刀等）。對于CNC車削中心，備有12把或更多的刀具（右車刀、左車刀、鏜桿、鉆頭等）。書動機(jī)床的自動換刀器及刀庫使它們對材料的工藝裝備作出自然的選擇。 零件必須在加工站點(diǎn)之間自動化的移動，采用了數(shù)種不同的物料輸送系統(tǒng)，把這些零件從一個站點(diǎn)輸送到另一個站點(diǎn)。物料輸送系統(tǒng)的選擇是數(shù)種系統(tǒng)特征函數(shù)。首先，物料輸送系統(tǒng)的選擇必須適應(yīng)零件（或許是零件的夾具）的負(fù)荷及批量。大型的、重型的零件需要大型的、強(qiáng)力的輸送系統(tǒng)，如滾子輸送、導(dǎo)向小車、軌道驅(qū)動車輛系統(tǒng)。構(gòu)成的機(jī)床數(shù)量及機(jī)床布置也提供了另一種設(shè)計(jì)上的考慮。如果用單一的物料輸送機(jī)來運(yùn)送零件到系統(tǒng)內(nèi)的所有機(jī)床，則運(yùn)輸機(jī)的工作覆蓋面至少必須是和整個系統(tǒng)一樣大。通常一臺機(jī)器人定位于一兩臺機(jī)床或一個裝卸站。一臺輸送機(jī)或自動導(dǎo)向車可以擴(kuò)大到數(shù)英里的工廠區(qū)域。物料輸送也可以以即時的方式將零件從一臺機(jī)床輸送到另一臺機(jī)床。如果系統(tǒng)內(nèi)的機(jī)床耗費(fèi)大量的時間在等待輸送零件的到來，則其生產(chǎn)率是不會高地。如果有許多種零件包括在系統(tǒng)內(nèi)，而且這些零件要經(jīng)常輸送到機(jī)床上，物料系統(tǒng)要能夠支持這些活動。通常由采用極快的輸送裝置或靠平行地使用幾種裝置來實(shí)現(xiàn)。例如：用一臺機(jī)器人支持一臺機(jī)床，而不是用一臺機(jī)器人運(yùn)送零件到系統(tǒng)內(nèi)的所有機(jī)床。 2.1.2刀具及夾具 用途多樣性是柔性制造系統(tǒng)的關(guān)鍵，由此，在系統(tǒng)中使用的刀具必須能夠支持多種零件及產(chǎn)品的生產(chǎn)。在柔性制造系統(tǒng)中，使用專用的或成型刀具并不典型。使用成型刀具得到輪廓，通?？梢酝ㄟ^輪廓書空系統(tǒng)或標(biāo)準(zhǔn)的銑刀得到。標(biāo)準(zhǔn)的銑刀可以用于各種不同的零件而不是只能加工單一的輪廓。使用任何專用刀具其利潤和成本的經(jīng)濟(jì)分析都是必須的，以確定最佳的刀具組合。然而，因書空機(jī)床僅有有限數(shù)量的刀具可供存取，極少數(shù)的刀具應(yīng)當(dāng)包括在內(nèi)。 柔性制造系統(tǒng)通常容易忽視的一個方面是所使用的夾具。因?yàn)閵A具是系統(tǒng)中工具的一部分。人們會爭議這樣一個事實(shí)，對系統(tǒng)中的夾具也應(yīng)標(biāo)準(zhǔn)化。工件裝在創(chuàng)制出的“柔性夾具”中，這種僅在幾年前才開始使用的夾具可以支持多種零件。許多柔性制造系統(tǒng)的獨(dú)特方面是零件裝在夾具（或隨行夾具）中而在系統(tǒng)中運(yùn)動，夾具做成相同的尺寸，這樣物料輸送系統(tǒng)可以專門化去輸送單一的幾何形體，零件精確的定位在夾具上，同時隨同夾具從一個站點(diǎn)運(yùn)動大另一個站點(diǎn)。這種類型的夾具，通常稱為隨行夾具。現(xiàn)在所應(yīng)用的許多隨行夾具都加工出標(biāo)準(zhǔn)的T型槽，同時使用標(biāo)準(zhǔn)的夾具組件創(chuàng)建出適應(yīng)于切削加工的零件的定位及夾緊的條件。 3.柔性制造系統(tǒng)的計(jì)算機(jī)控制 3.1 FMS構(gòu)架 FMS是一個必須被通過一臺計(jì)算機(jī)或者計(jì)算機(jī)網(wǎng)絡(luò)控制的設(shè)備和過程的復(fù)雜的網(wǎng)絡(luò)。 為了使控制FMS的任務(wù)更易處理，系統(tǒng)通常被分成一個個基于任務(wù)的階層。 已經(jīng)逐步成的標(biāo)準(zhǔn)之一的是國家標(biāo)準(zhǔn)與技術(shù)局(NIST)工廠控制階層。 (NIST以前叫國家標(biāo)準(zhǔn)局， NBS.) 這個階層由5 步組成， 在圖（2）表示了系統(tǒng)由物質(zhì)機(jī)器加工設(shè)備，圖（3）系統(tǒng)的最低的組成部分。 工作站設(shè)備恰好處于過程水平面存在并且起著預(yù)防綜合和設(shè)備接口的作用。 例如棘瓜固定設(shè)備和編程要素也是工作站的一部分。 工作站通常提供人力機(jī)器接口和機(jī)器零件接口。 而脫機(jī)程序適合NC那種易于AML給機(jī)器人工作的工作站水平。 小屋是在在機(jī)器之間的相互作用階層的單位，并成為系統(tǒng)的一部分。 小屋控制器提供了那些機(jī)器和物質(zhì)處理系統(tǒng)之間的接口。 照此，小屋控制器負(fù)責(zé)系統(tǒng)的排序和調(diào)度部分。車間水平的集成和多房間重現(xiàn)生成了存貨清單的計(jì)劃和管理。 圖（2） 圖（3） 3.2 FMS安排和控制 柔性制造系統(tǒng)，像其他制造系統(tǒng)一樣，能區(qū)別出零件之間較大的復(fù)雜性。 這復(fù)雜性不僅包括系統(tǒng)中機(jī)器的數(shù)量和確定的數(shù)量， 而且包括那些復(fù)雜性的部分和控制要求的那些具體設(shè)備。一些FMS只要求有一個簡單的可編程控制器就行了，而其它的還要求有復(fù)雜的計(jì)算機(jī)控制系統(tǒng)。在以后的章節(jié)里，還要提出一些FMS及其控制的例子。 最簡單的FMS由一臺處理器、裝載/卸載區(qū)域和原料處理機(jī)(一個最簡單的FMS可以只由一臺機(jī)器構(gòu)成)。 這系統(tǒng)的操作包括了往下的一個傳輸裝置。一旦零件被裝到機(jī)器上，機(jī)器人縮回到一個“安全的位置”，然后機(jī)器開始加工。 雖然這是一個非常簡單的系統(tǒng)，但是它例舉了幾種有趣的設(shè)計(jì)和必須考慮的控制部件。如果在系統(tǒng)中，只有一個部分在運(yùn)作，那么系統(tǒng)就只需要最小數(shù)量的開關(guān)和傳感器。系統(tǒng)所需要的是，所有傳輸帶上的零件使用同樣的方法定位。這還需要使機(jī)器人每一次都用同樣的定位方法能讓把零件裝在到數(shù)控機(jī)床上。在輸送裝置的末端發(fā)現(xiàn)有零件已到達(dá)的時候，需要一個行程或者微開關(guān)。 Integrated Computer Aided Manufacturing 1.INTRODUCTION Today’s industry competes in a truly international marketplace. Efficient transportation networks have created a “world market” in which we participate on a daily basis. For any industrial country to compete in this market, it must have companies that provide economic high-quality products to their customers in a timely manner. The importance of integrating product design and process design to achieve a design for production system cannot be overemphasized. However, even once a design is finalized, manufacturing industries must be willing to accommodate their customers by allowing last-minute engineering-design changes without affecting shipping schedules or altering product quality. Most U.S.-based manufacturing companies look toward CAD/CAM and CIM to provide this flexibility in their manufacturing system . Today ,the use of computers in manufacturing is common . Manufacturing system are being designed that not only process parts automatically ,but also move the parts from machine to machine and sequence the ordering of operations in the system.（ Figure 1） contains a plot of the economic regions of manufacturing. It should be noted that manual handcrafted goods will always have a market in the United States as well as abroad. This is also true of industrial products—there will continue to be a need for special one-of-a-kind items. The spectrum of one-of-a-kind goods through high-volume goods dictates that a variety of manufacturing methods be used to meet our various industrial needs. Some of these systems will look like the factories that our grandparents labored in, whereas others will take on a futuristic look. In the following sections, a discussion of flexible manufacturing systems is presented. Figure 1 Volume versus variety regions for economic manufacturing 2.FLEXIBLE MANUFACTURING SYSTEMS A flexible manufacturing system, or FMS as they are more commonly known, is a reprogram-able manufacturing system capable of producing a variety of products automatically. Since Henry Ford first introduced and modernized the transfer line, we have been able to perform a variety of manufacturing operations automatically. However, altering these systems to accommodate even minor changes in the product has been quite taxing. Whole machines might have to be introduced to the system while other machines or components are modified or retired to accommodate small changes in a product. In today’s competitive marketplace ,it is necessary to accommodate customer changes or the customer will find someone else who will accommodate the changes. Conventional manufacturing system s have been marked by one of two distinct features: 1. Job shop type systems were capable of producing a variety of product ,but at a high cost. 2. Transfer lines could produce large volumes of a product at a reasonable cost, but were limited to the production of one ,two, or very few different parts. The advent of numerical control (NC) and robotics has provided us with reprogramming capabilities at the machine level with minimum setup time. NC machines and robots provide the basic physical building blocks for re-programmable manufacturing systems. 2.1.FMS Equipment 2.1.1Machines In order to meet the requirements of the definition of an FMS, the basic processing in the system must be automated. Because automation must be programmable in order to accommodate a variety of product-processing requirements, easily alterable as well as versatile machines must perform the basic processing. For this reason, CNC turning centers, CNC machining centers, and robotic workstations comprise the majority of equipment in these systems. These machines are not only capable of being easily reprogrammed, but are also capable of accommodating a variety of tooling via a tool changer and tool-storage system. It is not unusual for a CNC machining center to contain to 12 or more tools (right-hand turning tools, left-hand turning tools ,boring bars, drills ,and so on ) . The automatic tool changer and storage capabilities of NC machines make them natural choices for material-processing equipment. Parts must also be moved between processing stations automatically. Several different types of material-handling systems are employed to move these parts from station to station. The selection of the type of material-handling system is a function of several system features. The material-handling system, first, must be able to accommodate the load and bulk of the part and perhaps the part fixture. Large, heavy parts require large , powerful handling systems such as roller conveyors guided vehicles or track-driven vehicle systems. The number of machines to be included in the system and the layout of the machines also present another design consideration. If single material handler must be at least as large as the physical system. A robot is normally only capable of addressing one or two machines and load-and-unload station. A conveyor or automatic guide vehicle(AGV) system can be expanded to include miles of factory floor. The material-handling system must also be capable of moving parts from one machine to another in a timely manner. Machines in the system will be unproductive if they spend much of their time waiting for parts to be delivered by the material handler. If many parts are included in the system and they require frequent visits to machines, then the material-handling system must be capable of supporting these activities. This usually can be accommodated by using either a very fast handling device of by using several devices in parallel, for example, instead of using a single robot to move parts to all the machines in the system, a robot would only support a single machine. 2.1.2 Tooling and fixtures. Versatility is the key to most FMSs, and as such the tooling used in the system must be capable of supporting a variety of products or parts. The use of special forming tools in an FMS is not typical in practice. The contours obtained by using forming tools can usually be obtained through a contour-control NC system and a standard mill. The standard mill then can be used for a variety of parts rather than to produce a single special contour. An economic of the cost and benefits of any special tooling is necessary to determine the best tooling combination. However, because NC machines have a limited of tools that are accessible, very special tools should be included. One of the commonly neglected aspects of an FMS is the fixturing used. Because fixtures are part of the tooling of the system, one could argue that they should also be standard for the system. Work on creating “flexible fixtures” that could be used to support a variety of components has only recently begun. See Chapter 5.One unique aspect of many FMSs is that the part is also moved about the system in the fixture (or pallet fixture). Fixtures are made to the same dimensions so that the material-handling system can be specialized to handle a single geometry. Parts are located precisely on the fixture and moved from one station to another on the fixture. Fixtures of this type are usually called pallet fixtures, or pallets. Many of the pallet fixtures employed today have standard “T-slots” cut in them, and use standard fixture kits to create the part-locating and-holding environment need for machining. 3.COMPUTER CONTROL OF FLEXIBLE MANUFACTURING SYSTEMS 3.1 FMS Architecture An FMS is a complex network of equipment and processes that must be controlled via a computer or network of computers. In order to make the task of controlling an FMS more tractable, the system is usually divided into a task-based hierarchy. One of the standard hierarchies that have evolved is the National Institute of Standards and Technology(NIST) factory-control hierarchy. (NIST was formerly the National Bureau of standards. NBS.) This hierarchy consists of five levels and is illustrated in Figures 2 and Figures 3 The system consists of physical machining equipment at the lowest level of the system. Workstation equipment resides just above the process level and provides integration and interface functions for the equipment. For instance pallet fixtures and programming elements are part of the workstation. The workstation typically provides both man-machine interface as well as machine-part interface. Off-line programming such as APT for NC or AML for robot resides at the workstation level. The cell is the unit in the hierarchy where interaction between machines becomes part of the system. The cell controller provides the interface between the machines and material-handling system. As such ,the cell controller is responsible for sequencing and scheduling parts through the system. At the shop level integration of multiple cells occurs as well as the planning and management of inventory. The Fig2 Figure 3 The relationship between the data-administration (DAS) in the NIST architecture :(1)the topologies of the Integrated Manufacturing Data Administration System(IMDAS) data-administration system;(2)the net work data-communication network; (3)the hierarchical system of data-driven control: data preparation is implied in (4) the facility level of control facility level is the place in the hierarchy where the master production schedule is constructed and manufacturing resource planning is conducted. Ordering materials planning inventories and analyzing business plans are part of the activities that affect t he production system. Poor business and manufacturing plans will incapacitate the manufacturing system just as surly the unavailability of a machine. 3.2 FMS Scheduling and control Flexible manufacturing systems, like other manufacturing system can differ significantly complexity . This complexity is not only determined by the number of machines and the number of parts resident in the system, but also by the complexity of parts and control requirements of the specific equipment . Some FMSs require only a simple programmable controller to regulate the flow of parts though the system, whereas others require sophisticated computer control systems. In the following sections , example of FMSs and their control are presented. The most simple FMS consists of a processing machine, a load/unload area, and a material handler (a one-machine system is the most simple FMS that can be constructed ). Operation of this system consists of loading the part(s) that move down a conveyor the machine. Once the part is loaded onto the machine , the robot is retracted to a “safe position” and the machining begins. Although this is a very simple system, it illustrates several interesting design and control decisions that must be considered. If only a single part is to be processed in the system, a minimum number of switches and sensors necessary for the system. One requirement of the system is that the parts on the conveyor all have to be oriented in the same way. This is required so that the robot can pick up the part and deliver it to the NC machine in the same orientation every time. A proximity switch or micro-switch is required at the end of the conveyor to detect when a part is resident.