组合机床毕业设计外文翻译

外文资料The aggregate machine-tool CAD system development and research Abstract aggregate machine-tool CAD is in Window 95/98, Wndows under the NT4.0 environment, designs personnel's special-purpose CAD system with VC5.0 and the AutoCAD R14 ADS/ARX technology development face the aggregate machine-tool.This software technological advance, performance reliable, function strong, convenient practical, has provided the modernized design tool for our country aggregate machine-tool profession.Key word: Aggregate machine-tool CAD jig CAD multi-axle-box CAD1 uses the aggregate machine-tool CAD technology imperative The aggregate machine-tool is with according to serialized, the standardized design general part and the special purpose machine which composes according to the work piece shape and the processing technological requirement design special-purpose part, belongs to the disposable design, the disposable manufacture piecework product.Therefore, the design quantity is big, the design work is complex.In thecurrent competition intense market economy, the user to the engine bed technical sophistication, the quality reliability as well as the goods supply cycle all requests very high, but guaranteed these many factors the key is the design. In the past that backward manual design method has not been able to satisfy the product design the request, uses the CAD technology, throws off the chart board, has become the current technological revolution the tidal current, imperative.2 aggregate machine-tool CAD the application present situation Overseas aggregate machine-tool CAD technology research starts the comparison early.At the beginning of the 70's, some industry developed country first starts in the multi-axle-box CAD aspect to study. Has entered since in particular for the 90's, along with the computer technology development, the interactive cartography and the database management system and so on the development and the application, causes the aggregate machine-tool CAD technology day by day practical also the use scope expands unceasingly, the developed country has used the CAD technology generally in the aggregate machine-tool design.At present, to CAD/CAM integrative system development. In recent years, according to us to American several main engine bed factories (BURGMAST, KINGSBURY, companies and so onINGERSOLL LAMB, CINCINNATI, MILACRON, CROSS) the understanding, its CAD technology obtained the universal application. In which most noticeable is INGERSOLL Corporation has 50 interactive CAD workstation composition software and hardware environment, caused it to realize nearly 100% CAD.On the domestic machine tool design portfolio using CAD understanding earlier. The beginning of the 1970s, Dalian Machine Tool Institute portfolio started on the research in this area of work. 1978 state as a combination of mechanical CAD machine industrial projects, and instructed the Shanghai Jiaotong University. Dalian Machine Tool Institute portfolio, a ministry official in charge of the Institute of Automation, Dalian Polytechnic University, Qinghua University, Beijing University of Technology, Shanghai Institute of mechanical and electrical products and other units to participate in the drilling machine CAD combination of research, This raised our portfolio Machine CAD technology in the district. After 10 years of efforts and achieved initial results.However, the combination of machine CAD system is 12-27 in VAX II and Micro VAX II on the development, hardware investment, which is difficult to use. By the time the hardware and software environment for the restrictions, narrow scope of applicationsoftware, users inconvenient.3 Development portfolio dedicated machine CAD system software CAD technology is the contemporary electronic information technology an important component of , CAD technology to be commercialized as the most important high-tech industries. The supporting software and hardware, on the basis of different industries, different professions secondary development software, developed for the industry, The dedicated professional commercial software can not only make good economic returns, but will make significant social benefits. "Ninth Five-Year Plan" period state auto industry as a pillar industry of the national economy, for the industry to provide a combination of technologies and equipment to machine tool industry to develop rapidly. Along with the development of the auto industry, machine designed to enhance portfolio quality, shorten the design cycle has become an extremely urgent task. Combined Machine CAD technology and can shorten the design cycle and improve design quality, enterprises in the sector improve its competitive edge, enterprises will bring about significant economic benefits.Dalian is China's important industrial base, as a combination of Machine Tool Industry Technology and Development Center inDalian Machine Tool Institute portfolio, industry should play the leading role for the realization of design automation, enhance technological innovation and product competitiveness. promoting our portfolio machine design standards, as soon as possible combination of machine tool industry to provide factory-functional, flexible operation, with a friendly interface, high technological content portfolio Machine CAD software.4 software with the technical basis for the development of microelectronicsTechnology, computer performance has been greatly improved. P II has now dominated the market, P III began listing its CPU performance has been close to the years before the target workstation. Foreign CAD software to the PC Window95/98, Windows NT transplant, such as Pro / Engineer, I-Sui, such as CADDS5. Computer Graphics Accelerator in improving performance, the entity can basically the movement and rotation. PC CAD is a development direction, the corresponding hardware to lower than many workstations. After years of efforts, we use Windows SDK software development technology, Windows environment more dynamic process of technical data exchange (DDE). Database technique (ODBC), Graphics software technology and thedevelopment of secondary targets OLE technology (OLE), Development of a generic combination of mechanical CAD and CAD machine integrated CAD system. 5 Combination Machine CAD system softwarePortfolio Machine CAD system software using C + + language, in the Windows environment for the development of the combination of machine design parameters of the graphic information management system. Database systems with C + + language independent preparation of the financial database software and operating system parameters graphic systems into one. formed powerful parametric graphic information management system. Modular Machine CAD system including removable fixture CAD system, Modular Machine Automatic Line program 3D CAD graphics system, the total portfolio Machine CAD system, Portfolio Map Machine CAD systems and machine tool's multi-axle box CAD system.5.1 Combination fixture mechanical CAD system using parametric CAD graphics information management technology and interactive design methods, developed portfolio fixture CAD system, its widespread applicability, practical and promote the use of broad prospects. Combination fixture CAD system, in accordance with its main functions can be divided into four modules :Location Support System CAD system, Clamping CAD system, CAD-oriented systems and devices typical fixture clamping force of the computer-aided analysis and calculation.5.1.1 Location Support System CAD systems for supporting the system by positioning support, Auxiliary support and spacing element composition. Location Support refers to the processing maintain a certain position workpiece components; Auxiliary support is only for the processing of the rigidity and stability of an activity-supporting components. Building support plate, supporting block, ancillary support, fixed-pin, telescopic pin parametric graphics library and database performance through inquiries Location Support System database, Positioning support amending parameters graphic parameters, the use of interactive design method, positioning support CAD system.5.1.2 clamping CAD system clamping usually by clamping force, Transmission among agencies and clamping element is composed of three parts. Part of clamping force for the purpose of generating power source, and will pass on the middle forces drive; Middle drive as a Force that is, to change the direction of force and size, which can produce self-locking, to ensure that the processing power source or disappeared, the role of the workpiece in the cutting force despite reliable clamping;Clamping elements to bear by the middle of the drive transmission clamping force, and direct contact with the workpiece clamping action and implementation. Clamping established tank, clamping components, direct clamping bodies, self-locking clamping mechanism parameters of the graphics and performance database, Clamping inquiries by the Performance database changes clamping mechanism parameters graphic parameters, the use of interactive design, Clamping achieve CAD.5.1.3 device-oriented CAD system installation guide role is to ensure that the tool and workpiece and the tool of inter - The exact location, raising tool system supports rigid. Correct selection, design-oriented devices, assurance of the accuracy and processing of reliable machine plays an important role in the work. Establish a fixed-oriented packages, "roll-forward" - oriented devices, , "roll-forward" device parameters oriented graphics library and database performance through inquiry-oriented device performance database, revised guidance device parameters graphic parameters, the use of interactive design method, CAD-oriented devices.5.1.4 typical fixture clamping force computer-aided analysis and calculation of the machine to ensure normal reliableworking conditions, the clamping force the smaller the better. If blindly increasing the clamping force, which will result in the following consequences : increased fixture drive size; To improve clamping force and linked to the fixture so rigid fixture is too big; increase the clamping of the workpiece in the deformation and effects processing accuracy. Therefore, the right to determine clamping force is important. Typical fixture clamping force computer-aided analysis and calculation : the clamping screw clamping force analysis and calculation Wedge Clamp the clamping force analysis and calculation, the eccentric clamping clamping force analysis and calculation Clamping other agencies clamping force analysis and calculation.Combination fixture interactive CAD system design methods, the use of flexible, widespread applicability, meet all the technical requirements. Fixture system through the establishment of various components of the graphics library, parts of the parameters of graphics library, Parameter graphics information management system, interactive mapping portfolio fixture.5.2 Combination Machine automatic alignment options CAD 3D graphics system, the total portfolio Machine CAD system,Portfolio Map Machine CAD System 5.2.1 portfolio automatic alignment machine 3D graphics CAD System The CAD system can automatically determine portfolio machine line, drawing portfolio machine automatically 3D graphics, Universal Machine portfolio management structure and performance parts database. This three part by the three independent process to achieve, Using Windows environment more dynamic process of technical data exchange (DDE). achieving three independent process dynamic data exchange, completed the following types of machine configuration combinations Machine Design : more horizontal axle box processing, multi-axle box vertical machining, multi-axle box tilt-processing, the first Horizontal Boring processing, Boring first vertical machining, boring head tilted machining, drilling the first horizontal machining, drilling the first vertical machining, Drilling of the first tilt-processing, tapping the first horizontal machining, the first vertical machining tapping, tapping the first tilt-processing, Milling of the first horizontal machining, milling head vertical machining, milling machining head tilt.5.2.2 total portfolio Machine CAD system map total portfolio machine with automatic computer-aided design and human-computer design interactive design methods. Automaticdesign of the structure from the program to map out the final completion of a one-time, interactive design is user participation, choice of interactive components, models and determine a method of positioning. Combination machine is used by the serialization, standardized generic components and by the shape of the workpiece and the processing requirements of the dedicated parts of dedicated machine, thus Machine features that determine its computer-aided design methods. Its versatility to be completed by the computer, and a dedicated help from computer users to achieve, that is, to avoid the automatic design of the applicability of poor, narrow face design limitations. Total portfolio machine parameters graphic information management system in Windows development environment of a human-machine interactive located Total system, which integrates the Windows SDK technology, Database technology and graphics software secondary development of the ADS technology, engineering design provides a very convenient, Efficient design of the machine tool map. The system is suitable for drilling, expansion joints, and tasty, boring, milling, etc. Tapping Machine processing, machine configuration form of single-position reclining, Li, tilt and composite portfolio machine, mobile work desktop machine combinations,combinations Rotary desktop machine.5.2.3 Combination Machine CAD system portfolio Map Machine Tool schematic design and adjustment team Machine for the important work of one of the drawings, is to identify combinations machine linked size, composition Machine Drawing the basis for the total. To accomplish drilling and reaming, boring, Reaming, Tapping and milling processes. Portfolio machining complex matrix. According to the development of the last 10 years combined experience in the CAD machine, the automated design, only a few input parameters will be completed portfolio Machining Map software, but the application of the matrix of small, have limitations. Combination Machine Map parameters graphic information management system software, interactive design, the use of flexible, widespread applicability, meet all the technical requirements. Combination Machine Map parameters graphic information management system from the main spindle and then leverage, the guidance sets, Tool database operating systems, the operating system parameters graphics, Interactive mapping system to determine composition and cutting machine usage module four components. Axlebox over5.3 CAD system more Axlebox CAD systemCAD system more Axlebox CAD system is a specialized applicationsoftware can be used for drilling and expansion. hinges, milling, drilling and thread offensive attack composite portfolio Machine Tool box design. System for the raw data from the combination of machine design, a plan that is three cards (workpiece map, processing matrix, Machine size map and the associated productivity calculation card), such as spindle coordinates, speed, and on this basis, interactive system to automatically or engaging in various types of work.5.3.1 Multi-axle box drive system design combinationMulti-axle box drive system design combination of multi-axle box machine drive system is a multi-axis, multi-gear, Multi-time complex transmission system. We have adopted a two-axis, three-axis drive, the basic methodology Transmission is the formation of the two basic methods of connecting continuously portfolio called. The complete transmission module coordinates, various geometric interference checking, transmission components strength check. To achieve optimum transmission purposes (minimum number of drive shaft, gear minimal number), using the following design, as illustrated in figure 1, as shown in Figure 2.Figure 1 2 shaft gear design Figure 2 triaxial GearDesign Optimization Optimization0 -- gear shaft has 0 -- have gearshaft1 -- the new design Gear 1 -- Design newgear6 Portfolio Machine CAD software operating environmentSoftware operating environment for the hardware : CPU 486 more,Memory 16 M over all software required disk space 350 M above.Software running the software environment : Windows 95/98,Windows NT 4.0, AutoCAD R14.0 7 Portfolio Machine CAD softwarehas been approved by experts and has a market push 1998The combination of machine CAD software approved by experts.The software technology advanced, reliable performance, strongfunction, convenient and practical. China machine toolindustry portfolio provides a modern design tools, thetechnology level of a leading position at home. The software has been designed in modular machine tool manufacturing plant and the professional engaged in internal-combustion engines, Engine production of large and medium-sized enterprises in the design and manufacture of modular machine tool sector wider application. Constant portfolio such as Jiangsu Machine Co., the second machine factory in Baoding, Diesel Co., Shandong Huayuan Levin move Engine Company Limited. Enterprises in the transformation of traditional industries, through the use of CAD technology, the electronic play of the power of information technology, improve the design level, and enhance the company's ability to create and product competitiveness, achieved good economic and social benefits.中文译文组合机床CAD系统开发与研究1 采用组合机床CAD技术势在必行组合机床是用按系列化、标准化设计的通用部件和按工件的形状及加工工艺要求设计的专用部件组成的专用机床，属于一次性设计、一次性制造的单件生产产品。

英文原文名Automatic production line PLC control中文译文：自动化生产线自动上料站的PLC控制自动生产线是由工件传送系统和控制系统，将一组自动机床和辅助设备按照工艺顺序联结起来，自动完成产品全部或部分制造过程的生产系统，简称自动线。

二十世纪20年代，随着汽车、滚动轴承、小电机和缝纫机和其他工业发展,机械制造业开始出现在自动生产线,第一个是组合机床自动线。

在20世纪20年代,第一次出现在汽车工业流水生产线和半自动生产线,然后发展成自动生产线。

第二次世界大战后,在机械制造工业发达国家,自动生产线的数量急剧增加。

采用自动生产线生产的产品应该足够大,产品设计和技术应该是先进的、稳定的和可靠的,基本上保持了很长一段时间维持不变。

自动线用于大,大规模生产可以提高劳动生产率,稳定和提高产品质量,改善劳动条件,降低生产区域,降低生产成本,缩短生产周期,保证生产平衡、显著的经济效益。

自动生产线的一个干预指定的程序或命令自动操作或控制的过程,我们的目标是稳定、准确、快速。

自动化技术广泛用于工业、农业、军事、科学研究、交通运输、商业、医疗、服务和家庭,等自动化生产线不仅可以使人们从繁重的体力劳动、部分脑力劳动以及恶劣、危险的工作环境,能扩大人的器官功能,极大地提高劳动生产率,提高人们认识世界的能力,可以改变世界。

下面我说下它的应用范围：机械制造业中有铸造、锻造、冲压、热处理、焊接、切削加工和机械装配等自动线，也有包括不同性质的工序，如毛坯制造、加工、装配、检验和包装等的综合自动线。

加工自动线发展最快,应用最广泛的机械制造。

主要包括:用于处理盒、外壳、各种各样的部件,如组合机床自动线;用于加工轴、盘部分,由通用、专业化、或自动机器自动专线;转子加工自动线;转子自动线加工过程简单、小零件等。

1.确保节拍时间:无论什么样的产品,都必须完成的时间生产。

2.单元过程:只有一个产品,单位部分处理、组装、加工和材料。

The Aggregate Machine-toolThe Aggregate Machine-tool is based on the workpiece needs, based on a large number of common components, combined with a semi-automatic or automatic machine with a small number of dedicated special components and process according to the workpiece shape and design of special parts and fixtures, composed. Combination machine is generally a combination of the base, slide, fixture, power boxes, multi-axle, tools, etc. From.Combination machine has the following advantages: (1) is mainly used for prism parts and other miscellaneous pieces of perforated surface processing. (2) high productivity. Because the process of concentration, can be multi-faceted, multi-site, multi-axis, multi-tool simultaneous machining. (3) precision and stability. Because the process is fixed, the choice of a mature generic parts, precision fixtures and automatic working cycle to ensure consistent processing accuracy. (4) the development cycle is short, easy to design, manufacture and maintenance, and low cost. Because GM, serialization, high degree of standardization, common parts can be pre-manufactured or mass organizations outsourcing. (5) a high degree of automation, low labor intensity. (6) flexible configuration. Because the structure is a cross-piece, combination. In accordance with the workpiece or process requirements, with plenty of common parts and a few special components consisting of various types of flexible combination of machine tools and automatic lines; tools to facilitate modification: the product or process changes, the general also common components can be reused.Combination of box-type drilling generally used for processing or special shape parts. During machining, the workpiece is generally not rotate, the rotational motion of the tool relative to the workpiece and tool feed movement to achieve drilling, reaming, countersinking, reaming, boring and other processing. Some combination of turning head clamp the workpiece using the machine to make the rotation, the tool for the feed motion, but also on some of the rotating parts (such as the flywheel, the automobile axle shaft, etc.) of cylindrical and face processing.Generally use a combination of multi-axis machine tools, multi-tool, multi-process, multi-faceted or multi-station machining methods simultaneously, productivity increased many times more than generic tools. Since the common components have been standardized and serialized, so can be flexibly configured according to need, you can shorten the design and manufacturing cycle. Multi-axle combination is the core components of general machine tools. It is the choice of generic parts, is designed according to special requirements, in combination machine design process, is one component of a larger workload. It is based on the number and location of the machining process diagram and schematic design combination machine workpiece determined by the hole, cutting the amount of power transmission components and the design of each spindle spindle type movement. Multi-axle power from a common power box, together with the power box installed on the feed slide, to be completed by drilling, reaming and other machining processes. The parts to be processed according to the size of multi-axle box combination machine tool design, based on an original drawing multi-axle diagram, determine the range of design data,the above design, implementation, completion of a two-sided 24-hole machining, achieve better the design requirements.In order to adapt to the development of CNC machine tools in combination , appeared composed of CNC machine tools CNC machining modules. Modular is the result of a combination of machine tool numerical control machine tool combination brings, but also the basis of a combination of CNC machine tools , CNC machining enriched the universal modular combination of components of the machine, it will cause a fundamental piece for machine tool type changes . Over the past decade , the combination of machine tools and automatic line has made great strides in efficiency, productivity , flexibility and the use of concurrent engineering to develop a more rational, more savings programs. With the development of digital technology, electronic technology , the combination of machine mechanical structure and control system has undergone great changes. With a combination of the following development tools : 1 NC . Combination of CNC machine tools emerge , not only changed in the past by the relay circuit consisting of a combination of machine tool control systems , but also make head or even a combination of the mechanical structure of the machine components of general criteria huge change occurred . 2 modular . NC modular greatly enriched the common combination of components of the machine, it will cause a fundamental change occurred for machine tool parts , according to the principles of modular design , based on the functional analysis division of the combination of multi- axle box for each machine level modules. 3 speed. As the high-speed processing can reduce the surface roughness and cutting force components , reducing the cutting temperature , improve productivity, so the speed of the machine is just beginning research , especially the main movement of CNC machine tools and feed velocity has reached a very high speed . Conform to the trend of high-speed machine tools , machine tool 's speed will be higher. 4 , precision . Because the CNC machine to achieve , so more and more high machining accuracy . 5, full protection technology . Now the machine is fully enclosed features a large , almost all mechanical housings are fully closed . Fully enclosed protection, not only to make the machine more attractive appearance and its production line , but also improves the safety, reliability and ease of maintenance . Combination machine with both the advantages of low cost and high efficiency in large volume production has been widely used, and can consist of automated production lines. .组合机床组合机床是根据工件加工需要，以大量通用部件为基础，配之以少量的专用部件和按工件形状和加工工艺设计的专用部件和夹具，组成的半自动或自动的专用机床。

ⅡAggregate machine-tool and from generatortechnological developmentIn uses the CNC three coordinates processing’s module from the generator in and transfers the tow the aggregate machine-tool and the aggregate machine-tool from the generator are one kind of special-purpose highly effective automation technical equip, at present, because it still was the mass mechanical product realization is highly effective, high grade and the efficient production key equipment, thus is widely applied to the automobile, the tractor, the internal combustion engine and the compressor and soon many industrial productions domain. Among them, specially the automobile industry, is the aggregate machine-tool and from the generator biggest user. If the German populace automotive factory in the Slaughter engine factory, the metal-cutting machine tool which at the beginning of the 90's uses mainly is from the generator (60%),the aggregate machine-tool (20%) and the processing center (20%).Obviously, in the mass production mechanical industry sector, the equipmentwhich massively uses is the aggregate machine-tool and from the generator. Therefore, aggregate machine-tool and its from the generator technical performance and the synthesis automation level, has decided these industry sector products production efficiencies, the product quality and the ent erprise production organization’s structure in the very great degree, also has decided the enterprise product competitive ability in the very great degree.The modern aggregate machine tool and from the generator took the integration of machinery product, it is technical the and so on control, actuation, survey, monitoring, cutting tool and mechanical module synthesis reflection. In the recent 20 years, these technologies have make great strides, simultaneously as aggregate machine-tool main profession and so on user's automobile and internal combustion engine also has the very big change, its produce market life unceasingly reduces, the variety increases day by day also the quality unceasingly enhances. These factors powerfully impelled and have driven the aggregate machine tool and from the generator technology unceasing development.1Aggregate machine-tool variety development keyIn aggregate machine-tool this kind of special purpose machine, the rotation type multiplex position aggregate machine-tool and holds thievery important status from the generator. Because these two kind of engine beds may assign the work piece many processing’s working procedure to many Canadian location in, and at the same time can carryon the processing from many directions to the work piece several surface, in addition, but also may through the indexing jig (on rotary table engine bed) or through indexing, the turn over installment (inform generator in) realizes the work piece five processing’s or completely processes, thus has the very high automat city and the production efficiency, by industry sector and so on the automobile, motorcycle and compressor uses.According to related statistical data, Germany in 1,990 ~ in 1992period, the rotation type multiplex position aggregate machine-too land approximately respectively accounts for the aggregate machine-tool total from the generator output about 50%.Should point out that, the rotation type multiplex position tool-tool is in fact one kind of special pattern small from the generator, suits to processing overall size <= 250mm center small. With compares from the generator, in the processing identical kind of work piece situation, the rotation type multiplex position tool-tool occupies the work area to have to be approximately smaller than from the generator 2/3.2 Further reduces from the generator meter timeAt present, take the mass production as the characteristic passenger vehicle and the light truck, its engine annual output usually is about600, 000, the realization such great volume production, the rotation type multiplex position aggregate machine-tool and from the generator in three class of movements situations, its meter time generally is 20~ 30 seconds, when the components production batch is bigger, the engine bed meter time also must shorter (table 1). In the 70's, must realize the such short meter from the generator, often must use the compound double location or the establishment double thread means, namely to decides from the generator meter,the working procedure time longest processing working procedure to have through the parallel two same proc essing’s location, if the restrictive working procedure are more time, then through uses two same from the generator balances from generator system processing meter. Obviously, like this must increase the equipment investment and the work area.Reduces the non-cutting time mainly is reduces including the work piece transportation, the processing module fast introduction as wells the processing module by quickly enters transforms enters after the labor cuts into the time to the cutting tool which the work piece spend. In order to reduce this part of spatial travel time, generally uses enhance the work piece (work piece direct transportation) or accompanies the jig the transfer rate and the processing module rapid traverse speed. At present, accompanies the jig the transfer rate tube possible to reach 60m/min or higher, the processing module rapid traverse speed reaches 40m/min. At present, accompanies the jig high speed feed way commonly used to have the proportion valve to control or the cycloid actuation feedway. At the end of the 70's, Hon berg Corporation has used the feed way in its processing gear box body from the generator in which the proportion valve controls. Should from generator long 18.2m, some 12 Canadian location, transportation step of distance be 1400mm, the transportation weights 7000kg, the transfer rate reaches 45.6m/min, step of distance transportation time is only 2.5s. Chart 4 is this feed way state of motion curve. Because the proportion valve control system haste good start and the braking quality, also the system structure is simple, until now, this kind of feed way still many is used from the generator.3 Aggregate machine-tool flexibility progress is rapidMore than ten for years, took the aggregate machine-tool important user the automobile industry, for caters to the people individuality demand, the automobile aberration variety increases day by day, launches the competition by the multi- varieties to become one of auto market competition characteristics, this causes the tool-tool manufacturing industry to face is changing form thematic- varieties production challenge. In order to adapt themulti-varieties production, the tradition processes the sole variety the rigidity aggregate machine tool and must enhance its flexibility from the generator. In the 70's, the numerical control system reliability had the very big enhancement, therefore to at the end of the 70's and at the beginning of the 80's, like Align, Hüller-Hille and company and so on Ex-cell-o develops the numerical control processing module and the flexibility one after another from the generator, from this time on the numerical control aggregate machine-tool and the flexibility increase year by year from the generator. From 1988 to1992, the Japan aggregate machine-tool and (including partial other forms special purpose machine) the output numerical control rate has reached 32% from the generator ~ 39%, the output value numerical control ratio reaches 35% ~ 51%; The Germany aggregate machine-too land from the generator output numerical control rate is 18% ~ 62%, the output value numerical control rate reaches 45% ~ 66%. These numerals indicated that, in the recent ten years, the tool-tool numerical control development is extremely rapid. Should point out that, since has entered for the 90's, the auto market competition hastens intensely, the produce market lifefurther reduces, the new vehicle type development cycle reduces (at present generally is day by day 35 months), the automobile variety unceasingly increases, thus the automobile industry increases day by day to the flexible automation technical equip demand quantity. If the Japanese Toyota car company, is the company subordinate factory flexibility processing system popular rate achieves 100% in this century's end goal. Very obviously, the aggregate machine tool and its at maintains its high production efficiency from the generator under the condition, further enhances its flexibility on increasingly to have the vital significance.The aggregate machine-tool flexibility mainly is through uses the numerical control technology to realize. The development flexibility aggregate machine-tool and the flexibility develops the numerical control processing module from the generator important premise, but has the longer development history the processing center technology to provide the mature experience for the development numerical control processing module. Flexibility aggregate machine-tool and flexibility’scomposed which by the numerical control processing module from generator, the passable application and the change numerical control procedure realizes from moves the knife, automatically replaces the change processing traveling schedule, the operating cycle, the cutting parameter as well as processes the position and soon, adapts the aberration variety processing. The flexibility aggregate machine-tool and the flexibility the numerical control processing module which use from the generator, according to its numerical control coordinates (axis) the number, mainly has the single coordinates (Z), the double coordinates (X-Z, Y-Z, Z-U and Z-B and soon) and three coordinates (X-Y-Z) processes the module; According toots main axle number, has the single axle and the multiple spindle processing module, also has the single axle and the multiple spindle compound process.The column moves the type CNC three coordinates processing’s module tube possible to use X axis and the Y axis linkage realizes the peripheral craft, specially when gear box body this kind of rigidity worse work piece, mayuse compares the minor diameter the milling cutter, the realization is high speed (cutting speed to reach 2500m/min) peripheral, from this reduces time the processing the work piece distortion. This uses the double coordinates processing module with the large diameter milling cutter to carry on much more superior than. The multiple spindle-processing module is another kind of important module, mainly uses in to process the box body and the plate class work piece flexibility aggregate machine-tool and the flexibility from the generator. This kind of module has the many kinds of different structural style, but basically may divide into from moves the box type multiple spindle processing module (chart 7), transfers the tower system multiple spindle processing module (chart 8) and the rotation work table model multiple spindle processing module (chart 9). From moves the box type module because may specially establish in many storehouses stores up therefore may use for to process more different varieties the work piece. But transfers the tower system and the rotation work table model multiplespindle processing module, because allows the rotary table which installs to be limited (generally is 4 ~ 6), therefore this kind of processing module only can realize the limited variety processing system multiple spindle processing module, not only may realize the different variety work piece processing, moreover in from generator meter time in (if metre adequate time), this kind of processing module also may in the identical Canadian location through it from moves the knife or trades the box, realizes the multi channel processing working procedure (to bethink in turn The drill hole, drills outland attacks the silk), thus reduces from the generator processing labor figure, reduces from the generator length. The single axle and the multiple spindle compound processing module is one kind of three coordinates numerical controls processing module, passable from has moved the knife either automatically replaces realizes the single axle processing or the multiple spindle processing. Is worth mentioning, Corporation promotes the CNCMACH modulation system in 80'sintermediate stages Germany Hon berg (chart 10) is hasthe characteristic very much one kind of modular system, this system full application modulation structure principle, in took the system base module in the CNC three coordinates module, through fluctuates each kind of different function module, assembles Cheng Gashing the different coordinates or does not use the craft use the processing module. To be specific, looking from the coordinates, besides three coordinates, but also may the group form a pair the coordinates and the single coordinates processing module; Looking from the knife storehouse that, may install the cutting tool store house may alone realize the cutting tool automatic replacements, also may realize the cutting tool replacements in turn.CNC MACH system, not only in mechanism aspect, moreover in aspect ands on control and software also is the modulation. Therefore, uses this system module, may very conveniently assemble the flexibility from the generator (FTL), the flexible processing unit (FMC) or the flexible manufacture system (FMS). Besides above each kind of CNCprocessing module, the robot and the servo actuatethe jig also are the flexibility aggregate machine-tool and the flexibility from the generator important part. Specially in the flexibility from the generator in, at present comparatively generally has used the Dragon Gate type spatial frame robot to carry on the work piece on the automatic yummy treats, uses in work piece indexing or the turn over. In order to transport the different work piece, may in from the generator nearby the establishment fingernail storehouse, the realization fingernail automatic replacement. The jig provides the servo drive, adapts in the work piece race the different work piece automatically to clamp. Chart 11 shows are a processing carrying capacity truck eight kind of gearboxes bodies’ flexibility from the generator. This line uses the numerical control processing module has four double coordinates numerical controls module, six numerical controls transfers the tower system multiple spindle processing module and six numerical controls three coordinates processing module. The auxiliary location has cleans the location and uses the robot to carry on the operation the attire to clamp the workstation.Because composes from the generator processing module all is the numerical control, when by one kind of work piece processing transformation for another kind of work piece processing, only must be good through the change numerical control procedure, but did not need to carry on aspect the and so on machinery adjustment and the equipment.The aggregate machine-tool reduces day by day from the generator flexibility rapid development and the meter time, fully had demonstrated the CNC technology and the cutting tool technology the huge technology advancement which bring for the aggregate machine-tool automatic line, causes the flexibility from the generator in thematic- varieties, the mass production to become the important technical equip. But must point out in here that, during the tool-tool and from generator realization flexibility development, the processing center high-speed development exceptionally is rapid. At the beginning of the 90's, the flexible production line which discomposed by this kind of high speed processing center enter the mass realm of production, appeared the processing center and from thegenerator competition aspect.------ Rajput R K Elements of Mechanical Engineering. Katson Publ.House 组合机床现状与前景 组合机床和组合机床自动线是一种专用高效自动化技术装备，目前，由于它仍是大批量机械产品实现高效、 高质量和经济性生产的关键装备，因而被广泛应用于汽车、拖拉机、内燃机和压缩机等许多工业生产领域。

双面钻孔组合机床液压系统设计毕业设计1 绪论1.1 组合机床的发展现状及前景组合机床（transfer and unit machine）是根据工件加工需要,以大量通用部件为基础，配以按工件特定形状和加工工艺设计的专用部件和夹具，组成的一种高效的半自动或自动专用机床[5]。

在我国，组合机床发展已有28年的历史，其科研和生产都具有相当的基础，应用也已深入到很多行业。

是当前机械制造业实现产品更新，进行技术改造，提高生产效率和高速发展必不可少的设备之一。

它的特征是高效、高质、经济实用，因而被广泛应用于工程机械、交通、能源、军工、轻工、家电等行业[8]。

我国传统的组合机床及组合机床自动线主要采用机、电、气、液压控制，它的加工对象主要是生产批量比较大的大中型箱体类和轴类零件（近年研制的组合机床加工连杆、板件等也占一定份额），完成钻孔、扩孔、铰孔，加工各种螺纹、镗孔、车端面和凸台，在孔内镗各种形状槽，以及铣削平面和成形面等[5]。

随着技术的不断进步，一种新型的组合机床——柔性组合机床越来越受到人们的青睐，它应用多位主轴箱、可换主轴箱、编码随行夹具和刀具的自动更换，配以可编程序控制器（PLC）、数字控制（NC）等，能任意改变工作循环控制和驱动系统，并能灵活适应多品种加工的可调可变的组合机床。

另外，近年来组合机床加工中心、数控组合机床、机床辅机（清洗机、装配机、综合测量机、试验机、输送线）等在组合机床行业中所占份额也越来越大。

由于组合机床及其自动线是一种技术综合性很高的高技术专用产品，是根据用户特殊要求而设计的，它涉及到加工工艺、刀具、测量、控制、诊断监控、清洗、装配和试漏等技术。

我国组合机床及组合机床自动线总体技术水平比发达国家要相对落后，国内所需的一些高水平组合机床及自动线几乎都从国外进口。

工艺装备的大量进口势必导致投资规模的扩大，并使产品生产成本提高。

因此，市场要求我们不断开发新技术、新工艺，研制新产品，由过去的“刚性”机床结构，向“柔性”化方向发展，满足用户需求，真正成为刚柔兼备的自动化装备[16]。

Design Of Tool Machine PropResearch significanceThe original knife machine control procedures are designed individually, not used tool management system, features a single comparison, the knife only has to find the tool knife, knife positioning the shortest path, axis tool change, but does not support large-scale tool.Automatic knife in the knife election, in the computer memory knife-election on the basis of using the Siemens 840 D features, and the election procedures knife more concise, and comp lete the space Daotao View. ATC use the knife rapid completion of STEP-7 programming, and have been tested in practice. In the positioning of the knife, PLC controlled modular design method, which future production of similar machines will be very beneficial, it is easy to use its other machine. Automatic tool change systems will be faster growth, reduced tool change time, increase the positioning accuracy tool is an important means to help NC technology development.Tool and inventory components of modern production is an important link in the management, especially for large workshop management. The traditional way of account management, and low efficiency, high error rate, and not sharing information and data, tools and the use of state can not track the life cycle, are unable to meet the current information management needs. With actual production, we have to establish a workshop tool for the three-dimensional tool storage system to meet the knife workshop with auxiliary storage and management needs.The system uses optimization technology, a large number of computer storage inventory information, timely, accurate, and comprehensive tool to reflect the inventory situation. The entire system uses a graphical interface, man-machine dialogue tips from the Chinese menu, select various functions can be realized and the importation of all kinds of information. Management system using online help function. Through the workshop management, network management and sharing of information. Have automated inventory management, warehousing management tool, a tool for the management and statistical functions.1.System components and control structureThe entire system, including the structure and electrical machinery control systems.1.1.1Mechanical structure and working principleTool from the stent, drive, drive system, Turret, shielding, control system, and electrical components. Support from the column, beam, the upper and lower guide Central track, and track support component.1) Drive for the system chosen VVVF method. Cone used brake motors, with VVVF by Cycloid reducer through sprocket drive.2) Drag a variable frequency drive system and control technology. VVVF adopted, will speed drive shaft in the normal range adjustment to control the speed rotary turret to 5 ~ 30mm in, the drive shaft into two, two under through sprocket, the two profiled rollers Chain driven rotating shelves. Expansion chain adopted by the thread tight regulation swelling, swelling the regular way. - Conditioned, under the same chain-of-conditioning, so that the chain of uniform.3) Turret and shields the entire total of 14 independent Turret. 13 of them as a socket-Turret, as a drawer-Turret, each Turret back through the pin and, under the conveyor chain link chain plate, installed at the bottom roller, chain driven rotating turret rotation along the track. Outlet-Turret and BT50-BT40 Turret Turret two kinds of forms. To strengthen management, security, landscaping modeling, shelf peripherals and shields. Turret-drawer drawer placed at six other Des V oeux a knife, can be categorized with some of knife auxiliary equipment, such as bits, such as turning tools.1.1.2.Electrical Control SystemThis tool storage systems is the main electrical control their shelves for operational control and position control. Operational control equipment, including operation of the start of braking control. Position Control is the main location and address of the shelves for testing. Control system as shown in Figure 1.图 1 Tool Control System for the1) Electric Transmission horizontal rotary tool storage systems are the mechanical movements are repeated short-term work system. And the run-time system needs some speed, speed transmission needs, the system will use VVVF method can be used simple structure, reliable operation of the motor and frequency inverter.2) Control of the system is divided into two kinds of manual control and automatic control,manual control as a general reserve and debugging methods of work; ways to the system control computer (IPC) and the control unit (inverter contactor , etc.) consisting of a control system.3) location and positioning accuracy of the system automatically identify the site and location using a detection device as proximity switches, relays through the plate-point isolation and the number plate recorded close to the switching signal acquisition and operation of Hutchison with a Optimal Path addressable identify the current location and shelves of the purpose of the shelf location. In order to enable a more accurate positioning system, adopted two photoelectric switches, to detect the two shelves of the two films.1.2.The functions of the knifeknife The is the role of reserves a certain number of tools, machine tool spindle in hand to achieve the fungibility a disc cutter knife is the type of library, the chain knives, and other means, in the form of the knife and capacity according to the Machine Tool to determine the scope of the process.mon typesThe knife is a tool storage devices, the common knife mainly in the following forms:(1) the turret knifeIncluding the first level turret vertical turret and the first two, see Figure 2.6 a) and b):(2) the disc cutterDisc knife in the library with discoid knife, cutting tool along See how vertical arrangement (including radial and axial from knife from knife), along See how radial array into acute or arranged in the form of the knife. Simple, compact, more applications, but are ring-cutter, low utilization of space. Figure 2.7 a) to c). If the knife storage capacity must be increased to increase the diameter of the knife, then the moment of inertia also increased correspondingly, the election campaign long knife. Tool number not more than 32 general. Cutter was multi-loop order of the space utilization knife, but inevitably given the knife from complex institutions, applicable to the restricted space Machine Tool storage capacity and more occasions. Two-discstructure is two smaller capacity knife on both sides of the sub-spindle place, more compactlayout, the number of certificates corresponding increase knife, apply to small and medium-sized processing center.(3) the chain knifeIncluding single-and multi-ring chain ring chain, chain link can take many forms change, see Figure 2.8 a) to c), thebasic structure shown inFigure 2. 8 doFeatures: knife apply tothe larger capacity of theoccasion, the space of thesmall number ofgenerally applicable tothe tool in the 30-120.Only increase the lengthof the chain tool will increase the number should not be increased circumferential speed of itsmoment of inertia of the knife does not increase the disc as large.(4) linear combination knife and the knife libraryThe linear knife simple structure in Figure 2.9, tool single order, the capacity of small knife, used for CNC lathe and drill press on. Because the location of fixed knife, ATC completed action by the spindle without manipulator. The cutter knife is generally the turret combination turret with a combination of the disc cutter knife and the chain combination. Every single knife the knife certificates of smaller, faster tool change. There are also some intensive drum wheel, and the lattice-type magazine for the knife, the knife-intensive though. Small footprint, but because of structural constraints, basically not used for single processing center, the concentration used for FMS for the knife system.1.4 Tool storage capacityTool storage capacity of the first to consider the needs of processing, from the use of point of view, generally 10 to 40 knives, knife will be the utilization of the high, and the structure is。

中英文资料外文翻译文献TRANSFER AND UNIT MACHINEWhile the specific intention and application for transfer and unit machine vary from one machine type to another, all forms of transfer and unit machine have common benefits. Here are but a few of the more important benefits offered by TRANSFER AND UNIT MACHINE equipment.The first benefit offered by all forms of transfer and unit machine is improved automation. The operator intervention related to producing workpieces can be reduced or eliminated. Many transfer and unit machine can run unattended during their entire machining cycle, freeing the operator to do other tasks. This gives the transfer and unit machine user several side benefits including reduced operator fatigue, fewer mistakes caused by human error, and consistent and predictable machining time for each workpiece. Since the machine will be running under program control, the skill level required of the transfer and unit machine operator (related to basic machining practice) is also reduced as compared to a machinist producing workpieces with conventional machine tools.The second major benefit of transfer and unit machine technology is consistent and accurate workpieces. Today's transfer and unit machines boast almost unbelievable accuracy and repeatability specifications. This means that once a program is verified, two, ten, or one thousand identical workpieces can be easily produced with precision and consistency.rd benefit offered by most forms of transfer and unit machine tools is flexibility. Since these machines are run from programs, running a different workpieceis almost as easy as loading a different program. Once a program has been verified and executed for one production run, it can be easily recalled the next time the workpiece is to be run. This leads to yet another benefit, fast change over. Since these machines are very easy to set up and run, and since programs can be easily loaded, they allow very short setup time. This is imperative with today's just-in-time (JIT) product requirements.Motion control - the heart of transfer and unit machineThe most basic function of any transfer and unit machine is automatic, precise, and consistent motion control. Rather than applying completely mechanical devices to cause motion as is required on most conventional machine tools, transfer and unit machines allow motion control in a revolutionary manner2. All forms of transfer and unit machine equipment have two or more directions of motion, called axes. These axes can be precisely and automatically positioned along their lengths of travel. The two most common axis types are linear (driven along a straight path) and rotary (driven along a circular path).Instead of causing motion by turning cranks and handwheels as is required on conventional machine tools, transfer and unit machines allow motions to be commanded through programmed commands. Generally speaking, the motion type (rapid, linear, and circular), the axes to move, the amount of motion and the motion rate (feedrate) are programmable with almost all transfer and unit machine tools.A transfer and unit machine command executed within the control tells the drive motor to rotate a precise number of times. The rotation of the drive motor in turn rotates the ball screw. And the ball screw drives the linear axis (slide). A feedback device (linear scale) on the slide allows the control to confirm that the commanded number of rotations has taken place3. Refer to fig.1.Fig.1Though a rather crude analogy, the same basic linear motion can be found on a common table vise. As you rotate the vise crank, you rotate a lead screw that, in turn, drives the movable jaw on the vise. By comparison, a linear axis on a transfer and unit machine machine tool is extremely precise. The number of revolutions of the axis drive motor precisely controls the amount of linear motion along the axis.How axis motion is commanded - understanding coordinate systemsIt would be infeasible for the transfer and unit machine user to cause axis motion by trying to tell each axis drive motor how many times to rotate in order to command a given linear motion amount4. (This would be like having to figure out how many turns of the handle on a table vise will cause the movable jaw to move exactly one inch!) Instead, all transfer and unit machine controls allow axis motion to be commanded in a much simpler and more logical way by utilizing some form of coordinate system. The two most popular coordinate systems used with transfer and unit machines are the rectangular coordinate system and the polar coordinate system. By far, the more popular of these two is the rectangular coordinate system.The program zero point establishes the point of reference for motion commands in a transfer and unit machine program. This allows the programmer to specify movements from a common location. If program zero is chosen wisely, usually coordinates needed for the program can be taken directly from the print.With this technique, if the programmer wishes the tool to be sent to a position one inch to the right of the program zero point, X1.0 is commanded. If the programmer wishes the tool to move to a position one inch above the program zero point, Y1.0 is commanded. The control will automatically determine how many times to rotate each axis drive motor and ball screw to make the axis reach the commanded destination point . This lets the programmer command axis motion in a very logical manner. Refer to fig.2, 3.Fig.2Fig.3All discussions to this point assume that the absolute mode of programming is used6. The most common transfer and unit machine word used to designate the absolute mode is G90. In the absolute mode, the end points for all motions will be specified from the program zero point. For beginners, this is usually the best and easiest method of specifying end points for motion commands. However, there is another way of specifying end points for axis motion.In the incremental mode (commonly specified by G91), end points for motions are specified from the tool's current position, not from program zero. With this method of commanding motion, the programmer must always be asking "How far should I move the tool?" While there are times when the incremental mode can be very helpful, generally speaking, this is the more cumbersome and difficult method of specifying motion and beginners should concentrate on using the absolute mode.Be careful when making motion commands. Beginners have the tendency tothink incrementally. If working in the absolute mode (as beginners should), the programmer should always be asking "To what position should the tool be moved?" This position is relative to program zero, NOT from the tools current position.Aside from making it very easy to determine the current position for any command, another benefit of working in the absolute mode has to do with mistakes made during motion commands. In the absolute mode, if a motion mistake is made in one command of the program, only one movement will be incorrect. On the other hand, if a mistake is made during incremental movements, all motions from the point of the mistake will also be incorrect.Assigning program zeroKeep in mind that the transfer and unit machine control must be told the location of the program zero point by one means or another. How this is done varies dramatically from one transfer and unit machine and control to another8. One (older) method is to assign program zero in the program. With this method, the programmer tells the control how far it is from the program zero point to the starting position of the machine. This is commonly done with a G92 (or G50) command at least at the beginning of the program and possibly at the beginning of each tool.Another, newer and better way to assign program zero is through some form of offset. Refer to fig.4. Commonly machining center control manufacturers call offsets used to assign program zero fixture offsets. Turning center manufacturers commonly call offsets used to assign program zero for each tool geometry offsets.Fig. 4Flexible manufacturing cellsA flexible manufacturing cell (FMC) can be considered as a flexible manufacturing subsystem. The following differences exist between the FMC and the FMS:1.An FMC is not under the direct control of thecentral computer. Instead, instructions from the centralcomputer are passed to the cell controller.2.The cell is limited in the number of part families itcan manufacture.The following elements are normally found in an FMC:•Cell controller•Programmable logic controller (PLC)•More than one machine tool•A materials handling device (robot or pallet)The FMC executes fixed machining operations with parts flowing sequentially between operations.High speed machiningThe term High Speed Machining (HSM) commonly refers to end milling at high rotational speeds and high surface feeds. For instance, the routing of pockets in aluminum airframe sections with a very high material removal rate1. Over the past 60 years, HSM has been applied to a wide range of metallic and non-metallic workpiece materials, including the production of components with specific surface topography requirements and machining of materials with hardness of 50 HRC and above. With most steel components hardened to approximately 32-42 HRC, machining options currently include: Rough machining and semi-finishing of the material in its soft (annealed) condition heat treatment to achieve the final required hardness = 63 HRC machining of electrodes and Electrical Discharge Machining (EDM) of specific parts of dies and moulds (specifically small radii and deep cavities with limitedaccessibility for metal cutting tools) finishing and super-finishing of cylindrical/flat/cavity surfaces with appropriate cemented carbide, cermet, solid carbide, mixed ceramic or polycrystalline cubic boron nitride (PCBN)For many components, the production process involves a combination of these options and in the case of dies and moulds it also includes time consuming hand finishing. Consequently, production costs can be high and lead times excessive.It is typical in the die and mould industry to produce one or just a few tools of the same design. The process involves constant changes to the design, and because of these changes there is also a corresponding need for measuring and reverse engineering .The main criteria is the quality level of the die or mould regarding dimensional, geometric and surface accuracy. If the quality level after machining is poor and if it cannot meet the requirements, there will be a varying need of manual finishing work. This work produces satisfactory surface accuracy, but it always has a negative impact on the dimensional and geometric accuracy.One of the main aims for the die and mould industry has been, and still is, to reduce or eliminate the need for manual polishing and thus improve the quality and shorten the production costs and lead times.Main economical and technical factors for the development of HSMSurvivalThe ever increasing competition in the marketplace is continually setting new standards. The demands on time and cost efficiency is getting higher and higher. This has forced the development of new processes and production techniques to take place. HSM provides hope and solutions...MaterialsThe development of new, more difficult to machine materials has underlined the necessity to find new machining solutions. The aerospace industry has its heat resistant and stainless steel alloys. The automotive industry has different bimetal compositions, Compact Graphite Iron and an ever increasing volume of aluminum3. The die and mould industry mainly has to face the problem of machining highhardened tool steels, from roughing to finishing.QualityThe demand for higher component or product quality is the result of ever increasing competition. HSM, if applied correctly, offers a number of solutions in this area. Substitution of manual finishing is one example, which is especially important on dies and moulds or components with a complex 3D geometry.ProcessesThe demands on shorter throughput times via fewer setups and simplified flows (logistics) can in most cases, be solved by HSM. A typical target within the die and mould industry is to completely machine fully hardened small sized tools in one setup. Costly and time consuming EDM processes can also be reduced or eliminated with HSM.Design & developmentOne of the main tools in today's competition is to sell products on the value of novelty. The average product life cycle on cars today is 4 years, computers and accessories 1.5 years, hand phones 3 months... One of the prerequisites of this development of fast design changes and rapid product development time is the HSM technique.Complex productsThere is an increase of multi-functional surfaces on components, such as new design of turbine blades giving new and optimized functions and features. Earlier designs allowed polishing by hand or with robots (manipulators). Turbine blades with new, more sophisticated designs have to be finished via machining and preferably by HSM . There are also more and more examples of thin walled workpieces that have to be machined (medical equipment, electronics, products for defence, computer parts) Production equipmentThe strong development of cutting materials, holding tools, machine tools, controls and especially CAD/CAM features and equipment, has opened possibilities that must be met with new production methods and techniques5.Definition of HSMSalomon's theory, "Machining with high cutting speeds..." on which, in 1931,took out a German patent, assumes that "at a certain cutting speed (5-10 times higher than in conventional machining), the chip removal temperature at the cutting edge will start to decrease..."Given the conclusion:" ... seems to give a chance to improve productivity in machining with conventional tools at high cutting speeds..."Modern research, unfortunately, has not been able to verify this theory totally. There is a relative decrease of the temperature at the cutting edge that starts at certain cutting speeds for different materials.The decrease is small for steel and cast iron. But larger for aluminum and other non-ferrous metals. The definition of HSM must be based on other factors.Given today's technology, "high speed" is generally accepted to mean surface speeds between 1 and 10 kilometers per minute or roughly 3 300 to 33 000 feet per minute. Speeds above 10 km/min are in the ultra-high speed category, and are largely the realm of experimental metal cutting. Obviously, the spindle rotations required to achieve these surface cutting speeds are directly related to the diameter of the tools being used. One trend which is very evident today is the use of very large cutter diameters for these applications - and this has important implications for tool design.There are many opinions, many myths and many different ways to define HSM. Maintenance and troubleshootingMaintenance for a horizontal MCThe following is a list of required regular maintenance for a Horizontal Machining Center as shown in fig.5. Listed are the frequency of service, capacities, and type of fluids required. These required specifications must be followed in order to keep your machine in good working order and protect your warranty.fig. 5DailyTop off coolant level every eight hour shift (especially during heavy TSC usage).Check way lube lubrication tank level.Clean chips from way covers and bottom pan.Clean chips from tool changer.Wipe spindle taper with a clean cloth rag and apply light oil.Weekly•Check for proper operation of auto drain on filter regulator.On machines with the TSC option, clean the chip basket on the coolant tank.Remove the tank cover and remove any sediment inside the tank. Be careful to disconnect the coolant pump from the controller and POWER OFF the control before working on the coolant tank . Do this monthly for machines without the TSC option.Check air gauge/regulator for 85 psi.For machines with the TSC option, place a dab of grease on the V-flange of tools. Do this monthly for machines without the TSC option.Clean exterior surfaces with mild cleaner. DO NOT use solvents.Check the hydraulic counterbalance pressure according to the machine's specifications.Place a dab of grease on the outside edge of the fingers of the tool changer and run through all tools".MonthlyCheck oil level in gearbox. Add oil until oil begins dripping from over flow tube at bottom of sump tank.Clean pads on bottom of pallets.Clean the locating pads on the A-axis and the load station. This requires removing the pallet.•Inspect way covers for proper operation and lubricate with light oil, if necessary.Six monthsReplace coolant and thoroughly clean the coolant tank.Check all hoses and lubrication lines for cracking.Annually•Replace the gearbox oil. Drain the oil from the gearbox, and slowly refill it with 2 quarts of Mobil DTE 25 oil.•Check oil filter and clean out residue at bottom for the lubrication chart.Replace air filter on control box every 2 years.Mineral cutting oils will damage rubber based components throughout the machine.TroubleshootingThis section is intended for use in determining the solution to a known problem. Solutions given are intended to give the individual servicing the TRANSFER AND UNIT MACHINE a pattern to follow in, first, determining the problem's source and, second, solving the problem.Use common senseMany problems are easily overcome by correctly evaluating the situation. All machine operations are composed of a program, tools, and tooling. You must look at all three before blaming one as the fault area. If a bored hole is chattering because of an overextended boring bar, don't expect the machine to correct the fault.Don't suspect machine accuracy if the vise bends the part. Don't claim hole mis-positioning if you don't first center-drill the hole.Find the problem firstMany mechanics tear into things before they understand the problem, hoping that it will appear as they go. We know this from the fact that more than half of all warranty returned parts are in good working order. If the spindle doesn't turn, remember that the spindle is connected to the gear box, which is connected to the spindle motor, which is driven by the spindle drive, which is connected to the I/O BOARD, which is driven by the MOCON, which is driven by the processor. The moral here is don't replace the spindle drive if the belt is broken. Find the problem first; don't just replace the easiest part to get to.Don tinker with the machineThere are hundreds of parameters, wires, switches, etc., that you can change in this machine. Don't start randomly changing parts and parameters. Remember, there is a good chance that if you change something, you will incorrectly install it or break something else in the process6. Consider for a moment changing the processor's board. First, you have to download all parameters, remove a dozen connectors, replace the board, reconnect and reload, and if you make one mistake or bend one tiny pin it WON'T WORK. You always need to consider the risk of accidentally damaging the machine anytime you work on it. It is cheap insurance to double-check a suspect part before physically changing it. The less work you do on the machine the better.组合机床虽然各种组合机床的功能和应用各不相同，但它们有着共同的优点。

XX外文翻译专业学生姓名班级学号指导教师外文资料名称CONSTITUTE MACHINE TOOL AND ITSAUTOMATION ASSEMBLY LINE外文资料出处：JOURNAL OF HEFEI UNIVERSITY OF(用外文写)TECHNOLOGY附件： 1.外文资料翻译译文2.外文原文组合机床及其自动生产线摘要：组合机床及其自动生产线是集机电于一体的自动化程度较高的制造技术和成套工艺装备,它的特征是高效、高质、经济实用,因而被广泛用于工程机械、交通、能源、军工、轻工、家电等行业。

本文根据工厂需要,设计一台能高效加工大批量产品的专用组合机床。

文章从工艺方案设计、总体设计、部件设计等几部分进行设计。

关键词：组合机床；自动控制；机床；许多情况下，成型加工出来的工件必须在尺寸和光洁度方面进一步精整，以满足它们的设计技术要求。

为满足精度公差，需要从工件上去掉小量的材料。

通常机床就是用于这种加工的设备。

通过切削工具使工件成型达到所需的尺寸，机床通过其基础构件的功能作用，以控制相互关系，支持、夹紧工具和工件，基本部件列举如下：a) 床身. 这是个主要部件，它为主轴、拖板箱等提供了一个基础和连接中介，在负载作用下，它必须使形变和振动保持最小。

b) 拖板箱和导轨. 机床部件（如拖板箱）的移动，通常是在精确的导轨面约束下靠直线运动来实现。

c) 主轴和轴承. 角位移是围绕一个旋转轴线发生的。

该轴线的位置必须在机床中极端精确的限度内保持恒定，而且是靠精密的主轴和轴承来提供保证。

d) 动力装置. 电机是为机床普遍采用的动力装置，通过对各个电机的合适定位，使皮带和齿轮传动装置减少到最少。

e) 传动连杆机构. 连杆机构是个通用术语，用来代表机械、液压、气动或电动机构，这些机构与确定的角位移和线位移相互关联。

加工工艺主要由两部分组成:a) 粗加工工艺. 粗加工，金属切除率高，因而切削力也较大，但其所要求的精度较低。

Development and application of combined machine tool The combination of machine tools based on general parts, workpiece supported by the specific shape and design of special processing of parts and fixtures, the composition semiautomatic or automatic special machine. Combination machine generally adopts multi shaft, knife, more processes, more or multiple locations simultaneously processes, and production efficiency ratio general machine tool high several times to several times. As generic components have been standardized and serialized, may need to be flexible configuration, can shorten design and manufacturing cycle. Therefore, the aggregate machine-tool has the advantages of high efficiency and low cost, the large, mass production to be widely applied, and can be used to compose the automatic production line. Processing, workpiece generally does not rotate, by movement of the rotatable cutter and tool and workpiece relative feed movement, to achieve drilling, reaming, counterboring, reaming, boring, milling, cutting and processing of external thread face and etc.. Some combination machine adopts clamping workpiece machining head to rotate, by the tool for the feed movement, also can achieve some rotating parts ( such as car rear axle flywheel, etc.) of the face and processing.In twentieth Century since the 70's, along with the cutting tool with indexable inserts, dense gear milling cutter, boring size automatic detection and automatic compensation for tool technology development, combination of the machining accuracy of the machine tool is improved. Milling plane plane of up to 0.05mm and1000 mm, the surface roughness can be as low as 2.5to 0.63 microns; boring accuracy up to IT7~6, hole distance precision can reach 0.03~ 0.02 micron. A dedicated machine is along with the automobile industry development. In some parts of special machine tool for repeated use, and gradually developed into a general components, resulting in a combined machine tool. The earliest combination machine is made in the United States in 1911, for the processing of auto parts. Initially, the machine tool manufacturingplant has its own general component standard. In order to improve different factory universal interchangeability of the parts, and is convenient for users to use and repair.The Design ProcessDesigning starts with a need real.Existing apparatus may need improvements in durability, efficiency, weight, speed, or cost. New apparatus may be needed to perform a function previouslydone by men, such as computation, assembly, or servicing. With the objective wholly or partlyIn the design preliminary stage, should allow to design the personnel fully to display the creativity, not each kind of restraint., namely in front of the plan blueprint is corrected. Only then, only then does not send to stops up the innovation the mentality. Usually, must propose several sets of design proposals, then perform the comparison. Has the possibility very much in the plan which finally designated, has used certain not in plan some ideas which accepts.When the general shape and a few dimensions of the several components become apparent, analysis can begin in earnest. The analysis will have as its objective satisfactory or superior performance, plus safety and durability with minimum weight, and a competitive cost. Optimum proportions and dimensions will be sought for each critically loaded section, together with a balance between the strengths of the several components. Materials and their treatment will be chosen. These important objectives can be attained only by analysis based upon the principles of mechanics, such as those of static for reaction forces and for the optimum utilization of friction; of dynamics for inertia, acceleration, and energy; of elasticity and strength of materials for stress and deflection; of physical behavior of materials; and of fluid mechanics for lubrication and hydrodynamic drives. The analyses may be made by the same engineer who conceived the arrangement of mechanisms, or, in alarge company, they may be made by a separate analysis division or research group. Design is a reiterative and cooperative process, whether done formally or informally, and the analyst can contribute to phases other than his own. Product design requires much research and development. Many Concepts of an idea must be studied, tried, and then either used or discarded. Although the content of each engineering problem is unique, the designers follow the similar process to solve the problems.Machinery design covers the following contents.1. Provides an introduction to the design process , problemformulation ,safety factors.2. Reviews the material properties and static and dynamic loading analysis ,Including beam , vibration and impact loading.3. Reviews the fundamentals of stress and defection analysis.4. Introduces fatigue-failure theory with the emphasis on stress-life approaches to high-cycle fatigue design, which is commonly used in the design of rotation machinery.5. Discusses thoroughly the phenomena of wear mechanisms, surface contact stresses ,and surface fatigue.6. Investigates shaft design using the fatigue-analysis techniques.7. Discusses fluid-film and rolling-element bearing theory and application8. Gives a thorough introduction to the kinematics, design and stress analysis of spur gears , and a simple introduction to helical ,bevel ,and worm gearing.9. Discusses spring design including compression ,extension and torsion springs.10. Deals with screws and fasteners including power screw and preload fasteners.11. Introduces the design and specification of disk clutches and brakes.。

编号本科生毕业设计架体（4⨯Φ15）钻孔组合机床设计Frame body (415) Drilling Machine Tool Design学生姓名专业机械制造及其自动化学号指导教师分院机电工程分院年月摘要本机床设计是架体（4⨯Φ15）钻孔组合机床，组合机床是以通用部件为基础，配以少量专用部件，对一种或若干种工件按预先确定的工序进行加工的机床。

它能够对工件进行多刀、多轴、多面、多工位的同时加工，机床自动化程度高。

并根据零件加工工艺方法，使设计的机床能达到其要求的加工精度、表面粗糙度及技术要求。

机床包括主轴箱、动力箱、滑台、床身、中间底座；而我主要是设计主轴箱，根据动力箱输出轴的转速520r/min，通过一系列的齿轮传动，达到我所设计的主轴转速633r/min。

传动比为1/1.2也达到了为使结构紧凑的目的。

在传动比方面采用的是在最后一级使传动比升速是为了使主轴上的齿轮不过大，也到达了传动系统的要求。

遵循主轴部件结构的主要特征，前端轴承我采用了推力球轴承和向心球轴承的组合。

因为主轴是进行钻削加工，轴向切削力较大，所以选用了推力球轴承，而用向心球轴承承受径向力。

在传动系统方面我采用的是一根输出轴带动两根对称的中间轴，两根中间轴各带动两根主轴，符合传动系统的一般要求，做到了主要传动件规格少，数量少，体积小；这些便是我设计组合机床方案制定的主要内容。

关键词：切削用量主轴主轴箱动力箱齿轮ABSTRACTThis engine bed is according to is the braking was mad the pump body drill hole designs the aggregate machine-tool, the aggregate machine-tool is take the general part as a foundation, matches by the few special-purpose parts, according to the working procedure which determined in advance carries on the processing to one kind of or certain kind of work pieces the engine bed. It can carry on the multi- knives to the work piece, multiple spindle，the multi- surface, the multi- locations simultaneously the processing.Engine bed including headstock, power box, Skids platform ，lathe bed, middle foundation; But I mainly design the headstock, according to power box output shaft rotational speed 520r/min，Through a series of gear drive, achieved I design main axle rotational speed 567r/min。

Multi-purpose aggregate machine-tool time Timothy and Jacobs, Denis' A receives then then, outstanding Philip U.S.A. Michigan universitySummary:The aggregate machine-tool machining center may cause the demand which the processing manufacturing industry adapts changes unceasingly, uses the pool of labor power effectively, and has the competitive power in global scale's market. Key word: Make the lathe up Regarding the multi-purpose aggregate machine-tools, in the industrial field has many names to descr ibe it, like “the multitasking installment”, “the multi-purpose engine beds”, “the multi-procedure production system” and so on, it may be called the processing domain truly the nova, may reduce the cost, the simplified disposition, and has maintained in the US territory produces. In the past only then used the duty which many machine operations could complete, now may concentrate to an engine bed on processes completes. As a result of market demand's unceasing change, the product life cycle is reducing unceasingly, today's market more intense demand multitasking installment concept. Carries out the fine profit management when the entire production environment, compared to having not concentrated the components processing to a machine on completes a finer profit. Some tradition's manufacturing industry manufacturer thought that the multi-purpose aggregate machine-tools are too complex, very difficult to find the appropriate operators also the difficult problem innovates on the spot on the insufficiency for the metal working basic principle and in the Production workshop related new engine bed use solution aspect training. Intuition type technical control The equipment use “carries off the quantity of heat” the type design, has different material which the lathe bed, the steeliness straight line rolling guide, on the steeliness revolving tool box saddle, the equipment uses, all these combine make an engine bed together. These with the thermal conductivity, the volume expansion are related. All different size's thing can by the different speed growth. As a result of this reason, needs to make the hot friendly engine bed, with the aim of knowing gives off heat the weak point in where, can compensate through the reasonable engine bed design. The part is the entire journey movement. The engine bed glide produces rubs and transform hotly. The machining produces the hot filings fall to the different place, the refrigerant can mix in the entire process in which. Will present the different temperature province continually on the cutting tool, will therefore also have many things to have the influence to the thermostability. The cutting tool technology turned the multi-purpose aggregate machine-tools has had the milling and cutting power “the versatile machine”. According t o the material introduced that the most remarkable characteristic is in these engine bed whole has the intuition. The anti-collision preservation technology was already mature, in certain circumstances, even if uses the manual operation pattern, can also avoid the occurrence which collides. Because the control software has the very good intuition, the user operation friendly degree unceasingly is also enhancing. Believe the multi-purpose aggregate machine-tools by its survivability world-wide in the more different processing scenes. The off-line programming optimization and the NC automatic control system's formation alreadymade this technology to be easier to accept, when therefore uses the procedure when the engine bed, does not need to spend many time tune-up procedure and confirmed that some part does not have the question. If components need to provide the high and low two revolving tool box saddle simultaneously to carry on the rough machining, in this kind of situation the programming is quite difficult, because it needs two revolving tool box saddles also to feed. The AdMac system may realize tool rest's automatic programming which simultaneously feeds to these, and can cause the correct main axle speed, the correct feed rate and so on all parameters to realize the synchronization. Okuma Corporation's collision avoidance system design based on actual processing operating mode anti-collision simulation, therefore, if the operator has installed the wrong cutting tool or has established the wrong parameter, the control system will examine and prevents the engine bed to enter the processing condition. Through cooperates with the Siemens, INDEX Corporation may provide the 3D pattern now “the hypothesized engine bed”, has custom-made according to some specific model's engine bed. The result indicated that the simulation processes not only the fabricated parts and the actual end product is similar, is the one-to-one copy simply. The intuition type control interface, the simulation as well as other software technique are progressive, the more Production workshops have opened wide the front door to the multi-purpose aggregate machine-tools, but if does not have the corresponding knowledge to train and to solve the question creativity, the manufacturer is also very difficult to realize and the full use advanced engine bed flexibility aspect superiority. The work which does to the machine are more, the machine will be more complex, also needs to have the stronger skill person correspondingly to be able to operate it. If machinist past one day operated 3 engine beds, then he has this kind of multi-purpose engine bed now, might produce more components. More importantly, he may draw support from software's help to cause the production efficiency to be higher, regarding transformation processing components preparation, may also establish the processing craft plan. Because the replacement components need to lower 3 main axles, therefore before replacing the components, the workshop should process as far as possible many components. Regarding the multi-purpose engine beds, the transformation components speed is quick, the production batch of time interval is shorter, the stock is lower, the production efficiency is higher. Can use multi-purpose engine bed's some workshops fully, very quick will discover the post function the unification. Now, a workshop may only use an operator, an adjuster and a programming teacher, in the future these 3 work definitely may do by a person. In the traditional post description the machinist will transit becomes one to adjust engineer, if this engineer the familiar components processing programming, that were also more ideal. Regarding such transformation, training has been simple, so long as trains 1 individual line, but is not 3 individuals. Looking from the long views, this will provide to the people the higher post degree of satisfaction. When adjusts engineer to be responsible to process the programming, and pays attention to the components processing personally time the entire process, he completely has become this components control. In addition, but should also makes more effort in the cutting tool choice and the programming aspect, must make anymodel the multi-purpose aggregate machine-tool to succeed, the workshop needs to provide the skilled machinist, has ability and completes many kinds of operations nimbly. Therefore, crosswise training was at any time in the past more important. Regarded as the milling and the lathe work the different discipline the viewpoint never to return. Regarding the programmers, this belongs to their time. Regarding personnel who will program, will understand the engine bed and controls it, this will be their ability manifestation. The cutting tool will choose most people not to install the passenger vehicle tire to the race car on, but processed the cutting tool to have such situation. The cutting tool should match with the new engine bed, is conceivably redundant on the new engine bed uses the old cutting tool to the production efficiency influence. In order to match the multi-purpose aggregate machine-tools, the new cutting tool and the cutting tool adapter technology was already developed. At present the industrial field is developing the development the processing cutting tool, may complete the turning on the identical tool rest, boring and drills truncates the processing, is only processes the phase to differ from regarding the work piece angle. The processing operates the difference even confuses is unclear. The new processing cutting tool may complete the milling and the turning. Since has moved the technology (engine bed) is this century develops is extremely rapid and one of influence enormous science and technology. The modern automation technology is one kind of completely new productive forces, is one of direct creation public wealth principal means that is playing the enormous promotion effect to humanity's production activity and the material civilization. Therefore, the automated technology receives various countries widely to take seriously with more and more applications. As machine tool has a strong interchangeability, it is necessary to improve the general level of production technology components to improve the accuracy of parts. Complete specification, dynamic and static performance parameters of advanced.In the machinery manufacturing industry, accounting for about 70% of small and medium batch production, in some of the production enterprises, such as machine tools, valve industry, with its key process using combination of machine tools. The development of adjustable, quick transfer, assembly and flexible to adapt to the characteristics of multi-species processing machine tool is very urgent. Turret machine tool spindle box, can be combined for box-type machine tool spindle and automatic tool change CNC machine tool can be used for small batch production, but the complex structure of such machines, the cost is higher.The development of new tools. Improve the durability of the tool, greatly shorten the combination of machine tool downtime and more time for tool change and improve the economic benefits of the combined machine.To develop automatic detection technology. Automatically detect the size and bows and arrows, including the hardness of the blank check, drilling depth, cutting tools break, finishing size and geometry of the inspection, due to the rapid development of electronic components, integrated controller, microprocessor applications, is more automated detection technology reliable, and can be machined components control the actual size smaller than the prescribed tolerance range, but also the workpiece can beprocessed are grouped according to tolerance, so that by grouping tolerance assembly. The machinery automation (engine bed), mainly refers to the machine-building industry applies the automated technology, realizes the processing object continuously the automatic production, realizes the optimized effective automatic production process, the increase production investment processing transformation and the flow rate. The machinery automation technology's application and the development, are the machine-building industry technological transformations, the technology advancement principal means and the technological development main direction. Machinery automation technical standards, not only affects the entire machine-building industry the development, and has the very tremendous immediate influence to the national economy various departments' technology advancement. Therefore, develops our country's machine-building industry automation technology, conforms to our country socialism basic principle, conforms to our country modern production law of development. How to develop our country's machinery automation technology (engine bed), here has the technical policy question, should be realistic, all embark from our country's concrete national condition, do each foundation work, takes the China's road of machinery automation technological development. The domestic and foreign industry history tells us, realizes the machinery automation is from to high-level, from simply to complex, from is preliminarily imperfect the consummation the developing process. After machine's operation uses the automatic regulator, the production method only then gradually transits from the mechanization to the mechanism control (tradition) automated, the numerical control automation, the computer control automation. Only then after having established the Automated factory, the production process can overall automate, can make the productivity to enhance comprehensively, achieves automated the high-level ideal stage. The machinery automation technology first starts from the 1920s in the machine manufacture cold finishing production in enormous quantities process to develop the application, after in the 60s, to adapt the market demand and the change, for the enhancement machine-building industry to the market nimble rapid reaction's ability, starts to establish the variable automation production system, namely revolves the computer technology the flexible automation. It is in the manufacture system invariable or in the change small situation, the machinery equipment either production management process through the automatic detection, the information processing, the analysis judgment realizes the anticipated operation or some kind of process automatically, and can from make one kind of components to transform automatically to makes another kind of different components. The social practice proved that under this kind of definition's manufacture system automation and the contemporary majority enterprises are not actually accommodating. The contemporary society also not in the science and technology, the material and the personnel aspect prepares to realize this automated condition, insists such to do only meets the wasted effort. This kind of situation is not exceptional regarding the separate production method's machine-building industry, the difficulty can bigger. In the 80s internationally appeared started to use computer integration manufacture system CIMS (Computer Integrated Manufacturing), the flexible automation production pattern also had thiskind of situation. The initial period take the information integration as a key point, take the high automaticity as the characteristic, but in realized in the process to encounter the difficulty. In view of the fact that realizes the large amount investment which the computer integration manufacture system's automation overall needs (an overall Automated factory to spend several hundred hundred million US dollars, flexible manufacture system regular price is 600 ~ 25,000,000 US dollars), undertakes the huge risk, in addition questions and so on technical difficulty and reliability, the world industrially advanced country started “to run into a wall produces a dif ferent product”, transfers pays great attention the information integration the effect, pursues low cost automation LCA (Low Cost Automation) enterprise organizational structure and movement way. The aggregate machine-tool future development more use transmissions and so on variable speed motor and ball bearing guide screw, will simplify structure, the reduction production metre; Uses the numerical control system and the headstock, the jig automatic replacement system, enhances the craft controllability; As well as integrates the flexible manufacture system and so on. Machine tool and general purpose machine tools and other special machine comparison, has the following characteristics:1) The combination of machine tool parts and standard parts common about all the machine parts and components of the total 70 to 80%, so the design and manufacturing cycle is short, less investment, high efficiency, good economic results.2) The combination of multi-machine tool processing, and high degree of automation, so tools than general-purpose high production efficiency, product quality and stability, low labor intensity.3) General machine tool components are carefully designed and long-term production practice test, another batch manufacturing plant, so the structure stable, reliable, easy to use and maintenance.4) When processing parts on a combination machine, the use of special fixtures, tools and guidance devices, processing quality assurance by the technology and equipment, less demanding on the operative level.5) When the processing of product updates, the use of other types of special machine tools, its most of the pieces to be scrapped. Combination machine tool, its common parts and standard parts can be reused, do not be designed and manufactured.6) machine tool automatic machine tool easily linked into line to meet the needs of large-scale production. Machine tool commonly used in general components are: body, base, column, power box, power slide, cutting a variety of first class technology. For some sequential processing by the multi-station machine tool, also has a movable table or rotary table. Power box, cutting head and a variety of technology is a combination of power sliding table cutting machine to complete the main campaign or feed movement of the power unit. Also managed to complete the cutting of which the main movement and feed movement of the power head. Body, column, the middle base is a combination of machine tools and other supporting components, play a machine based skeleton. Machine tool parts between rigidity and accuracy of preservation, mainly by these parts guarantee.多功能组合机床美国密歇根大学菲利普摘要：总的机床加工中心需求的变化，这可能会导致加工制造业不断变化，采用有效的劳动力集中，并在全球范围内提高市场竞争力。

毕业设计题目:两缸柴油机机体8-M8螺纹底孔组合钻床的总体设计及主轴箱设计学科部：___________________________________专业：____________________________________班级：____________________________________学号：____________________________________学生姓名：_________________________________指导教师：_________________________________起讫日期：_________________________________中文摘要本次设计是对卧式单面8 轴组合钻床的设计，设计的内容包括组合钻床的总体设计以及多轴箱的设计。

组合钻床的总体设计主要是“三图”的设计。

三图的设计包括：被加工零件工序图、加工示意图、机床联系尺寸图。

多轴箱的设计关键是传动系统方案的确定。

再根据传动系统图确定手柄轴和油泵轴的位置安排，然后进行坐标计算，绘制多轴箱装配总图，箱体补充加工图，前盖补充加工图、最后根据上面的内容设计组合钻床。

关键子字：组合钻床、多轴箱、被加工零件工序图、加工示意图、机床联系尺寸图。

外文摘要This design is to horizontal axis combination drilling machine of single anddesign, the design of content including combination drilling machine of the overall design and the design of the spindle box. Combination drilling machine of the overall design mainly is the "three figure" design. The design of the three figure includes: processing parts process diagram, processing schemes, machine tool contact size figure. The design of the spindle box is key to the scheme determination of transmission system. Again according to the transmission system graph determine the handle axis and oil pump shaft placement, and then coordinate calculation, draw spindle box of general assembly, the casing is added processing figure, the front cover added processing diagram, according to the content of the above design combination drilling machine.Key son word : combination drilling machine, spindle box, be processing parts process diagram, processing schemes, machine tool contact size figure.、尸■、亠前言组合机床是用按系列化标准化设计的通用部件和按被加工零件的形状及加工工艺要求设计的专用部件组成的专用机床。

Conventional Machining ProcessesConventional machining is the group of machining operations that use single- or multi-point tools to remove material in the form of chips. Metal cutting involves removing metal through machining operations. Machining traditionally takes place on lathes, drill presses, and milling machines with the use of various cutting tools. Most machining has very low set-up cost compared with forming, molding, and casting processes. However, machining is much more expensive for high volumes. Machining is necessary where tight tolerances on dimensions and finishes are required.Turning is one of the most common of metal cutting operations. In turning, a workpiece is rotated about its axis as single-point cutting tools are fed into it, shearing away excess material and creating the desired cylindrical surface. Turning can occur on both external and internal surfaces to produce an axially-symmetrical contoured part. Parts ranging from pocket watch components to large diameter marine propeller shafts can be turned on a lathe.Apart from turning, several other operations can also be performed on lathe.Boring and internal turning. Boring and internal turning are performed on the internal surfaces by a boring bar or suitable internal cutting tools. If the initial workpiece is solid, a drilling operation must be performed first. The drilling tool is held in the tailstock, and the latter is then fed against the workpiece. When boring is done in a lathe, the work usually is held in a chuck or on a face plate. Holes may be bored straight, tapered, or to irregular contours. Boring is essentially internal turning while feeding the tool parallel to the rotation axis of the workpiece.Facing is the producing of a flat surface as the result of a tool’s being fed across the end of the rotating workpiece. Unless the work is held on a mandrel, if both ends of the work are to be faced, it must be turned around after the first end is completed and then the facing operation repeated. The cutting speed should be determined from the largest diameter of the surface to be faced.Facing may be done either from the outside inward or from the center outward. In either case, the point of the tool must be set exactly at the height of center of rotation.Because the cutting force tends to push the tool away from the work, it is usually desirable to clamp the carriage to the lathe bed during each facing cut to prevent it from moving slightly and thus producing a surface that is not flat. In the facing of casting or other materials that have a hard surface, the depth of the first cut should be sufficient to penetrate the hard material to avoid excessive tool wear.Parting is the operation by which one section of a workpiece is severed from the remainder by means of cutoff tool. Because cutting tools are quite thin and must have considerable overhang, this process is less accurate and more difficult. The tool should be set exactly at the height of axis of rotation, be kept sharp, have proper clearance angles, and be fed into the workpiece at a proper and uniform feed rate.Threading can be considered as turning since the path to be travelled by the cutting tool is helical. However, there are some major differences between turning and threading. While in turning, the interest is in generating a smooth cylindrical surface, in threading the interest is in cutting a helical thread of a given form and depth which can be calculated from the formulae. There are two basic requirements for thread cutting. An accurately shaped and properly mounted tool is needed because thread cutting is a form-cutting operation. The resulting thread profile is determined by the shape of the tool and its position relative to the workpiece.The second by requirement is that the tool must move longitudinally in a specific relationship to the rotation of workpiece, because this determines the lead of the thread. This requirement is met through the use of the lead screw and the split unit, which provide positive motion of carriage relative to the rotation of spindleLathe bed is foundation of the engine lathe, which heavy, rugged casting is made to support the working parts of the lathe. The size and mass of the bed gives the rigidity necessary for accurate engineering tolerances required in manufacturing. On top of the bed are machined slideways that guide and align the carriage and tailstock, as they are move from one end of the lathe to the other.Headstock is clamped atop the bed at left-hand end of the lathe and contains the motor that drives the spindle whose axis is parallel to the guideways through a series of gears housed within the gearbox. The function of gearbox is to generate a number of different spindle speeds. A spindle gear is mounted on the rear of the spindle to transmit power through the change gears to the feeding box that distributes the power to the lead screw for threading or to the feed rod for turning.The spindle has a through hole extending lengthwise through which bar stocks can be fed if continuous production is used. The hole can hold a plain lathe center by its tapered inner surface and mount a chuck, a face plate or collet by its threaded outer surface.Carriage assembly is actually an H-shaped block that sits across the guideways and in front of lathe bed. The function of the carriage is to carry and move the cuttingtool longitudinally. It can be moved by hand or by power and can be clamped into position with a locking nut. The carriage is composed of the cross slide, compound rest, tool saddle, and apron.The cross slide is mounted on the dovetail guideways on the top of the saddle and it moved back and forth at 90°to the axis of the lathe by the cross slide lead screw. The lead screw can be hand or power activated.The compound rest is mounted on the cross slide and can be swiveled and clamped at any angle in a horizontal plane. The compound is typically used for cutting chamfers or tapers, but must also be used when cutting thread. The compound rest can only be fed by hand. There is no power to compound rest. The cutting tool and tool holder are secured in the tool post which is mounted directly to the compound rest.The tool saddle is an H shaped casting mounted on the top of the guideways and houses the cross slide and compound rest. It makes possible longitudinal, cross and angular feeding of the tool bit.The apron is attached to the front of the carriage and contains the gears and feed clutches which transmit motion from the feed rod or lead screw to carriage and cross slide. When cutting screw threads, power is provided to the gearbox of the apron by the lead screw. In all other turning operations, it is the feed rod that drives the carriage.Tailstock is composed of a low base and the movable part of the tail-stock proper, the transverse adjustments being made with a cross screw furnished with a square head. The two parts are hold together by the holding-down bolts which secure the tailstock to the bed.。

The machinability of materialThe machinability of a material usually defined in terms of four factors:(1). Surface finish and integrity of the machined part;(2). Tool life obtained;(3). Force and power requirements;(4). Chip control.Thus, good machinability good surface finish and integrity, long tool life, and low force And power requirements. As for chip control, long and thin (stringy) cured chips, if not broken up, can severely interfere with the cutting operation by becoming entangled in the cutting zone.Because of the complex nature of cutting operations, it is difficult to establish relationships that quantitatively define the machinability of a material. In manufacturing plants, tool life and surface roughness are generally considered to be the most important factors in machinability. Although not used much any more, approximate machinability ratings are available in the example below.1. Machinability Of SteelsBecause steels are among the most important engineering materials , their machinability has been studied extensively. The machinability of steels has been mainly improved by adding lead and sulfur to obtain so-called free-machining steels.Resulfurized and Rephosphorized steels. Sulfur in steels forms manganese sulfide inclusions (second-phase particles), which act as stress raisers in the primary shear zone. As a result, the chips produced break up easily and are small; this improves machinability. The size, shape, distribution, and concentration of these inclusions significantly influence machinability. Elements such as tellurium and selenium, which are both chemically similar to sulfur, act as inclusion modifiers in resulfurized steels.Phosphorus in steels has two major effects. It strengthens the ferrite, causing increased hardness. Harder steels result in better chip formation and surface finish. Note that soft steels can be difficult to machine, with built-up edge formation and poor surface finish. The second effect is that increased hardness causes the formation of short chips instead of continuous stringy ones, thereby improving machinability.Leaded Steels. A high percentage of lead in steels solidifies at the tip of manganese sulfide inclusions. In non-resulfurized grades of steel, lead takes the form of dispersed fine particles. Lead is insoluble in iron, copper, and aluminum and their alloys. Because of its low shear strength, therefore, lead acts as a solid lubricant and is smeared over the tool-chip interface during cutting. This behavior has been verified by the presence of high concentrations of lead on the tool-side face of chips when machining leaded steels.When the temperature is sufficiently high-for instance, at high cutting speeds and feeds —the lead melts directly in front of the tool, acting as a liquid lubricant. In addition to this effect, lead lowers the shear stress in the primary shear zone, reducing cutting forces and power consumption. Lead can be used in every grade of steel, such as 10xx, 11xx, 12xx, 41xx, etc. Leaded steels are identified by the letter L between the second and third numerals (for example, 10L45). (Note that in stainless steels, similar use of the letter L means “low carbon,” a condition that improves their corrosion resistance.)However, because lead is a well-known toxin and a pollutant, there are serious environmental concerns about its use in steels (estimated at 4500 tons of lead consumption every year in the production of steels). Consequently, there is a continuing trend toward eliminating the use of lead in steels (lead-free steels). Bismuth and tin are now being investigated as possible substitutes for lead in steels.Calcium-Deoxidized Steels. An important development is calcium-deoxidized steels, in which oxide flakes of calcium silicates (CaSo) are formed. These flakes, in turn, reduce the strength of the secondary shear zone, decreasing tool-chip interface and wear. Temperature is correspondingly reduced. Consequently, these steels produce less crater wear, especially at high cutting speeds.Stainless Steels. Austenitic (300 series) steels are generally difficult to machine. Chatter can be s problem, necessitating machine tools with high stiffness. However, ferritic stainless steels (also 300 series) have good machinability. Martensitic (400 series) steels are abrasive, tend to form a built-up edge, and require tool materials with high hot hardness and crater-wear resistance. Precipitation-hardening stainless steels are strong and abrasive, requiring hard and abrasion-resistant tool materials.The Effects of Other Elements in Steels on Machinability. The presence of aluminum and silicon in steels is always harmful because these elements combine with oxygen to form aluminum oxide and silicates, which are hard and abrasive. These compounds increase tool wear and reduce machinability. It is essential to produce and use clean steels.Carbon and manganese have various effects on the machinability of steels, depending on their composition. Plain low-carbon steels (less than 0.15% C) can produce poor surface finish by forming a built-up edge. Cast steels are more abrasive, although their machinability is similar to that of wrought steels. Tool and die steels are very difficult to machine and usually require annealing prior to machining. Machinability of most steels is improved by cold working, which hardens the material and reduces the tendency for built-up edge formation.Other alloying elements, such as nickel, chromium, molybdenum, and vanadium, which improve the properties of steels, generally reduce machinability. The effect of boron is negligible. Gaseous elements such as hydrogen and nitrogen can have particularly detrimental effects on the properties of steel. Oxygen has been shown to have a strong effect on the aspect ratio of the manganese sulfide inclusions; the higher the oxygen content, the lower the aspect ratio and the higher the machinability.In selecting various elements to improve machinability, we should consider the possible detrimental effects of these elements on the properties and strength of the machined part in service. At elevated temperatures, for example, lead causes embrittlement of steels (liquid-metal embrittlement, hot shortness), although at room temperature it has no effect on mechanical properties.Sulfur can severely reduce the hot workability of steels, because of the formation of iron sulfide, unless sufficient manganese is present to prevent such formation. At room temperature, the mechanical properties of resulfurized steels depend on the orientation of the deformed manganese sulfide inclusions (anisotropy). Rephosphorized steels are significantly less ductile, and are produced solely to improve machinability.2. Machinability of Various Other MetalsAluminum is generally very easy to machine, although the softer grades tend toform a built-up edge, resulting in poor surface finish. High cutting speeds, high rake angles, and high relief angles are recommended. Wrought aluminum alloys with high silicon content and cast aluminum alloys may be abrasive; they require harder tool materials. Dimensional tolerance control may be a problem in machining aluminum, since it has a high thermal coefficient of expansion and a relatively low elastic modulus.Beryllium is similar to cast irons. Because it is more abrasive and toxic, though, it requires machining in a controlled environment.Cast gray irons are generally machinable but are. Free carbides in castings reduce their machinability and cause tool chipping or fracture, necessitating tools with high toughness. Nodular and malleable irons are machinable with hard tool materials.Cobalt-based alloys are abrasive and highly work-hardening. They require sharp, abrasion-resistant tool materials and low feeds and speeds.Wrought copper can be difficult to machine because of built-up edge formation, although cast copper alloys are easy to machine. Brasses are easy to machine, especially with the addition pf lead (leaded free-machining brass). Bronzes are more difficult to machine than brass.Magnesium is very easy to machine, with good surface finish and prolonged tool life. However care should be exercised because of its high rate of oxidation and the danger of fire (the element is pyrophoric).Molybdenum is ductile and work-hardening, so it can produce poor surface finish. Sharp tools are necessary.Nickel-based alloys are work-hardening, abrasive, and strong at high temperatures. Their machinability is similar to that of stainless steels.Tantalum is very work-hardening, ductile, and soft. It produces a poor surface finish; tool wear is high.Titanium and its alloys have poor thermal conductivity (indeed, the lowest of all metals), causing significant temperature rise and built-up edge; they can be difficult to machine.Tungsten is brittle, strong, and very abrasive, so its machinability is low, although it greatly improves at elevated temperatures.Zirconium has good machinability. It requires a coolant-type cutting fluid, however, because of the explosion and fire.3. Machinability of Various MaterialsGraphite is abrasive; it requires hard, abrasion-resistant, sharp tools.Thermoplastics generally have low thermal conductivity, low elastic modulus, and low softening temperature. Consequently, machining them requires tools with positive rake angles (to reduce cutting forces), large relief angles, small depths of cut and feed, relatively high speeds, andproper support of the workpiece. Tools should be sharp.External cooling of the cutting zone may be necessary to keep the chips from becoming “gummy” and sticking to the tools. Cooling can usually be achieved with a jet of air, vapor mist, or water-soluble oils. Residual stresses may develop during machining. To relieve these stresses, machined parts can be annealed for a period of time at temperatures ranging from C ︒80 to C ︒160 (F ︒175to F ︒315), and then cooled slowly and uniformly to room temperature.Thermosetting plastics are brittle and sensitive to thermal gradients during cutting. Their machinability is generally similar to that of thermoplastics.Because of the fibers present, reinforced plastics are very abrasive and are difficult to machine. Fiber tearing, pulling, and edge delamination are significant problems; they can lead to severe reduction in the load-carrying capacity of the component. Furthermore, machining of these materials requires careful removal of machining debris to avoid contact with and inhaling of the fibers.The machinability of ceramics has improved steadily with the development of nanoceramics and with the selection of appropriate processing parameters, such as ductile-regime cutting .Metal-matrix and ceramic-matrix composites can be difficult to machine, depending on the properties of the individual components, i.e., reinforcing or whiskers, as well as the matrix material.4. Thermally Assisted MachiningMetals and alloys that are difficult to machine at room temperature can be machined more easily at elevated temperatures. In thermally assisted machining (hotmachining), the source of heat—a torch, induction coil, high-energy beam (such as laser or electron beam), or plasma arc—is forces, (b) increased tool life, (c) use of inexpensive cutting-tool materials, (d) higher material-removal rates, and (e) reduced tendency for vibration and chatter.It may be difficult to heat and maintain a uniform temperature distribution within the workpiece. Also, the original microstructure of the workpiece may be adversely affected by elevated temperatures. Most applications of hot machining are in the turning of high-strength metals and alloys, although experiments are in progress to machine ceramics such as silicon nitride.SUMMARYMachinability is usually defined in terms of surface finish, tool life, force and power requirements, and chip control. Machinability of materials depends not only on their intrinsic properties and microstructure, but also on proper selection and control of process variables.材料的可机加工性一种材料的可机加工性通常以四种因素的方式定义：（1）、分的表面光洁性和表面完整性。

毕业设计(论文)外文资料翻译系部：机械工程系专业：机械工程及自动化姓名：学号：外文出处Optimal Process Planning for a CombinedPunch-and-Laser Cutting Machine UsingAnt Colony Optimization附件： 1.外文资料翻译译文；2.外文原文。

注：请将该封面与附件装订成册。

附件1：外文资料翻译译文蚁群优化—冲压激光组合机床的最佳工艺设计方法摘要一部既能进行冲压又能进行激光切割操作的机器就是所谓的冲压激光组合机床。

这种类型的机床在市场上已经有二十年了。

尽管工序设计软件已经用于这类组合机床的设计，但是从我们搜索的结果来看，这类组合机床最优的工序设计还没有被直接研究出来。

本文提到的冲压激光组合机床的问题可通过整合知识，定量分析和数字优化等方法来解决。

这些方法又带来了下面的问题：（Ⅰ）每一个功能应该有什么样的操作，（Ⅱ）什么是最佳操作序列（工具路径）以实现最大生产效率。

蚁群优化（蚁群优化）算法被用来寻找最佳的刀具轨迹。

而且有关其灵敏度的控制参数也得到了分析。

通过研制，这种方法可以大大地提高冲压激光组合机床的工作效率。

这种方法也很容易自动化和整合生成G-代码子程序，而且与此相关的课题也在进行着研究。

关键词组合机床冲压激光组合机床金属板工序设计最优化蚁群优化1 引言现代计算机数字控制（数控）转塔式机床作为被高度广泛应用的工作机，有着快速精确地生产金属薄板和塑料部件的能力。

然而，这种转塔式机床的变化只能限定材料是通过冲压操作从工件上去除的。

当工件有很大一部分面积要去除时，或者当工件需要被分成许多独立的工件时，再或者要制造相当长或者大的直径零配件时，这只能通过一系列重复的冲压操作才能完成材料的去除。

这样的重复的去除材料的操作有效地增加冲床的多功能性。

但是，这些操作，有时，导致了不想要的结果，比如形成不清晰的轮廓，不能进行高度精确的生产，粗糙的边以及相关操作的缓慢等（克拉克和卡波恩，1980年）。

英语原文：Integrated Machine and Control DesignAbstract—In this paper, we describe a systematic design procedure for reconfigurable machine tools and their associated control systems. The starting point for the design is a set of operations that must be performed on a given part or part family. These operations are decomposed into a set of functions that the machine must perform and the functions are mapped to machine modules, each of which has an associated machine control module. Once the machine is constructed from a set of modules, the machine control modules are connected. An operation sequence control mod ule, user interface control module, and mode-switching logic complete the control design. The integration of the machine and control design and the reconfigurability of the resulting machine tool are described in detail.I. IntroductionIn today’s competitive markets, manufacturing systems must quickly respond to changing customer demands and diminishing product life cycles. Traditional transfer lines are designed for high volume production, operate in a fixed automation paradigm, and therefore cannot readily accommodate changes in the product design. On the other hand, conventional CNC-based “flexible” manufacturing system offer generalized flexibility but are generally slow and expensive since they are not optimized for any particular product or a family of products.An effort at the University of Michigan aims to develop the theory and enabling technology for reconfigurable machining systems. Instead of building a machining system from scratch each time a new part is needed, an existing system can be reconfigured to produce the new part. In this paper, we describe how an integrated machine and control design strategy can result in machine tools which can be quickly and easily configured and reconfigured.In order to provide exactly the functionality and capacity needed to process a family of parts, RMTs are designed around a given family of parts. Given a set of operations to be performed, RMTs can be configured by assembling appropriate machine modules. Each active module in the library has a control module associated with it. As the mechanical modules are assembled, the control modules will be connected and the machine will be ready to operate. Extensive and time-consuming specialized control system design will not be required. Section II describes how the machine is designed from a set of basic machine modules,This research was supported in part by the NSF-ERC connected in a well-defined fashion, and Section III describes how the control is similarly assembled from a library of control modules. This modular construction of the machine and control allows formany levels of reconfigurability as described in Section IV. The paper concludes with a description of future work in Section V.II. Machine DesignOngoing work on manufacturing system configuration at the University of Michigan addresses the problem of starting from a part (or part family) description and extracting the machining operations necessary to produce the part(s). The operations are grouped according to tolerance, order of execution, and desired cycle time of the system, with the intention that each operation “cluster” can be produced on a single machine tool. The operation cluster considered here is to drill a set of holes for the cam tower caps on V6 and V8 cylinder heads shown in Figure 1. The input to the reconfigurable machine tool design procedure is the cutter location data generated by a process planner for this operation cluster. data includes positioning and drilling information.The RMT design procedure consists of three main stages: task clarification, module selection, and evaluation. After a brief literature review, these three stages will be outlined in this section.A. Related researchSince reconfigurability is a relatively new concept in ma chining systems, there is little, if any, published literature on the design of reconfigurable machine tools. However, modular machine tools have been on the market for several years, and some of the published articles on modular robots, modular machines and assembly do have some rel-evance to the design of reconfigurable machine tools. For example, Shinno and Ito proposed a methodology for generating the structural configuration of machine tools. They decomposed the machine tool structures into simple geometric forms: e.g. boxes, cylinders, etc. Yan and Chen [21], [1] extended this work to the ma chining center structural design. [12] adapted Ito’s method for modular machine t ool synthesis and de-veloped a method for enumerating machine tool modules. Paradis and Khosla [15] determined the modular assembly configuration which is optimally suited to perform a specific task. On the systems front, Rogers and Bottaci [16] discussed the significance of reconfigurable manufacturing systems, and Owen et al. [13] developed a modular reconfigurable manufacturing system synthesis program for educational pur poses.In our work, traditional methods of motion representation and topology (i.e. screw theory, graph theory, etc.) are employed to capture the characteristics of RMTs. These mathematical schemes are used for topological synthesis, function-decomposition, and mapping procedures; details can be found in [9].Figure 1B.Task clarificationThe design of an RMT begins with task clarification, which entails analyzing the cutter location data to determine the set of functions which are necessary to accomplish the desired kinematic motions. There are three steps. First, graphs are generated which abstractly representationFig. 3. High-level operation sequence, showing causal dependencies and concurrencies.This abstract representation of the sequence of operations is derived from the CL data, and will be used to design the sequencing control the motions. These graphs are then decomposed into functions, and finally the functions are mapped onto machine modules which exist in the library.A graph representation of the machine tool structure allows for systematic enumeration of alternate configurations and also provides a method of identification of nonisomorphic graphs. The graph representation is also used for bookkeeping to assign machine modules to the graph elements. A graph consists of a set of vertices connected together by edges. In using a graph as an abstract represen tation of a machine tool structure, we define two different types of vertices: type 0 and type 1. A vertex represents a physical object with two ports; each port represents the location on the object where it can be attached to a neighboring object. A type 0 vertex has input and output ports that are in-line with respect to each other, whereas a type 1 vertex has input and output ports that are perpendicular to each other. Machining tasks are also classified as type 0 or type 1, depending on whether the tool is parallel or per pendicular to the workpiece.C. Module selectionCommercially available modules are selected from the module library for each ofthe functions (structural as well as kinematic) that were mapped to the graph in the task clarification stage. The data stored for each module in the library includes the homogenous transformation matrix representing its kinematic or structural function, the twist vector supplemented by range of motion information, a compliance matrix representing the module stiffness, module connectivity information, and power requirements (for active modules such as spindles and slides).The first step in module selection is to compare the homogeneous transformation matrices of the modules with the task requirement matrix such that when appropriate modules are selected to meet the task requirements, the product of all module matrices should be equal to the desired task matrix: T = T1· T2 · · · Tn. Again, there may be many possible choices of modules for a given structural configuration. Figure 6 shows how different slides, spindles, and structural elements can be assembled according to the graph of Figure 4.A slide module, with its CAD model and transformation matrix, is shown in Figure7. It is capable of one direction of linear motion, indicated by the ~1 variable in its transformation matrix. Its database entry, shown in Table I, stores not only its transformation matrix but also the manufacturer name, model number, initial position, power level, and motion data. The twist vector is augmented by information on the minimum, initial, and maximum displacement of the module.TABLE IDatabase information and documentation for the machinemodule shown in Figure 7.(a) V6 machine (b) V8 machineFig. 2. Reconfigurable machine tool designs for the two different parts.D. EvaluationOnce a set of kinematically-feasible modules have been selected, the resulting machine design must be evaluated. The criteria for evaluation of the reconfigurable machine tools synthesized by the above systematic procedure include the work envelope, the number of degrees of freedom, the number of modules used, and the dynamic stiffness.The number of kinematic degrees of freedom of the machine tool must be kept to a minimum required to meet the requirements, both to reduce the actuation power and minimize the chain of errors. Machine tool designs which are generated using this methodology for the example parts of Figure 1 are shown in Figure 8.The resulting designs must be evaluated with respect to the expec ted accuracy. The stiffness of the entire machine tool, one of the most important factors in performance, is estimated based on the module compliance matrices and the connection method.III. Control DesignAs the machine is built from modular elements, so is the control. In this work, we focus on the logic control for sequencing and coordination of the machine modules; a discrete-event system formalism is used [6]. There is one control module associated with each active machine module; we refer to these as machine control modules. In the machine design, there are passive elements which connect the active elements together. In the control design, there must also be“glue” modules which connect the machine control modules. The overall architecture of the control system for an RMT is shown in Figure 9.The structure is similar for either of the two machines shown in Figure 8; for the V8 machine, there is no Y -axis control module. As shown, the machine control modules are at the lowest level; these interact directly with the mechanical system. Three modules handle the mode switching logic. In this section, we briefly describe each of these types of control modules as well as their interaction and coordina tion.A. Machine control modulesEach machine control module has awell-defined interface specification: itaccepts discrete-event commands from agiven set, and returns discrete-eventresponses from a given set. Within thecontrol module will be all of the continuous-variable control, such as servo control foraxes. This continuous control is designedusing standard PID algorithms and the axisparameters such as inertia, power, lead screw pitch, which come from the machine module definition. In addition, each machine control module will contain con trols for any machine services associated with the machine module, such as lubrication or coolant. Thus, each machine control module is a self-contained controller for the machinemodule itaccompanies, and can bedesigned andtestedindependentlyof the rest ofthe machine.Fig.10.Slide ControllerThe design of a machine control module must be done only once for each machine module in the library. Whenever the machine module is used in a machine design, the control module can be used in the associated control design. The control module may be used independently, with its own processing power, I/O and a network connection to the rest of the control system, or it may be used as a piece of the overall machine controller which is implemented in a centralized fashion.B. Operation sequenceThe operation sequence module is defined from the high level sequence extracted from the cutter location data shown in Figure 3.C. Modular control structureThe user interface control module interacts with the user through a set of pushbuttons to turn the control system on and off, switch between control modes, and single-step through the operation sequence. Its main functions are to pass the user commands through to the rest of the controller, and to display the current state of the machine to the user.IV. Conclusions and Future WorkHistorically, machine tool design has been experience based. In this research, we described a mathematical basis for synthesis and evaluation of Reconfigurable Machine Tools and their associated controllers. This research work has addressed both the generation of machine tool configurations and modular control design. The systematic design process begins with the machining requirements.The presented methodology for synthesis of machine tools allows a library of machine modules to be precompiled and stored in a database, self-contained with con-trollers and ready to be used in any machine design. The methodology also ensures that all kinematically viable and distinctly different configurations are systematically enu-merated to reduce the chance of missing a good design.We have already developed a Java-based program which automates the machinedesign process; we are currently incorporating the control design procedure withi n the existing framework.The authors would like to acknowledge the support and invaluable feedback from the industrial members of the ERC who have participated in this project.中文译文组合机床与控制设计摘要——在本文中，我们描述一个系统的设计程序的可重构机床及其控制系统。

毕业设计(论文)外文资料翻译系部：专业：姓名：学号：外文出处：English For Electromechanical(用外文写)Engineering附件：1.外文资料翻译译文；2.外文原文。

附件1：外文资料翻译译文机床机床是用于切削金属的机器。

工业上使用的机床要数车床、钻床和铣床最为重要。

其它类型的金属切削机床在金属切削加工方面不及这三种机床应用广泛。

车床通常被称为所有类型机床的始祖。

为了进行车削，当工件旋转经过刀具时，车床用一把单刃刀具切除金属。

用车削可以加工各种圆柱型的工件，如：轴、齿轮坯、皮带轮和丝杠轴。

镗削加工可以用来扩大和精加工定位精度很高的孔。

钻削是由旋转的钻头完成的。

大多数金属的钻削由麻花钻来完成。

用来进行钻削加工的机床称为钻床。

铰孔和攻螺纹也归类为钻削过程。

铰孔是从已经钻好的孔上再切除少量的金属。

攻螺纹是在内孔上加工出螺纹，以使螺钉或螺栓旋进孔内。

铣削由旋转的、多切削刃的铣刀来完成。

铣刀有多种类型和尺寸。

有些铣刀只有两个切削刃，而有些则有多达三十或更多的切削刃。

铣刀根据使用的刀具不同能加工平面、斜面、沟槽、齿轮轮齿和其它外形轮廓。

牛头刨床和龙门刨床用单刃刀具来加工平面。

用牛头刨床进行加工时，刀具在机床上往复运动，而工件朝向刀具自动进给。

在用龙门刨床进行加工时，工件安装在工作台上，工作台往复经过刀具而切除金属。

工作台每完成一个行程刀具自动向工件进给一个小的进给量。

磨削利用磨粒来完成切削工作。

根据加工要求，磨削可分为精密磨削和非精密磨削。

精密磨削用于公差小和非常光洁的表面，非精密磨削用于在精度要求不高的地方切除多余的金属。

车床车床是用来从圆形工件表面切除金属的机床，工件安装在车床的两个顶尖之间，并绕顶尖轴线旋转。

车削工件时，车刀沿着工件的旋转轴线平行移动或与工件的旋转轴线成一斜角移动，将工件表面的金属切除。

车刀的这种位移称为进给。

车刀装夹在刀架上，刀架则固定在溜板上。

溜板是使刀具沿所需方向进行进给的机构。

英文原文Multi-purpose aggregate machine-tool timeRegarding the multi-purpose aggregate machine-tools, in the industrial field has many names to describe it, like “the multitasking installment”, “the multi-purpose engine beds”, “the multi-procedure production system” and so on, it may be called the processing domain truly the nova, may reduce the cost, the simplified disposition, and has maintained in the US territory produces. Inthe past only then used the duty which many machine operations could complete, now may concentrate to an engine bed on processes completes.As a result of market demand's unceasing change, the product life cycle is reducing unceasingly, today's market more intense demand multitasking installment concept. Carries out the fine profit management when the entire production environment, compared to having not concentrated the components processing to a machine on completes a finer profit.Some tradition's manufacturing industry manufacturer thought that the multi-purpose aggregate machine-tools are too complex,very difficult to find the appropriate operators also the difficult problem innovates on the spot on the insufficiency for the metal working Basic principle and in the Production workshop related new engine bed use solution aspect training.Intuition type technical controlThe equipment use “carries off the quantity of heat” the type design, has different material which the lathe bed, the steeliness straight line rolling guide, on the steeliness revolving tool box saddle, the equipment uses, all these combine make an engine bed together. These with the thermal conductivity, the volume expansion are related. All different size's thing can by the different speed growth.As a result of this reason, needs to make the hot friendly engine bed, with the aim of knowing gives off heat the weak point in where, can compensate through the reasonable engine bed design. The part is the entire journey movement. The engine bed glide produces rubs and transform hotly. The machining produces the hot filings fall to the different place, the refrigerant can mix in the entire process in which. Will present the different temperature province continually on the cutting tool, will therefore also have many things to have the influence to the thermostability. The cutting tool technology turned the multi-purpose aggregate machine-tools has had the milling and cutting power “the versatile machine”.According to the material introduced that the most remarkable characteristic is in these engine bed whole has the intuition. The anti-collision preservation technology was already mature, in certain circumstances, even if uses the manual operation pattern, can also avoid the occurrence which collides. Because the control software has the very good intuition, the user operation friendly degree unceasingly is also enhancing. Believe the multi-purpose aggregate machine-tools by its survivability world-wide in the more different processing scenes.The off-line programming optimization and the NC automatic control system's formation already made this technology to be easier to accept, when therefore uses the procedure when the engine bed, does not need to spend many time tune-up procedure and confirmed that some part does not have the question. If components need to provide the high and low two revolving tool box saddle simultaneously to carry on the rough machining, in this kind of situation the programming is quite difficult, because it needs two revolving tool box saddles also to feed. The AdMac system may realize tool rest's automatic programming which simultaneously feeds to these, and can cause the correct main axle speed, the correct feed rate and so on all parameters to realize the synchronization.Okuma Corporation's collision avoidance system design based on actual processing operating mode anti-collision simulation, therefore, if the operator has installed the wrong cutting tool or has established the wrong parameter, the control system will examine and prevents the engine bed to enter the processing condition. Through cooperates with the Siemens, INDEX Corporation may provide the 3D pattern now “the hypothesized engine bed”, has custom-made according to some specific model's engine bed. The result indicated that the simulation processes not only the fabricated parts and the actual end product is similar, is the one-to-one copy simply.The intuition type control interface, the simulation as well as other software technique are progressive, the more Production workshops have opened wide the front door to the multi-purpose aggregate machine-tools, but if does not have the corresponding knowledge to train and to solve the question creativity, the manufacturer is also very difficult to realize and the full use advanced engine bed flexibility aspect superiority. The work which does to the machine are more, the machine will be more complex, also needs to have the stronger skill person correspondingly to be able to operate it.If machinist past one day operated 3 engine beds, then he has this kind of multi-purpose engine bed now, might produce more components. More importantly, he may draw support from software's help to cause the production efficiency to be higher, regarding transformation processing components preparation, may also establish the processing craft plan. Because the replacement components need to lower 3 main axles, therefore before replacing the components, the workshop should process as far as possible many components. Regarding the multi-purpose engine beds, the transformation components speed is quick, the production batch of time interval is shorter, the stock is lower, the production efficiency is higher. Can use multi-purpose engine bed's some workshops fully, very quick will discover the post function the unification. Now, a workshop may only use an operator, an adjuster and a programming teacher, in the future these 3 work definitely may do by a person.In the traditional post description the machinist will transit becomes one to adjust engineer, if this engineer the familiar components processing programming, that were also more ideal. Regarding such transformation, training has been simple, so long as trains 1 individual line, but is not 3individuals. Looking from the long views, this will provide to the people the higher post degree of satisfaction. When adjusts engineer to be responsible to process the programming, and pays attention to the components processing personally time the entire process, he completely has become this components control. In addition, but should also makes more effort in the cutting tool choice and the programming aspect, must make any model the multi-purpose aggregate machine-tool to succeed, the workshop needs to provide the skilled machinist, has ability and completes many kinds of operations nimbly. Therefore, crosswise training was at any time in the past more important. Regarded as the milling and the lathe work the different belongs to their time. Regarding personnel who will program, will understand the engine bed and controls it, this will be their ability manifestation.The cutting tool will choose most people not to install the passenger vehicle tire to the race car on, but processed the cutting tool to have such situation. The cutting tool should match with the new engine bed, is conceivably redundant on the new engine bed uses the old cutting tool to the production efficiency influence. In order to match the multi-purpose aggregate machine-tools, the new cutting tool and the cutting tool adapter technology was already developed. At present the industrial field is developing the development the processing cutting tool, may complete the turning on the identical tool rest, boring and drills truncates the processing, is only processes the phase to differ from regarding the work piece angle. The processing operates the difference even confuses is unclear. The new processing cutting tool may complete the milling and the turning. The machinery automation technology first starts from the 1920s in the machine manufacture cold finishing production in enormous quantities process to develop the application, after in the 60s, to adapt the market demand and the change, for the enhancement machine-building industry to the market nimble rapid reaction's ability, starts to establish the variable automation production system,namely revolves the computer technology the flexible automation. It is in the manufacture system invariable or in the change small situation, the machinery equipment either production management process through the automatic detection, the information processing, the analysis judgment realizes the anticipated operation or some kind of process automatically, and can from make one kind of components to transform automatically to makes another kind of different components. The social practice proved that under this kind of definition's manufacture system automation and the contemporary majority enterprises are not actually accommodating. The contemporary society also not in the science and technology, the material and the personnel aspect prepares to realize this automated condition, insists such to do only meets the wasted effort. This kind of situation is not exceptional regarding the separate production method's machine-building industry, the difficulty can bigger.The aggregate machine-tool future development more use transmissions and so on variable speed motor and ball bearing guide screw,will simplify structure, the reduction production metre; Uses the numerical control system and the headstock, the jig automatic replacement system, enhancesthe craft controllability; As well as integrates the flexible manufacture system and so on.中文译文多用途组合机床对于多功能组合机床，在工业领域有许多名字来描述它，如“多任务处理装置”，“多功能机床”，“多工序生产系统”等，它确实可称为加工领域的新星，可降低成本，简化配置，和一直保持在美国本土生产。