冲压模具外文文献教程文件

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模具设计外文文献

模具设计外文文献

The Development Status and Trend of MoldThe mold is the manufacturing industry important craft foundation, in our country, the mold manufacture belongs to the special purpose e quipment manufacturing industry. China although very already starts to make the mold and the use mold, but long-term has not formed the industry. Straight stabs 0 centuries 80's lat er periods, the Chinese mold industry only then drives into the devel opment speedway. Recent years, not only the state-owned mold enterprise had the very big development, the three investm ents enterprise, the villages and towns (individual) the mold enterpr ise's development also rapid quietly.Although the Chinese mold industrial development rapid, but compa res with the demand, obviously falls short of demand, its main gap co ncentrates precisely to, large-scale, is complex, the long life mold domain. As a result of in aspect and so on mold precision, life, manufacture cycle and productivity, China and the international average horizontal and the developed cou ntry still had a bigger disparity, therefore, needed massively to imp ort the mold every year .The Chinese mold industry must continue to sharpen the productivity, from now on will have emphatically to the profession internal structu re adjustment and the state-of-art enhancement.The structure adjustment aspect, mainly is the enterprise structure to the specialized adjustment, the product structure to center the ups cale mold development, to the import and export structure improvement, center the upscale automobile cover mold forming analysis and the str ucture improvement, the multi-purpose compound mold and the compound processing and the laser techn ology in the mold design manufacture application, the high-speed cutting, the super finishing and polished the technology, the i nformaton direction develops .The recent years, the mold profession structure adjustment and the or ganizational reform step enlarges, mainly displayed in, large-scle, precise, was complex, the long life, center the upscale mold an d the mold standad letter development speed is higher than the common mold product; The plastic mold an the compression casting mold propo rtion increases; Specialized mold factory quantty and its productivit y increase;"The three investments" and the private enterprise develops rapidly; The joint stocksystem transformation step speeds up and so on. Distri butes from the area looked,takeZhejiang Delta and Yangtze River delta as central southeast coastal a rea development quickly to mid-west area, south development quickly to north. At present develops qu ickest, the mold produces the most centralized province is Guangdong and Zhejiang, places such as Jiangsu, Shanghai, Ahui and Shandong als o has a bigger development in recent years.Although our country mold total quantity had at present achieved the suitable scale, the mold level also has the very big enhancement, after but design manufacture horizontal overall rise and fall indust ry developed country and so on Yu De, America, date, France, Italy ma ny. The current existence question and the disparity mainly display i n following several aspects:(1)The total quantity falls short of demandDomestic mold assembling one rate only, about 70%. Low-grade mold, center upscale mold assembling oneself rate only has 50% about.(2)the enterprise organizational structure, the product structure, the technical structure and the import and export structure does not ga therIn our country mold production factory to be most is from the lab or mold workshop which produces assembles oneself (branch factory), f rom produces assembles oneself the proportion to reach as high as abo ut 60%, but the overseas mold ultra 70% is the commodity mold. The sp ecialized mold factory mostly is "large and complete", "small and entire" organization form, but overseas mostly is "small but", "is speci ally small and fine". Domestic large-scale, precise,complex, the long life mold accounts for the total qua ntity proportion to be insufficient 30%, but overseas in 50% above 2004 years, ratio of the mold import and export is 3.7:1, the import and export balances the after net import volume to amount to 1.32 billi on US dollars, is world mold net import quantity biggest country.(3)The mold product level greatly is lower than the international sta ndard The production cycle actually is higher than the international water broad product level low mainly to display in the mold precision, cavity aspect and so on surface roughness, life and structure.(4)Develops the ability badly, economic efficiency unsatisfactory our country mold enterprise technical personnel proportion lowThe level is lower, also does not take the product development, and is frequent in the passive position in the market. Our country each mold staff average year creation output value approximately, ten thousa nd US dollars, overseas mold industry developed country mostly 15 to1 0, 000 US dollars, some reach as high as 25 to10, 000 US dollars, rel ative is our country quite part of molds enterprises also continues to use the workshop type management with it, truly realizes the enterp rise which the modernized enterprise manages fewTo create the above disparity the reason to be very many, the mold long-term has not obtained the value besides the history in as the product which should have, as well as the most state-owned enterprises mechanism cannot adapt the market economy, but also has the following several reasons:(1)Country to mold industry policy support dynamics also insufficientlyAlthough the country already was clear about has promulgated the mold profession industrial policy, but necessary policy few, carried outdynamics to be weak. At present enjoyed the mold product increment d uty enterprise nation 185; the majority enterprise still the tax burd en is only overweight. The mold enterprise carries on the technologic al transformations introduction equipment to have to pay the consider able amount the tax money, affects the technology advancement, moreov er privately operated enterprise loan extremely difficult.(2)Talented person serious insufficient, the scientific research deve lopment and the technical attack investment too urineMold profession is the technology, the fund, the work crowded industr y, alongwith the time progress and the technical development, grasps the tale nted person which and skilled utilizes the new technology exceptional ly short, the high-quality mold fitter and the enterprise management talent extremely is also anxious. Because the mold enterprise benefit unsatisfactory and takes insufficiently the scientific research development and the tec hnical attack, the scientific research unit and theuniversities, colleges and institutes eye stares at is creating incom e, causes the mold profession invests too few in the scientific resea rch development and the technical attack aspect, causes the mold tech nological development step doe not to be big, progresses does not be quick.(3)The craft equipment level is low, also is not good, the using fact or is low.Recent years ,our country engine bed profession progressed quickl y, has been able to provide the quite complete precision work equipme nt, but compared with the overseas equipment, still had a bigger disp arity. Although the domestic many enterprises have introduced many ov erseas advanced equipment, but the overall equipment level low are ve ry more than the overseas many enterprises. As a result of aspect the and so on system and fund reason, introduces the equipment not neces sary, the equipment and the appendix not necessary phenomenon are ext remely common, the equipment utilization rate low question cannot obt ain the comparatively properly solution for a long time .(4)Specialization, standardization, commercialized degree low, the co operation abilityBecause receives "large and complete" "small and entire" the infl uence since long ago, mold specialization level low, the specialized labor division is not careful, the commercialized degree is low. At p resent domestic every year produces mold, commodity mold minister 40% about, other for from produce uses for oneself.Between the molds enterprise cooperates impeded, completes the compar atively large-scale mold complete task with difficulty. Mold standardization level low, mold standard letter use cave rare is low also to the mold quali ty, the cost has a more tremendous influence, specially has very trem endous influence.(5)The mold material and the mold correlation technology fallThe mold material performance, the quality and the variety questi on often can affect the mold quality, the life and the cost, the dome stically produced molding tool steel and overseas imports the steel p roducts to compare has a bigger disparity. Plastic, plate, equipment energy balance, also direct influence mold level enhancement.At present, our country economy still was at the high speed devel opment phase,on the international economical globalization development tendency is day by day obvious, this has provided the good condition and the opp ortunity for the our country mold industry high speed development. On the one hand, the domestic mold market will continue high speed to d evelop, on the other hand, the mold manufacture also gradually will s hift as well as the transnational group to our country carries on the mold purchase trend to our country extremely to be also obvious. The refore, will take a broad view the future, international, the domesti c mold market overall development tendency prospect will favor, estim ated the Chinese mold will obtain the high speed development under th e good market environment, our country not only can become the mold g reat nation, moreover certainly gradually will make the powerful nati on to the mold the ranks to make great strides forward. "The Eleventh Five-Year Plan" period, the Chinese mold industry level not only has the v ery big enhancement in the quantity and the archery target aspect, mo reover the profession structure, the product level, the development i nnovation ability, enterprise's system and the mechanism as well as t he technology advancement aspect also can obtain a bigger development. The mold technology has gathered the machinery, the electron, chemist ry, optics, the material, the computer, the precise monitor and the i nformation network and so on many disciplines, is a comprehensive nat ure multi-disciplinary systems engineering.The mold technology development tendency mainly is the mold product to larger-scale, precise, more complex and a more economical direction develops, the mold product technical content unceasingly enhances, the mold man ufacture cycle unceasingly reduces, the mold production faces the inf ormation, is not having the chart, is fine, the automated direction d evelops, the mold enterprise to the technical integration, the equipm ent excellent, is producing approves the brand, the management inform ation, the management internationalization direction develops.Mold profession in "The Eleventh Five-Year Plan" period needs to solve the key essential technology should be the mold information, the digitized technology and precise, ultra fine, high speed, the highly effective manufacture technology aspect breakthrough. Along with the national economy total quantity and the industry product technology unceasing development, all the various tr ades and occupations tothe mold demand quantity more and more big, the specification more and more is also high.Although mold type many, but its development should be with empha sis both can meet the massive needs, and has the comparatively high-tech content, specially at present domestic still could not be self-sufficient, needs the massive imports the mold and can represent the development direction large-scale, precise, is complex, the long life mold. Standard letter type, quantity, level and the production of the mold have significant infl uence to the entire mold profession development. Therefore, some important mold standard letters also must prioritize, moreover its develo pment speed should quickly to the mold development speed, like this be able unceasingly to raise our country mold standardization level, t hus improves the mold quality, reduces the mold production cycle, red uces the cost. Because our country mold product holds the bigger price superiority in the international market, therefore regarding the ex portation prospect good mold product also should take key develops. A ccording to the above required quantity big, the technical content is high, represents the development direction, the export prospect good principle choice prioritize product, moreover chooses the product to have at present to have the certain technology base, belongs has the condition, has the product which the possibility develops.Our country mold profession still will have to enhance from now on the general character technology had:(1)To establish in the CAD/CAE platform the advanced mold design tech nology, enhances modernization which the mold designed, information, intellectualization, standardized level .(2)Establishes in the CAM/CAPP foundation the advanced mold processing technology and the advanced manufacture technology unifies, raisesthe automated level and the production efficiency which the mold proc esses.(3)The mold production enterprise's information management technology. For example PDM (product data management), ERP (enterprise resource m anagement), MIS (mold manufacture management information system) and information network technology the and so on INTERMET platform applic ation, the promotion and the development .(4)Are high speed, Gao Jing, the compound mold processing technology research and the application. For example the ultra fine ramming mold manufacture technology, the precise plastic and the compression cast ing mold manufacture technology and so on.(5)Enhances the mold production efficiency, reduces the cost and redu ces the mold production cycle each kind of fast economical mold manufacture technology.(6)The advanced manufacture technology application. For example hot t echnology and so on flow channel technology, gas auxiliary technology, hypothesized technology, nanotechnology, rapid scanning technology, r eversion project, parallel project in the mold research, the developm ent, the processing process application.(7)The raw material the simulation technology which forms in the mold.(8)The advanced mold processing and the appropriation equipment resea rch and the development .(9)The mold and the mold standard letter, the important auxiliary sta ndardized technology.(10)The mold and its the product examination technology.(11)High quality, the new mold material research and the development and its the correct application .(12)The mold production enterprise's modern management technologyDie trend1.Mold CAD / CAE / CAM being integrated, three-dimensional, intelligent and network direction(1)Mold software feature integratedDie software features of integrated software modules required relativ ely complete, while the function module using the same data model, in order to achieve Syndicated news management and sharing of informati on to support the mold design, manufacture, assembly, inspection, tes ting and production management of the entire process to achieve optimal benefits. Series such as the UK Delcam's software will include a s urface / solid geometric modeling, engineering drawing complex geomet ry, advanced rendering industrial design, plastic mold design expert system, complex physical CAM, artistic design and sculpture automaticprogramming system, reverse engineering and complex systems physical line measurement systems. A higher degree of integration of the soft ware includes: Pro / ENGINEER, UG and CATIA, etc.. Shanghai Jiao tong University, China with finite element analysis of metal plastic form ing systems and Die CAD / CAM systems; Beijing Beihang Haier Software Ltd. CAXA Series software; Jilin Gold Grid Engineering Research Cent er of the stamping die mold CAD / CAE / CAM systems.(2)Mold design, analysis and manufacture of three-dimensionalTwo-dimensional mold of traditional structural design can no longer meet modern technical requirements of production and integration.Mold design,analysis,manufacturing three-dimensional technology, paperless software required to mold a new gen eration of three-dimensional, intuitive sense to design the mold, using three-dimensional digital model can be easily used in the product structure of CAE analysis, tooling manufacturability evaluation and CNC machin ing, forming process simulation and information management and shaing.Such as Pro / ENGINEER, UG and CATIA software such as with parametri c, feature-based, all relevant characteristics, so that mold concurrent engineer ing possible.In addition, Cimatran company Mold expert, Delcam's Ps-mold and Hitachi Shipbuilding of Space-E/mold are professional injection mold 3D design software, interacti ve 3D cavity, core design, mold base design configuration and typical structure. Australian company Moldflow realistic three-dimensional flow simulation software MoldflowAdvisers been widely pra ised by users and applications.China Huazhong University of Science h ave developed similar software HSC3D4.5F and Zhengzhou University, Z-mold software.For manufacturing, knowledge-based intelligent software function is a measure of die important sign of advanced and practical one.Such as injection molding experts Cim atron's software can automatically generate parting direction based parting line and parting surface, generate products corresponding to t he core and cavity, implementation of all relevant parts mold, and fo r automatically generated BOM Form NC drilling process, and can intel ligentlyprocess parameter setting, calibration and other processing results.(3)Mold software applications, networking trendWith the mold in the enterprise competition, cooperation, product ion and management, globalization, internationalization, and the rapi d development of computer hardware and software technology, the Inter net has made in the mold industry, virtual design, agile manufacturin g technology both necessary and possible.The United States in its "21st Century Manufacturing Enterprise S trategy" that the auto industry by 2006 to achieve agile manufacturin g / virtual engineering solutions toautomotive development cycle shortened from 40 months to 4 months.2.Mold testing, processing equipment to the precise, efficient, and m ulti-direction(1)Mold testing equipment more sophisticated, efficientSophisticated Complex, large-scale mold development, testing equipment have become increasingly de manding.Precision Mould precision now reached 2~3m, more domestic manufac turers have to use Italy, the United States, Japan and other countrie s in the high-precision coordinate measuring machine, and with digital scanning.Such as Dongfeng Motor Mould Factory not only has the capacity 3250m m × 3250mm Italian coordinate measuring machine, also has a digital photography optical scanner, the first in the domestic use of digital photography, optical scanning as a means of spatial three-dimensional access to information, enabling the establishment from the measurement of physical → model output of engineering drawings →→ the whole process of mold making, reverse engineering a successful technology development and applications. This equipment include: sec ond-generation British Renishaw high-speed scanners (CYCLON SERIES2) can be realized and contact laser pro be complementary probe, laser scanner accuracy of 0.05mm, scanning pr obe contact accuracy of 0.02 mm.Another German company GOM ATOS portable scanners,Japan Roland's PIX -30, PIX-4 desktop scanner and the United Kingdom Taylor Hopson's TALYSCAN150 multi-sensor, respectively Three-dimensional scanner with high speed, low-cost and functional composite and so on.(2)CNC EDMJapan Sodick linear motor servo drive using the company'sAQ325L, AQ550LLS-WEDM have drivenfast response, transmission and high positioning accuracy, the advant ages of small thermal deformation. Switzerland Chanmier company NCEDM with P-E3 adaptive control, PCE energy control and automatic programming exp ert systems.Others also used the powder mixed EDM machining technology, micro-finishing pulse power and fuzzy control (FC) technologies.(3)High-speed milling machine (HSM)Milling is an important means of cavity mold.The low-temperature high-speed milling with the workpiece, cutting force is small, smooth proc essing, processing quality, processing efficiency (for the general mi lling process 5 to 10 times) and can process hard materials (<60HRC) and many other advantages. Thus in the mold processing more and more attention. Ruishikelang company UCP710-type five-axis machining center, machine tool positioning accuracy up to 8μm, home-made closed-loop vector control spindle with a maximum speed 42000r/min. Italy RA MBAUDI's high-speed milling, the processing range of up to 2500mm × 5000mm × 1800 mm, speed up 20500r/min, cutting feed speed of 20m/min. HSM generally used large, medium-sized mold, such as motor cover mold, die casting mold, large plastic surface machining, the surface precision up to 0.01mm.。

冲压工艺与外文翻译文档

冲压工艺与外文翻译文档

冲压工艺与外文翻译文档1. The mold designing and manufacturingThe mold is the manufacturing industry important craft foundation, in our country, the mold manufacture belongs to the special purpose equipment manufacturing industry. China although very already starts to make the mold and the use mold, but long-term has not formed the industry. Straight stabs 0 centuries 80's later periods, the Chinese mold industry only then drives into the development speedway. Recent years, not only the state-owned mold enterprise had the very big development, the three investments enterprise, the villages and towns (individual) the mold enterprise's development also rapid quietly.Although the Chinese mold industrial development rapid, but compares with the demand, obviously falls short of demand, its main gap concentrates precisely to, large-scale, is complex, the long life mold domain. As a result of in aspect and so on mold precision, life, manufacture cycle and productivity, China and the international average horizontal and the developed country still had a bigger disparity, therefore, needed massively to import the mold every year .The Chinese mold industry must continue to sharpen the productivity, from now on will have emphatically to the profession internal structure adjustment and the state-of-art enhancement. The structure adjustment aspect, mainly is the enterprise structure to the specialized adjustment, the product structure to center the upscale mold development, to the import and export structure improvement, center the upscale automobile cover mold forming analysis and the structure improvement, the multi-purpose compound mold and the compound processing and the laser technology in the mold design manufacture application, the high-speed cutting, the super finishing and polished the technology, the information direction develops . The recent years, the mold profession structure adjustment and the organizational reform step enlarges, mainly displayed in, large-scale, precise, was complex, the long life, center the upscale mold and the mold standard letter development speed is higher than the common mold product; The plastic mold and the compression casting mold proportion increases; Specialized mold factory quantity and its productivity increase; “The three investments" and the private enterprise developsrapidly; The joint stock system transformation step speedsup and so on. Distributes from the area looked, take Zhejiang Delta and Yangtze River delta as central southeast coastal area development quickly to mid-west area, south development quickly to north. At present develops quickest, the mold produces the most centralized province is Guangdong and Zhejiang, places such as Jiangsu, Shanghai, Anhui and Shandong also has a bigger development in recent years.2. Mold Present Status of TechnologyTechni cal level of China’s mold industry currently uneven, with wide disparities generally speaking, with the developed industrial countries, Hong Kong and Taiwan advanced level, there is a large gap.The use of CAD / CAM / CAE / CAPP and other technical design and manufacture molds, either wide application, or technical level, there is a big gap between both. In the application of CAD technology design molds, only about 10% of the mold used in the design of CAD, aside from drawing board still has a long way to go; in the application of CAE design and analysis of mold calculation, it was just started, most of the game is still in trial stages and animation; in the application of CAM technology manufacturing molds, first, the lack of advanced manufacturingequipment, and second, the existing process equipment (including the last 10 years the introduction of advanced equipment) or computer standard (IBM PC and compatibles, HP workstations, etc.) different, or because of differences in bytes, processing speed differences, differences in resistance to electromagnetic interference, networking is low, only about 5% of the mold manufacturing equipment of recent work in this task; in the application process planning CAPP technology, basically a blank state, based on the need for a lot of standardization work; in the mold common technology, such as mold rapid prototyping technology, polishing, electroforming technologies, surface treatment technology aspects of CAD / CAM technology in China has just started. Computer-aided technology, software development, is still at low level, the accumulation of knowledge and experience required. Most of our mold factory, mold processing equipment shop old, long in the length of civilian service, accuracy, low efficiency, still use theordinary forging, turning, milling, planning, drilling, grinding and processing equipment, mold, heat treatment is still in use salt bath, box-type furnace, operating with the experience of workers, poorly equipped, high energy consumption. Renewal ofequipment is slow, technological innovation; technological progress is not much intensity. Although in recent years introduced many advanced mold processing equipment, but are too scattered, or not complete, only about 25% utilization, equipment, some of the advanced functions are not given full play.3. Die trend(1) Mold software features integratedDie software features of integrated software modules required relatively complete, while the function module using the same data model, in order to achieve Syndicated news management and sharing of information to support the mold design, manufacture, assembly, inspection, testing and production management of the entire process to achieve optimal benefits. Series such as the UK Delcam's software will include a surface / solid geometric modeling, engineering drawing complex geometry, advanced rendering industrial design, plastic mold design expert system, complex physical CAM, artistic design and sculpture automatic programming system, reverse engineering and complex systems physical line measurement systems. A higher degree of integration of the software includes:Pro / __R, UG and CATIA, etc.. Shanghai Jiao tong University, China with finite element analysis of metal plastic forming systems and Die CAD / CAM systems; Beijing Bei hang Haier Software Ltd. CAXA Series software; Jilin Gold Grid Engineering Research Center of the stamping die mold CAD / CAE / CAM systems.(2) Mold design, analysis and manufacture of three-dimensionalTwo-dimensional mold of traditional structural design can no longer meet modern technical requirements of production and integration. Mold design, analysis, manufacturing three-dimensional technology, paperless software required to mold a new generation of three-dimensional, intuitive sense to design the mold, using three-dimensional digital model can be easily used in the product structure of CAE analysis, tooling manufacturability evaluation and CNC machining, forming processsimulation and information management and sharing. Such as Pro / E, UG and CATIA software such as with parametric, feature-based, all relevant characteristics, so that mold concurrent engineering possible. In addition, Cimarron company Mold expert, Delcam's Ps-mold and Hitachi Shipbuilding ofSpace-E/mold are professional injection mold 3D design software, interactive 3D cavity, core design, mold base design configuration and typical structure . Australian company Mold flow realistic three-dimensional flow simulation software MoldflowAdvisers been widely praised by users and applications. China Huazhong University of Science has developed similar software HSC3D4.5F and Zhengzhou University, Z-mold software. For manufacturing, knowledge-based intelligent software function is a measure of die important sign of advanced and practical one. Such as injection molding experts Cimarron’s software can automatically generate parting direction based parting line and parting surface, generate products corresponding to the core and cavity, implementation of all relevant parts mold, and for automatically generated BOM Form NC drilling process, and can intelligently process parameter setting, calibration and other processing results.(3) Mold software applications, networking trendWith the mold in the enterprise competition, cooperation, production and management, globalization, internationalization, and the rapid development of computer hardware and software technology, the Internet has made in the mold industry, virtualdesign, and agile manufacturing technology both necessary and possible.4. Heat Treatment of DieTraditional die and mould design, mainly by experience or semi―experience,is isolated from manufacturing process. Before the design is finalized,the scheme of die and mould is usually modified time and again,thus some disadvantages come into being, such as long development period, high cost and uncertain practical effect. Due to strong desires for precision, service life, development period and cost, modern die and mould should be designed and manufactured perfectly. Therefore more and more advanced technologies and innovations have been applied, for example, concurrentengineering, agile manufacturing virtual manufacturing, collaborative design, etc. Heat treatment of die and mould is as important as design, manufacture and assembly because it has a vital effect on manufacture,assembly and service life.Design and manufacture of die and mould have progressed rapidly,but heat treatment lagged seriously behind them.As die and mould industry develops,heat treatment must ensure die and mould there are good state of manufacture,assembly andwear―resistant properties by request. Impertinent heat treatment can influence die and mould manufacturing such as over―hard and―soft and assembly.Traditionally the heat treatment process was made out according to the methods and properties brought forward by designer.This could make the designers of die and mould and heat treatment diverge from each other,for the designers of die and mould could not fully realize heat treatment process and materials properties,and contrarily the designers rarely understood the service environment and designing thought. These divergences will impact the progress of die and mould to a great extent. Accordingly,if the process design of heat treatment is considered in the early designing stage,the aims of shortening development period,reducing cost and stabilizing quality will be achieved and the sublimation of development pattern from serial to concurrent will be realized.Concurrent engineering takes computer integration system as a carrier, at the very start subsequent each stage and factors have been considered such as manufacturing,heat treating,properties and so forth in order to avoid the error.The concurrent pattern has dismissed the defect of serial pattern, which bringabout a revolution against serial pattern.In the present work.the heat treatment was integrated into the concurrent circumstance of the die and mould development,and the systemic and profound research was performed.5. SummaryThe 21st century, in the new situation of economic globalization, with capital, technology and labor market re-integration of equipment manufacturing in China after joining the WTO will become the world's equipment manufacturing base. In the modern manufacturing industry, no matter which industry, engineering equipment, are increasingly used to provide the products from the mold industry. In order to meet the user's high-precision mold manufacturing, short delivery time, the urgent demand low-cost, mold industry is extensive application of modern advanced manufacturing technology to speed up the mold industry, technological progress, to meet the basic sectors of the mold process equipment urgent needs.。

冲压模具成型外文翻译参考文献

冲压模具成型外文翻译参考文献

冲压模具成型外文翻译参考文献(文档含中英文对照即英文原文和中文翻译)4 Sheet metal forming and blanking4.1 Principles of die manufacture4.1.1 Classification of diesIn metalforming,the geometry of the workpiece is established entirely or partially by the geometry of the die.In contrast to machining processes,ignificantly greater forces are necessary in forming.Due to the complexity of the parts,forming is often not carried out in a single operation.Depending on the geometry of the part,production is carried out in several operational steps via one or several production processes such as forming or blanking.One operation can also include several processes simultaneously(cf.Sect.2.1.4).During the design phase,the necessary manufacturing methods as well as the sequence and number of production steps are established in a processing plan(Fig.4.1.1).In this plan,theavailability of machines,the planned production volumes of the part and other boundary conditions are taken into account.The aim is to minimize the number of dies to be used while keeping up a high level of operational reliability.The parts are greatly simplified right from their design stage by close collaboration between the Part Design and Production Departments in order to enable several forming and related blanking processes to be carried out in one forming station.Obviously,the more operations which are integrated into a single die,the more complex the structure of the die becomes.The consequences are higher costs,a decrease in output and a lower reliability.Fig.4.1.1 Production steps for the manufacture of an oil sumpTypes of diesThe type of die and the closely related transportation of the part between dies is determined in accordance with the forming procedure,the size of the part in question and the production volume of parts to be produced.The production of large sheet metal parts is carried out almost exclusively using single sets of dies.Typical parts can be found in automotive manufacture,the domestic appliance industry and radiator production.Suitable transfer systems,for example vacuum suction systems,allow the installation of double-action dies in a sufficiently large mounting area.In this way,for example,the right and left doors of a car can be formed jointly in one working stroke(cf.Fig.4.4.34).Large size single dies are installed in large presses.The transportation of the parts from oneforming station to another is carried out mechanically.In a press line with single presses installed one behind the other,feeders or robots can be used(cf.Fig.4.4.20 to 4.4.22),whilst in large-panel transfer presses,systems equipped with gripper rails(cf.Fig.4.4.29)or crossbar suction systems(cf.Fig.4.4.34)are used to transfer the parts.Transfer dies are used for the production of high volumes of smaller and medium size parts(Fig.4.1.2).They consist of several single dies,which are mounted on a common base plate.The sheet metal is fed through mostly in blank form and also transported individually from die to die.If this part transportation is automated,the press is called a transfer press.The largest transfer dies are used together with single dies in large-panel transfer presses(cf.Fig.4.4.32).In progressive dies,also known as progressive blanking dies,sheet metal parts are blanked in several stages;generally speaking no actual forming operation takes place.The sheet metal is fed from a coil or in the form of metal ing an appropriate arrangement of the blanks within the available width of the sheet metal,an optimal material usage is ensured(cf.Fig.4.5.2 to 4.5.5). The workpiece remains fixed to the strip skeleton up until the laFig.4.1.2 Transfer die set for the production of an automatic transmission for an automotive application-st operation.The parts are transferred when the entire strip is shifted further in the work flow direction after the blanking operation.The length of the shift is equal to the center line spacing of the dies and it is also called the step width.Side shears,very precise feeding devices or pilot pins ensure feed-related part accuracy.In the final production operation,the finished part,i.e.the last part in the sequence,is disconnected from the skeleton.A field of application for progressive blanking tools is,for example,in the production of metal rotors or stator blanks for electric motors(cf.Fig.4.6.11 and 4.6.20).In progressive compound dies smaller formed parts are produced in several sequential operations.In contrast to progressive dies,not only blanking but also forming operations areperformed.However, the workpiece also remains in the skeleton up to the last operation(Fig.4.1.3 and cf.Fig.4.7.2).Due to the height of the parts,the metal strip must be raised up,generally using lifting edges or similar lifting devices in order to allow the strip metal to be transported mechanically.Pressed metal parts which cannot be produced within a metal strip because of their geometrical dimensions are alternatively produced on transfer sets.Fig.4.1.3 Reinforcing part of a car produced in a strip by a compound die setNext to the dies already mentioned,a series of special dies are available for special individual applications.These dies are,as a rule,used separately.Special operations make it possible,however,for special dies to be integrated into an operational Sequence.Thus,for example,in flanging dies several metal parts can be joined together positively through the bending of certain metal sections(Fig.4.1.4and cf.Fig.2.1.34).During this operation reinforcing parts,glue or other components can be introduced.Other special dies locate special connecting elements directly into the press.Sorting and positioning elements,for example,bring stamping nuts synchronised with the press cycles into the correct position so that the punch heads can join them with the sheet metal part(Fig.4.1.5).If there is sufficient space available,forming and blanking operations can be carried out on the same die.Further examples include bending,collar-forming,stamping,fine blanking,wobble blanking and welding operations(cf.Fig.4.7.14 and4.7.15).Fig.4.1.4 A hemming dieFig.4.1.5 A pressed part with an integrated punched nut4.1.2 Die developmentTraditionally the business of die engineering has been influenced by the automotive industry.The following observations about the die development are mostly related to body panel die construction.Essential statements are,however,made in a fundamental context,so that they are applicable to all areas involved with the production of sheet-metal forming and blanking dies.Timing cycle for a mass produced car body panelUntil the end of the 1980s some car models were still being produced for six to eight years more or less unchanged or in slightly modified form.Today,however,production time cycles are set for only five years or less(Fig.4.1.6).Following the new different model policy,the demands ondie makers have also changed prehensive contracts of much greater scope such as Simultaneous Engineering(SE)contracts are becoming increasingly common.As a result,the die maker is often involved at the initial development phase of the metal part as well as in the planning phase for the production process.Therefore,a muchbroader involvement is established well before the actual die development is initiated.Fig.4.1.6 Time schedule for a mass produced car body panelThe timetable of an SE projectWithin the context of the production process for car body panels,only a minimal amount of time is allocated to allow for the manufacture of the dies.With large scale dies there is a run-up period of about 10 months in which design and die try-out are included.In complex SE projects,which have to be completed in 1.5 to 2 years,parallel tasks must be carried out.Furthermore,additional resources must be provided before and after delivery of the dies.These short periods call for pre-cise planning,specific know-how,available capacity and the use of the latest technological and communications systems.The timetable shows the individual activities during the manufacturing of the dies for the production of the sheet metal parts(Fig.4.1.7).The time phases for large scale dies are more or less similar so that this timetable can be considered to be valid in general.Data record and part drawingThe data record and the part drawing serve as the basis for all subsequent processing steps.They describe all the details of the parts to be produced. The information given in theFig.4.1.7 Timetable for an SE projectpart drawing includes: part identification,part numbering,sheet metal thickness,sheet metal quality,tolerances of the finished part etc.(cf.Fig.4.7.17).To avoid the production of physical models(master patterns),the CAD data should describe the geometry of the part completely by means of line,surface or volume models.As a general rule,high quality surface data with a completely filleted and closed surface geometry must be made available to all the participants in a project as early as possible.Process plan and draw developmentThe process plan,which means the operational sequence to be followed in the production of the sheet metal component,is developed from the data record of the finished part(cf.Fig.4.1.1).Already at this point in time,various boundary conditions must be taken into account:the sheet metal material,the press to be used,transfer of the parts into the press,the transportation of scrap materials,the undercuts as well as thesliding pin installations and their adjustment.The draw development,i.e.the computer aided design and layout of the blank holder area of the part in the first forming stage–if need bealso the second stage–,requires a process planner with considerable experience(Fig.4.1.8).In order to recognize and avoid problems in areas which are difficult to draw,it is necessary to manufacture a physical analysis model of the draw development.With this model,theforming conditions of the drawn part can be reviewed and final modifications introduced,which are eventually incorporated into the data record(Fig.4.1.9).This process is being replaced to some extent by intelligent simulation methods,through which the potential defects of the formed component can be predicted and analysed interactively on the computer display.Die designAfter release of the process plan and draw development and the press,the design of the die can be started.As a rule,at this stage,the standards and manufacturing specifications required by the client must be considered.Thus,it is possible to obtain a unified die design and to consider the particular requests of the customer related to warehousing of standard,replacement and wear parts.Many dies need to be designed so that they can be installed in different types of presses.Dies are frequently installed both in a production press as well as in two different separate back-up presses.In this context,the layout of the die clamping elements,pressure pins and scrap disposal channels on different presses must be taken into account.Furthermore,it must be noted that drawing dies working in a single-action press may be installed in a double-action press(cf.Sect.3.1.3 and Fig.4.1.16).Fig.4.1.8 CAD data record for a draw developmentIn the design and sizing of the die,it is particularly important to consider the freedom of movement of the gripper rail and the crossbar transfer elements(cf.Sect.4.1.6).These describe the relative movements between the components of the press transfer system and the die components during a complete press working stroke.The lifting movement of the press slide,the opening and closing movements of the gripper rails and the lengthwise movement of the whole transfer are all superimposed.The dies are designed so that collisions are avoided and a minimum clearance of about 20 mm is set between all the moving parts.4 金属板料的成形及冲裁4. 模具制造原理4.1.1模具的分类在金属成形的过程中,工件的几何形状完全或部分建立在模具几何形状的基础上的。

冲压模具外文英语文献翻译

冲压模具外文英语文献翻译

外文翻译Heat Treatment of Die and Mould Oriented Concurrent Design LI Xiong,ZHANG Hong-bing,RUAN Xue —yu,LUO Zhong —hua,ZHANG YanTraditional die and mould design,mainly by experience or semi —experience ,is isolated from manufacturing process.Before the design is finalized ,the scheme of die and mould is usually modified time and again ,thus some disadvantages come into being,such as long development period,high cost and uncertain practical effect.Due to strong desires for precision,service life,development period and cost,modern die and mould should be designed and manufactured perfectly.Therefore more and more advanced technologies and innovations have been applied,for example,concurrent engineering,agile manufacturing virtual manufacturing,collaborative design,etc.Heat treatment of die and mould is as important as design,manufacture and assembly because it has a vital effect on manufacture ,assembly and service life .Design and manufacture of die and mould have progressed rapidly ,but heat treatment lagged seriously behind them .As die and mould industry develops ,heat treatment must ensure die and mould there are good state of manufacture ,assembly and wear —resistant properties by request. Impertinent heat treatment can influence die and mould manufacturing such as over —hard and —soft and assembly .Traditionally the heat treatment process was made out according to the methods and properties brought forward Abstract:Many disadvantages exist in the traditional die design method which belongsto serial pattern. It is well known that heat treatment is highly important to thedies. A new idea of concurrent design for heat treatment process of die andmould was developed in order to overcome the existent shortcomings of heattreatment process. Heat treatment CAD/CAE was integrated with concurrentcircumstance and the relevant model was built. These investigations canremarkably improve efficiency, reduce cost and ensure quality of R and D forproducts.Key words:die design; heat treatment; mouldby designer.This could make the designers of die and mould and heat treatment diverge from each other,for the designers of die and mould could not fully realize heat treatment process and materials properties,and contrarily the designers rarely understood the service environment and designing thought. These divergences will impact the progress of die and mould to a great extent. Accordingly,if the process design of heat treatment is considered in the early designing stage,the aims of shortening development period,reducing cost and stabilizing quality will be achieved and the sublimation of development pattern from serial to concurrent will be realized.Concurrent engineering takes computer integration system as a carrier,at the very start subsequent each stage and factors have been considered such as manufacturing,heat treating,properties and so forth in order to avoid the error.The concurrent pattern has dismissed the defect of serial pattern,which bring about a revolution against serial pattern.In the present work.the heat treatment was integrated into the concurrent circumstance of the die and mould development,and the systemic and profound research was performed.1 Heat Treatment Under Concurrent CircumstanceThe concurrent pattern differs ultimately from the serial pattern(see Fig.1).With regard to serial pattern,the designers mostly consider the structure and function of die and mould,yet hardly consider the consequent process,so that the former mistakes are easily spread backwards.Meanwhile,the design department rarely communicates with the assembling,cost accounting and sales departments.These problems certainly will influence the development progress of die and mould and the market foreground.Whereas in the concurrent pattern,the relations among departments are close,the related departments all take part in the development progress of die and mould and have close intercommunion with purchasers.This is propitious to elimination of the conflicts between departments,increase the efficiency and reduce the cost.Heat treatment process in the concurrent circumstance is made out not after blueprint and workpiece taken but during die and mould designing.In this way,it is favorable to optimizing the heat treatment process and making full use of the potential of the materials.2 Integration of Heat Treatment CAD/CAE for Die and MouldIt can be seen from Fig.2 that the process design and simulation of heat treatment are the core of integration frame.After information input via product design module and heat treatment process generated via heat treatment CAD and heat treatment CAE module will automatically divide the mesh for parts drawing,simulation temperature field microstructure analysis after heat—treatment and the defect of possible emerging (such as overheat,over burning),and then the heat treatment process is judged if the optimization is made according to the result reappeared by stereoscopic vision technology.Moreover tool and clamping apparatus CAD and CAM are integrated into this system.The concurrent engineering based integration frame can share information with other branch.That makes for optimizing the heat treatment process and ensuring the process sound.2.1 3-D model and stereoscopic vision technology for heat treatmentThe problems about materials,structure and size for die and mould can be discovered as soon as possible by 3-D model for heat treatment based on the shape of die and mould.Modeling heating condition and phase transformation condition for die and mould during heat treatment are workable,because it has been broken through for the calculation of phase transformation thermodynamics,phase transformation kinetics,phase stress,thermal stress,heat transfer,hydrokinetics etc.For example,3-D heat—conducting algorithm models for local heating complicated impression and asymmetric die and mould,and M ARC software models for microstructure transformation was used.Computer can present the informations of temperature,microstructure and stress at arbitrary time and display the entire transformation procedure in the form of 3-D by coupling temperature field,microstructure field and stress field.If the property can be coupled,various partial properties can be predicted by computer.2.2 Heat treatment process designDue to the special requests for strength,hardness,surface roughness and distortion during heat treatment for die and mould,the parameters including quenching medium type,quenching temperature and tempering temperature and time,must be properlyselected,and whether using surface quenching or chemical heat treatment the parameters must be rightly determined.It is difficult to determine the parameters by computer fully.Since computer technology develops quickly in recent decades,the difficulty with large—scale calculation has been overcome.By simulating and weighing the property,the cost and the required period after heat treatment.it is not difficult to optimize the heat treatment process.2.3 Data base for heat treatmentA heat treatment database is described in Fig.3.The database is the foundation of making out heat treatment process.Generally,heat treatment database is divided into materials database and process database.It is an inexorable trend to predict the property by materials and process.Although it is difficult to establish a property database,it is necessary to establish the database by a series of tests.The materials database includes steel grades,chemical compositions,properties and home and abroad grades parallel tables.The process database includes heat treatment criterions,classes,heat preservation time and cooling velocity.Based on the database,heat treatment process can be created by inferring from rules.2.4 Tool and equipment for heat treatmentAfter heat treatment process is determined,tool and equipment CAD/CAE systemtransfers the information about design and manufacture to the numerical control device.Through rapid tooling prototype,the reliability of tool and the clamping apparatus can be judged.The whole procedure is transferred by network,in which there is no man—made interference.3 Key Technique3.1 Coupling of temperature,microstructure,stress and propertyHeat treatment procedure is a procedure of temperature-microstructure—stress interaction.The three factors can all influence the property (see Fig.4).During heating and cooling,hot stress and transformation will come into being when microstructure changes.Transformation temperature-microstructure and temperature—microstructure—and stress-property interact on each other.Research on the interaction of the four factors has been greatly developed,but the universal mathematic model has not been built.Many models fit the test nicely,but they cannot be put into practice.Difficulties with most of models are solved in analytic solution,and numerical method is employed so that the inaccuracy of calculation exists.Even so,comparing experience method with qualitative analysis,heat treatment simulation by computer makes great progress.3.2 Establishment and integration of modelsThe development procedure for die and mould involves design,manufacture,heat treatment,assembly,maintenance and so on.They should have own database and mode1.They are in series with each other by the entity—relation model.Through establishing and employing dynamic inference mechanism,the aim of optimizing design can be achieved.The relation between product model and other models was built.The product model will change in case the cell model changes.In fact,it belongs to the relation of data with die and mould.After heat treatment model is integrated into the system,it is no more an isolated unit but a member which is close to other models in the system.After searching,calculating and reasoning from the heat treatment database,procedure for heat treatment,which is restricted by geometric model,manufacture model for die and mould and by cost and property,is obtained.If the restriction is disobeyed,the system will send out the interpretative warning.All design cells are connected by communication network.3.3 Management and harmony among membersThe complexity of die and mould requires closely cooperating among item groups.Because each member is short of global consideration for die and mould development,they need to be managed and harmonized.Firstly,each item group should define its own control condition and resource requested,and learn of the request of up- and-down working procedure in order to avoid conflict.Secondly,development plan should be made out and monitor mechanism should be established.The obstruction can be duly excluded in case the development is hindered.Agile management and harmony redound to communicating information,increasing efficiency,and reducing redundancy.Meanwhile it is beneficial for exciting creativity,clearing conflict and making the best of resource.4 Conclusions(1) Heat treatment CAD/CAE has been integrated into concurrent design for die and mould and heat treatment is graphed,which can increase efficiency,easily discover problems and clear conflicts.(2)Die and mould development is performed on the same platform.When the heat treatment process is made out,designers can obtain correlative information and transfer self-information to other design departments on the platform.(3)Making out correct development schedule and adjusting it in time can enormously shorten the development period and reduce cost.References:[1] ZHOU Xiong-hui,PENG Ying-hong.The Theory and Technique of Modern Die and Mould Design and Manufacture[M].Shanghai:Shanghai Jiaotong University Press 2000(in Chinese).[2] Kang M,Park& Computer Integrated Mold Manufacturing[J].Int J Computer Integrated Manufacturing,1995,5:229-239.[3] Yau H T,Meno C H.Concurrent Process Planning for Finishing Milling and Dimensional Inspection of Sculptured Surface in Die and Mould Manufacturing[J].Int J Product Research,1993,31(11):2709—2725.[4] LI Xiang,ZHOU Xiong-hui,RUAN Xue-yu.Application of Injection Mold Collaborative Manufacturing System [J].JournaI of Shanghai Jiaotong University,2000,35(4):1391-1394.[5] Kuzman K,Nardin B,Kovae M ,et a1.The Integration of Rapid Prototyping and CAE in Mould Manufacturing[J].J Materials Processing Technology,2001,111:279—285.[6] LI Xiong,ZHANG Hong—bing,RUAN Xue-yu,et a1.Heat Treatment Process Design Oriented Based on Concurrent Engineering[J].Journal of Iron and Steel Research,2002,14(4):26—29.文献出处:LI Xiong,ZHANG Hong-bing,RUAN Xue—yu,LUO Zhong—hua,ZHANG Yan.Heat Treatment of Die and Mould Oriented Concurrent Design[J].Journal of Iron and Steel Research,2006,13(1):40- 43,74模具热处理及其导向平行设计李雄,张鸿冰,阮雪榆,罗中华,张艳摘要:在一系列方式中,传统模具设计方法存在许多缺点。

模具设计相关专业毕业论文(外文原文+翻译)之翻译[管理资料]

模具设计相关专业毕业论文(外文原文+翻译)之翻译[管理资料]

可行成形图在汽车覆盖件冲压工艺高效设计的应用Dae-Cheol Ko a,Seung-Hoon Cha b,Sang-Kon Lee c,Chan-Joo Lee b,Byung-Min Kim d,*a ILIC, Pusan National University, 30 Jangjeon-Dong, Kumjeong-Gu, Busan609-735, South Koreab Precision Manufacturing Systems Division, Pusan National University, 30Jangjeon-Dong, Kumjeong-Gu, Busan 609-735, South Koreac PNU-IFAM, Joint Research Center, Pusan National University, 30Jangjeon-Dong, Kumjeong-Gu, Busan 609-735, South Koread School of Mechanical Engineering, Pusan National University, 30 Jangjeon-Dong, Kumjeong-Gu, Busan 609-735, South Korea摘要:本文提出使用可行的成形图来表示无断裂和起皱的安全区域,进而有效和快速地设计冲压工艺方法。

要确定可行的成形图,有限元分析对应于正交实验设计的过程变量组合。

随后,基于成形极限图的有限元分析,确定断裂和起皱的特征值。

所有组合的特征值在整个过程中,通过人工神经网络训练进行了一系列预测。

可行的成形图从所有组合的过程变量中最终确定。

以汽车覆盖件如转动架和车轮毂的冲压工艺作为实例来验证利用成形图的进行过程设计有效性。

有限元模拟结果与实验模拟结果比较表明,利用可行的成形图来进行冲压工艺的设计是有效的并适用于实际的过程。

冲压模具英文参考文献(精选120个最新)

冲压模具英文参考文献(精选120个最新)

冲压模具是在冷冲压加工中,将材料(金属或非金属)加工成零件(或半成品)的一种特殊工艺装备,称为冷冲压模具(俗称冷冲模)。

冲压,是在室温下,利用安装在压力机上的模具对材料施加压力,使其产生分离或塑性变形,从而获得所需零件的一种压力加工方法。

下面是搜索整理的冲压模具英文参考文献,欢迎借鉴参考。

冲压模具英文参考文献一: [1]Wei Wu. Design and Analysis of Flat Washer Stamping Compound Mold[P]. Proceedings of the 2018 8th International Conference on Mechatronics, Computer and Education Informationization (MCEI 2018),2018. [2]Zengsheng Wang,Hansong Yang,Guohua Mu. Research on Teaching Reform of Stamping Process and Die Design[P]. Proceedings of the 2016 International Conference on Contemporary Education, Social Sciences and Humanities,2015. [3]Hongxing Dong. Research on Application of Comprehensive Teaching Design into the Teaching of Cold Stamping Forming Technology and Die Design[P]. Proceedings of the 2016 2nd International Conference on Social Science and HigherEducation,2016. [4]Zengsheng Wang,Luoming Zhang,Qinglian Meng. Research on Teaching Reform of Stamping Technology and Die Design[P]. Proceedings of the 4th International Conference on Contemporary Education, Social Sciences and Humanities (ICCESSH 2019),2019. [5]Sisi Chen,Zhanguo Li,Yaochen Shi,Yunguang Cai. Research on stamping die reconstruction method based on binocular stereovision[P]. Proceedings of the 2017 6th International Conference on Energy and Environmental Protection (ICEEP 2017),2017. [6]Indivarie Ubhayaratne,Michael P. Pereira,Yong Xiang,Bernard F. Rolfe. Audio signal analysis for tool wear monitoring in sheet metal stamping[J]. Mechanical Systems and Signal Processing,2017,85. [7]L. Fernandes,F.J.G. Silva,M.F. Andrade,R. Alexandre,A.P.M. Baptista,C. Rodrigues. Increasing the stamping tools lifespan by using Mo and B4C PVD coatings[J]. Surface & CoatingsTechnology,2017,325. [8]R. Muvunzi,D.M. Dimitrov,S. Matope,T.M. Harms. Evaluation of Models for Cooling System Design in Hot Stamping Tools[J]. Procedia Manufacturing,2017,7. [9]Ousse?ni Marou Alzouma,Franck Marion,Anne-Charlotte Robisson. The importance of the amount/thickness of die wall lubricant for UO 2 pellets pressing[J]. Ceramics International,2018,44(11). [10]Kailun Zheng,Yangchun Dong,Hanshan Dong,JonathanFernandez,Trevor A Dean. Investigation of the lubrication performance using WC: C coated tool surfaces for hot stampingAA6082[J]. Procedia Engineering,2017,207. [11]Ersyzario Edo Yunata,Tatsuhiko Aizawa,Kenji Tamaoki,Masao Kasugi. Plasma Polishing and Finishing of CVD-Diamond Coated WC (Co) Dies for Dry Stamping[J]. Procedia Engineering,2017,207. [12]L. Fernandes,F.J.G. Silva,M.F. Andrade,R. Alexandre,A.P.M. Baptista,C. Rodrigues. Improving the punch and die wear behavior in tin coated steel stamping process[J]. Surface & Coatings Technology,2017,332. [13]Xiaochuan Liu,Mohammad M. Gharbi,Oualid Manassib,Omer El Fakir,LiLiang Wang. Determination of the interfacial heat transfer coefficient between AA7075 and different forming tools in hot stamping processes[J]. Procedia Engineering,2017,207. [14]Li-Wei Chen,Ming-Jhe Cai. Development of a hot stamping clinching tool[J]. Journal of Manufacturing Processes,2018,34. [15]Xiaochuan Liu,Omer El Fakir,Mohammad M. Gharbi,LiLiang Wang. Effect of tool coating on interfacial heat transfer coefficient in hot stamping of AA7075 aluminium alloys[J]. ProcediaManufacturing,2018,15. [16]Yuki Nakagawa,Ken-ichiro Mori,Tomoyoshi Maeno,Yoshitaka Nakao. Reduction in holding time at bottom dead centre in hot stamping by water and die quenching[J]. ProcediaManufacturing,2018,15. [17]Tomoki Hasegawa,Tatsuhiko Aizawa,Tadahiko Inohara,Kenji Wasa,Masahiro Anzai. Hot mold stamping of optical plastics and glasses with transcription of super-hydrophobic surfaces[J]. Procedia Manufacturing,2018,15. [18]Chunping Cao,Meng Li,Yu Li,Yu Sun. Intelligent fault diagnosis of hot die forging press based on binary decision diagram and fault tree analysis[J]. Procedia Manufacturing,2018,15. [19]Shiva Shankar Mangalore Babu,Stuart Berry,Michael Ward,Michal Krzyzanowski. Numerical investigation of key stamping process parameters influencing tool life and wear[J]. 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模具设计外文文献

模具设计外文文献

模具设计外文文献The Development Status and Trend of MoldThe mold is the manufacturing industry important craft foundation, in our country, the mold manufacture belongs to the special purpose e quipment manufacturing industry. China although very already starts to make the mold and the use mold, but long-term has not formed the industry. Straight stabs 0 centuries 80's lat er periods, the Chinese mold industry only then drives into the devel opment speedway. Recent years, not only the state-owned mold enterprise had the very big development, the three investm ents enterprise, the villages and towns (individual) the mold enterpr ise's development also rapid quietly.Although the Chinese mold industrial development rapid, but compa res with the demand, obviously falls short of demand, its main gap co ncentrates precisely to, large-scale, is complex, the long life mold domain. As a result of in aspect and so on mold precision, life, manufacture cycle and productivity, China and the international average horizontal and the developed cou ntry still had a bigger disparity, therefore, needed massively to imp ort the mold every year .The Chinese mold industry must continue to sharpen the productivity, from now on will have emphatically to the profession internal structu re adjustment and the state-of-art enhancement.The structure adjustment aspect, mainly is the enterprise structure to the specialized adjustment, the product structure to center the ups cale mold development, to the import and export structure improvement, center the upscale automobile cover mold forming analysis and the str ucture improvement, the multi- purpose compound mold and the compound processing and the laser techn ology in the mold design manufacture application, the high-speed cutting, the super finishing and polished the technology, the i nformaton direction develops .The recent years, the mold profession structure adjustment and the or ganizational reform step enlarges, mainly displayed in, large-scle, precise, was complex, the long life, center the upscale mold an d the mold standad letter development speed is higher than the common mold product; The plastic mold an the compression casting mold propo rtion increases; Specialized mold factory quantty and its productivit y increase;"The three investments" and the private enterprise develops rapidly; The joint stocksystem transformation step speeds up and so on. Distri butes from the area looked,takeZhejiang Delta and Yangtze River delta as central southeast coastal a rea development quickly to mid-west area, south development quickly to north. At present develops qu ickest, the mold produces the most centralized province is Guangdong and Zhejiang, places such as Jiangsu, Shanghai, Ahui and Shandong als o has a bigger development in recent years.Although our country mold total quantity had at present achieved the suitable scale, the mold level also has the very big enhancement, after but design manufacture horizontal overallrise and fall indust ry developed country and so on Yu De, America, date, France, Italy ma ny. The current existence question and the disparity mainly display i n following several aspects:(1)The total quantity falls short of demandDomestic mold assembling one rate only, about 70%. Low- grade mold, center upscale mold assembling oneself rate only has 50% about.(2)the enterprise organizational structure, the product structure, the technical structure and the import and export structure does not ga therIn our country mold production factory to be most is from the lab or mold workshop which produces assembles oneself (branch factory), f rom produces assembles oneself the proportion to reach as high as abo ut 60%, but the overseas mold ultra 70% is the commodity mold. The sp ecialized mold factory mostly is "large and complete", "small and entire" organization form, but overseas mostly is "small but", "is speci ally small and fine". Domestic large-scale, precise,complex, the long life mold accounts for the total qua ntity proportion to be insufficient 30%, but overseas in 50% above 2004 years, ratio of the mold import and export is 3.7:1, the import and export balances the after net import volume to amount to 1.32 billi on US dollars, is world mold net import quantity biggest country.(3)The mold product level greatly is lower than the international sta ndard The production cycle actually is higher than the international water broad product level low mainly todisplay in the mold precision, cavity aspect and so on surface roughness, life and structure.(4)Develops the ability badly, economic efficiency unsatisfactory our country mold enterprise technical personnel proportion lowThe level is lower, also does not take the product development, and is frequent in the passive position in the market. Our country each mold staff average year creation output value approximately, ten thousa nd US dollars, overseas mold industry developed country mostly 15 to1 0, 000 US dollars, some reach as high as 25 to10, 000 US dollars, rel ative is our country quite part of molds enterprises also continues to use the workshop type management with it, truly realizes the enterp rise which the modernized enterprise manages few To create the above disparity the reason to be very many, the mold long-term has not obtained the value besides the history in as the product which should have, as well as the most state- owned enterprises mechanism cannot adapt the market economy, but also has the following several reasons:(1)Country to mold industry policy support dynamics also insufficientlyAlthough the country already was clear about has promulgated the mold profession industrial policy, but necessary policy few, carried outdynamics to be weak. At present enjoyed the mold product increment d uty enterprise nation 185; the majority enterprise still the tax burd en is only overweight. The mold enterprise carries on the technologic al transformations introduction equipment to have to pay the consider able amount the tax money, affects the technology advancement, moreov er privately operated enterprise loan extremely difficult.(2)Talented person serious insufficient, the scientific research deve lopment and the technical attack investment too urine Mold profession is the technology, the fund, the work crowded industr y, alongwith the time progress and the technical development, grasps the tale nted person which and skilled utilizes the new technology exceptional ly short, the high-quality mold fitter and the enterprise management talent extremely is also anxious. Because the mold enterprise benefit unsatisfactory and takes insufficiently the scientific research development and the tec hnical attack, the scientific research unit and theuniversities, colleges and institutes eye stares at is creating incom e, causes the mold profession invests too few in the scientific resea rch development and the technical attack aspect, causes the mold tech nological development step doe not to be big, progresses does not be quick.(3)The craft equipment level is low, also is not good, the using fact or is low.Recent years ,our country engine bed profession progressed quickl y, has been able to provide the quite complete precision work equipme nt, but compared with the overseas equipment, still had a bigger disp arity. Although the domestic manyenterprises have introduced many ov erseas advanced equipment, but the overall equipment level low are ve ry more than the overseas many enterprises. As a result of aspect the and so on system and fund reason, introduces the equipment not neces sary, the equipment and the appendix not necessary phenomenon are ext remely common, the equipment utilization rate low question cannot obt ain the comparatively properly solution for a long time .(4)Specialization, standardization, commercialized degree low, the co operation abilityBecause receives "large and complete" "small and entire" the infl uence since long ago, mold specialization level low, the specialized labor division is not careful, the commercialized degree is low. At p resent domestic every year produces mold, commodity mold minister 40% about, other for from produce uses for oneself.Between the molds enterprise cooperates impeded, completes the compar atively large-scale mold complete task with difficulty. Mold standardization level low, mold standard letter use cave rare is low also to the mold quali ty, the cost has a more tremendous influence, specially has very trem endous influence.(5)The mold material and the mold correlation technology fallThe mold material performance, the quality and the variety questi on often can affect the mold quality, the life and the cost, the dome stically produced molding tool steel and overseas imports the steel p roducts to compare has a bigger disparity. Plastic, plate, equipment energy balance, also direct influence mold level enhancement.At present, our country economy still was at the high speed devel opment phase,on the international economical globalization development tendency is day by day obvious, this has provided the good condition and the opp ortunity for the our country mold industry high speed development. On the one hand, the domestic mold market will continue high speed to d evelop, on the other hand, the mold manufacture also gradually will s hift as well as the transnational group to our country carries on the mold purchase trend to our country extremely to be also obvious. The refore, will take a broad view the future, international, the domesti c mold market overall development tendency prospect will favor, estim ated the Chinese mold will obtain the high speed development under th e good market environment, our country not only can become the mold g reat nation, moreover certainly gradually will make the powerful nati on to the mold the ranks to make great strides forward. "The Eleventh Five-Year Plan" period, the Chinese mold industry level not only has the v ery big enhancement in the quantity and the archery target aspect, mo reover the profession structure, the product level, the development i nnovation ability, enterprise's system and the mechanism as well as t he technology advancement aspect also can obtain a bigger development. The mold technology has gathered the machinery, the electron, chemist ry, optics, the material, the computer, the precise monitor and the i nformation network and so on many disciplines, is a comprehensive nat ure multi-disciplinary systems engineering.The mold technology development tendency mainly is the mold product to larger-scale, precise, more complex and a more economical direction develops, the mold product technical content unceasingly enhances, the mold man ufacture cycle unceasingly reduces, the mold production faces the inf ormation, is not having the chart, is fine, the automated direction d evelops, the mold enterprise to the technical integration, the equipm ent excellent, is producing approves the brand, the management inform ation, the management internationalization direction develops.Mold profession in "The Eleventh Five-Year Plan" period needs to solve the key essential technology should be the mold information, the digitized technology and precise, ultra fine, high speed, the highly effective manufacture technology aspect breakthrough. Along with the national economy total quantity and the industry product technology unceasing development, all the various tr ades and occupations tothe mold demand quantity more and more big, the specification more and more is also high.Although mold type many, but its development should be with empha sis both can meet the massive needs, and has the comparatively high-tech content, specially at present domestic still could not be self-sufficient, needs the massive imports the mold and can represent the development direction large- scale, precise, is complex, the long life mold. Standard letter type, quantity, level and the production of the mold have significant infl uence to the entire mold profession development. Therefore, some important mold standard letters also must prioritize, moreover its develo pment speed should quickly to the mold development speed, like this be able unceasingly to raise our country mold standardization level, t hus improves the mold quality, reduces the mold production cycle, red uces the cost. Because our country mold product holds the bigger price superiority in the international market, therefore regarding the ex portation prospect good mold product also should take key develops. A ccording to the above required quantity big, the technical content is high, represents the development direction, the export prospect good principle choice prioritize product, moreover chooses the product to have at present to have the certain technology base, belongs has the condition, has the product which the possibility develops.Our country mold profession still will have to enhance from now on the general character technology had:(1)To establish in the CAD/CAE platform the advanced mold design tech nology, enhances modernization which the mold designed, information, intellectualization, standardized level .(2)Establishes in the CAM/CAPP foundation the advanced mold processing technology and the advanced manufacture technology unifies, raisesthe automated level and the production efficiency which the mold proc esses.(3)The mold production enterprise's information management technology. For example PDM (product data management), ERP (enterprise resource m anagement), MIS (mold manufacture management information system) and information network technology the and so on INTERMET platform applic ation, the promotion and the development .(4)Are high speed, Gao Jing, the compound mold processing technology research and the application. For example the ultra fine ramming mold manufacture technology, the precise plastic and the compression cast ing mold manufacture technology and so on.(5)Enhances the mold production efficiency, reduces the cost and redu ces the mold production cycle each kind of fast economical mold manufacture technology.(6)The advanced manufacture technology application. For example hot t echnology and so on flow channel technology, gas auxiliary technology, hypothesized technology, nanotechnology, rapid scanning technology, r eversion project, parallel project in the mold research, the developm ent, the processing process application.(7)The raw material the simulation technology which forms in the mold.(8)The advanced mold processing and the appropriation equipment resea rch and the development .(9)The mold and the mold standard letter, the important auxiliary sta ndardized technology.(10)The mold and its the product examination technology.(11)High quality, the new mold material research and the development and its the correct application .(12)The mold production enterprise's modern management technologyDie trend1.Mold CAD / CAE / CAM being integrated, three-dimensional, intelligent and network direction(1)Mold software feature integratedDie software features of integrated software modules required relativ ely complete, while the function module using the same data model, in order to achieve Syndicated news management and sharing of informati on to support the mold design, manufacture, assembly, inspection, tes ting and production management of the entire process to achieve optim al benefits. Series such as the UK Delcam's software will include a s urface / solid geometric modeling, engineering drawing complex geomet ry, advanced rendering industrial design, plastic mold design expert system, complex physical CAM, artistic design and sculpture automaticprogramming system, reverse engineering and complex systems physical line measurement systems. A higher degree of integration of the soft ware includes: Pro / ENGINEER, UG and CATIA, etc.. Shanghai Jiao tong University, China with finite element analysis of metal plastic form ing systems and Die CAD / CAM systems; Beijing Beihang Haier Software Ltd. CAXA Series software; Jilin Gold Grid Engineering Research Cent er of the stamping die mold CAD / CAE / CAM systems.(2)Mold design, analysis and manufacture of three-dimensionalTwo-dimensional mold of traditional structural design can no longer meet modern technical requirements of production and integration.Mold design,analysis,manufacturing three-dimensional technology, paperless software required to mold a new gen eration of three-dimensional, intuitive sense to design the mold, using three-dimensional digital model can be easily used in the product structure of CAE analysis, tooling manufacturability evaluationand CNC machin ing, forming process simulation and information management and shaing.Such as Pro / ENGINEER, UG and CATIA software such as with parametri c, feature-based, all relevant characteristics, so that mold concurrent engineer ing possible.In addition, Cimatran company Mold expert, Delcam's Ps-mold and Hitachi Shipbuilding of Space-E/mold are professional injection mold 3D design software, interacti ve 3D cavity, core design, mold base design configuration and typical structure. Australian company Moldflow realistic three-dimensional flow simulation software MoldflowAdvisers been widely pra ised by users and applications.China Huazhong University of Science h ave developed similar software HSC3D4.5F and Zhengzhou University, Z-mold software.For manufacturing, knowledge-based intelligent software function is a measure of die important sign of advanced and practical one.Such as injection molding experts Cim atron's software can automatically generate parting direction based parting line and parting surface, generate products corresponding to t he core and cavity, implementation of all relevant parts mold, and fo r automatically generated BOM Form NC drilling process, and can intel ligentlyprocess parameter setting, calibration and other processing results.(3)Mold software applications, networking trendWith the mold in the enterprise competition, cooperation,product ion and management, globalization, internationalization, and the rapi d development of computer hardware and software technology, the Inter net has made in the mold industry, virtual design, agile manufacturin g technology both necessary and possible.The United States in its "21st Century Manufacturing Enterprise S trategy" that the auto industry by 2006 to achieve agile manufacturin g / virtual engineering solutions to automotive development cycle shortened from 40 months to 4 months.2.Mold testing, processing equipment to the precise, efficient, and m ulti-direction(1)Mold testing equipment more sophisticated, efficientSophisticated Complex, large-scale mold development, testing equipment have become increasingly de manding.Precision Mould precision now reached 2~3m, more domestic manufac turers have to use Italy, the United States, Japan and other countrie s in the high-precision coordinate measuring machine, and with digital scanning.Such as Dongfeng Motor Mould Factory not only has the capacity 3250m m × 3250mm Italian coordinate measuring machine, also has a digital photography optical scanner, the first in the domestic use of digital photography, optical scanning as a means of spatial three-dimensional access to information, enabling the establishment from the measurement of physical → model output of engineering drawings →→ the whole process of mold making, reverseengineering a successful technology development and applications. This equipment include: sec ond-generation British Renishaw high-speed scanners (CYCLON SERIES2) can be realized and contact laser pro be complementary probe, laser scanner accuracy of 0.05mm, scanning pr obe contact accuracy of 0.02 mm.Another German company GOM ATOS portable scanners,Japan Roland's PIX -30, PIX-4 desktop scanner and the United Kingdom Taylor Hopson's TALYSCAN150 multi-sensor, respectively Three-dimensional scanner with high speed, low-cost and functional composite and so on.(2)CNC EDMJapan Sodick linear motor servo drive using the company's AQ325L, AQ550LLS-WEDM have drivenfast response, transmission and high positioning accuracy, the advant ages of small thermal deformation. Switzerland Chanmier company NCEDM with P-E3 adaptive control, PCE energy control and automatic programming exp ert systems.Others also used the powder mixed EDM machining technology, micro-finishing pulse power and fuzzy control (FC) technologies.(3)High-speed milling machine (HSM)Milling is an important means of cavity mold.The low-temperature high-speed milling with the workpiece, cutting force is small, smooth proc essing, processing quality, processing efficiency (for the general mi lling process 5 to 10 times) and can process hardmaterials (<60HRC) and many other advantages. Thus in the mold processing more and more attention. Ruishikelang company UCP710-type five-axis machining center, machine tool positioning accuracy up to 8μm, home-made closed-loop vector control spindle with a maximum speed 42000r/min. Italy RA MBAUDI's high-speed milling, the processing range of up to 2500mm × 5000mm × 1800 mm, speed up 20500r/min, cutting feed speed of 20m/min. HSM generally used large, medium-sized mold, such as motor cover mold, die casting mold, large plastic surface machining, the surface precision up to 0.01mm.。

冲压模具成型外文翻译参考文献

冲压模具成型外文翻译参考文献

冲压模具成型外文翻译参考文献冲压模具成型外文翻译参考文献(文档含中英文对照即英文原文和中文翻译)4 Sheet metal forming and blanking4.1 Principles of die manufacture4.1.1 Classification of diesIn metalforming,the geometry of the workpiece is established entirely or partially by the geometry of the die.In contrast to machining processes,ignificantly greater forces are necessary in forming.Due to the complexity of the parts,forming is often not carried out in a single operation.Depending on the geometry of the part,production is carried out in several operational steps via one or several production processes such as forming or blanking.One operation can also include several processes simultaneously(cf.Sect.2.1.4).During the design phase,the necessary manufacturing methods as well as the sequence and number of production steps are established in a processing plan(Fig.4.1.1).In this plan,theavailability of machines,the planned production volumes of the part and other boundary conditions are taken into account.The aim is to minimize the number of dies to be used while keeping up a high level of operational reliability.The parts are greatly simplified right from their design stage by close collaboration between the Part Design and Production Departments in order to enable several forming and related blanking processes to be carried out in one forming station.Obviously,the more operations which are integrated into a single die,the more complex the structure of the die becomes.Theconsequences are higher costs,a decrease in output and a lower reliability.Fig.4.1.1 Production steps for the manufacture of an oil sump Types of diesThe type of die and the closely related transportation of the part between dies is determined in accordance with the forming procedure,the size of the part in question and the production volume of parts to be produced.The production of large sheet metal parts is carried out almost exclusively using single sets of dies.Typical parts can be found in automotive manufacture,the domestic appliance industry and radiator production.Suitable transfer systems,for example vacuum suction systems,allow the installation of double-action dies in a sufficiently large mounting area.In this way,for example,the right and left doors of a car can be formed jointly in one working stroke(cf.Fig.4.4.34).Large size single dies are installed in large presses.The transportation of the parts from oneforming station to another is carried out mechanically.In a press line with single presses installed one behind the other,feeders or robots can be used(cf.Fig.4.4.20 to 4.4.22),whilst in large-panel transfer presses,systems equipped with gripper rails(cf.Fig.4.4.29)or crossbar suction systems(cf.Fig.4.4.34)are used to transfer the parts.Transfer dies are used for the production of high volumes of smaller and medium size parts(Fig.4.1.2).They consist of several single dies,which are mounted on a common base plate.The sheet metal is fed through mostly in blank form and also transported individually from die to die.If this part transportation is automated,the press is called a transfer press.The largest transfer dies are used together with single dies in large-panel transfer presses(cf.Fig.4.4.32).In progressive dies,also known as progressive blanking dies,sheet metal parts are blanked in several stages;generally speaking no actual forming operation takes place.The sheet metal is fed from a coil or in the form of metal ing an appropriate arrangement of the blanks within the available width of the sheet metal,an optimal material usage is ensured(cf.Fig.4.5.2 to 4.5.5). The workpiece remains fixed to the strip skeleton up until the laFig.4.1.2 Transfer die set for the production of an automatic transmission for an automotive application-st operation.The parts are transferred when the entire strip is shifted further in the work flow direction after the blanking operation.The length of the shift is equal to the center line spacing of the dies and it is also called the step width.Side shears,very precise feeding devices or pilot pins ensure feed-related part accuracy.In the final production operation,the finished part,i.e.the last part in the sequence,is disconnected from the skeleton.A field of application for progressive blanking tools is,for example,in the production of metal rotors or stator blanks for electric motors(cf.Fig.4.6.11 and 4.6.20).In progressive compound dies smaller formed parts are produced in several sequential operations.In contrast to progressive dies,not only blanking but also forming operations areperformed.However, the workpiece also remains in the skeleton up to the last operation(Fig.4.1.3 and cf.Fig.4.7.2).Due to the height of the parts,the metal strip must be raised up,generally using lifting edges or similar lifting devices in order to allow the strip metal to be transported mechanically.Pressed metal parts which cannot be produced within a metal strip because of their geometrical dimensions are alternatively produced on transfer sets.Fig.4.1.3 Reinforcing part of a car produced in a strip by a compound die setNext to the dies already mentioned,a series of special dies are available for special individual applications.These dies are,as a rule,used separately.Special operations make it possible,however,for special dies to be integrated into an operational Sequence.Thus,for example,in flanging dies several metal parts can be joined together positively through the bending of certain metal sections(Fig.4.1.4and cf.Fig.2.1.34).During this operation reinforcing parts,glue or other components can be introduced.Other special dies locate special connecting elements directly into the press.Sorting and positioning elements,for example,bring stamping nuts synchronised with the press cycles into the correct position so that the punch heads can join them with the sheet metal part(Fig.4.1.5).If there is sufficient space available,forming and blanking operations can be carried out on the same die.Further examples include bending,collar-forming,stamping,fine blanking,wobble blanking and welding operations(cf.Fig.4.7.14 and4.7.15).Fig.4.1.4 A hemming dieFig.4.1.5 A pressed part with an integrated punched nut4.1.2 Die developmentTraditionally the business of die engineering has been influenced by the automotive industry.The following observations about the die development are mostly related to body panel die construction.Essential statements are,however,made in a fundamental context,so that they are applicable to all areas involved with the production of sheet-metal forming and blanking dies.Timing cycle for a mass produced car body panelUntil the end of the 1980s some car models were still being produced for six to eight years more or less unchanged or in slightly modified form.T oday,however,production time cycles are set for only five years or less(Fig.4.1.6).Following the new different model policy,the demands ondie makers have alsochanged prehensive contracts of much greater scope such as Simultaneous Engineering(SE)contracts are becoming increasingly common.As a result,the die maker is often involved at the initial development phase of the metal part as well as in the planning phase for the production process.Therefore,a muchbroader involvement is established well before the actual die development is initiated.Fig.4.1.6 Time schedule for a mass produced car body panel The timetable of an SE projectWithin the context of the production process for car body panels,only a minimal amount of time is allocated to allow for the manufacture of the dies.With large scale dies there is a run-up period of about 10 months in which design and die try-out areincluded.In complex SE projects,which have to be completed in 1.5 to 2 years,parallel tasks must be carried out.Furthermore,additional resources must be provided before and after delivery of the dies.These short periods call for pre-cise planning,specific know-how,available capacity and the use of the latest technological and communications systems.The timetable shows the individual activities during the manufacturing of the dies for the production of the sheet metal parts(Fig.4.1.7).The time phases for large scale dies are more or less similar so that this timetable can be considered to be valid in general.Data record and part drawingThe data record and the part drawing serve as the basis for all subsequent processing steps.They describe all the details of the parts to be produced. The information given in theFig.4.1.7 Timetable for an SE projectpart drawing includes: part identification,part numbering,sheet metal thickness,sheet metal quality,tolerances of the finished part etc.(cf.Fig.4.7.17).To avoid the production of physical models(master patterns),the CAD data should describe the geometry of the part completely by means of line,surface or volume models.As ageneral rule,high quality surface data with a completely filleted and closed surface geometry must be made available to all the participants in a project as early as possible.Process plan and draw developmentThe process plan,which means the operational sequence to be followed in the production of the sheet metal component,is developed from the data record of the finished part(cf.Fig.4.1.1).Already at this point in time,various boundary conditions must be taken into account:the sheet metal material,the press to be used,transfer of the parts into the press,the transportation of scrap materials,the undercuts as well as thesliding pin installations and their adjustment.The draw development,i.e.the computer aided design and layout of the blank holder area of the part in the first forming stage–if need bealso the second stage–,requires a process planner with considerable experience(Fig.4.1.8).In order to recognize and avoid problems in areas which are difficult to draw,it is necessary to manufacture a physical analysis model of the draw development.With this model,theforming conditions of the drawn part can be reviewed and final modifications introduced,which are eventually incorporated into the data record(Fig.4.1.9).This process is being replaced to some extent by intelligent simulation methods,through which the potential defects of the formed component can be predicted and analysed interactively on the computer display.Die designAfter release of the process plan and draw development and the press,the design of the die can be started.As a rule,at thisstage,the standards and manufacturing specifications required by the client must be considered.Thus,it is possible to obtain a unified die design and to consider the particular requests of the customer related to warehousing of standard,replacement and wear parts.Many dies need to be designed so that they can be installed in different types of presses.Dies are frequently installed both in a production press as well as in two different separate back-up presses.In this context,the layout of the die clamping elements,pressure pins and scrap disposal channels on different presses must be taken into account.Furthermore,it must be noted that drawing dies working in a single-action press may be installed in a double-action press(cf.Sect.3.1.3 and Fig.4.1.16).Fig.4.1.8 CAD data record for a draw developmentIn the design and sizing of the die,it is particularly important to consider the freedom of movement of the gripper rail and the crossbar transfer elements(cf.Sect.4.1.6).These describe the relative movements between the components of the press transfer system and the die components during a complete press working stroke.The lifting movement of the press slide,theopening and closing movements of the gripper rails and the lengthwise movement of the whole transfer are all superimposed.The dies are designed so that collisions are avoided and a minimum clearance of about 20 mm is set between all the moving parts.4 金属板料的成形及冲裁4. 模具制造原理4.1.1模具的分类在金属成形的过程中,工件的几何形状完全或部分建立在模具几何形状的基础上的。

冲压模具外文文献

冲压模具外文文献

冲压模具外文文献Progressive DieProgressive die has the following advantages1) Class into the module is multi-process dies, in a mold caninclude punching, bending, forming and drawing a variety of multi-pass process, with a higher than the compound die labor productivity, butalso can produce quite complex stampings;2) Progressive Die Operation Security, because staff do not have to enter the danger zone;3) Class Progressive Die Design, The process can be distributed. Do not focus on one station , there is no Compound Dies "Minimum wall thickness" problem. Therefore relatively high mold strength, longer life expectancy. 4) Progressive Die Easy Automation That is easy to Automatic feeding ,Autoout of parts Automatic lamination;5) Class Progressive die can be High-speed press production, because the workpiece can be directly down the drain and waste;6) Use Class Progressive die can be Reduce the presses, semi-finished products to reduce transport. Workshop area and storage space can be greatly reduced.Progressive Dies The disadvantage is that complex structure, manufacturing of high precision, long life cycle and high costs. Because of progressive die is a To the workpiece, the shape of successive out, each punch has a positioning error, is more difficult to maintainstability in the workpiece, the relative position of the one-off appearance. However, high precision parts, not all contours of all, the shape relative position requirements are high, you can be washed in the shape of the same station, on the relative position of demanding the same time, out of this part of the profile, thus ensuring precision parts. First, process pieces of carry approachProcesses and the determination of nesting is of the progressive die design a very important link. In considering the processes and nesting, we must first consider the process method of carriage parts.Bending parts there are two main ways to carry:1) Blanking station in the upper and lower pressure, so that after blanking process pieces and re-pressed into the material inside. Generally only about access to material thickness of thel/3, but has enough to process pieces with the material sent to the next process, within the workpiece in the working procedure have all been pressed into the material inside the remnant. Beyond that, after process pieces are washed curved shape, until the last escape from the Strip. The drop in this way conveying pairs of thick material is very effective, because the thin material easy to bagging, wrinkles, or bent, thus blanking out the flat blank song, not with the advance of material and stops in a station caused the accident.Simple blanking progressive die, sometimes in order to ensure that the workpiece is flat and has also taken off after the re-feed materialsput pressure on people within the approach, in the latter process to workpiece pushed.Because blanking after being re-pressed into the workpiece can notbe material in the thickness direction all entered the hole, so in the blanking die station after the plane, to the corresponding lower.2) Rush to need to bend some of the surrounding material, the restof the parts remain in the article (Volume)Materials, there is no separation. As the hub of to the material, You may need to spend a long Progress in distance delivery.Second, the principle of work arrangements1)Blanking the workpiece to avoid the use of complex shapes convex mode. Rather more than the increase a process to simplify the convex mode shapes. 2)"U"-shaped pieces can be divided into two out, asFigure7--76As shown in order to avoid material stretched, out of Workpiece dimensions vary.Figure7--76 U shaped pieces of curved process3)In the asymmetric bending, the workpiece slide easily can be shown in Figure7—77shown with teeth inserts were inserts into the bend Convex Mold and roof in order to prevent the workpiece sliding. The main disadvantage of this method is the a)After the procedure b)pre-process workpiece plane with prints. Also available on the heat treatment before Convex Mold and roof pre-perforated, after tryout after the sheet metal through the tryout will be two holes without sliding inlay Ping . If sliding is used tooth inserts.Figure7--77 To prevent the sheet metal bending generated whensliding1- Bending Convex Die 2- Cut off Convex Die 3- Roof 4- With teeth inserts4) Bending or deep drawing of the workpiece, high-quality plastic surgery procedures should be added.5) Waste, such as continuous, should increase the cutting process, using waste cutter cut. Automatic press itself, as some waste cutter, you do not have to die to consider.6) Can be countersunk head hole punching. Figure7—78 shows thefirst holepunching of the workpiece . When clamping the punch die Xiaoping Tou both plane and concave hole stretch of artificial parts, and contact with each other in order to prevent inward deformation of holes. Clamping direction due to the strict size requirements, so the punch assembly when subject to a high degree of repair potential. Also can be used as shown in Figure 7-79 height adjustment body punch. The upper punch 3 face, contact with the slider 2. Slider right-hand side has opened a T-shaped slot to accommodate the screw 5 in the head. Rotating screw 5, then move along the slider 2. As the slider 2 and the mold base 4 in order to ramp contact with each other, while the punch 3 in the fixed plate is sliding in with l, consequent punch in the direction of the location of mold can be adjusted. Adjusted with the nut 6 fixed .Figure7--78 Stamp shen head hole1—Convex Die 2- DieFigure7--79 Punch height adjustment body1- Fixed Plate 2-Slider 3- Punch 4- On the mold base 5- Screw6- Nut7) There are strict requirements of local relative position withinthe shape, should consider the possibility of the same station on the out, in order to maintain accuracy. If there are really difficult to be broken down into two working bits. Be better placed in two adjacent stations.Third, the principle of stamping operations sequencing1)For pure blanking progressive dies, in principle, the first ,punch, followed by re-punching shape I expected, the final and then washed down from the Strip on the integrity of the workpiece. Carrier should be maintained of material of sufficient strength, can be accurate when sent to press.2)For the blanking bending progressive die should be washed beforecut off part of the hole and bend the shape I expected, and then bending, and finally washed near the curved edge holes and the side hole-bit accuracy of the sidewall holes. Washed down by the final separation of parts.3) Drawing for the progressive die stamping , first make arrangement to cut processes, further drawing, the final washed down from thearticle on the workpiece material.4)For with the deep drawing, bending stamping parts, the first drawing, then I punched the surrounding material, followed by bending plus.5)For stamping with a stamping parts, in order to facilitate themetal flow and reduce the stamping force, stamping parts of neighboringI expected to be an appropriate resection, and then arrange stamping. The final re -Precision Die-Cut materials .If there are holes on the embossing position, in principle, should be embossed after the punching.6)For with the stamping, bending and stamping workpiece, inprinciple, is the first imprint ,And then punching Yu Liu, And then bending process. Fourth, nesting layout1) Nesting mapping, you can start with plane launch fig start, right designed to blanking station, left the design forming station. Step by step according to the actual situation after the amendment.2) Consider increasing the intensity to be an empty station molds. Continuous drawing more frequently when the first drawing after being a backup space industry in order to increase the number of drawing. High precision, complex shape of the workpiece should be less to set an empty station. Step away from the mold is greater than 16mm When more than set up an empty station. Interval accuracy The poor should not be easily added an empty station. 3) Decided to process pieces of carry approach.4) Note that material rolling direction. Rolling direction affectsnot only the economic effects of nesting, but also affect theperformance of the workpiece. 5) Burr bending parts should be located in inside.6) Thin material used Guide is being sold, But do not side edge trimming. For thick material or heavy section materials, in order to avoid guide is being sold off the need to side edge trimming.7) According to the workpiece dimensions and the scale of production to determine a shape one pieces two documents or four parts, or more pieces. 8) Stamping process does not allow any scattered debris left on the die surface.9) Residual material on the press to consider the possibility of other parts.。

冲压模具 英文论文

冲压模具 英文论文

Computational published quarterly by the Association
Materials Science of Computational Materials Science
The optimal design of micro-punching
die by using abductive and SA methods
J.-Ch. Lin a, K.-S. Lee b, W.-S. Lin c,*
a Department of Mechanical Design Engineering, National Formosa University,
64 Wunhua Road, Huwei, Yunlin ,Taiwan
of the punch and die has been a common topic for scholars.
Design/methodology/approach: The input parameters (punching times, clearance) and output results (wear)
MANUFACTURING AND PROCESSING OF ENGINEERING MATERIALS
92 (C) Copyright by International OCSCO World Press. All rights reserved. 2009
As a result, the mathematics model is difficult to converge and the neural network will inaccurately predict wear.

冲压模具类外文文献翻译、中英文翻译、外文翻译

冲压模具类外文文献翻译、中英文翻译、外文翻译

模具工业是国民经济的基础工业,是国际上公认的关键工业,工业发达国家称之为“工业之母”。

模具成型具有效率高,质量好,节省原材料,降低产品成本等优点。

采用模具制造产品零件已成为当今工业的重要工艺手段。

模具在机械,电子,轻工,纺织,航空,航天等工业领域里,已成为使用最广泛的工业化生产的主要工艺装备,它承担了这些工业领域中60%--80%产品零件,组件和部件的加工生产。

“模具就是产品质量”,“模具就是经济效益”的观念已被越来越多的人所认识和接受。

在中国,人们已经认识到模具在制造业中的重要基础地位,认识更新换代的速度,新产品的开发能力,进而决定企业的应变能力和市场竞争能力。

在目前用薄钢板制造发动机罩盖的传统还是会持续相当一段时间,所以有必要在钢板的基础上通过利用计算机软件的功能分析零件的工艺性能(结构合理,受力,是否容易冲出破面、、、),发现现有零件的不足之处,讨论并确定改进这些不足之处,进而改善模具的设计,改良冲裁方式;最终实现产品的改良,改善产品的力学性能,外观,使用效果,和造价等等。

冲压加工是通过模具来实现的,从模具角度来看,模具生产技术水平的高低,已成为衡量一个国家产品制造水平高低的重要标志,因为模具在很大程度上决定着产品的质量、效益和新产品的开发能力。

“模具是工业生产的基础工艺装备”也已经取得了共识。

据统计,在电子、汽车、电机、电器、仪器、仪表、家电和通信等产品中,60%~80%的零部件都要依靠模具成形。

用模具生产制件所具备的高精度、高复杂程度、高一致性、高生产率和低消耗,是其他加工制造方法所不能比拟的。

同时,冲压加工也创造了巨大的价值增值,模具是“效益放大器”,用模具生产的最终产品的价值,往往是模具自身价值的几十倍、上百倍。

目前全世界模具年产值约为600亿美元,日、美等工业发达国家的模具工业产值已超过机床工业,从1997年开始,我国模具工业产值也超过了机床工业产值。

其中冲压模具在所有模具(锻造模、压铸模、注塑模等)中,无论从数量、重量或者是从价值上都位居榜首。

冲压模具中英文对照

冲压模具中英文对照

冲压模具中英文对照Stamping die is a key component in the stamping process, and it plays a crucial role in shaping metal sheets into desired forms. 冲压模具是冲压工艺中的关键组件,它在将金属板材成形为所需形状中发挥着至关重要的作用。

Stamping die is commonly used in various industries such as automotive, aerospace, electronics, and construction. 冲压模具通常被广泛应用于汽车、航空航天、电子和建筑等各个行业。

The design and manufacturing of stamping die require high precisionand expertise. 冲压模具的设计和制造需要高度的精密度和专业知识。

The quality of stamping die directly affects the quality and efficiency of the stamping process. 冲压模具的质量直接影响了冲压过程的质量和效率。

Therefore, it is important to understand the characteristics and functions of stamping die in order to produce high-quality products. 因此,了解冲压模具的特点和功能对于生产高质量产品是非常重要的。

Stamping die can be classified into various types based on their functions, such as blanking die, piercing die, bending die, and progressive die. 根据其功能,冲压模具可以被分类为各种类型,如剪床模、冲孔模、弯曲模和级进模。

冲压模具技术外文翻译(含外文文献)

冲压模具技术外文翻译(含外文文献)

前言在目前激烈的市场竞争中,产品投入市场的迟早往往是成败的关键。

模具是高质量、高效率的产品生产工具,模具开发周期占整个产品开发周期的主要部分。

因此客户对模具开发周期要求越来越短,不少客户把模具的交货期放在第一位置,然后才是质量和价格。

因此,如何在保证质量、控制成本的前提下加工模具是值得认真考虑的问题。

模具加工工艺是一项先进的制造工艺,已成为重要发展方向,在航空航天、汽车、机械等各行业得到越来越广泛的应用。

模具加工技术,可以提高制造业的综合效益和竞争力。

研究和建立模具工艺数据库,为生产企业提供迫切需要的高速切削加工数据,对推广高速切削加工技术具有非常重要的意义。

本文的主要目标就是构建一个冲压模具工艺过程,将模具制造企业在实际生产中结合刀具、工件、机床与企业自身的实际情况积累得高速切削加工实例、工艺参数和经验等数据有选择地存储到高速切削数据库中,不但可以节省大量的人力、物力、财力,而且可以指导高速加工生产实践,达到提高加工效率,降低刀具费用,获得更高的经济效益。

1.冲压的概念、特点及应用冲压是利用安装在冲压设备(主要是压力机)上的模具对材料施加压力,使其产生分离或塑性变形,从而获得所需零件(俗称冲压或冲压件)的一种压力加工方法。

冲压通常是在常温下对材料进行冷变形加工,且主要采用板料来加工成所需零件,所以也叫冷冲压或板料冲压。

冲压是材料压力加工或塑性加工的主要方法之一,隶属于材料成型工程术。

冲压所使用的模具称为冲压模具,简称冲模。

冲模是将材料(金属或非金属)批量加工成所需冲件的专用工具。

冲模在冲压中至关重要,没有符合要求的冲模,批量冲压生产就难以进行;没有先进的冲模,先进的冲压工艺就无法实现。

冲压工艺与模具、冲压设备和冲压材料构成冲压加工的三要素,只有它们相互结合才能得出冲压件。

与机械加工及塑性加工的其它方法相比,冲压加工无论在技术方面还是经济方面都具有许多独特的优点,主要表现如下;(1) 冲压加工的生产效率高,且操作方便,易于实现机械化与自动化。

冲压模具英文文献

冲压模具英文文献

Forming DiesForming dies, often considered in the same class with bending dies, are classified as tools that form or bend the blank along a curved axis instead of a straight axis. There is very little stretching or compressing of the material. The internal movement or the plastic flow of the material is localized and has little or no effect on the total area or thickness of the material. The operations classified as forming are bending, drawing, embossing, curling, beading, twisting, spinning, and hole flanging.A large percentage of stampings used in the manufacturing of products require some forming operations. Some are simple forms that require tools of low cast and conventional design. Others may have complicated forms, which require dies that produce multiple forms in one stroke of the press. Some stampings may be of such nature that several dies must be used to produce the shapes and forms required.A first consideration in analyzing a stamping is to select the class of die to perform the work. Next to be considered is the number of stampings required, and this will govern the amount of money that should be spent in the design and building of the tools. Stampings of simple channels in limited production can be made on a die classed as a solid form die. It would be classified under channel forming dies. Others-the block and pad type-are also channel forming dies. Such operations as curling, flanging, and embossing as well as channeling employ pressure pads.A forming die may be designed in many ways and produce the same results; at this point the cost of the tool, safety of operation, and also the repairing and reworking must be considered. The tool that is cheapest and of the simplest design may not always be best because it may not produce the stamping to the drawing specifications. Where limited production is required, and a liberal tolerance is allowed in a stamping, a solid form die can be used.Drawing DiesDrawing is a process of changing a flat, precut metal blank into a hollow vessel without excessive wrinkling, thinning, or fracturing. The various forms produced may be cylindrical or box-shaped with straight or tapered sides or a combination of straight, tapered, or curved sides. The size of the parts may vary from 0.250″(6.35mm)diameter or smaller, to aircraft or automotive parts large enough to require the use of mechanical handling equipment.Die Design PrinciplesCoining Dies. In backward extruding dies the punch is always smaller in diameterthan the die cavity in order to give theclearance between punch and dieequaling the desired wall thickness ofthe part to be produced. The punch isloaded as a column. To minimizepunch failure it is desirable to coin theslugs to a close fit in diameter to assureconcentricity. Figure 8-66 illustrates acoining die to prepare a slug forbackward extrusion. Coining the slugto fit the diepot and coining the upperend to fit and guide the free end of the punch will minimize punch breakage of the extruding die.Backward Extrusion Dies. A typical backward extrusion die is shown in Figure8-67. The use of a carbide die cavitywill minimize wear due to excessivepressures. The carbide insert is shrunkinto a tapered holder. The holder has a1◦ side taper that prestresses thecarbide insert to minimize expansionand fatigue failure. The inserts arewell supported on hardened blocks.The extruding punch is guided by aspring-loaded guide plate which inturn is positioned by a tapered pilotingring on the lower die. Ejection of thefinished part from the die is bycushion or pressure cylinder. Figure 8-68illustrates a backward extrusion die withan unusual punch penetration ratio of 5:1 made possible with a modified flat-endpunch profile.Forward Extrusion Dies. Figure 8-69 is an example of a typical forwardextrusion die in which the metal flows inthe same direction as the punch, but at agreater rate owing to change in the cross-sectional area. The lower carbide guidering is added to maintain straightness. The nest above the upper carbide guide ring serves as a guide for the punch during the operation. Figure 8-70 illustrates anotherforward extrusion die in which the punch creates the orifice through which the metal flows. The extruding pressure is applied through the punch guide sleeve.Combination Extruding Dies. A typical combination forward and backward extrusion die is shown in Figure 8-71. In this die, the two –piece pressure anvil acts as a bottom extruding punch and a shedder. The upper extruding punch is guided by a spring-loaded guide plate into which the guide sleeve is mounted. To maintainconcentricity between the punch anddie, the punch guide sleeve iscentered into the die insert.Punch Design.The mostimportant feature of punch design isend profile. A punch with a flat endface and a corner radius not over0.020″(0.51mm) can penetrate threetimes its diameter in steel, four to sixtimes its diameter in aluminum. Apunch with a bullet-shaped nose orwith a steep angle will cut through the phosphate coat lubricant quicker than a flat-end punch. When the lubricant is displaced in extrusion, severe galling and wear of the punch will take palce. The punch must be free of grinding marks and requires a 4µ in.(0.10µm) finish, lapped in the direction of metal flow. The punch should be made of hardened tool steel or carbide. In some backward extrusion dies a shoulder is provided on punch to square up the metal as it meets this shoulder.Pressure Anvil Design. The function of the pressure anvil is to form the base of the diepot, to act as a bottom extruding punch, and to act as a shedder unit to eject the finished part. Heat treatment and surface finish requirements are the same for pressure anvils and for punches.Diepot Design. To resist diepot bursting pressure, the tool steel or carbide die ring is shrunk into the shrink ring or die shoe. The die shoe is normally in compression. A shrink fit of 0.004″per in.(0.004mm per mm) of diameter of the insert is desirable. Material, heat treatment, and finish requirements of the diepot are the same as for the punch. The recommended material for shrink rings is a hot-worked alloy tool steel which is hardened to Rc 50-Rc 52. A two-piece diepot insert is sometimes used for complex workpiece shapes.Punch Guide Design. The guide ring minimizes the column loading on the punch above the diepot. The spring-loaded guide sleeve pilots the punch into the diepot and maintains concentricity between them. The guide ring can also act as a stripper. The proper use of guide sleeves permits higher penetration ratios.成型模成型模具,通常被认为是与弯曲模属于同一类,被作为工具,沿着弯曲的轴线而非直线轴线使工件半成品成型或弯曲。

【机械专业英文文献】在冲压模具设计的拉伸壁起皱分析

【机械专业英文文献】在冲压模具设计的拉伸壁起皱分析

Int J Adv Manuf Technol (2002) 19:253–2592002 Springer-Verlag London LimitedAn Analysis of Draw-Wall Wrinkling in a Stamping Die DesignF.-K. Chen and Y.-C. LiaoDepartment of Mechanical Engineering, National Taiwan University, Taipei, Taiwan Wrinkling that occurs in the stamping of tapered square cups and stepped rectangular cups is investigated. A common characteristic of these two types of wrinkling is that the wrinkles are found at the draw wall that is relatively unsupported.In the stamping of a tapered square cup, the effect of process parameters, such as the die gap and blank-holder force, on the occurrence of wrinkling is examined using finiteelement simulations. The simulation results show that the larger the die gap, the more severe is the wrinkling, and such wrinkling cannot be suppressed by increasing the blank-holder force. In the analysis of wrinkling that occurred in the stamping of a stepped rectangular cup, an actual production part that has a similar type of geometry was examined. The wrinkles found at the draw wall are attributed to the unbalanced stretching of the sheet metal between the punch head and the step edge. An optimum die design for the purpose of eliminating the wrinkles is determined using finite-element analysis. The good agreement between the simulation results and those observed in the wrinkle-free production part validates the accuracy of the finite-element analysis, and demonstrates the advantage of using finite-element analysis for stamping die design.Keywords: Draw-wall wrinkle; Stamping die; Stepped rectangular cup; Tapered square cups1. IntroductionWrinkling is one of the major defects that occur in the sheet metal forming process. For both functional and visual reasons,wrinkles are usually not acceptable in a finished part. There are three types of wrinkle which frequently occur in the sheet metal forming process: flange wrinkling, wall wrinkling, and elastic buckling of the undeformed area owing to residual elastic compressive stresses. In the forming operation of stamping a complex shape, draw-wall wrinkling means the occurrence of wrinkles in the die cavity. Since the sheet metal in the wall area is relatively unsupported by the tool, the elimination of wall wrinkles is more difficult than the suppression of flange wrinkles. It is well known that additional stretching of the material in the unsupported wall area may prevent wrinkling,and this can be achieved in practice by increasing the blankholder force; but the application of excessive tensile stresses leads to failure by tearing. Hence, the blank-holder force must lie within a narrow range, above that necessary to suppress wrinkles on the one hand, and below that which produces fracture on the other. This narrow range of blank-holder force is difficult to determine. For wrinkles occurring in the central area of a stamped part with a complex shape, a workable range of blank-holder force does not even exist.In order to examine the mechanics of the formation of wrinkles, Yoshida et al. [1] developed a test in which a thin plate was non-uniformly stretched along one of its diagonals.They also proposed an approximate theoretical model in which the onset of wrinkling is due to elastic buckling resulting from the compressive lateral stresses developed in the non-uniform stress field. Yu et al. [2,3] investigated the wrinkling problem both experimentally and analytically. They found that wrinkling could occur having two circumferential waves according to their theoretical analysis, whereas the experimental results indicated four to six wrinkles. Narayanasamy and Sowerby [4] examined the wrinkling of sheet metal when drawing it through a conical die using flat-bottomed and hemispherical-ended punches. They also attempted to rank the properties that appeared tosuppress wrinkling.These efforts are focused on the wrinkling problems associated with the forming operations of simple shapes only, such as a circular cup. In the early 1990s, the successful application of the 3D dynamic/explicit finite-element method to the sheetmetal forming process made it possible to analyse the wrinkling problem involved in stamping complex shapes. In the present study, the 3D finite-element method was employed to analyse the effects of the process parameters on the metal flow causing wrinkles at the draw wall in the stamping of a tapered square cup, and of a stepped rectangular part.A tapered square cup, as shown in Fig. 1(a), has an inclined draw wall on each side of the cup, similar to that existing in a conical cup. During the stamping process, the sheet metal on the draw wall is relatively unsupported, and is therefore prone to wrinkling. In the present study, the effect of various process parameters on the wrinkling was investigated. In the case of a stepped rectangular part, as shown in Fig. 1(b),another type of wrinkling is observed. In order to estimate the effectiveness of the analysis, an actual production part with stepped geometry was examined in the present study. The cause of the wrinkling was determined using finite-element analysis, and an optimum die design was proposed to eliminate the wrinkles. The die design obtained from finite-element analysis was validated by observations on an actual production part.Sketches of (a) a tapered square cup.Sketches of(b) a stepped rectangular cup.Fig. 1.2. Finite-Element ModelThe tooling geometry, including the punch, die and blankholder,were designed using the CAD program PRO/ENGINEER. Both the 3-node and 4-node shell elements were adopted to generate the mesh systems for the above tooling using the same CAD program. For the finite-element simulation,the tooling is considered to be rigid, and the corresponding meshes are used only to define the tooling geometry and are not for stress analysis. The same CAD program using 4-node shell elements was employed to construct the mesh system for the sheet blank. Figure 2 shows the mesh system for the complete set of tooling and the sheet-blank used in the stamping of a tapered square cup. Owing to the symmetric conditions, only a quarter of the square cup is analysed. In the simulation, the sheet blank is put on the blank-holder and the die is moved down to clamp the sheet blank against the blank-holder. The punch is then moved up to draw the sheet metal into the die cavity.In order to perform an accurate finite-element analysis, the actual stress–strain relationship of the sheet metal is required as part of the input data.In the present study, sheet metal with deep-drawing quality is used in the simulations.A tensile test has been conducted for the specimens cut along planes coinciding with the rolling direction (0°) and at angles of 45°and 90°to the rolling direction.The average flow stress σ,calculated from the equation σ=(σ0+2σ45+σ90)/4, for each measured true strain,as shown in Fig.3, is used for the simulations for the stampings of the tapered square cup and also for the stepped rectangular cup.All the simulations performed in the present study were run on an SGI Indigo 2 workstation using the finite-element program PAMFSTAMP. To complete the set of input data required for the simulations, the punch speed is set to 10 m s_1 and a coefficient of Coulomb friction equal to 0.1 is assumed.Fig. 2. Finite-element mesh.Fig. 3. The stress–strain relationship for the sheet metal.3. Wrinkling in a Tapered Square CupA sketch indicating some relevant dimensions of the tapered square cup is shown in Fig. 1(a). As seen in Fig. 1(a), the length of each side of the square punch head (2Wp), the die cavity opening (2Wd), and the drawing height (H) are considered as the crucial dimensions that affect the wrinkling.Half of the difference between the dimensions of the die cavity opening and the punch head is termed the die gap (G) in the present study, i.e. G = Wd-Wp. The extent of the relatively unsupported sheet metal at the draw wall is presumably due to the die gap, and the wrinkles are supposed to be suppressed by increasing the blank-holder force. The effects of both the die gap and the blank-holder force in relation to the occurrence of wrinkling in the stamping of a tapered square cup are investigated in the following sections.3.1 Effect of Die GapIn order to examine the effect of die gap on the wrinkling, the stamping of a tapered square cup with three different die gaps of 20 mm, 30 mm, and 50 mm was simulated. In each simulation, the die cavity opening is fixed at 200 mm, and the cup is drawn to the same height of 100 mm. The sheet metal used in all three simulations is a 380 mm × 380 mm square sheet with thickness of 0.7 mm, the stress–strain curve for the material is shown in Fig. 3.Fig. 4. Wrinkling in a tapered square cup (G =50 mm).The simulation results show that wrinkling occurred in all three tapered square cups, and the simulated shape of the drawn cup for a die gap of 50 mm is shown in Fig. 4. It is seen in Fig. 4 that the wrinkling is distributed on the draw wall and is particularly obvious at the corner between adjacent walls. It is suggested that the wrinkling is due to the large unsupported area at the draw wall during the stamping process,also,the side length of the punch head and the die cavity openingare different owing to the die gap. The sheet metal stretched between the punch head and the die cavity shoulder becomes unstable owing to the presence of compressive transverse stresses. The unconstrained stretching of the sheet metal under compression seems to be the main cause for the wrinkling at the draw wall. In order to compare the results for the three different die gaps, the ratio β of the two principal strains is introduced, β being εmin/εmax, where εmax and εmin are the major and the minor principal strains, respectively. Hosford and Caddell [5] have shown that if the absolute value of β is greater than a critical value, wrinkling is supposed to occur, and the larger the absolute value of β, the greater is the possibility of wrinkling.The βvalues along the cross-section M–N at the same drawing height for the three simulatedshapes with different die gaps, as marked in Fig. 4, are plotted in Fig. 5. It is noted from Fig. 5 that severe wrinkles are located close to the corner and fewer wrinkles occur in the middle of the draw wall for all three different die gaps. It is also noted that the bigger the die gap, the larger is the absolute value of β. Consequently,increasing the die gap will increase the possibility of wrinkling occurring at the draw wall of the tapered square cup.3.2 Effect of the Blank-Holder ForceIt is well known that increasing the blank-holder force can help to eliminate wrinkling in the stamping process. In order to study the effectiveness of increased blank-holder force, the stamping of a tapered square cup with die gap of 50 mm,which is associated with severe wrinkling as stated above, was simulated with different values of blank-holder force. The blank-holder force was increased from 100 kN to 600 kN,which yielded a blank-holder pressure of 0.33 MPa and 1.98 MPa, respectively. The remaining simulation conditions are maintained the same as those specified in the previous section.(An intermediate blank-holder force of 300 kN was also used in the simulation.)The simulation results show that an increase in the blankholder force does not help to eliminate the wrinkling that occurs at the draw wall.The β values along the cross-section compared with one another for the stamping processes with blank-holder force of 100 kN and 600 kN. The simulation results indicate that the _ values along the cross-section M–N are almost identical in both cases. In order to examine the difference of the wrinkle shape for the two different blank-holder forces, five cross-sections of thedraw wall at different heights from the bottom to the line M–N, as marked in Fig. 4, are plotted in Fig. 6 for both cases.It is noted from Fig. 6 that the waviness of the cross-sections for both cases is similar. This indicates that the blank-holder force does not affect the occurrence of wrinkling in the stamping of a tapered square cup, because the formation of wrinkles is mainly due to the large unsupported area at the draw wall where large compressive transverse stresses exist. The blankholder force has no influence on the instability mode of the material between the punch head and the die cavity shoulder.Distance(mm)Fig. 5. β-value along the cross-section M–N for different die gaps.Fig. 6. Cross-section lines at different heights of the draw wall fordifferent blank-holder forces. (a) 100 kN. (b) 600 kN.4. Stepped Rectangular CupIn the stamping of a stepped rectangular cup, wrinkling occurs at the draw wall even though the die gaps are not so significant.Figure 1(b) shows a sketch of a punch shape used for stamping a stepped rectangular cup in which the draw wall C is followed by a step D–E. An actual production part that has this type of geometry was examined in the present study. The material used for this production part was 0.7 mm thick, and the stress–strain relation obtained from tensile tests is shown in Fig. 3.The procedure in the press shop for the production of this stamping part consists of deep drawing followed by trimming.In the deep drawing process, no draw bead is employed on the die surface to facilitate the metal flow. However, owing to the small punch corner radius and complex geometry, a split occurred at the top edge of the punch and wrinkles were found to occur at the draw wall of the actual production part,as shown in Fig. 7. It is seen from Fig. 7 that wrinkles are distributed on the draw wall, but are more severe at the corner edges of the step, as marked by A–D and B–E in Fig. 1(b).The metal is torn apart along the whole top edge of the punch,as shown in Fig. 7, to form a split.Fig. 7. Split and wrinkles in the production part.Fig. 8. Simulated shape for the production part with split and wrinkles.In order to provide a further understanding of the deformation of the sheet-blank during the stamping process, a finiteelement analysis was conducted. The finite-element simulation was first performed for the original design. The simulated shape of the part is shown from Fig. 8. It is noted from Fig.8 that the mesh at the top edge of the part is stretched significantly, and that wrinkles are distributed at the draw wall,similar to those observed in the actual part.The small punch radius, such as the radius along the edge A–B, and the radius of the punch corner A, as marked in Fig.1(b), are considered to be the major reasons for the wall breakage. However, according to the results of the finiteelement analysis, splitting can be avoided by increasing the above-mentioned radii. This concept was validated by the actual production part manufactured with larger corner radii. Several attempts were also made to eliminate the wrinkling.First, the blank-holder force was increased to twice the original value. However, just as for the results obtained in the previous section for the drawing of tapered square cup, the effect of blank-holder force on the elimination of wrinkling was not found to be significant. The same results are also obtained by increasing the friction or increasing the blank size. We conclude that this kind of wrinkling cannot be suppressed by increasing the stretching force.Since wrinkles are formed because of excessive metal flow in certain regions, where the sheet is subjected to large compressive stresses, a straightforward method of eliminating the wrinkles is to add drawbars in the wrinkled area to absorb the redundant material. The drawbars should be added parallel to the direction of the wrinkles so that the redundant metal can be absorbed effectively. Based on this concept, two drawbars are added to the adjacent walls, as shown in Fig. 9, to absorb the excessive material. The simulation results show that the wrinkles at the corner of the step are absorbed by the drawbars as expected, however some wrinkles still appear at the remaining wall. This indicates the need to put more drawbars at the draw wall to absorb all the excess material. This is, however,not permissible from considerations of the part design.Fig. 9. Drawbars added to the draw walls.One of the advantages of using finite-element analysis for the stamping process is that the deformed shape of the sheet blank can be monitored throughout the stamping process, which is not possible in the actual production process. A close look at the metal flow during the stamping process reveals that the sheet blank is first drawn into the die cavity by the punch head and the wrinkles are not formed until the sheet blank touches the step edge D–E marked in Fig. 1(b). The wrinkled shape is shown in Fig. 10. This provides valuable information for a possible modification of die design.Fig. 10. Wrinkle formed when the sheet blank touches the steppededge.Fig. 11. Cut-off of the stepped corner.Fig. 12. Simulated shape for the modified die design.An initial surmise for the cause of the occurrence of wrinkling is the uneven stretch of the sheet metal between the punch corner radius A and the step corner radius D, as indicated in Fig. 1(b). Therefore a modification of die design was carried out in which the step corner was cut off, as shown in Fig.11, so that the stretch condition is changed favourably, which allows more stretch to be applied by increasing the step edges.However, wrinkles were still found at the draw wall of the cup. This result implies that wrinkles are introduced because of the uneven stretch between the whole punch head edge and the whole step edge, not merely between the punch corner and the step corner. In order to verify this idea, two modifications of the die design were suggested: one is to cut the whole step off, and the other is to add one more drawing operation, that is, to draw the desired shape using two drawing operations.The simulated shape for the former method is shown in Fig.12. Since the lower step is cut off, the drawing process is quite similar to that of a rectangular cup drawing, as shown in Fig. 12. It is seen in Fig. 12 that the wrinkles were eliminated.In the two-operation drawing process, the sheet blank was first drawn to the deeper step, as shown in Fig. 13(a). Subsequently,the lower step was formed in the second drawing operation, and the desired shape was then obtained, as shown in Fig. 13(b). It is seen clearly in Fig. 13(b) that the stepped rectangular cup can be manufactured without wrinkling, by a two-operation drawing process. It should also be noted that in the two-operation drawing process, if an opposite sequence is applied, that is, the lower step is formed first and is followed by the drawing of the deeper step, the edge of the deeper step,as shown by A–B in Fig. 1(b), is prone to tearing because themetal cannot easily flow over the lower step into the die cavity.The finite-element simulations have indicated that the die design for stamping the desired steppedrectangular cup using one single draw operation is barely achieved. However, the manufacturing cost is expected to be much higher for the twooperation drawing process owing to the additional die cost and operation cost. In order to maintain a lower manufacturing cost, the part design engineer made suitable shape changes, and modified the die design according to the finite-element simulation result to cut off the lower step, as shown in Fig.12. With the modified die design, the actual stamping die for production was manufactured and the production part was found to be free from wrinkles, as shown in Fig.14.The part shape also agreed well with that obtained from the finiteelement simulation.Fig. 13. (a) First operation and (b) second operation in the two-operation drawing process.Fig. 14. The defect-free production part.In order to further validate the finite-element simulation results, the thickness distribution along the cross-section G–H obtained from the simulation result as indicated in Fig. 14,was compared with those measured from the production part.The comparison is shown in Fig. 15. It can be seen in Fig.15 that the predicted thickness distribution by finite-element simulation agrees well with that measured directly in the production part. This agreement confirms the effectiveness of the finite-element analysis.Fig. 15. The simulated and measured thickness distribution along G–H.5. Summary and Concluding RemarksTwo types of wrinkling occurring in stamping processes were investigated using finite-element analysis, and the causes for wrinkling were examined and the methods to eliminate such wrinkles were developed.The first type of wrinkling appears at the draw wall in the stamping of a tapered square cup. The occurrence of wrinkling is attributed to the large die gap, which is the difference between the side length of the die cavity opening and the side length of the punch head. The large die gap results in a large unsupported area of sheet metal when the metal is drawn into the die cavity and an unfavourable stretch between the punch head and die cavity shoulder. The large unsupported area of sheet metal is therefore prone to wrinkling. The finite-element simulations show that this type of wrinkling cannot be suppressed by increasing the blank-holder force.Another type of wrinkling investigated occurs in an actual stamping part that has a stepped rectangular geometry. It is found that wrinkling occurs at the draw wall above the step even though the die gap is not sufficiently large. The wrinkling is due to the uneven stretch between the punch head and the step edge, according to the finite-element analysis. Several attempts were made in the die design to eliminate the wrinkling,using finite-element simulations, and an optimum design in which the step was cut off is finally established. The modified die design for eliminating wrinkles was validated by the production of a defect-free production part. The good agreement between the simulation results and those observed in the drawn production part demonstrates the accuracy of the finite-element analysis, and the effectiveness of using finite-element simulations as a substitute for the expensive method of actual die try-outs is thereby confirmed.AcknowledgementsThe authors wish to thank the National Science Council of the Republic of China for the grant NSC-86–2212-E002–028 that made this project possible. They also wish to thank KYM for providing the production part.References1. K. Yoshida, H. Hayashi, K. Miyauchi, Y. Yamato, K. Abe, uda, R. Ishida and Y. Oike, “The effects of mechanical properties of sheet metals on the growth and removing of buckles dueto non-uniform stretching”, Scientific Papers, Institute of Physics and Chemistry Research, 68, pp. 85–93, 1974.2. T. X. Yu, W. Johnson and W. J. Stronge, “Stamping and springback of circular plates deformed in hemispherical dies”, International Journal of Mechanical Sciences, 26, pp. 131–148, 1984.3. W. J. Stronge, M. P. F. S utcliffe and T. X. Yu, “Wrinkling of elasto-plastic circular plates during stamping”, Experimental Mechanics, pp. 345–353, 1986.4. R. Narayanasamy and R. Sowerby, “Wrinkling of sheet metals when drawing through a conical die”, Journal of Material Processi ng Technology, 41, pp. 275–290, 1994.5. W. F. Hosford and R. M. Caddell, Metal Forming: Mechanics and Metallurgy, 2nd edn, 1993.。

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冲压模具外文文献Progressive DieProgressive die has the following advantages1) Class into the module is multi-process dies, in a mold can include punching, bending, forming and drawing a variety of multi-pass process, with a higher than the compound die labor productivity, but also can produce quite complex stampings;2) Progressive Die Operation Security, because staff do not have to enter the danger zone;3) Class Progressive Die Design, The process can be distributed. Do not focus on one station , there is no Compound Dies "Minimum wall thickness" problem. Therefore relatively high mold strength, longer life expectancy.4) Progressive Die Easy Automation That is easy to Automaticfeeding ,Autoout of parts Automatic lamination;5) Class Progressive die can be High-speed press production, because the workpiece can be directly down the drain and waste;6) Use Class Progressive die can be Reduce the presses, semi-finished products to reduce transport. Workshop area and storage space can be greatly reduced.Progressive Dies The disadvantage is that complex structure, manufacturing of high precision, long life cycle and high costs. Because of progressive die is a To the workpiece, the shape of successive out, each punch has a positioning error, is more difficult to maintain stability in the workpiece, the relative position of the one-off appearance. However, high precision parts, not all contours of all, the shape relative position requirements are high, you can be washed in the shape of the same station, on the relative position of demanding the same time, out of this part of the profile, thus ensuring precision parts.First, process pieces of carry approachProcesses and the determination of nesting is of the progressive die design a very important link. In considering the processes and nesting, we must first consider the process method of carriage parts.Bending parts there are two main ways to carry:1) Blanking station in the upper and lower pressure, so that after blanking process pieces and re-pressed into the material inside. Generally only about access to material thickness of thel/3, but has enough to process pieces with the material sent to the next process, within the workpiece in the working procedure have all been pressed into the material inside the remnant. Beyond that, after process pieces are washed curved shape, until the last escape from the Strip. The drop in this way conveying pairs of thick material is very effective, because the thin material easy to bagging, wrinkles, or bent, thus blanking out the flat blank song, not with the advance of material and stops in a station caused the accident.Simple blanking progressive die, sometimes in order to ensure that the workpiece is flat and has also taken off after the re-feed materials putpressure on people within the approach, in the latter process to workpiece pushed. Because blanking after being re-pressed into the workpiece can not be material in the thickness direction all entered the hole, so in the blanking die station after the plane, to the corresponding lower.2) Rush to need to bend some of the surrounding material, the rest of the parts remain in the article (Volume)Materials, there is no separation. As the hub of to the material, You may need to spend a long Progress in distance delivery.Second, the principle of work arrangements1)Blanking the workpiece to avoid the use of complex shapes convex mode. Rather more than the increase a process to simplify the convex mode shapes.2)"U"-shaped pieces can be divided into two out, as Figure7--76As shown in order to avoid material stretched, out of Workpiece dimensions vary.Figure7--76 U shaped pieces of curved process3)In the asymmetric bending, the workpiece slide easily can be shown in Figure7—77shown with teeth inserts were inserts into the bend Convex Mold and roof in order to prevent the workpiece sliding. The main disadvantage of this method is the a)After the procedure b)pre-process workpiece plane with prints. Also available on the heat treatment before Convex Mold and roof pre-perforated, after tryout after the sheet metal through the tryout will be two holes without sliding inlay Ping . If sliding is used tooth inserts.Figure7--77 To prevent the sheet metal bending generated when sliding1- Bending Convex Die 2- Cut off Convex Die 3- Roof 4- With teeth inserts 4) Bending or deep drawing of the workpiece, high-quality plastic surgery procedures should be added.5) Waste, such as continuous, should increase the cutting process, using waste cutter cut. Automatic press itself, as some waste cutter, you do not have to die to consider.6) Can be countersunk head hole punching. Figure7—78 shows the first hole punching of the workpiece . When clamping the punch die Xiaoping Tou both plane and concave hole stretch of artificial parts, and contact with each other in order to prevent inward deformation of holes. Clamping direction due to the strict size requirements, so the punch assembly when subject to a high degree of repair potential. Also can be used as shown in Figure 7-79 height adjustment body punch. The upper punch 3 face, contact with the slider 2. Slider right-hand side has opened a T-shaped slot to accommodate the screw 5 in the head. Rotating screw 5, then move along the slider 2. As the slider 2 and the mold base 4 in order to ramp contact with each other, while the punch 3 in the fixed plate is sliding in with l, consequent punch in the direction of the location of mold can be adjusted. Adjusted with the nut 6 fixed.Figure7--78 Stamp shen head hole1—Convex Die 2- DieFigure7--79 Punch height adjustment body1- Fixed Plate 2-Slider 3- Punch 4- On the mold base 5- Screw6- Nut7) There are strict requirements of local relative position within the shape, should consider the possibility of the same station on the out, in order to maintain accuracy. If there are really difficult to be broken down into two working bits. Be better placed in two adjacent stations.Third, the principle of stamping operations sequencing1)For pure blanking progressive dies, in principle, the first ,punch, followed by re-punching shape I expected, the final and then washed down from the Strip on the integrity of the workpiece. Carrier should be maintained of material of sufficient strength, can be accurate when sent to press.2)For the blanking bending progressive die should be washed before cut off part of the hole and bend the shape I expected, and then bending, and finally washed near the curved edge holes and the side hole-bit accuracy of the sidewall holes. Washed down by the final separation of parts.3) Drawing for the progressive die stamping , first make arrangement to cut processes, further drawing, the final washed down from the article on the workpiece material.4)For with the deep drawing, bending stamping parts, the first drawing, then I punched the surrounding material, followed by bending plus.5)For stamping with a stamping parts, in order to facilitate the metal flow and reduce the stamping force, stamping parts of neighboring I expected to be an appropriate resection, and then arrange stamping. The final re -Precision Die-Cut materials .If there are holes on the embossing position, in principle, should be embossed after the punching.6)For with the stamping, bending and stamping workpiece, in principle, is the first imprint ,And then punching Yu Liu, And then bending process.Fourth, nesting layout1) Nesting mapping, you can start with plane launch fig start, right designed to blanking station, left the design forming station. Step by step according to the actual situation after the amendment.2) Consider increasing the intensity to be an empty station molds. Continuous drawing more frequently when the first drawing after being a backup space industry in order to increase the number of drawing. High precision, complex shape of the workpiece should be less to set an empty station. Step away from the mold is greater than 16mm When more than set up an empty station. Interval accuracy The poor should not be easily added an empty station.3) Decided to process pieces of carry approach.4) Note that material rolling direction. Rolling direction affects not only the economic effects of nesting, but also affect the performance of the workpiece.5) Burr bending parts should be located in inside.6) Thin material used Guide is being sold, But do not side edge trimming. For thick material or heavy section materials, in order to avoid guide is being sold off the need to side edge trimming.7) According to the workpiece dimensions and the scale of production to determine a shape one pieces two documents or four parts, or more pieces.8) Stamping process does not allow any scattered debris left on the die surface.9) Residual material on the press to consider the possibility of other parts.。

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