滑移式起重夹钳装置主机的加工工艺设计【含CAD图纸、说明书】【GJ系列】
收藏
资源目录
压缩包内文档预览:(预览前20页/共28页)
编号:73756750
类型:共享资源
大小:1.75MB
格式:ZIP
上传时间:2020-04-17
上传人:好资料QQ****51605
认证信息
个人认证
孙**(实名认证)
江苏
IP属地:江苏
45
积分
- 关 键 词:
-
含CAD图纸、说明书
GJ系列
滑移
起重
夹钳
装置
主机
加工
工艺
设计
CAD
图纸
说明书
GJ
系列
- 资源描述:
-
购买设计请充值后下载,,资源目录下的文件所见即所得,都可以点开预览,,资料完整,充值下载可得到资源目录里的所有文件。。。【注】:dwg后缀为CAD图纸,doc,docx为WORD文档,原稿无水印,可编辑。。。带三维备注的都有三维源文件,由于部分三维子文件较多,店主做了压缩打包,都可以保证打开的,三维预览图都是店主用电脑打开后截图的,具体请见文件预览,有不明白之处,可咨询QQ:414951605===========题目最后备注XX系列,只是店主整理分类,与内容无关,请忽视
- 内容简介:
-
湖南理工学院毕业设计(论文)中期检查表 毕业设计(论文)题 目滑移式起重夹钳装置主机的加工工艺设计学生姓名钮科学 号14071902394院 别机械工程学院专 业机械设计制造及其自动化指导教师谭湘夫检查日期2011年4月15日指导教师检查情况记载及修改意见:已完成任务:在毕业设计前一阶段,该生主要完成了以下工作。写出了毕业设计开题报告;收录了参考文献;去工厂进行了实地考察;翻译了英语文献;写作了毕业设计论文的前言和目录情况记载:2010.12.10 下达毕业设计任务书2010.12.20再次下达设计前准备工作:查阅文献,撰写开题报告;实习;安排设计任务、收集资料(要求收集20篇参考文献),教会学生上图书馆网站下载科研论文(大部分学生不会下载论文)2011.2.23 检查学生对国内外起重夹钳技术的发展及应用情况的了解程度、给学生讲解夹钳装置的工作原理;作好制作夹钳模型的准备工作2011.2.27 要求学生将3000字的与本课题有关的英文文献译成中文;布置写毕业设计(论文)开题报告2011.3.2 与学生见面,检查开题报告撰写情况,该生完成任务较好2011.3.7 收集开题报告,修改学生的开题报告2011.3.9 讲解常用夹钳装置的结构分类;确定起重夹钳设计方案2011.3.19 要求该生做滑移式起重夹钳装置主机的加工工艺设计2011.3.30 带学生到机器有限公司实习2011.4.7 在机器公司制作夹钳模型,到工业品市场买电机等电器元件2011.4.12 要求写作前言2011.4.15 要求撰写毕业设计(论文)初稿指导教师意见:该生前期工作完成很好,能积极思考问题,完成了毕业设计前期计划,可开始下一步论文写作工作。签名: 2011.4.15注:此表用于指导教师在学生毕业设计(论文)初稿完成后对学生执行任务书情况进行中期检查时用,由指导教师填写。毕业设计(论文)任务书课题名称:滑移式起重夹钳装置主机的 加工工艺设计 学生姓名: 钮 科 院 别:机械工程学院 专 业:机械设计制造及其自动化 指导教师: 谭湘夫 2010年12月1日1、主题词、关键词:夹钳机构;加工工艺设计;钳臂加工;吊臂加工;轴的加工;工艺装备的选择;滑移式重力自动开关装置加工2、毕业设计(论文)内容要求:(1) 查阅文献资料, 其中中文文献不得少于15篇,外文文献不少于3篇,将其中一篇外文文献(不少于3000英文单词)翻译成中文(将中英文装订在一起)。写出国内外起重夹钳技术的发展及应用情况、夹钳装置的工作原理、夹钳装置的工作要求及性能(2) 进行常用夹钳装置的分类及夹钳装置的工艺总体装配设计夹钳装置主要零部件如钳臂、吊臂、轴等零件的加工工艺设计;工艺装备的选择(3) 滑移式重力自动开关装置加工工艺设计(4) 用铅笔绘夹钳装置主要部件图六张;还要求用AUTOCAD将上述图绘出(5) 交论文初稿(纸质打印稿)(6) 说明书的撰写要求认真、准确、条理清晰,文中引用的文献要依次编号,其序号用方括号括起,如5、6,置于右上角,文献内容必须严格按照引用的先后顺序依次在毕业设计(设计(论文))的最后列出,文档运用 “word长篇文档排版技巧”,按学院毕业设计手册要求的格式与样式排版,用公式编辑器编辑公式,毕业设计说明书正文字数在1.5万字以内,交打印稿与电子稿3、文献查阅指引:1刘兰生. 摩擦式夹钳紧力的简捷计算J.起重运输机械,1989,(1):-. 2顾必冲. 一种自动的夹钳控制装置J. 港口装卸, 1991,(3):13-16.3 谢华郗江云, 李建红.装配设计M. 北京:机械工业出版社, 2007.4倪泽娅. 重力式板坯夹钳的开发与研制J. 重型机械科技, 2006, (2):14-17. 5 利用百度搜索工具查阅相关内容的最新进展6利用湖南理工学院图书馆电子阅览室查阅、 收集相关资料7一定要找到三篇与论文有关的英文原版参考文献,参考文献至少1篇其中外文文献不少于3篇,将一篇外文文献(不少于3000英文单词)翻译成中文4、毕业设计(论文)进度安排:第1周 实习;设计前准备工作,接受工艺设计任务、收集资料(18篇参考文献)第2、4周 了解课题背景、国内外起重夹钳技术的发展及应用情况、夹钳装置的工作原理;作好制作准备工作;将3000字的与本课题有关的英文文献译成中文;交毕业设计(论文)开题报告第5、6周 进行常用夹钳装置的分类及夹钳装置的工艺总体装配设计;第7、8周 夹钳装置主要零部件如钳臂、吊臂、轴等零件的加工工艺设计;旋转棘轮重力自动开关装置加工工艺设计;毕业设计(论文)中期检查;第9、10周用铅笔和AUTOCAD绘夹钳装置主要零部件图各六张;交论文初稿(纸质);第11、12周 制作夹钳设备第13、14周 整理设计说明书,交毕业设计终稿(要交WORD文档和PDF文档两种格式的电子稿);准备毕业答辩第15周 交毕业设计(论文)答辩申请暨资格审查表 ;毕业答辩教研室意见:该课题与机械设计制造及其自动化专业培养目标结合紧密,内容丰富、要求合理,课题的难易程度适中,适合本科生作毕业设计用,进度安排合理。 负责人签名: 注:本任务书一式三份,由指导教师填写,经教研室审批后一份下达给学生,一份交指导教师,一份留系里存档。毕业设计(论文)开题报告课题名称:滑移式起重夹钳装置主机的加工工艺设计学生姓名: 钮 科 系 别: 机械工程学院 专 业: 机械制造及其自动化 指导教师: 谭湘夫 2011年 2月 25 日一、综述国内外对本课题的研究动态,说明选题的依据和意义: 夹钳装置是夹钳起重机的取物装置 ,夹钳起重机能否可靠地工作,主要取决于夹钳的性能。夹钳装置是夹钳起重机的取物装置,它与起重机的几个工作机构配合,可从铸锭车上拧断汤道,夹取钢锭,将钢锭装人均热炉,再从均热炉取出加热后的钢锭送进运锭车或直接放到辊道上运往初轧机。此外,夹钳起重机还可用来拨移钢锭车或夹上清 炉耙 清理 炉底。夹钳起重机在完成上述工艺程序时,由于运行速度较快,振动大,夹持的又往往是红热的钢锭,因此夹钳装置的各个零部件除应有足够的强度外,还应有良好的夹持性能,保证夹持的钢锭不至从钳口脱落本次毕业设计题目是“滑移式起重夹钳装置主机的加工工艺设计”。二、研究的基本内容,拟解决的主要问题:(1) 查阅文献资料, 其中中文文献不得少于15篇,外文文献不少于3篇,将其中一篇外文文献(不少于3000英文单词)翻译成中文(将中英文装订在一起)。写出国内外起重夹钳技术的发展及应用情况、夹钳装置的工作原理、夹钳装置的工作要求及性能(2) 进行常用夹钳装置的分类及夹钳装置的工艺总体装配设计夹钳装置主要零部件如钳臂、吊臂、轴等零件的加工工艺设计;工艺装备的选择(3) 滑移式重力自动开关装置加工工艺设计(4) 用铅笔绘夹钳装置主要部件图六张;还要求用AUTOCAD将上述图绘出(5) 交论文初稿(纸质打印稿)三、研究的步骤、方法、措施及进度安排:1、查阅相关文献资料,充分利用校图书馆的数字资源,了解目前国内外起重夹钳技术的发展及应用情况,夹钳装置的工作原理;2、进行常用夹钳装置的分类及夹钳装置的工艺总体装配设计;夹钳装置主要零部件如钳臂、吊臂、轴等零件的加工工艺设计;旋转棘轮重力自动开关装置加工工艺设计;3、运用AUTOCAD绘夹钳装置主要零件图;4、制作夹具设备。5、按南湖学院相关要求整理完成毕业设计。进度安排: 第1周 实习;设计前准备工作,接受工艺设计任务、收集资料(18篇参考文献)第2、4周 了解课题背景、国内外起重夹钳技术的发展及应用情况、夹钳装置的工作原理;作好制作准备工作;将3000字的与本课题有关的英文文献译成中文;交毕业设计(论文)开题报告第5、6周 进行常用夹钳装置的分类及夹钳装置的工艺总体装配设计;第7、8周 夹钳装置主要零部件如钳臂、吊臂、轴等零件的加工工艺设计;旋转棘轮重力自动开关装置加工工艺设计;毕业设计(论文)中期检查;第9、10周 用铅笔和AUTOCAD绘夹钳装置主要零部件图各六张;交论文初稿(纸质);第11、12周 制作夹钳设备第13、14周 整理设计说明书,交毕业设计终稿(要交WORD文档和PDF文档两种格式的电子稿);准备毕业答辩第15周 交毕业设计(论文)答辩申请暨资格审查表 ;毕业答辩四、主要参考文献:1刘兰生. 摩擦式夹钳紧力的简捷计算J.起重运输机械,1989,(1):-. 2顾必冲. 一种自动的夹钳控制装置J. 港口装卸, 1991,(3):13-16.3 谢华郗江云, 李建红.装配设计M. 北京:机械工业出版社, 2007.4倪泽娅. 重力式板坯夹钳的开发与研制J. 重型机械科技, 2006, (2):14-17. 5 仝国伟; 起重机运行歪斜及其改善措施J.金属加工(冷加工)2010,24.6 李正民; 板坯夹钳搬运起重机J.太原科技1996,03.7 曹自立; 642525t板坯夹钳起重机试制成功J.起重运输机械1994,04.五、指导教师意见:该生的课题的深度、广度以及工作量均适合作为毕业生的毕业设计,该生查阅了大量文献资料,课题研究前期准备工作已完成,研究内容与方法以及进度安排合理可行。签名: 六、教研室意见:签名: 注:此表由学生本人填写,一式三份,一份留系里存档,指导教师和学生本人各保存一份。COMPUTER-AIDED CNC PROGRAMMINGFOR THE MACHINING OF NON-TYPICAL PARTSGrzegorz NikielGrzegorz NIKIEL, Ph.D., Eng., University of Bielsko-Biaa, Department ofManufacturing Technology and Automation, 43-309 Bielsko-Biaa, ul. Willowa 2,gnikielath.bielsko.pl1. Introduction Many manufacturing firms, especially medium and small, has to solve problem of production development and search of new customers. In many cases this leads to the assortment enlarging of already manufactured products. Often this is joined with implementation of the new manufacturing processes. In conditions of market competition it demands high flexibility which is often got in way replacing of conventional manufacturing resources by the modern CNC tool machines 1. This is essentials condition for more efficient development, higher quality and faster adoption to new requirements 2. For maintenance of the low costs of manufacturing for production of small and medium batches very often the Group Technology is applied 3. With help of grouping of the manufactured components into families more efficient the machines, devices, workers are used. In the processes planning one from most important tasks is the CNC machine tool programming 4, 5. Very often the CAD/CAM systems are used from reason their possibility of flexible programming. In the case of typical components such approach the positive results gives, though it demands an efficient co-operations between constructors and technologist. Sometimes from different reasons it is impossible, especially when the Group Technology is applied. Usually the part programs for machining of single components are created, but the modern CNC controllers offer some methods of programming, which to machining of some similar components can be used. Such methods are:1.Cycles 6. The cycles are design for machining of typical surfaces (the holes, threads, slots etc.). Usually a parametric description of machined surfaces is applied which enable the easy and fast changes of their geometry. Unfortunately they be characterized by small flexibility and small influence onto strategy of machining, dependent only from the parameters of cycle. In the modern controllers it permit onto a Workshop Oriented Programming (WOP), i.e. programming directly by the operators, often aided by a dialog programming (sometimes a conversational programming called). Therefore this is relative simple programming method, very often used in industrial practice.2.Parametric programming 5, 6. A typical part program is executed from beginning to end in one run. In parametric programming the execution of part program can run into different way (e.g. by conditional instruction IF. THEN. use). In addition, a multiple repetition of the part program fragment is accessible (REPEAT loop, WHILE loop etc.). Furthermore, the arithmetical functions and other advanced functions are possible. The axis positions, feed and speed functions, etc. can be specified by a parametric expressions (by R-parameters use). Into this way it was been possible to create own machining cycles also. This approach demands high skills of programming and is very labour-consuming also. Exact verification of the program is necessary, in this its immunity in the dangerous situations (e.g. joined with application of incorrect value of the input parameters). Therefore in view of above mentioned defects it is infrequently used in industrial practice.3. Programming based on the freely defined contours. The task depends on defining of machined contour and its automatic conversion to the CNC codes. If the automatic cutter radius compensation (the G41 and G42 functions) is not used then additionally a equidistant has to be generated. This sub-task is easy to realization if mentioned contour is represented in a CAD system with help of the Offset function. Second sub-task often is realized in way of export of graphic form of the tool path to the typical formats of data exchange (DXF, HPGL etc.). In next step by the suitable postprocessors use (for example the solution given in 7) conversion of tool path onto the CNC codes is performed. From practical regards this approach in generality for the simple operations is applied, e.g. a laser cutting, a water jet cutting etc. A solution integrating both sub-tasks in one application program are applied also the AutoCUT is the best example 8. In practice this solution is not applied too often although it possesses many advantages.In the conditions of small batch production a process planning to the CNC programming is often restricted 9. In this situation large meaning has integration of the CAD/CAM systems with omission of CAPP stage. The Features idea is then a effective method of data exchange 10, 11, 12. When the Group Technology is used, after supplement by appropriate data bases and knowledge bases, it can be best solution for production of typical elements 13, 14. In case of non-typical parts such approach generally is ineffective. Mainly in view of the widely applied methods of Features recognizing which limit number of the Feature types 10, 12. Maybe in future a solution will bring integration of CAD/CAM/CNC systems based on the STEP-NC standards (ISO 14649, ISO 10303:238) 15, 16 which will replace traditionally applied CNC programming with G-codes onto thing of the neutral format of data exchange.2. Analysis of the examplesPresented below examples of the group CNC machining are a fragment of production program from the small firm. Generally this components have non-typical shapes, they are manufactured from hard materials (e.g. austenitic stainless steel), usually needed the special jigs and fixtures, in the conditions of small batch production. The planning processes in this case demand a participation of technologists with large experience. A specific character of accessible tool machines for defining of the method of CNC programming should to consider also. After execution of detailed analysis onto subject of the discussed methods the following conclusions were formulated: The machined shapes exclude applying of the standard cycles. Most of the programs is design for the complicated profiles machining. From here description of these profiles is largest problem. Moreover, machining of the components is performed on the different tool machines, equipped in different controller. For most of machined components the exact drawing documentation is not made. In a production order the general drawings are included, often described by parametric dimensions. Then current values of this parameters are given also. Short series and large variety of the components demands fast modifying of current production program. Fast CNC programming and the programs implementation is necessary, best directly at tool machine (WOP). Often the operators of tool machines possess large knowledge and experience in the area of manufacturing technology, sufficient for preparation of simple program (in range of the technology). Fast preparation of the tool path is limitation only. General conclusion is such, that in presented case use of the universal CAD/CAM systems for CNC programming is very difficult. Moreover, it joins with high costs of shopping and trainings for the workers. Low flexibility of this method is expected also, especially time of programming can be a great problem. In this situation a parametric programming as the best solution was considered. But, as it was shew on the examples, the parametric programming can be realized in different way.2.1. Example I the grooved rollers finish machiningFinish machining of the grooved rollers family was subject of research (Fig. 1). Basic changing dimensions for rollers were external diameter d, working profile length L and profile angle . The profile of co-operate roller is moved by half pitch. Finish machining is performed by turning with use of tool with the V type rhombic insert (nose angle equal 35), where the nose radius r is equal 0,4 mm (Fig. 1). The tool reference point is located in the insert nose center. For each pair of rollers their profile is designed in a CAD environment according to the dimensions of rolling elements. A fast method of tool path generation was the main subject of performed research. First of all generating of the tool path (only finishing, without rough machining which is programmed in a manual mode) and forming it in accordance with requirements of appropriate language. As has been mentioned above the use of parametric program was considered. With help of the advanced programming methods (e.g. transformations of co-ordinate system, sub-programs etc.) it was been possible to achievement the aim of this study. However, number of the machined rollers is very small (some per year). Therefore another approach was accepted. Because for each roller a exact CAD model is prepared (2D model), it was used to CNC programming. For achievement of this aim the following activities was considered: For each used CNC controller the framework of part program is created, including program header, technological functions, tool functions and program end (without tool path). In a CAD environment the model co-ordinate system is assigned to the workpiece co-ordinate system. In the semi-automatic mode from the model of working surface a tool path is extracted with use the Offset function. Manually the run-in path and the run-out path is added. For different elements of tool path (with working interpolation or with rapid interpolation) different attributes of line were applied. The designed tool path is converted to a numerical form in semi-automatic mode by special program (written in LISP language) and inserted to the part program (created previously). User has to show only first element of the tool path, further analysis is worked out on basis of the drawing data base (Fig. 2). Finally the part program is verified, the cutting parameters values are corrected and a graphical simulation of machining is executed (Fig. 3). Total time of program planning (without preparing of CAD model) then about some minutes. An universal postprocessor was not applied (e.g. 7) because format of the CNC program can be easily adapt to requirements of controller. Furthermore time of designing became significantly shortened. 2.2. Example II the multi-edge rings profile machining The multi-edge rings profile machining was subject of the research (Fig. 4). On the face three zones of grooves are machined. Number of grooves (n1, n2, n3) results from companies recommendations. In every zone the constant value of pitch S is kept. The grooves dimensions (S, F, G) and the chamfer dimension w are changing and they have to be contain in the recommended limits. Their values are calculated for the constant diameters D1 and D2 (given in a production order). Just after complete determining of grooves geometrical form the machining operation can be designed. The rings are machined by tool with square insert (S type) Fig. 4. The tool reference point is located in the insert nose center. In order to clearly determine of the remaining ring dimensions the following dependences were accepted (according to the recommendations):and the geometrical dependences are described as follows (Fig. 4):what causes that the S, w and F dimensions in given ranges have to be changed until total number of grooves will not be a natural number. The above task as a optimization problem has treated where three decision values are given (S, w and F) and the constrains is given according to equation (1). The criterion function is calculated according to equation (2). The problem of optimization has solved by the Hooke-Jeves method use 17. When ring geometry is finally determined then calculations of tool path elements is very simple tool is moved along equidistant. Therefore was assumed that this two tasks will be solved by means of one program (Fig. 5), a similar approach was showed in 18. After introduction of value of well-known dimensions (e.g. from production order) the value of remaining dimensions are automatically calculated. If user accepts this values then the part program is generated automatically (in non-parametric form). In opposite case user can improve values of dimensions and their correctness is checked by program. After execution of simulation (Fig. 6) the part program can be transmitted to CNC controller. 2.3. Example III the eccentric seal rings machiningThe eccentric seal rings machining was subject of the research. The external surface of ring which have shape of cone, is machined in analyzed operation. (Fig. 7). A machining datum is located on the internal cylindrical surface (with diameter D) and on the face surface. The groove with diameter dr is made as option. Steel cylindrical ring is a semi-product (from acid-resistant steel or from stainless steel). Described operation comprise two stages: the roughing machining (removal of considerable allowance on part of ring) and finish machining (for obtainment of the exact shape). The shape accuracy has larger importance than the surface roughness (the exploational requirements) 19. The operation is executed by use of typical tool with rhombic insert (C type). In the part program a linear position of tool (linear co-ordinates Z and X) and an angular position of spindle (angular co-ordinate C) have to be joint. Initially a 3D parametric model making was analyzed (e.g. in AutoDesk Inventor environment) and use it for generating of the part program (e.g. in EdgeCAM environment 20, 21). Finally another approach was accepted a parametric program was used for rings machining. This decision is justified by following premises: larger influence onto machining strategy, especially due to the machined materials; possibility of program set-up directly at the machine tool, even by machine operators; easy and fast changes of part program execution; considerably smaller size of program; high cost of the CAM systems. Nevertheless this solution own one important disadvantage the group program has to work in accordance to very complicated algorithm. Especially, where calculations of co-ordinate points on the cone have to be carried out. Moreover, cutter radius compensation is performed (automatic cutter radius compensation is impossible). In this situation efficiency of a CNC controller can to make significant limitation. It was checked that time of calculation at full implementation of mentioned algorithm on the CNC controller is too long in relation to required speed of machining. Simplifying of the program was indispensable for correct realization of this operation.The final form of proposed CNC program is showed in Fig. 8. The main program (PIERSCIEN.MPF) is fixed for the rings family, where the machining in a parametric form is described. A subprogram (DANE.SPF) is a data set (in the R-parameters form) which dimensions of the concrete ring define (from a design documentation). Moreover, mentioned subprogram contains the technological parameters (a speed, a feed, etc.) and co-ordinates of the selected points on the machined surface. These points are required to calculation other remaining coordinates in the part program. Mentioned coordinates are determined by use of an additional program, working in the external computer 19. To tasks of this program should help user at data introducing (Fig. 9), the necessary calculations and the subprogram saving in accordance with requirements of given CNC controller. In next step the part program simulation can be performed (Fig. 10). In last step the part program is sent to a CNC controller. In proposed form the main program contains about 190 blocks, the subprogram about 150 blocks. If it was accepted first from considered solutions then part program is considerably longer. Presented part program generates about 80100 thousands of the tool movements. 3. A CNC programming in off-line modeA CNC programming directly on the machine tools (in on-line mode) is very difficult, even sometime impossible. Advanced methods of parametric programming (calculation on the parameters, the structural functions, the jumps etc.) demand exact verification of the algorithm. Exclude this functions usually such part programs use simple methods for the co-ordinates giving. A graphical simulation of parametric programs was not been possible to execute in wide applied popular CAM systems (from reason of the rules of their work). Moreover, often in industrial practice fast conversion a NC program to other language is required. From this in practice sometimes one should to create specialized software 22. Therefore the original system for NC programs analysis and simulation was realized 23 Fig. 3, Fig. 6, Fig. 10. Acceleration and facilitation of programming in off-line mode,especially for parametric programs is main purpose. Discussed system contains typical modules specialized editor, graphical simulation module, offset registers, parameters table, programs database, serial transmission module, etc. As base language was accepted Sinumerik 840D/810D (Siemens) because largest set of functions it contains. Onto its basis was created original, internal programming language (where work philosophy is based on the APT system idea). Therefore the work of this system runes in accordance with presented architecture Fig. 11. A preprocessor translates the part program written in language of concrete controller (Siemens, Fanuc, Heidenhain) onto its internal language. Simultaneously syntactic correctness of the part program is checked. In this form the CNC program is analyzed and executed through processor and in analogical form is remembered. In next step this program can be simulated or translated by postprocessor onto CNC program for other controllers. If necessary is including a new language then should to make only new postprocessor or preprocessor, without necessity of changes in the processor. Common procedures for analyses and simulation, included in the processor, simplify adaptation of the system to new tasks.4. ConclusionIn all presented above examples the typical CNC programming methods use was analyzed. Both cycles as programming with help of the Computer Aided Manufacturing systems (CAM) based on parametric solid models were ineffective. For all analyzed surfaces their geometry is significantly different from geometry of the standard cycles. If CAM software is used then has to be prepared exact model of the machined part (by CAD software). In conditions of small batch production no always this is possible. Use of described methods of programming can be often one real solution. Presented approach possesses many advantages. Firstly, significantly reduce the part programming time (to some minutes). The CNC programs can be generated by operators directly at tool machine. Possession of the exact drawings of machined parts is not required (with except of first presented example). Correctness of the generated programs is very high, applying of additional verification (e.g. graphical simulation) usually does not join from modification (except changes of machining parameter values). Significantly is decreased time and cost of the programs start. More expensive CAM software are not necessary. This approach could reduce the number of program changeovers and decrease programs length. The disadvantages of presented approach are naturally also. Firstly, is necessary additional time onto analysis of problem, solution proposing and often additional software preparing. Formulating of the complex geometric dependences for a tool path calculation demands large knowledge from area of mathematics and geometry. Moreover, a user should to know to write this formulas in the form of computer programs. Such approach does not have to generate additional costs onto shopping of the commercial programming systems because are accessible their free non-commercial versions (e.g. used by author Borland Turbo Delphi, AutoLISP or Visual Basic for Application available as the programming interfaces for AutoCAD, Inventor, etc.).In opinion of author in situation of process planning for the parts about non-typical shapes, especially when Group Technology is used, applying of non-typical methods of CNC programming is required also. Then use of unconventional tools of computer aid is necessary. Described in this paper solutions are the best example of this approach.References 1 B.Z. GONG: The processing of parts with group technology in an individual CNC machining center. Journal of Materials Processing Technology, 129(2002)1, 645-648. 2 J. BALIC: Model of automated computer aided NC machine tools programming. Journal of Achievements in Materials and Manufacturing Engineering.17(2006), 1-2, 309-312. 3 I. KURIC, J. KUBA: Development of CAPP systems based on group technology. Proc. of Int. Conf. Computer Integrated Manufacturing, Zakopane 2001, 285-292. 4 M. DJASSEMI: An Efficient CNC Programming Approach Based on Group Technology. Journal of Manufacturing Systems, 19(2000), 213-217. 5 M. DJASSEMI: A Parametric Programming Technique For Efficient CNC Machining Operations. Computers and Industrial Engineering, 35(1998)1, 33-36. 6 M. LYNCH: Parametric Programming for CNC Machines Tools and Touch Probes. Society of Manufacturing Engineers, 1996. 7 Translator on-line DXF-CNC. /index.html. 8 AutoCUT. Instytut Zaawansowanych Technologii Wytwarzania, Krakw. http:/www.ios.krakow.pl/cadcam/autocut.php. 9 S.R.K. JASTHI, P.N. RAO, N.K. TEWARI: Studies on process plan representation in CAPP systems. Computer Integrated Manufacturing Systems, 8(1995)3, 173-184. 10 G. VOSNIAKOS: An Intelligent Software System for the automatic generation of NC programs from wireframe models of 2-1/2D mechanical parts.Computer Integrated Manufacturing Systems, 11(1998)1-2, 53-65. 11 P.G. MAROPOULULOS: Review of research in tooling technology, process modelling and process planning. Part II: Process planning. Computer Integrated Manufacturing Systems, 8(1995)1, 13-20. 12 J. GAO, D.T. ZHENG, N. GINDY: Extraction of machining features for CAD/CAM integration. Journal of Advanced Manufacturing Technology, 24(2004), 573-581. 13 P. SHILPAN: Design features + process knowledge = automated CNC programming. Modern Machine Shop, 67(1994)6, 78-85. 14 M. SIEMITKOWSKI, W. PRZYBYLSKI: Modelling and simulation analysis of process alternatives in the cellular manufacturing of axially symmetric parts. Journal of Advanced Manufacturing Technology, 32(2007), 516-530. 15 A. NASSEHI, S.T. NEWMAN, R.D. ALLEN: The Application of Multi-Agent Systems for STEP-NC Computer Aided Planning of Prismatic Components. Journal of Machine Tools & Manufacture, 46(2006), 559-574.计算机辅助数控编程应用于非典型零件的加工(Grzegorz Nikiel博士,波兰别尔斯克-比亚瓦,制造技术与自动化学院)1. 简介许多制造公司,尤其是中,小型要解决生产发展和新客户的搜索问题。在许多情况下,这导致了生产的产品品种已扩大。通常这是加入了新的制造工艺的实施。在市场竞争条件下的高灵活性的要求往往是在传统的制造资源取代了现代数控工具机的方式得到了。这是更有效的发展要领,质量更高,更快的速度为新的要求条件。对于生产成本低的中小批量生产,往往成组技术维护应用。随着所制造的部件组合成的家庭更有效地帮助机器,设备,工人使用。在规划的过程中最重要的任务之一是数控机床的编程。很多时候的CAD / CAM系统所使用的原因,他们的灵活编程的可能性。在典型情况下,这种做法元件积极成果提供,但它要求建设者和技术人员之间有效的合作行动。 有时从不同的原因,是不可能的,尤其是在成组技术被应用。通常为单一成分加工的零件程序的创建,但现代CNC控制器提供了一些编程方法,这在一些类似部件的加工可以使用。这种方法是:1.周期。设计的周期是典型的表面加工(孔,螺纹,槽等)。通常是加工表面参数描述适用于几何形状,使他们容易和快速变化。不幸的是他们的特点和灵活性,小到小的加工策略的影响,只能从周期的参数而定。在现代控制它允许一个研讨会上面向编程(WOP),即通过编程往往一个对话框编程(有时称为会话编程)资助的经营者,直接。因此,这是相对简单的编程方法,往往应用于工业实践。2.参数化编程。一个典型的一部分,执行程序从开始到结束一分。参数规划的一部分,程序的执行可能遇到不同的方式(例如,如果.然后.使用条件指令)。此外,对部分程序段多重复访问(重复循环,而循环等)。此外,算术功能和其他先进的功能是可能的。轴的位置,饲料和速度的功能等,可以指定一个参数表达式(由R -参数的使用)。一直到这一点,有人可能创造自己的加工周期也途径。这种方法需要高技能的编程劳动,是非常耗时也。该方案的精确验证是必要的,这在危险情况下的豁免权(例如,对输入参数的应用程序加入了不正确的值)。因此,在上述缺陷的看法是很少用于工业实践。3.规划自由定义轮廓的基础。这个任务依赖于加工轮廓及其自动转换到数控代码定义。如果自动刀具半径补偿(即G41和G42的功能的)不使用,则有另外一个等距离的产生。此子任务是很容易实现的,如果提到轮廓CAD系统中的代表 - 与OFFSET函数的帮助。第二个子任务往往体现在对工具的路径图形形式的出口方式向数据交换(DXF文件,HPGL格式等)的典型格式。在合适的后处理器的使用(例如7中给出的解决方案)数控刀具上的代码路径转换下一步就是执行。从实际方面的一般性的简单的操作,这种方法被应用,例如:激光切割,水射流切割等一个解决方案,集成两个分在一个应用程序任务也适用 - 在AutoCUT就是最好的例子。这个解决方案是在实践中往往没有应用,虽然它具有许多优点。在小批量生产的条件下工艺设计到数控编程通常限制9。在这种情况下有较大意义的CAD / CAM与遗漏的CAPP系统集成的阶段。想法是那么的特点的数据交换的有效方法。当使用成组技术后,通过适当的数据库和知识库的补充,它可以最佳解决方案的典型元素的生产。在非典型零件通常情况下这种做法是无效的。主要是在识别特征的看法,普遍采用的方法的特征类型限制数。也许在未来的解决方案将带来的CAD / CAM /数控的STEP - NC的标准为基础的系统集成(异14649,国际标准化组织10303:238)将取代传统的东西运用到数控G代码编程中立的数据交换格式。2.分析的例子 下面的例子集团主办的数控加工的生产计划由小企业的片段。一般来说,这部分有不典型形状,它们是从硬质材料(如奥氏体不锈钢),通常需要在小批量生产的条件的特殊夹具及固定装置,制造。规划进程在这种情况下需要一个大的经验与技术专家的参与。可访问工具机的数控编程的方法确定具体的角色应该也考虑。经过详细分析了执行上讨论了以下结论制定方法问题:形状的加工周期排除标准
- 温馨提示:
1: 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。图纸软件为CAD,CAXA,PROE,UG,SolidWorks等.压缩文件请下载最新的WinRAR软件解压。
2: 本站的文档不包含任何第三方提供的附件图纸等,如果需要附件,请联系上传者。文件的所有权益归上传用户所有。
3.本站RAR压缩包中若带图纸,网页内容里面会有图纸预览,若没有图纸预览就没有图纸。
4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
5. 人人文库网仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对用户上传分享的文档内容本身不做任何修改或编辑,并不能对任何下载内容负责。
6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。
人人文库网所有资源均是用户自行上传分享,仅供网友学习交流,未经上传用户书面授权,请勿作他用。
川公网安备: 51019002004831号