小型臥式行星輪球磨機設(shè)計與運動分析【含7張CAD圖紙+文檔全套】
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湘潭大學(xué)興湘學(xué)院畢業(yè)論文(設(shè)計)工作中期檢查表系 機械設(shè)計制造及其自動化 專業(yè) 機械設(shè)計制造及其自動化 班級 2班 姓 名李勇杰學(xué) 號2008963128指導(dǎo)教師周后明指導(dǎo)教師職稱講師題目名稱 小型臥式行星輪球磨機設(shè)計及其運動分析題目來源 科研 企業(yè) 其它課題名稱題目性質(zhì) 工程設(shè)計 理論研究 科學(xué)實驗 軟件開發(fā) 綜合應(yīng)用 其它資料情況1、選題是否有變化 有 否2、設(shè)計任務(wù)書 有 否3、文獻綜述是否完成 完成 未完成4、外文翻譯 完成 未完成由學(xué)生填寫目前研究設(shè)計到何階段、進度狀況:完成了資料的檢索和查詢、系統(tǒng)總體方案的構(gòu)思及設(shè)計、系統(tǒng)方案的選擇設(shè)計?,F(xiàn)在處于系統(tǒng)詳細階段。由老師填寫工作進度預(yù)測(按照任務(wù)書中時間計劃) 提前完成 按計劃完成 拖后完成 無法完成工作態(tài)度(學(xué)生對畢業(yè)論文的認真程度、紀(jì)律及出勤情況): 認真 較認真 一般 不認真質(zhì)量評價(學(xué)生前期已完成的工作的質(zhì)量情況) 優(yōu) 良 中 差存在的問題與建議:1、利用計算機輔助設(shè)計的能力有待提高;2、借助文獻資料的能力有待提高;3、實際工程技能有待鍛煉和提高;4、綜合運用專業(yè)知識分析問題的能力有待培養(yǎng)的加強。 指導(dǎo)教師(簽名): 年 月 日建議檢查結(jié)果: 通過 限期整改 緩答辯系意見: 簽名: 年 月 日注:1、該表由指導(dǎo)教師和學(xué)生填寫。2、此表作為附件裝入畢業(yè)設(shè)計(論文)資料袋存檔。 湘 潭 大 學(xué)畢業(yè)論文(設(shè)計)任務(wù)書論文(設(shè)計)題目: 小型臥式行星球磨機的設(shè)計與運動分析 學(xué)號: 姓名: 專業(yè): 機械設(shè)計制造及其自動化 指導(dǎo)教師: 周后明 系主任: 周友行 一、主要內(nèi)容及基本要求行星式球磨機是混合、細磨、小樣制備、納米材料分散、新產(chǎn)品研制和小批量生產(chǎn)高新技術(shù)材料的必備裝置。本設(shè)計為小型臥式行星球磨機的設(shè)計與運動分析,其主要技術(shù)指標(biāo)與要求如下: 1、轉(zhuǎn)速:公轉(zhuǎn):50-400轉(zhuǎn)/分鐘自轉(zhuǎn):100-800轉(zhuǎn)/分鐘; 2、電機功率: 0.75kw、220V、50HZ; 3、工作方式:兩個或四個球磨罐同時工作; 4、進料拉度:4-10mm; 5、出料粒度:可達0.1um 設(shè)計要求: 1、完成小型臥式行星球磨機的的設(shè)計和選型論證 2、小型臥式行星球磨機的的結(jié)構(gòu)設(shè)計和運動學(xué)分析,繪制部件裝配圖和主要零件圖,圖紙總量折合成A0,不少于2張 3、撰寫設(shè)計說明書,關(guān)鍵零件應(yīng)進行強度和剛度計算,說明書字數(shù)不少于15萬4、完成資料查閱和3000字的文獻翻譯 二、重點研究的問題小型臥式行星球磨機的的結(jié)構(gòu)設(shè)計及相關(guān)強度校核、運動學(xué)分析。 三、進度安排序號各階段完成的內(nèi)容完成時間1查閱資料、調(diào)研第1,2周2制訂設(shè)計方案第3,4周3分析與計算第5,6周4繪部件裝配圖第7,8、9周5繪零件圖第10,11周6撰寫設(shè)計說明書第12,13周7準(zhǔn)備答辯材料第14周8畢業(yè)答辯第15周四、應(yīng)收集的資料及主要參考文獻1、機械設(shè)計手冊 2、機械傳動設(shè)計手冊 3、顏景平,易紅等. 行星式球磨機研制及其節(jié)能機理 . 東南大學(xué)學(xué)報,2008,32(1):27-31 4、康善存. 硬脆材料的精密切割及發(fā)展趨勢J. 機械制造,1997,7:46 5、網(wǎng)絡(luò)相關(guān)資信 湘 潭 大 學(xué) 興湘學(xué)院 本科畢業(yè)設(shè)計(論文)開題報告題 目小型臥式行星輪球磨機設(shè)計與運動分析姓 名李勇杰學(xué)號2008963128專 業(yè)機械設(shè)計制造及其自動化班級機械2班指導(dǎo)教師周后明職稱講師填寫時間2012年2月20日 2012年2月說 明1根據(jù)湘潭大學(xué)畢業(yè)設(shè)計(論文)工作管理規(guī)定,學(xué)生必須撰寫畢業(yè)設(shè)計(論文)開題報告,由指導(dǎo)教師簽署意見,系主任批準(zhǔn)后實施。2開題報告是畢業(yè)設(shè)計(論文)答辯委員會對學(xué)生答辯資格審查的依據(jù)材料之一。學(xué)生應(yīng)當(dāng)在畢業(yè)設(shè)計(論文)工作前期內(nèi)完成,開題報告不合格者不得參加答辯。3畢業(yè)設(shè)計(論文)開題報告各項內(nèi)容要實事求是,逐條認真填寫。其中的文字表達要明確、嚴(yán)謹,語言通順,外來語要同時用原文和中文表達。第一次出現(xiàn)縮寫詞,須注出全稱。4本報告中,由學(xué)生本人撰寫的對課題和研究工作的分析及描述,應(yīng)不少于2000字。5開題報告檢查原則上在第24周完成,各系完成畢業(yè)設(shè)計開題檢查后,應(yīng)寫一份開題情況總結(jié)報告。6. 填寫說明:(1) 課題性質(zhì):可填寫A工程設(shè)計;B論文;C. 工程技術(shù)研究;E.其它。(2) 課題來源:可填寫A自然科學(xué)基金與部、省、市級以上科研課題;B企、事業(yè)單位委托課題;C校級基金課題;D自擬課題。(3) 除自擬課題外,其它課題必須要填寫課題的名稱。(4) 參考文獻不能少于10篇。(5) 填寫內(nèi)容的字體大小為小四,表格所留空不夠可增頁。本科畢業(yè)設(shè)計(論文)開題報告學(xué)生姓名 李勇杰學(xué) 號2008963128專 業(yè)機械設(shè)計制造及其自動化指導(dǎo)教師周后明職 稱講師所在系工程系課題來源自擬課題課題性質(zhì)綜合應(yīng)用課題名稱小型臥式行星輪球磨機設(shè)計與運動分析一、選題的目的與意義 隨著現(xiàn)代工業(yè)對超細物料需求量的日益增加,對品質(zhì)要求的不斷提高,新的超細粉磨設(shè)備及新型粉磨工藝不斷出現(xiàn)。行星式球磨機在能耗、鋼耗和效率等方面比常規(guī)圓筒形球磨機更有優(yōu)勢。90 年代以來, 機械合金化法已成為制備新型復(fù)合材料的熱門課題?,F(xiàn)已發(fā)現(xiàn), MA 通過行星式高能球磨機的高能研磨作用, 可以引起材料原子尺度的結(jié)合與化學(xué)反應(yīng), 可以實現(xiàn)非晶質(zhì)化, 可以將金屬間化合物組元粉體固態(tài)下生成金屬間化合物, 可以使某些液態(tài)下并不互溶的體系實現(xiàn)較寬成分范圍的固溶; 另一方面,由于高能球磨機的強烈撞擊與研磨作用, 還可以制備出各種單質(zhì)元素的納米級粉體材料和金屬陶瓷納米材料等。行星式高能球磨機之所以能成功地實現(xiàn)上述新型材料的制備, 主要取決于行星式高能球磨機的工作能力, 本文通過對行星式高能球磨機的運動學(xué)及動力學(xué)分析, 使人們能較深入地了解到行星式高能球磨機的工作原理, 這對于MA 的理論研究是有一定參考意義的。二、球磨機發(fā)展趨勢球磨機是陶瓷工業(yè)生產(chǎn)中能耗的大戶,因此積極的研發(fā)球磨機及其相關(guān)技術(shù),對于提高陶瓷產(chǎn)業(yè)的經(jīng)濟效益是非常有意義的。常規(guī)行星式球磨機中的球磨罐放置在水平的大盤上作行星運動,磨球和磨料受公轉(zhuǎn)和自轉(zhuǎn)兩個水平方向離心力的作用,相互碰撞研磨產(chǎn)品。龔姚騰等研制的微型雙筒行星式球磨機,磨筒自轉(zhuǎn)和公轉(zhuǎn)產(chǎn)生的離心力及磨筒與筒壁間的摩擦力使磨球與物料在筒內(nèi)產(chǎn)生互相沖擊、摩擦和上下翻滾等來磨碎物料;張克仁等研制的TCMJ一l型行星式超細球磨機,采用 以搓揉方式為主的平動式超細粉碎方法,實驗表明,該機具有效率高、節(jié)能效果明顯和超細磨礦的良好性能;陳世柱等研制的行星式高能球磨機由于磨球?qū)Ψ垠w頻繁強烈地撞擊、碾壓及搓揉等作用,具有較大的慣性力,因而對粉體能產(chǎn)生強烈的撞擊,其撞擊力隨著轉(zhuǎn)速的提高而成倍增加。南京大學(xué)儀器廠推出一種新型臥式行星球磨機。該機的特點是4只球磨罐被臥式安裝在豎直放置的大盤上作行星運動,罐內(nèi)的磨球和磨料在豎直平面內(nèi)受到公轉(zhuǎn)離心力、自轉(zhuǎn)離心力、重力3個力的共同作用,導(dǎo)致磨球與磨料在高速運轉(zhuǎn)中相互之間猛烈碰撞、擠壓,提高了研磨效率和研磨效果,同時,避免了一部分材料的結(jié)底現(xiàn)象。三、主要內(nèi)容及基本要求行星式球磨機是混合、細磨、小樣制備、納米材料分散、新產(chǎn)品研制和小批量生產(chǎn)高新技術(shù)材料的必備裝置。本設(shè)計為小型臥式行星球磨機的設(shè)計與運動分析,其主要技術(shù)指標(biāo)與要求如下: 1、轉(zhuǎn)速:公轉(zhuǎn):50-400轉(zhuǎn)/分鐘自轉(zhuǎn):100-800轉(zhuǎn)/分鐘; 2、電機功率: 0.75kw、220V、50HZ; 3、工作方式:兩個或四個球磨罐同時工作; 4、進料拉度:4-10mm; 5、出料粒度:可達0.1um 設(shè)計要求: 1、完成小型臥式行星球磨機的的設(shè)計和選型論證 2、小型臥式行星球磨機的的結(jié)構(gòu)設(shè)計和運動學(xué)分析,繪制部件裝配圖和主要零件圖,圖紙總量折合成A0,不少于2張 3、撰寫設(shè)計說明書,關(guān)鍵零件應(yīng)進行強度和剛度計算,說明書字數(shù)不少于15萬4、完成資料查閱和3000字的文獻翻譯 四、工作進度:序號 各階段完成的內(nèi)容 完成時間1 查閱資料、調(diào)研 第1,2周2 制訂設(shè)計方案 第3,4周3 分析與計算 第5,6周4 繪部件裝配圖 第7,8、9周5 繪零件圖 第10,11周6 撰寫設(shè)計說明書 第12,13周7 準(zhǔn)備答辯材料 第14周8 畢業(yè)答辯 第15周五、主要參考文獻(按作者、文章名、刊物名、刊期及頁碼列出)1、機械設(shè)計手冊 2、機械傳動設(shè)計手冊 3、顏景平,易紅等. 行星式球磨機研制及其節(jié)能機理 . 東南大學(xué)學(xué)報,2008,32(1):27-31 4、康善存. 硬脆材料的精密切割及發(fā)展趨勢J.機械制造,1997,7:46 5、網(wǎng)絡(luò)相關(guān)資信指導(dǎo)教師意 見指導(dǎo)教師簽名: 年 月 日系意見 系主任簽名: 年 月 日院意見 教學(xué)院長簽名: 年 月 日湘潭大學(xué)(興湘學(xué)院)畢業(yè)論文 題 目:小型臥式行星輪球磨機設(shè)計與運動分析 學(xué) 院: 興湘學(xué)院 專 業(yè): 機械設(shè)計制造及其自動化 學(xué) 號: 2008963128 姓 名: 李勇杰 指導(dǎo)教師: 周后明 完成日期: 2012年5月30日 Sener, B. and Wormald, P. (2001) “The Future of Computer Use in Product Design” Proceedings of CADE 2001 - Computers in Art and Design Education: Digital Creativity Crossing the Border, p.358-363, 9-12 April 2001, Glasgow, Scotland ISBN 0 901904 82 1 CADE 2001 Digital Creativity: Crossing the Border 358 The Future of Computer Use in Product Design Bahar Sener Paul Wormald Department of Design and Technology Loughborough University, England B.Senerlboro.ac.uk Abstract: This paper discusses research carried out as part of an ongoing PhD project into the use of CAD by industrial designers. The early research has been based on literature searching and face-to-face interviews carried out with postgraduate design students and practising design professionals. The aims of the interviews were; to investigate issues surrounding creativity and computer aided design (CAD); to explore the capability of current CAD systems for supporting design activity; and to identify user expectations in the near future. A significant outcome of this early part of the study is the identification of industrial designers future expectations for CAD systems that would give relevant technological and practical directions in the field of computer support for industrial design. 1. Introduction The development of CAD systems has undergone rapid development in the last twenty years. A major transformation in the media used by industrial designers to assist them in carrying out the design process has been witnessed with the use of computer. The first use of computer drawing techniques, as a simple computer-aided drawing board, was in the 1960s, and it was only in the 1980s that the working practices of designers in many industries was gradually transformed.1, 2 Since the introduction of computers into the field of design, the CAD industry has also come a long way with continuous improvements to the user interface. When computers were first used for industrial design, designers tended to use software originally intended for engineering.3, 4 Although there is an overlap between these disciplines, there are also significant differences in their expectations. For example, for the balance of their work engineers are more likely to use a CAD system to help them rapidly develop and document very precise definition of objects5 whereas industrial designers rely on experimenting with different views of the object,3 and to build and visualise free forms and organic shapes. Until the late 1980s CAD, in the industrial design context, effectively meant the computerisation of technical drawing.6 In parallel to the development of CAD systems, in order to answer industrial designers particular needs, Computer Aided Industrial Design (CAID) software was developed. The CAD industry has grown and changed in terms of the computer hardware utilised, the software technology employed and the impact of CAD on design and manufacturing organisations. Towards the end of the 1980s CAID packages that would enable the whole design process to be computerised, such as Alias, 3 were introduced to the market. Today, the effects of computer-based technological advances are widespread and that they have brought computers into design studios with an ever-increasing role in design activities. CAD is now 1 Black, I. (1990). Design Methodologies in a New Generation of CAD. CAD/CAM 1990 Conference Proceedings. 27-29 March 1990, Nec Birmingham, The Strathclyde Institute. pp. 402-412. 2 Jones, Tim (1997) New Product Development, Oxford: Butterworth-Heinemann. 3 McCullagh, K. (1996) 3D computer modelling in Industrial design. Co-Design Journal. 07.08.09(1996):28-35. 4 Hirschtick, J. (2000) The Future of CAD. MCAD-Productive Solutions for mechanical Engineers and Designers. 20(03):2. 5 Loosschilder, G. (1997) A picture tells a thousand words. The Design Journal. 0(1)41-57. 6 Cardaci, Kitty (1992) CAID: A Tool for the Flexible Organisation, Design Management Journal (Reprint), 3(2). Sener, B. and Wormald, P. (2001) “The Future of Computer Use in Product Design” Proceedings of CADE 2001 - Computers in Art and Design Education: Digital Creativity Crossing the Border, p.358-363, 9-12 April 2001, Glasgow, Scotland ISBN 0 901904 82 1 CADE 2001 Digital Creativity: Crossing the Border 359 applied through the various aspects of the design and manufacturing processes.7 Industrial design companies and manufacturing companies are designing and evaluating their products using several CAD tools. Nevertheless, the range of tools that can be used by industrial designers in all stages of design, from original idea to final product, is still limited. This is because of the current suite of CAD tools is relatively new and has been designed for either high profit margin based markets such as computer animation or large markets such as mechanical engineering.3, 8 When investigating the evolution of CAID tools, one of the main issues concerns recognising the industrial designers needs and the nature of their work before integrating CAD into the design process. This research aims to add to the debate through the findings of a PhD research programme. The main goal of the research is to achieve relevant technological and practical directions in the field of computer support for industrial design. 2. Literature review This section introduces the findings of the literature review undertaken as part of the study. Early research for the study has focused on searching literature in the area the use of computers in the process of the design of mass manufactured products. As computer technology has been changing very quickly the literature review is limited to the last two decades in order to find out state-of-the-art. The main sources of recent information were journal articles plus documents collected from the Internet and exhibitions visited. The literature review resulted in a number of repeated issues. These issues can be sorted into broader themes as follows: - creativity with computers, - data compatibility with other software and hardware, - communication and teamworking, - cost issues. 2.1 Creativity with computers Creativity is frequently considered to be the most important aspect in design. However, designers can never be completely independent of their tools, and the use of CAD has a number of implications for the products concerned.7 The research is looking at the creative use of CAD tools at the stage of product modelling rather than looking at creativity. In this context, creativity is the connected with series of activities that designers do in order to produce the most interesting and pleasant concepts for new products. It is concerned with the issues that allow designers; to experiment freely with such features as colour, surface finish, overall dimensions, product graphics,3 to generate forms very quickly, to keep records and so on, without fear of loosing the original concept. Recent CAD software gives designers the previously unavailable ability to deal with complex surfaces thereby, potentially, allowing them the opportunity to become more creative in their design.2 This potential of CAD is not an attribute of the system alone; it requires both a significant level of user skill and a number of design parameters to be in place before its significant use as a creative tool in the design process.9 Nevertheless, today, manufacturing industry is aware of several CAD systems that aim to provide a support role in the early stages of design, such as Alias Studio Tools.10 7 Zeitoun, Jean (1993) “CAD and the conception of objects.” In Jocelyn de Noblet, eds. Industrial Design reflection of a century. Paris, pp 373-380. 8 De S, A.G. and Rix, J. (2000) “Virtual prototyping: The Integration of Design and Virtual Reality.” In P. Brunet, C. Hoffmann and D. Roller eds. CAD Tools and Algorithms for Product Design. Berlin, London: Springer. 9 Warburton, N. (1996) A Heuristic Model for Digitally Integrated Design. Co-Design Journal. 07.08.09(1996):24-27. 10 Alias Studio Tools (2000) Accessed via WWW http:/ (23 September 2000). Sener, B. and Wormald, P. (2001) “The Future of Computer Use in Product Design” Proceedings of CADE 2001 - Computers in Art and Design Education: Digital Creativity Crossing the Border, p.358-363, 9-12 April 2001, Glasgow, Scotland ISBN 0 901904 82 1 CADE 2001 Digital Creativity: Crossing the Border 360 2.2 Data compatibility with other software and hardware There is a large number of CAD applications which store and use data, such as product geometry, and material attributes of the CAD model, in different ways. A high proportion of companies operate some sort of CAD system, such as AutoDesks AutoCAD or IBMs CATIA, running on different platforms ranging from PC and Apple Macintosh to Silicon Graphics and Hewlett-Packard UNIX workstations.2 However, most CAD packages from different vendors do not communicate with each other and model data cannot be shared directly.3 Today, in order to support different phases of the new product development process a wide variety of CAD software has been developed and introduced to the market. Consequently, the current data exchange formats are not able to serve all this variety of software and the data exchange problem still exists. 2.3 Communication and team working Industrial designers increasingly work in multidisciplinary teams which often consist of people inside their workplace and sometimes people contributing to projects from outside. When the teams goals are to maximise product quality and minimise development time and costs, 3 the need for high quality and efficient communication becomes essential. When the different segments of the design team, which can be located in different places, need to work on different parts of the same project, effective software enabling appropriate communication becomes essential. Although accesses to the Internet and video conferencing technology already assist designers to communicate design data in different continents, improvements can always be made. 2.4 Cost issues Although CAD systems have become much more cost effective then before,11 most of them are still regarded as high-priced to buy and upgrade, especially by the design divisions of small companies. The literature review has resulted in some preliminary conclusions and given an overview of the issues involved in the integration of computers in design. However, it was decided that more recent data about the current issues needed to be gathered by talking to the CAD users who take part in product development. Consequently, it was planned to arrange face-to-face interviews with these people. 3. Interviews and questionnaire with designers After the review of previous literature it was decided to talk to current CAD users in order to gather more up-to-date and focused information about their needs. A series of research questions was drawn up in order to provide direction to the brief. These questions concerned the strengths and weaknesses of the computer hardware and software as experienced by users, the expectations of those users on the topics of functionality and input/output options, and the identification of user expectations over the next five years. A questionnaire was designed to answer these questions. Face-to-face interviews with eight practising professional designers were carried out, as well as nineteen interviews with postgraduate design students. The aims of the interviews were to investigate creativity and the use of CAD; to explore the capability of current CAD systems to support design activity; and to identify user expectations in the near future. The interviews were conducted over four months with professional designers from multinational design companies plus ergonomists, engineers and designers. The postgraduate design students were all from Coventry University. Since the interviewees were chosen from different professionals involved in the design process they were using a variety of software applications in different phases of the design process. However, the majority of postgraduate design students were using Wavefront software from Alias. 11 Woolner, M., Adams, B. and Polletti, H. (1996) Computer technology in designer maker practices. Co-Design Journal. 07.08.09(1996):10-14. Sener, B. and Wormald, P. (2001) “The Future of Computer Use in Product Design” Proceedings of CADE 2001 - Computers in Art and Design Education: Digital Creativity Crossing the Border, p.358-363, 9-12 April 2001, Glasgow, Scotland ISBN 0 901904 82 1 CADE 2001 Digital Creativity: Crossing the Border 361 The interview questionnaire is not included in this paper due to the insufficient space. It was structured under four main sections: (1) Personal and company details, (2) The design process, (3) Computers, and (4) Future expectations, each with relevant questions reflecting the main themes of the investigation. Since the questionnaire was designed for practising designers some modifications were made after piloting, in order to make the questions more relevant to the student interviewees. Otherwise, the questionnaire was same for all participants. In this study qualitative research methods were selected in order to generate data rich in detail and embedded in a research context. The qualitative data was obtained by tape recordings during the interviews, and they were then evaluated. A number of repeated issues emerged, and these were sorted into broader themes. 4. Discussion The basis of this discussion is formed by the major points which arose from the interviews. From the findings of the interviews, the main issues can be categorised as; problems with computer graphical interface and usability, problems with data input devices, data compatibility with other software and hardware, and cost. Since data compatibility and cost issues are common results with the literature review, only problems with computer graphical interface and usability, and data input devices are discussed. Although the interview findings mostly reflect the postgraduate students attitudes towards the future use of CAD tools in industrial design, the questionnaire provided interesting answers that would help identify the extent of future expectations for CAD systems that industrial designers have. The research showed that the current spectrum of computer-modelling systems does not provide sufficient support for creativity. The results from the questionnaire have been used to generate the following wish list. 1. Computer graphical interface and usability; The major issue was how complicated software is to learn and use. Software should be: - easy to find what tool to use for which purpose, - easy to locate the tool, - easy to create complex shapes, - easy to remember which level of modelling is being used. It is important to consider the user-interaction dimensions of computer software. When working on a CAD system, the user should be able to concentrate on the creative design aspects of a CAD task instead of paying attention to the interaction with the computer. Incorrect and complex user interfaces may result in the misuse of the software, undermine customer understanding and acceptance, and increase the learning period. Even though some CAD systems have been promoted as easy-to-use with improved interfaces, the majority of interviewees (19 out of 28) had problems with interface and usability. They would like to have less complicated CAD software that they can learn in a much shorter time without having difficulty getting familiar with the interface. 2. Data input (devices); The major issue was how to produce life-like model. Life-like modelling can be achieved by: - shaping the object by hand, - interaction with the model - sculpting the model, - touching / feeling / holding the model, - moving around the model. It was noted that nearly all interviewees imagine a CAD system which enables them to shape the object by hand, interact with the model by touching, feeling and holding it as in real life. With the advent of recent simulation technology input and the output devices have attained a rich variety. In simulation technology, mainly known as Virtual Reality (VR), an artificial environment is created with computer hardware and software, and presented to the user in such a way that it appears and feels like a real environment in real time. Some new systems, named haptic systems, have been recently introduced in Sener, B. and Wormald, P. (2001) “The Future of Computer Use in Product Design” Proceedings of CADE 2001 - Computers in Art and Design Education: Digital Creativity Crossing the Border, p.358-363, 9-12 April 2001, Glasgow, Scotland ISBN 0 901904 82 1 CADE 2001 Digital Creativity: Crossing the Border 362 order to join visual interaction together with the simulation of physical interaction.12 Nevertheless, these tools have not yet been significantly introduced as a 3D modelling tool in industrial design. 5. Conclusions and future research From the preliminary results of this research it is possible that the scope of future research lies in new data input devices and/or systems, and 3D computer graphical interfaces. Having established what the future needs of current computer users in design are, research will focus on more precise and life-like 3D modelling with computer. Proposals for software, graphical interface or new input devices are possible results from future research. Issues which influence future research can be summarised below. The outcome of the literature review indicated that current manufacturing industry trends show demand for reducing the development costs and time while at the same time improving innovation, product quality and reacting quickly to new customers needs. 8 This means that a modern product development process needs to adapt itself to rapidly changing requirements. This would be achieved by integrating new technologies into the early design stages. Computer-modelling systems are moving from a geometry-based to a physically based approach. This means that geometry is not the only piece of information defining an object, and aspects concerning other physical characteristics of the object have to be considered and included in the model. However, current virtual models modelled on computers only become physical towards the end of the product development process, by means of output devices such as printers or rapid prototyping tools. It is important in the design of virtual products that they can be realistically designed, tested and presented without the immediate need for a real, physical model or prototype. Exploring the interaction from the conceptual stage of the design through to holding the model, perceiving the depth, feeling the resistance and the pressure it applies, and so on, may be rewarding and productive for the designer. Furthermore, the interaction with the design tools as well as the model itself should also be rewarding. Developments such as Virtual Reality and interactive prototyping, through which it is possible to interact with the model and to have force feedback, are major improvements allowing the users to investigate and understand the structure of objects. 3D digital technology potentially holds the future of modelling. However, it has not yet been introduced as a design tool in industrial/product design in a form which is entirely satisfactory for the designer. 12 Bordegoni, M. and De Angelis, F. (2000) “The Role of Haptic Devices for an Efficient Integration of Design, Simulation and Analysis.” In P. Brunet, C. Hoffmann and D. Roller eds. CAD Tools and Algorithms for Product Design. Berlin, London: Springer. Sener, B. and Wormald, P. (2001) “The Future of Computer Use in Product Design” Proceedings of CADE 2001 - Computers in Art and Design Education: Digital Creativity Crossing the Border, p.358-363, 9-12 April 2001, Glasgow, Scotland ISBN 0 901904 82 1 CADE 2001 Digital Creativity: Crossing the Border 363 References 1. Black, I. (1990). Design
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