汽車閥體零件機(jī)械加工工藝及夾具設(shè)計(jì)
汽車閥體零件機(jī)械加工工藝及夾具設(shè)計(jì),汽車閥體零件機(jī)械加工工藝及夾具設(shè)計(jì),汽車,閥體,零件,機(jī)械,加工,工藝,夾具,設(shè)計(jì)
邵陽(yáng)學(xué)院畢業(yè)設(shè)計(jì)(論文)
附錄: Micro-machine
From the beginning, mankind seems instinctively to have desired large machines and small machines. That is, large” and “small” in comparison with human-scale. Machine larger than human are powerful allies in the battle against the fury of nature; smaller machines are loyal partners that do whatever they are told.
1.introduce
If we compare the facility and technology of manufacturing larger machines, common sense tells us that the smaller machines are easier to make. Nevertheless, throughout the history of technology, larger machines have always stood out. The size of the restored models of the water-mill invented by Vitruvius in the Roman Era, the windmill of the Middle Ages, and the steam engine invented by Watt is overwhelming. On the other hand, smaller machines in history of technology are mostly tools. If smaller machines are easier to make, a variety of such machines should exist, but until modern times, no significant small machines existed except for guns and clocks
This fact may imply that smaller machines were actually more difficult to make. Of course , this does not mean simply that it was difficult to make a small machine; It means that it was difficult to invent a small machine that would be significant to human beings.
Some people might say that mankind may not have wanted smaller machines. This theory, however ,dies not explain the recent popularity of palm-size mechatronics products.
Some people might say that mankind may not have wanted smaller machines. This theory, however, does not explain the recent popularity of palm-size mechatronics products.
The absence of small machines in history may be due to the extreme difficulty in manufacturing small precision parts.
2. Why micromachine now
The dream of the ultimate small machine, or micro-machine, was first depicted in detail about 30 years ago in the 1966 movie “Fantastic Voyage”. At that time, the study of micro-machining of semiconductors had already begun. Therefore, manufacturing minute mechanisms through micro-machining of semiconductors would have been possible, even that time,. There was, however, a wait of over 20 years before the introduction, about 10 years ago, of electrostatic motors and gears made by semiconductor micromachining.
Why didn’t the study of micro-machining and the dream of micro-machines meet earlier? A possible reason for this is as follows. In addition to micro-machining, the development of micromachines requires a number of technologies including materials, instrumentations, control, energy, information processing, and design. Before micro-machine research and development can be started, all of these technologies must reach a certain level. In other words, the overall technological level, as a whole, must reach a certain critical point, but it hadn’t reached that point 30 ago.
Approximately 20 years after “Fantastic Voyage”., the technology level for micromachines finally reached a critical point. Micromotors and gears made by semiconductor micromachining were introduced at about that time, triggering the research on development of micromachines.
The backgroud of the micromachine boom, which started about 10 years ago, can be explained by the above.
3.micromachine as gentle machines
How do micromachines of the future differ from conventional machines? How will they change the relationship between nature and humans?
The most unique feature of micro-machine is, of course, its small size. Utilizing its tiny dimensions, a micromachine can perform tasks in a revolutionary way that would be impossible for conventional machines. That is, micro-machines do not affect the object or the environment as much as conventional machines do. Micromachines perform their tasks gently. This is a fundamental difference between micromachines and conventional machines.
The medical field holds the highest expectations for benefits from this feature of micromachines. Diadnosis and treatment will change drastically from conventional methods, and “Fantastic Voyage” may no longer be a fantasy. If a micromachine can gently enter a human body to treat illness, humans will be freed from painful surgery and uncomfortable gastro-camera testing. Furtherore, if micro-machines can halt the trend of ever-increasing size in medical equipment, it could slow the excess growth and complexity of medical technology, contributing to the solving of serious problems with high medical costs for citizens.
Micro-machines are gentle also in terms of machine maintenance, since they can be inspected and repaired without difficulty in reaching and overhauling the engine or plant. The more complex the machine, the more susceptible it is to malfunction due to overhaul and assembly. In addition, there have been more instances of human errors during overhaul and assembly. It is good for the machine if overhaul is not necessary. It is even better if maintenance can be performed without stopping the machine. Repeated stop-and-go operation will accelerate damage of the machine due to excess stress caused by thermal expansion.
Such gentleness of a mocromachine is an advantage, as well as a weakness in that a micromachine is too fragile to resist the object or the environment; this is the drawback of the micro-scale objects.
For example, a fish can swim freely against the current, but a small plankton cannot. This is result of physical laws and nothing can change it. Still, the plankton can live and grow in the natural environment by conforming to the environment.
Unlike conventional machines which fight and control natural, micromachines will probably adapt to and utilize nature. If a micromachine cannot proceed against the current, a way will be found to proceed with the flow, naturally avoiding collisions with obstacles.
4. Micro-electronics and mechatronics
The concept of micromachines and related technologies is still not adequately unified, as these are still at the development stage. The micromachines and related technologies are currently referred to by a variety of different terms. In the United States, the accepted term is “micro electro mechanical systems” (MEMS); in Europe, The term “Microsystems technology”(MST) is common, while the term “micro-engineering” is sometimes used in Britain. Meanwhile in Australia “micro-machine”. The most common term if it is translated into English is “micromachine”. The most common term if it is translated into English is “micromachine” in Japan. However “micro-robot” and “micro-mechanism” are also available case by case.
The appearance of these various terms should be items taken as reflecting not merely diversity of expression, but diversity of the items referred to. Depending on whether the item referred to is an object or a technology, the terminology may be summed up as follows:
Object: micro-robot, micro-mechanism
Technology: micro-engineering, MST
Object & technology: MEMS, micro-machine
With regard to technology, if we summarize the terms according to 1) where the technology for micromachine systems branched from, and 2) whether the object dealt with by the technology in question is an element or a machine system, the terms can be organized as follows. That is, MEMS and MST stem from mechatronics, and have developed dealing mainly with machine systems. In this sense, MEMS and MST on the one hand micromachines and microengineering on the other hand form two separate groups, but as former has started to move in the direction of machine systems, while the latter has already incorporated microelectronics, the difference between the two groups are gradually disappearing.
Looking at the areas in the two groups, given that the machine systems which are the main concern of micromachine include microelectronics, it would be natural to assume that micromachines inchude MEME and MST.
5 .the definition and development aim
It is difficult at present to give a unified definition of micromachines, but if these are taken to be machine systems as output of micromachine technology, the scope for variation of the definition narrows slightly.
The micromachine technology project being project being promoted under the Industrial Science and Technology Frontier Program Agency of Industrial Science and Technology of MITI, and the micro-machine Center, define micro-machines as follows:
Micro-machines are small machines composed of sophisticated functional elements less than a few millimeters in size, constructed to perform complex tasks on a small scale.
The above definition of micro-machines is in fact inseparable from the development aims for micro-machines. At present, debate on the definition of micro-machines is exactly the same as debating development aims, that is, the diversity of definitions of micromachines reflects the diversity of development aims.
6.Conclusions.
Micromachines are unconventional artifacts with respects to their gentle features to people and nature. The current diversity of the definition of them is originated from development objectives and technological starting points. Micromachine technologies, in view of their development prospect, are expected as generic technologies for the twenty-first century to support industry and medicine as well as daily life. Micromachine technologies are essential also for improving the conventional machines in general.
Micro-machines are artifacts in tiny size, but they will exert a strong influence on our lifestyles and society.
譯文:
微 型 機(jī) 器
從一開(kāi)始,人類似乎本能的就有一種想制造“大機(jī)器”和“小機(jī)器”的愿望,這里的所謂“大”和“小”是相對(duì)人類身體本身的尺寸而言。比人體大的機(jī)器將成為人類同暴虐無(wú)情的自然界做斗爭(zhēng)的得力助手,而些小機(jī)器則只能乖乖地聽(tīng)從人類的命令,讓干什么就干什么。
1、介紹
如果我們比較那些比較大的機(jī)器的設(shè)備和生產(chǎn)科技,普通的感覺(jué)告訴我們,小機(jī)器容易制造,然而,在全歷史期間,大機(jī)器已經(jīng)闡述了這一點(diǎn)。在羅馬時(shí)期,威克威斯發(fā)明的在水戰(zhàn)中已經(jīng)修復(fù)過(guò)的模型尺寸,還有,中世紀(jì)的風(fēng)車和瓦特發(fā)明的蒸汽機(jī)正在代替。在另一方面,科技?xì)v史上的小機(jī)器主要是工具,如果小機(jī)器容易制造,像這樣的很多種機(jī)器應(yīng)該存在。但直到現(xiàn)代,除了槍和時(shí)鐘之外,沒(méi)有標(biāo)志性的小機(jī)器誕生。
這個(gè)事實(shí)可能暗示小機(jī)器實(shí)際上更難制造。當(dāng)然,這不簡(jiǎn)單地意味著制造一個(gè)小機(jī)器是困難的。它意味著發(fā)明一個(gè)對(duì)人類有標(biāo)志性意義的小機(jī)器是困難的。
一些人可能說(shuō)人類不想要小機(jī)器,然而,這個(gè)理論不能解釋近來(lái)流行的袖珍型的機(jī)械產(chǎn)品。
歷史上小機(jī)器的缺乏可能因?yàn)樵谏a(chǎn)小的精確部分的困難。
2、為什么現(xiàn)在有微型機(jī)器
最后的小機(jī)器的夢(mèng)想,或者微型機(jī)器,大約在三十年前,即1966年由影片“夢(mèng)幻旅行”里,第一次詳細(xì)的描敘了。在那個(gè)時(shí)候半導(dǎo)體的微型機(jī)器的研究已經(jīng)開(kāi)始了。甚至在那個(gè)時(shí)候通過(guò)半導(dǎo)體的小機(jī)器的微小生產(chǎn)機(jī)械化已經(jīng)可能了,然而,在大約十年以前通過(guò)半導(dǎo)體小機(jī)械制造的馬達(dá)和傳動(dòng)裝置的產(chǎn)品出現(xiàn)之前等了二十年。
為什么小機(jī)器的研究和夢(mèng)想不能早點(diǎn)滿足呢?可能是下面這些原因,除微型機(jī)器外,小微型機(jī)器的發(fā)展要求很多科技,包括材料控制,能量,信息進(jìn)程和設(shè)計(jì),在微型機(jī)器可能開(kāi)始被研究和發(fā)展之前,所有的這些科技必須達(dá)到某一定的水平。換句話說(shuō),總之,全面的科技水平必須達(dá)到關(guān)鍵的一點(diǎn),但是在三十年前沒(méi)有達(dá)到那點(diǎn)。
大約在“夢(mèng)幻旅行”之后二十年,微型機(jī)器的科技水平最后達(dá)到了關(guān)鍵點(diǎn)上,也大約在那個(gè)時(shí)候通過(guò)半導(dǎo)體的微型機(jī)械制造的微型馬達(dá)和傳動(dòng)裝置的被介紹,啟發(fā)了微型機(jī)器發(fā)展的研究。
大約在十年前開(kāi)始的微型機(jī)械繁榮的背景可能是上述原因。
3、微型機(jī)器作為好機(jī)器
怎樣區(qū)別將來(lái)的微型機(jī)器和一般機(jī)器?他們將怎樣改變?nèi)祟惡妥匀坏年P(guān)系?
當(dāng)然,微型機(jī)器最獨(dú)特的特征是:它是很小的,利用它微小的尺寸,改革后的微型機(jī)器將可能像一般機(jī)器一樣執(zhí)行任務(wù),那就是微型機(jī)器不影響物體和環(huán)境,就像一般機(jī)器一樣,能很好的執(zhí)行任務(wù)。這就是一般機(jī)器和微型機(jī)器之間的基本區(qū)別。
醫(yī)療領(lǐng)域只有最高期望:從微型機(jī)器中可以得到益處,診斷和治療將從一般方式徹底改變,“夢(mèng)幻旅行”不可能是個(gè)夢(mèng)想。如果機(jī)器能夠進(jìn)入人的身體治療疾病,人類將減輕像手術(shù)一樣的痛苦和透射那樣的不舒服感,而且,在醫(yī)療器械方面如果微型機(jī)器能夠停止尺寸增長(zhǎng)的趨勢(shì),它可能減少醫(yī)療科技方面的增長(zhǎng)和復(fù)雜,而醫(yī)療科技將為人們解決嚴(yán)重問(wèn)題。
微型機(jī)器在機(jī)器維修方面也是很方便的。但是在拖動(dòng)設(shè)備時(shí)它們不能方便的修理,因?yàn)橥蟿?dòng)和安裝,機(jī)器越復(fù)雜,功能越敏銳。而且,在拖動(dòng)和安裝時(shí),人們出現(xiàn)的錯(cuò)誤有很多情況,如果沒(méi)有必要拖動(dòng),對(duì)機(jī)器來(lái)講是有益處的。如果不用停止機(jī)器就可以維修的話是最好的。反復(fù)的開(kāi)和停,將會(huì)加速機(jī)器的損壞,這是因?yàn)槔錃庋b置的膨脹引起壓力。
這樣好的微型機(jī)器有優(yōu)點(diǎn)也有缺點(diǎn)。那就是微型機(jī)器太脆弱不能抵制周圍環(huán)境和物體,這是因?yàn)槿鄙傥⑿臀铩?
例如,魚(yú)在水里能很自由的游,但是浮游生物不能,這是自然規(guī)律,沒(méi)有什么能改變,然而,浮游生物能夠在合適的環(huán)境里生活和成長(zhǎng)。
不象一般機(jī)器能對(duì)抗或控制自然,微型機(jī)器只可能適應(yīng)和利用自然,如果微型機(jī)器不能加速潮流,那么跟隨潮流將會(huì)發(fā)現(xiàn)一種方法,這樣可自然的避免碰撞和障礙。
4、微電
微型機(jī)器的概念和相關(guān)的科技不能充分的成為一體,因?yàn)檫@也是發(fā)展的階段,微機(jī)和相關(guān)科技當(dāng)今由不同時(shí)期決定,在美國(guó),接受的時(shí)期是“微電機(jī)械化系統(tǒng)”,在歐洲,“微系統(tǒng)科技”時(shí)期很普通,而在英國(guó),有時(shí)候是“微電”而同時(shí)在澳大利亞用“微型機(jī)器”,在日本的時(shí)期如果翻譯成英語(yǔ)就是“微機(jī)”,然而,“微機(jī)器人”和“微機(jī)械化”也是有益的。
這些不同時(shí)期的出現(xiàn)是反映而不僅僅是表達(dá)的不同,是指一系列的不同,根據(jù)指的物體還是科技,可用下列術(shù)語(yǔ)綜合:
物體:微機(jī)器人,微機(jī)械化
科技:機(jī)電,MST
物體與科技:MEMS,微機(jī)
關(guān)于科技,如果我們根據(jù)1)總結(jié)的時(shí)期分離出機(jī)械化系統(tǒng)的科技,根據(jù)2)是否可懷疑通過(guò)科技處理的物體,是一個(gè)基本元素還是機(jī)械系統(tǒng)。總結(jié)如下:那就是,從機(jī)械化MEMS和MST系列,已經(jīng)發(fā)展處理主要的機(jī)械系統(tǒng),在這種情況下一方面MEMS,MST,微機(jī)和微電,另一方面形成兩個(gè)分離的組。但是以前已經(jīng)開(kāi)始了機(jī)械系統(tǒng)移動(dòng)的方向,然而后來(lái)已經(jīng)混合了微電,這兩組之間的區(qū)別是逐漸消失的。
在這兩組看,假設(shè)機(jī)械系統(tǒng),它是主要包括基本元素的微機(jī);假定微機(jī)包括微電,那么假設(shè)微機(jī)包括MEMS和MST是很自然的。
5、定義和發(fā)展目標(biāo)
現(xiàn)在對(duì)微機(jī)下一個(gè)相一致的定義是困難的,但是如果這些極限當(dāng)作機(jī)械系統(tǒng)作為微機(jī)科技的產(chǎn)量,那么定義變化的儀器有點(diǎn)狹窄。
通過(guò)工業(yè)科學(xué)和科技領(lǐng)域的計(jì)劃以及微機(jī)中心,促進(jìn)了微機(jī)科技。定義微機(jī)如下:
微機(jī)是小的機(jī)器,由少于一毫m的復(fù)雜功能元素組成。用在一個(gè)小的尺度上,裝配來(lái)執(zhí)行復(fù)雜的任務(wù)。
以上微機(jī)的定義事實(shí)上是不能從微機(jī)發(fā)展的目標(biāo)中分離開(kāi)來(lái)的。目前,既討論微機(jī)的定義,同時(shí)討論發(fā)展的目標(biāo),那就是,微機(jī)的不同定義反映了發(fā)展目標(biāo)的不同。
6、結(jié)論
微機(jī)是不方便的,因?yàn)樗鼈儗?duì)人類而言所具有的特征?,F(xiàn)在定義的不同是源于發(fā)展目標(biāo)和科技起點(diǎn)?;乜此陌l(fā)展景色,微機(jī)科技被期望像一般科技一樣,在二十一世紀(jì)支持工業(yè)和醫(yī)療,跟日常生活相似??偟膩?lái)說(shuō),為提高普通機(jī)器,微科技是必要的。微機(jī)在微小尺寸方面是人造物品,但它們將對(duì)我們的生活和社會(huì)產(chǎn)生強(qiáng)烈的影響。
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