BYD-1水草收割船切割裝置設計【含CAD圖紙】

喜歡這套資料就充值下載吧。。。資源目錄里展示的都可在線預覽哦。。。下載后都有，，請放心下載，，文件全都包含在內(nèi)，，【有疑問咨詢QQ:1064457796 或 1304139763】 ==============================================喜歡這套資料就充值下載吧。。。資源目錄里展示的都可在線預覽哦。。。下載后都有，，請放心下載，，文件全都包含在內(nèi)，，【有疑問咨詢QQ:1064457796 或 1304139763】 ==============================================

中國地質(zhì)大學長城學院 本科畢業(yè)設計文獻綜述 系 別： 工程技術(shù)系 專 　業(yè)： 機械設計制造及其自動化 姓 名： 何俊達 學 號： 05208309 　 2012年　4月　13日 一 水草收割船的意義 水草在日常生活中有諸多的作用和價值，例如養(yǎng)殖、生態(tài)和景觀等有重要的價值體現(xiàn)，吸引著人們大量種植。但由于種植量過大，同時缺乏相應的管理措施，導致人工種植的水草一度發(fā)展到過剩的狀態(tài)。為了保持水域的生態(tài)平衡，需要在景觀水域中大量種植水草，但是在每年的高溫時節(jié)，水草生長非常迅速，必須及時進行收割清理，否則會對水質(zhì)造成二次污染。目前，水草治理方法主要有化學清除法和物理收割法。化學清除法會引起水質(zhì)污染，破壞生態(tài)環(huán)境，并對其他生物的生存造成很大影響。所以，人們大都采用更為環(huán)保的物理收割法來治理水草。但由于人工收割效率低下，往往打撈的速度跟不上水草生長的速度，因而機械收割就成為理想的水草治理方式。 二 水草收割船的目的 市場上一般的水草收割機多是機械控制的，動力來源復雜，難以實現(xiàn)收割船的簡單，智能，據(jù)此現(xiàn)狀，設計一種結(jié)構(gòu)緊湊，機構(gòu)傳動平穩(wěn)，效率高，機身全部動力來源為液壓，液壓控制液壓系統(tǒng)控制船的行走、割臺的升降以及輸送裝置的運動的水草收割船。這種新型的水草收割船可在水下實現(xiàn)切割，回收，傳送一體化連續(xù)作業(yè)方式，能夠達到清除多余的水草的目的，充分體現(xiàn)簡便化。 三 ?水草收割傳的發(fā)展過程 國外關于水草收割機的研制比較早，荷蘭等國早在50年代就開始使用專門的水利機械進行河道的清淤除草作業(yè)。荷蘭的IHC CO Konljn機械廠1958年研制出H系列兩棲式挖泥船共6種機型，隨后又相繼開發(fā)出M 系列、s系列和FB系列等多種清淤機械：荷蘭的HERDER公司也開始研制各種機型的河道除草機。起初他們一般是把切割器安裝在液壓挖掘機或農(nóng)用拖拉機上，把溝渠、河道內(nèi)的蒲草、雜草切割后撈起放于岸邊，其整機需停在岸邊或沿岸邊行駛進行作業(yè)，這就是陸用割草機。由于陸用割草機的使用范圍有較大限制．河道、溝渠旁常揎有樹木，無法停機，遠離岸邊的水草又無法切割到，因此研制一種能在河道中航行的水中割草機應運而生。60年代．英國的Rolbe公司開發(fā)出Oibeaux系列水中割草機，英國的John wider(工程)公司也開發(fā)出自己的系列產(chǎn)品．3O多年來，這些產(chǎn)品至今還在世界各地廣泛使用。 國內(nèi)也有一些相關企業(yè)及研究機構(gòu)進入該領域，并且取得了一定的研究成果，如寧波農(nóng)業(yè)機械研究所、桂林象山農(nóng)機廠、紹興縣農(nóng)林管理總部聯(lián)合研究的WH1800型河道清草機，北京市水利局聯(lián)合數(shù)家單位共同開發(fā)的的SGY-2.5型水草收割機，上海電器集團現(xiàn)代化裝備有限公司新液壓長研究開發(fā)的GC2230型號河道割草保潔船以及GC2000型小型河道割草作業(yè)機械。 經(jīng)歷半個世紀的發(fā)展歷程，水草收割機的設計，由開始的岸邊切割水草作業(yè)，水中水草作業(yè)，水中收割水草作業(yè)，到現(xiàn)在的水中切割、收獲、后續(xù)處理一體化作業(yè)模式，功能日益完善，而且經(jīng)過長時間的摸索和經(jīng)驗積累，其工作模式也發(fā)生了很大的改變。其主要是朝著小型化、自動化方向發(fā)展。 四 水草收割船的分類 1.根據(jù)切割器工作方式劃分 （1）往復式。切割器的主要構(gòu)造為兩把刀片，并且至少有一把作往復直線運動，與另一刀片形成相對切割。該種結(jié)構(gòu)的優(yōu)點是可以選擇合適的刀具參數(shù)來適應不同的環(huán)境。整個切割器是一個整體，只需一個動力端即可，容易實現(xiàn)同步工作；缺點是對刀具材料和刀具安裝精度要求高，維修不方便。 （2）旋轉(zhuǎn)式。這種切割器的主要構(gòu)造為旋轉(zhuǎn)軸的中心固定三四個刀片，工作的時候，刀片繞軸旋轉(zhuǎn)，不斷切割水草。這種刀具的主要優(yōu)點是多把刀具組裝而成，便于維修，缺點是滾刀的傳動軸必須安裝成偏心的形式，并且必須在水中工作，因此，對滾刀的動力傳輸以及密封的要求比較高。 2.根據(jù)切割器在船體的安裝位置分 （1）前置式。切割器安裝在船體的前端。優(yōu)點是能夠?qū)崿F(xiàn)割收一體化，水草的漏收率低，缺點是動力輸入端的傳動路線長，不適合剛性軸的工作。 （2）后置式。切割器安裝在船體的后端，優(yōu)點是船體行進過程中，拖動切割器行走，遇到韌性較大的水草，可以依靠慣性將其拉起，不至于沉頭。缺點是工作時，水草無法及時回收，容易造成二次污染。 （3）側(cè)置式。切割器安裝在船體一側(cè)，優(yōu)點是只有一個動力輸入端，動力集中，適用于水草密集的河道。缺點是切割時，必須有無水草區(qū)域，便于船體行走。 3.根據(jù)作業(yè)方式分 （1）割收連續(xù)式。主要應用于前置式。優(yōu)點是切除水草的同時，將水草回收，防止二次污染。缺點是需要兩個動力輸入端，動力要求高，結(jié)構(gòu)較為復雜。 （2）割收分開式。應用于側(cè)置式和后置式的情況。優(yōu)點是結(jié)構(gòu)簡單，功率要求低。缺點是割收分開作業(yè)，大大降低了工作效率，并且容易造成二次污染。 1.3.4 根據(jù)作業(yè)對象劃分 （1）近海水草式。主要收集近海水域的藻類水草。要求功率大，船體大，排水量大，不需要將水草收集起來，可以將水草沉入水底，船體必須配備適當?shù)木壬O備，而且船體的防腐要求很高，適合于大型水生植物收割機的連續(xù)作業(yè)。 （2）內(nèi)河水草式。主要用來收割內(nèi)陸江河、湖泊等淺水域的水草。水草的生長情況比較復雜，同時考慮到環(huán)境保護的問題，必須將水草及時收集打撈，因此，必須在船體上配備適當?shù)氖占b置，機構(gòu)比較復雜。 中國地質(zhì)大學長城學院 本科畢業(yè)論文外文資料翻譯 系 別： 工程技術(shù)系 專 業(yè)： 機械設計制造及其自動化 姓 名： 何俊達 學 號： 05208309 2012年 5 月 1 日 外文資料翻譯譯文 往復式切割機軸承的摩擦與潤滑 現(xiàn)在看來，有很多這種情況，許多學生在被問到關于摩擦的問題時，往往都沒引起足夠的重視，甚至是忽視它。實際上，摩擦從某種程度上說，存在于任何兩個相接 觸并有相對運動趨勢的部件之間。而摩擦這個詞，本身就意味著，兩個或兩個以上部件的阻止相對運動趨勢。 在一個機器中，運動部件的摩擦是有害的，因為它降低了機械對能量的充分利用。由它引起的熱能是一種浪費的能 量。因為不能用它做任何事情。還有，它還需要更大的動力來克服這種不斷增大的摩擦。熱能是有破壞性的。因為它產(chǎn)生了膨脹。而膨脹可以使得軸承或滑 動表面之間的配合更緊密。如果因為膨脹導致了一個足夠大的積壓力，那么，這個軸承就可能會卡死或密封死。另外，隨著溫度的升高，如果不是耐高溫材料制造的軸承，就可能會損壞甚至融化。 在運動部件之間會發(fā)生很多摩擦，如 1.啟動摩擦 2.滑動摩擦 3.轉(zhuǎn)動摩擦。 啟動摩擦是兩個固體之間產(chǎn)生的傾向于組織其相對運動趨勢的摩擦。當兩個固體處于靜止狀態(tài)時，這兩個零件表面的不平度 傾向于相互嵌入，形成楔入作用，為了使這些部件“動”起來。這些靜止部件的凹谷和尖峰必須整理光滑，而且能相互抵消。這兩個表面之間越不光滑，由運動造成的啟動摩擦（最大靜摩擦力）就會越大。 因為，通常來說，在兩個相互配合的部件之間，其表面不平度沒有固定的圖形。一旦運動部件運動起來，便有了規(guī)律可循，滑動就可以實現(xiàn)這一點。兩個運動部件之間的摩擦就叫做滑動摩擦。啟動摩擦通常都稍大于滑動摩擦。 轉(zhuǎn)動摩擦一般發(fā)生在轉(zhuǎn)動部件和設備上，這些設備“抵觸”極大的外作用力，當然這種外力會導致部件的變形和性能的改變。在這種情況下，轉(zhuǎn)動件的材料趨向于堆積并且強迫運動部件緩慢運動，這種改變就是通常所說的形變。可以使分子運動。當然，最終的結(jié)果是，這種額外的能量產(chǎn)生了熱能，這是必需的。因為它可以保證運動部件的運動和克服摩擦力。 由運動部件的表面不平度的楔入作用引起的摩擦可以被部分的克服，那就需要靠兩表面之間的潤滑。但是，即使是非常光滑的兩個表面之間也可能需要一種物質(zhì)，這種物質(zhì)就是通常所說的潤滑劑，它可以提供一個比較好的、比較薄的油膜。這個油膜使兩個表面分離，并且組織運動部件的兩個表面的相互潛入，以免產(chǎn)生熱量使兩表面膨脹，又引起更近的接觸。 減小摩擦的另一種方式是用不同的材料制造軸承和轉(zhuǎn)動零件?？梢阅命S銅軸承、鋁合金和含油軸承合金做例子進行解釋。也就是說用軟的或硬的金屬組成表面。含油軸承合金是軟的。這樣當軸承在油中浸泡過以后，因為毛細管的作用，將由帶到軸承的各個表面。這種類型的軸承把它的潤滑劑帶到應力最大的部位。 對運動部件潤滑以減小摩擦，應力和熱量，最常用的是油、脂、還有合成劑。每一種潤滑劑都有其各自不同的功能和用途。兩個運動部件之間的運動情況決定了潤滑劑的類型的選擇。潤滑劑的分布也決定了系統(tǒng)的選擇。 在低速度運動的部件，一個油溝足以將所需要的數(shù)量的潤滑劑送到相互運動的表面。 第二種通用的潤滑方法是飛濺潤滑系統(tǒng)，在每個周期內(nèi)這個系統(tǒng)內(nèi)一些零件經(jīng)過潤滑劑存儲的位置，帶起足夠的潤滑油，然后將其散布到所有的運動零件上。這種系統(tǒng)用于草坪修剪機中發(fā)動機的曲軸箱，對曲軸、連桿和活塞等零件進行潤滑。 在工業(yè)裝置中，常用的有一種潤滑系統(tǒng)是壓力系統(tǒng)。這種系統(tǒng)中，一個機器上的一個泵，可以將潤滑劑帶到所有的軸承表面。并且以一種連續(xù)的固定的速度和數(shù)量。 關于潤滑，還有許多其他的系統(tǒng)，針對各種類型的潤滑劑，對不同類型的運動零件是有效的。由于設備或裝置的速度、壓力和工作要求的提高，現(xiàn)代工業(yè)比以前任何時候都更注重選用適當?shù)臐櫥瑒? 盡管潤滑的主要目的之一是為了減小摩擦力，任何可以控制兩個滑動表面之間摩擦和磨損的物質(zhì)，不管是液體還是固體或氣體，都可以歸類于潤滑劑。 潤滑的種類 無潤滑滑動。經(jīng)過精心處理的、去除了所有外來物質(zhì)的金屬在相互滑動時會粘附或熔接到一起。當達不到這么高的純凈度時，吸附在表面的氣體、水蒸氣、氧化物和污染物就會降低摩擦力并減小粘附的趨勢，但通常會產(chǎn)生嚴重的磨損，這種現(xiàn)象被稱為“無潤滑”摩擦或者叫做干摩擦。 流體膜潤滑。在滑動面之間引入一層流體膜，把滑動表面完全隔離開，就產(chǎn)生了流體膜潤滑。這種流體可能是有意引入的。例如汽車主軸承中的潤滑油；也可能是無意中引入的，例如在光滑的橡膠輪胎和潮濕的路面之間的水。盡管流體通常是油、水和其他很多種類的液體，它可以是氣體。最常用的氣體是空氣。 為了把零件隔離開，潤滑膜中的壓力必須和作用在滑動面上的負荷保持平衡。如果潤滑膜中的壓力是由外源提供的，這種系統(tǒng)稱為流體靜壓潤滑。如果滑動表面之間的壓力是由于滑動面本身的形狀和運動所共同產(chǎn)生的，這種系統(tǒng)就稱為流體動壓力潤滑。 邊界潤滑。處于無潤滑滑動和流體膜潤滑之間的潤滑被稱為邊界潤滑。它可以被定為這樣一種潤滑狀態(tài)，在這種狀態(tài)中，表面之間的摩擦力取決于表面的性質(zhì)和潤滑劑中的其他性質(zhì)。邊界潤滑包括大部分潤滑現(xiàn)象，通常在機器的啟動和停止時出現(xiàn)。 固體潤滑。當普通潤滑劑沒有足夠的承受能力或者不能在溫度極限下工作時，石墨和二硫化鉬這一類固體潤滑劑得到廣泛應用。但潤滑劑不僅僅以脂肪、粉末和油脂這樣一些為人們所熟悉的形態(tài)出現(xiàn)，在一些精密的機器中，金屬也通常作為滑動面。 潤滑劑的作用 盡管潤滑劑主要是用來控制摩擦和磨損的，它們能夠而且通常也確實起到許多其他的作用，這些作用隨其用途不同而不同，但通常相互之間是有關系的。 控制摩擦力。 滑動面之間潤滑劑的數(shù)量和性質(zhì)對所產(chǎn)生的摩擦力有很大的影響。例如，不考慮熱和磨損這些相關因素，只考慮兩個油膜潤滑表面見的摩擦力，它能比兩個同樣表面，但沒有潤滑時小200倍。在流體潤滑狀況時，摩擦力與流體黏度成正比。一些諸如石油衍生物這類潤滑劑，可以有很多黏度，因此能夠滿足范圍寬廣的功能要求。在邊界潤滑狀態(tài)，潤滑劑黏度對摩擦力的影響不象其化學性質(zhì)的影響那么顯著。 磨損控制。磨蝕、腐蝕與固體和固體之間的接觸就會造成磨損。適當?shù)臐櫥瑒⒛軒椭朔鲜鎏岬降囊恍┠p現(xiàn)象。潤滑劑通過潤滑膜來增加滑動面之間的距離，從而減輕磨料污染物和表面不平度造成的損傷，因此，減輕了磨損和由固體與固體之間接觸造成的磨損。 控制溫度。潤滑劑通過減小摩擦和將產(chǎn)生的熱量帶走來降低溫度。其效果取決于潤滑劑的用量和外部冷卻措施。冷卻劑的種類也會在較小的程度上影響表面的溫度。 控制腐蝕。潤滑劑在控制表面腐蝕方面有雙重作用。當機器閑置不工作時，潤滑劑起到防腐劑的作用。當機器工作時，潤滑劑通過給被潤滑零件涂上一層可能含有添加劑，能使腐蝕性材料中和的保護膜來控制腐蝕。潤滑劑控制腐蝕的能力與潤滑劑保留在金屬表面的潤滑膜的厚度和潤滑劑的化學成分有直接的關系。 其他作用 除了減小摩擦外，潤滑劑還經(jīng)常有其他的用途。其中的一些用途如下所述。 傳遞動力。潤滑劑被廣泛用來作為液壓傳動中的工作液體。 絕緣。在象變壓器和配電裝置這些特殊用途中，具有很高介電常數(shù)的潤滑劑起電絕緣材料的作用。為了獲得最高絕緣性能，潤滑劑中不能含有任何雜質(zhì)和水分。 減振。在象減振器這樣的能量傳遞裝置中和在承受很高的間隙載荷的齒輪這樣的機器零件的周圍，潤滑劑被作為減振液使用。 密封。潤滑脂通常還有一個特殊作用，就是形成密封層以防止?jié)櫥瑒┩鉃a和污染物進入。 潤滑的目的就是為了，減小摩擦力，降低能量損耗，減少機器的熱量產(chǎn)生。熱量就是因為表面的相互間的相對運動造成的。潤滑劑可以是任何一種物質(zhì)，這樣的物質(zhì)被填充到發(fā)生相對運動的兩個表面之間，實現(xiàn)這一目的。大部分的潤滑劑是液體，比如說，油，脂，合成劑等。但它們有時也可能是固體，用在干軸承上，有的用在旋轉(zhuǎn)基體的軸承上，或者也可能是氣體，如空氣等，它是用在空氣軸承上。在潤滑劑和潤滑表面之間這種化學的和物質(zhì)的相互滲入作用，就是為了提供給機器一個良好的工作狀態(tài)。 對潤滑劑邊界的理解，往往是比較硬的，而且是流動的、非常薄的一層帖附在被潤滑的表面。這些表面通常是要發(fā)生相對滑動。有些人推斷，按這種理解，液體的這種化學合成是十分重要的，它們提出了這樣的詞“邊界潤滑”，邊界潤滑是和流體潤滑相對的另一種潤滑。 關于潤滑的五種不同的潤滑形式主要有： （1）無潤滑潤滑劑。 （2）流體膜潤滑。 （3）干潤滑。 （4）邊界潤滑。 （5）固體潤滑。 無潤滑潤滑劑是指軸承的工作表面被一種相對比較厚的液體潤滑劑分隔開，于是阻止了金屬表面的直接接觸，這樣得到的這種穩(wěn)定性就可以用一種理論來解釋：潤滑液在外壓力下工作的理論，盡管這只是一種可能。但確實需要在任何時候都得提供的足夠充分。這種擠壓力是運動表面本身施加給潤滑劑而產(chǎn)生的，當然這仍然是一種可能。這種由運動表面產(chǎn)生的擠壓力產(chǎn)生了必要的壓力來分隔工作表面來抵抗加在軸承上的載荷。所以，這種潤滑也可以被叫做液體潤滑。 還有一種潤滑方式，那是一種特別的潤滑劑，它有時是空氣或水，當加在軸承上的外載荷足夠高時，它就會以一種比較厚的狀態(tài)分隔開相互相對運動的工作表面。所以，不象上面的那種潤滑方式，并不需要兩種工作表面一定發(fā)生相對運動。 第三種潤滑方式是一種現(xiàn)象，這種現(xiàn)象是，一種潤滑劑是用在發(fā)生相對轉(zhuǎn)動的工作表面之間。比如說齒輪或者是滾動軸承。從數(shù)學上的解釋就需要接觸壓力和流體機械的理論。 當軸承不得不在較高的溫度下工作的時候，固體潤滑劑例如合成物等，必須被使用，因為通常使用的潤滑油在這種情況下都不能工作。目前，在這方面的研究正在實施，為了尋找到合成軸承的材料，并且有低損耗和小的熱量產(chǎn)生的性能。 在有的軸承上，搖桿旋轉(zhuǎn)或在軸承上轉(zhuǎn)動，相對運動就是滑動。在一個自鎖的軸承裝置中，這種相對運動就是轉(zhuǎn)動。其他的裝置也可能是旋轉(zhuǎn)或滑動。齒輪的齒嚙合是轉(zhuǎn)動與相對滑動的合成?；钊窍鄬τ趧傮w的滑動，所有的這些應用都需要潤滑劑來減小摩擦，降低能耗，減少熱量的產(chǎn)生。 在有些軸承的應用領域是不太成熟的。有些有連接桿的軸承，比如說汽車發(fā)動機上的，必須在幾千度高的高溫下和各種不同性質(zhì)的載荷下工作。這種軸承用在汽輪發(fā)動設備上可以說是穩(wěn)定性接近100%。還有另一種極端的情況，在有些軸承有幾千種應用，應對各種不同的載荷。其他的輔助設施就相對不重要了。需要的是一個簡單的、容易安裝的軸承。需要很少的甚至是不需要潤滑劑。在這種情況下，有的軸承并不是最好的選擇，因為成本和相近的公差。最近在軸承材料上的研究已有了一定的突破。隨著對潤滑的研究的知識的積累，設計出有良好工作狀況和較高的穩(wěn)定性的軸承已不是很遙遠了。 參考文獻： [1] 錢伯斯 T. L.帕金森 A. R. “知識代表及專家系統(tǒng)的混合轉(zhuǎn)換?！?美國機械工程 師學會，1998，120:468-474. [2] 凱爾其·詹姆斯R.“軟件升壓模具設計效率”的成型系統(tǒng)，1999， 3:16-23. [3] 李榮顯，陳育民，鄒昶,“開發(fā)一個并行模具設計系統(tǒng)：以知識為基礎的辦法”， 計算機集成制造系統(tǒng)，1997，4:287-307. [4] 斯特德曼薩利·佩爾M,“在工程設計專家系統(tǒng)：一種注塑成型的塑料件的應用” 智能制造，發(fā)動機1995，2:347-353. [5] 費爾南德斯A，卡斯塔尼J,賽爾 F, “CAD / CAE 信息的模具和熱塑性塑料注射原 型設計的”信息技術(shù)1997:117-124. [6] 道格拉斯M 布萊斯,“塑料注射成型，材料選擇和產(chǎn)品設計”1997:1-48. [7] 道格拉斯M 布萊斯，“塑料注射成型模具設計基礎”，1997，2:1-120. 外文原文 Reciprocating cutting machine Friction , Lubrication of Bearing In many of the problem thus far , the student has been asked to disregard or neglect friction . Actually , friction is present to some degree whenever two parts are in contact and move on each other. The term friction refers to the resistance of two or more parts to movement. Friction is harmful or valuable depending upon where it occurs. friction is necessary for fastening devices such as screws and rivets which depend upon friction to hold the fastener and the parts together. Belt drivers, brakes, and tires are additional applications where friction is necessary. The friction of moving parts in a machine is harmful because it reduces the mechanical advantage of the device. The heat produced by friction is lost energy because no work takes place. Also , greater power is required to overcome the increased friction. Heat is destructive in that it causes expansion. Expansion may cause a bearing or sliding surface to fit tighter. If a great enough pressure builds up because made from low temperature materials may melt. There are three types of friction which must be overcome in moving parts: (1)starting, (2)sliding, and(3)rolling. Starting friction is the friction between two solids that tend to resist movement. When two parts are at a state of rest, the surface irregularities of both parts tend to interlock and form a wedging action. To produce motion in these parts, the wedge-shaped peaks and valleys of the stationary surfaces must be made to slide out and over each other. The rougher the two surfaces, the greater is starting friction resulting from their movement . Since there is usually no fixed pattern between the peaks and valleys of two mating parts, the irregularities do not interlock once the parts are in motion but slide over each other. The friction of the two surfaces is known as sliding friction. As shown in figure ,starting friction is always greater than sliding friction . Rolling friction occurs when roller devces are subjected to tremendous stress which cause the parts to change shape or deform. Under these conditions, the material in front of a roller tends to pile up and forces the object to roll slightly uphill. This changing of shape , known as deformation, causes a movement of molecules. As a result ,heat is produced from the added energy required to keep the parts turning and overcome friction. The friction caused by the wedging action of surface irregularities can be overcome partly by the precision machining of the surfaces. However, even these smooth surfaces may require the use of a substance between them to reduce the friction still more. This substance is usually a lubricant which provides a fine, thin oil film. The film keeps the surfaces apart and prevents the cohesive forces of the surfaces from coming in close contact and producing heat . Another way to reduce friction is to use different materials for the bearing surfaces and rotating parts. This explains why bronze bearings, soft alloys, and copper and tin iolite bearings are used with both soft and hardened steel shaft. The iolite bearing is porous. Thus, when the bearing is dipped in oil, capillary action carries the oil through the spaces of the bearing. This type of bearing carries its own lubricant to the points where the pressures are the greatest. Moving parts are lubricated to reduce friction, wear, and heat. The most commonly used lubricants are oils, greases, and graphite compounds. Each lubricant serves a different purpose. The conditions under which two moving surfaces are to work determine the type of lubricant to be used and the system selected for distributing the lubricant. On slow moving parts with a minimum of pressure, an oil groove is usually sufficient to distribute the required quantity of lubricant to the surfaces moving on each other . A second common method of lubrication is the splash system in which parts moving in a reservoir of lubricant pick up sufficient oil which is then distributed to all moving parts during each cycle. This system is used in the crankcase of lawn-mower engines to lubricate the crankshaft, connecting rod ,and parts of the piston. A lubrication system commonly used in industrial plants is the pressure system. In this system, a pump on a machine carries the lubricant to all of the bearing surfaces at a constant rate and quantity. There are numerous other systems of lubrication and a considerable number of lubricants available for any given set of operating conditions. Modern industry pays greater attention to the use of the proper lubricants than at previous time because of the increased speeds, pressures, and operating demands placed on equipment and devices. Although one of the main purposes of lubrication is reduce friction, any substance-liquid , solid , or gaseous-capable of controlling friction and wear between sliding surfaces can be classed as a lubricant. Varieties of lubrication Unlubricated sliding. Metals that have been carefully treated to remove all foreign materials seize and weld to one another when slid together. In the absence of such a high degree of cleanliness, adsorbed gases, water vapor ,oxides, and contaminants reduce frictio9n and the tendency to seize but usually result in severe wear; this is called “unlubricated ”or dry sliding. Fluid-film lubrication. Interposing a fluid film that completely separates the sliding surfaces results in fluid-film lubrication. The fluid may be introduced intentionally as the oil in the main bearing of an automobile, or unintentionally, as in the case of water between a smooth tuber tire and a wet pavement. Although the fluid is usually a liquid such as oil, water, and a wide range of other materials, it may also be a gas. The gas most commonly employed is air. Boundary lubrication. A condition that lies between unlubricated sliding and fluid-film lubrication is referred to as boundary lubrication, also defined as that condition of lubrication in which the friction between surfaces is determined by the properties of the surfaces and properties of the lubricant other than viscosity. Boundary lubrication encompasses a significant portion of lubrication phenomena and commonly occurs during the starting and stopping off machines. Solid lubrication. Solid such as graphite and molybdenum disulfide are widely used when normal lubricants do not possess sufficient resistance to load or temperature extremes. But lubricants need not take only such familiar forms as fats, powders, and gases; even some metals commonly serve as sliding surfaces in some sophisticated machines. Function of lubricants Although a lubricant primarily controls friction and ordinarily does perform numerous other functions, which vary with the application and usually are interrelated . Friction control. The amount and character of the lubricant made available to sliding surfaces have a profound effect upon the friction that is encountered. For example, disregarding such related factors as heat and wear but considering friction alone between the same surfaces with on lubricant. Under fluid-film conditions, friction is encountered. In a great range of viscosities and thus can satisfy a broad spectrum of functional requirements. Under boundary lubrication conditions , the effect of viscosity on friction becomes less significant than the chemical nature of the lubricant. Wear control. wear occurs on lubricated surfaces by abrasion, corrosion ,and solid-to-solid contact wear by providing a film that increases the distance between the sliding surfaces ,thereby lessening the damage by abrasive contaminants and surface asperities. Temperature control. Lubricants assist in controlling corrosion of the surfaces themselves is twofold. When machinery is idle, the lubricant acts as a preservative. When machinery is in use, the lubricant controls corrosion by coating lubricated parts with a protective film that may contain additives to neutralize corrosive materials. The ability of a lubricant to control corrosion is directly relatly to the thickness of the lubricant film remaining on the metal surfaces and the chermical composition of the lubricant. Other functions Lubrication are frequently used for purposes other than the reduction of friction. Some of these applications are described below. Power transmission. Lubricants are widely employed as hydraulic fluids in fluid transmission devices. Insulation. In specialized applications such as transformers and switchgear , lubricants with high dielectric constants acts as electrical insulators. For maximum insulating properties, a lubricant must be kept free of contaminants and water. Shock dampening. Lubricants act as shock-dampening fluids in energy transferring devices such as shock absorbers and around machine parts such as gears that are subjected to high intermittent loads. Sealing. Lubricating grease frequently performs the special function of forming a seal to retain lubricants or to exclude contaminants. The object of lubrication is to reduce friction ,wear , and heating of machine pars which move relative to each other. A lubricant is any substance which, when inserted between the moving surfaces, accomplishes these purposes. Most lubricants are liquids(such as mineral oil, silicone fluids, and water),but they may be solid for use in dry bearings, greases for use in rolling element bearing, or gases(such as air) for use in gas bearings. The physical and chemical interaction between the lubricant and lubricating surfaces must be understood in order to provide the machine elements with satisfactory life. The understanding of boundary lubrication is normally attributed to hardy and doubleday , who found the extrememly thin films adhering to surfaces were often sufficient to assist relative sliding. They concluded that under such circumstances the chemical composition of fluid is important, and they introduced the term “boundary lubrication”. Boundary lubrication is at the opposite end of the spectrum from hydrodynamic lubrication. Five distinct of forms of lubrication that may be defined :(a) hydrodynamic; (b)hydrostatic;(c)elastohydrodynamic (d)boundary; (e)solid film. Hydrodynamic lubrication means that the load-carrying surfaces of the bearing are separated by a relatively thick film of lubricant, so as to prevent metal contact, and that the stability thus obtained can be explained by the laws of the lubricant under pressure ,though it may be; but it does require the existence of an adequate supply at all times. The film pressure is created by the moving surfaces itself pulling the lubricant under pressure, though it maybe. The film pressure is created by the moving surface to creat the pressure necessary to separate the surfaces against the load on the bearing . hydrodynamic lubrication is also called full film ,or fluid lubrication . Hydrostatic lubrication is obtained by introducing the lubricant ,which is sometime air or water ,into the load-bearing area at a pressure high enough to separate the surface with a relatively thick film of lubricant. So ,unlike hydrodynanmic lubrication, motion of one surface relative to another is not required . Elasohydrodynamic lubrication is the phenomenon that occurs when a lubricant is introduced between surfaces which are in rolling contact, such as mating gears or rolling bearings. The mathematical explanation requires the hertzian theory of contact stress and fluid mechanics. When bearing must be operated at exetreme temperatures, a solid film lubricant such as graphite or molybdenum disulfide must be use used because the ordinary mineral oils are not satisfactory. Must research is currently being carried out in an effort, too, to find composite bearing materials with low wear rates as well as small frictional coefficients. In a journal bearing, a shaft rotates or oscillates within the bearing , and the relative motion is sliding . in an antifriction bearing, the main relative motion is rolling . a follower may either roll or slide on the cam. Gear teeth mate with each other by a combination of rolling and sliding . pistions slide within their cylinders. All these applications require lubrication to reduce friction ,wear, and heating. The field of application for journal bearing s is immense. The crankshaft and connecting rod bearings of an automotive engine must poerate for thousands of miles at high temperatures and under varying load conditions . the journal bearings used in the steam turbines of power generating station is said to have reliabilities approaching 100 percent. At the other extreme there are thousands of applications in which the loads are light and the service relatively unimportant. a simple ,easily installed bearing is required ,suing little or no lubrication. In such cases an antifriction bearing might be a poor answer because because of the cost, the close ,the radial space required ,or the increased inertial effects. Recent metallurgy developments in bearing materials , combined with increased knowledge of the lubrication process, now make it possible to design journal bearings with satisfactory lives and very good reliabilities. 參考文獻： 1. Chambers T. L., Parkinson A. R., 1998, “Knowledge Representation and Conversion of HybridExpert Systems.” Transactions of the ASME, v 120,pp 468-474 2. Koelsch, James R., 1999, “Software boosts mold design efficiency“ Molding Systems,v57, n 3,p 16-23. 3. Lee, Rong-Shean, Chen, Yuh-Min, Lee, Chang-Zou,1997 “Development of a concurrent molddesign system: A knowledge-based approach”, Computer Integrated Manufacturing Systems, v 10,n 4, p 287-307 4. Steadman Sally, Pell Kynric M, 1995, “ Expert systems in engineering design: An application forinjection molding of plastic parts“ Journal of Intelligent Manufacturing, v6, p 347-353. 5. Fernandez A., Castany J., Serraller F., Javierre C., 1997, “CAD/CAE assistant for the design ofmolds and prototypes for injection of thermoplastics “Information Technological, v 8, p 117-124. 6. Douglas M Bryce, 1997, “Plastic injection molding -Material selection and product design”, v 2,pp 1-48. 7. Douglas M Bryce, 1997, “Plastic injection molding-Mold design fundamentals”, v2, pp 1-120