外文翻譯如何延長軸承壽命

1、如如何何延延長長軸軸承承壽壽命命摘要： 自然界苛刻的工作條件會(huì)導(dǎo)致軸承的失效，但是如果遵循一些簡單的規(guī)那么，軸承正常運(yùn)轉(zhuǎn)的時(shí)機(jī)是能夠被提高的。在軸承的使用過程當(dāng)中，過分的無視會(huì)導(dǎo)致軸承的過熱現(xiàn)象，也可能使軸承不能夠再被使用，甚至完全的破壞。但是一個(gè)被損壞的軸承，會(huì)留下它為什么被損壞的線索。通過一些細(xì)致的偵察工作，我們可以采取行動(dòng)來防止軸承的再次失效。關(guān)鍵詞： 軸承 失效 壽命導(dǎo)致軸承失效的原因很多，但常見的是不正確的使用、污染、潤滑劑使用不當(dāng)、裝卸或搬運(yùn)時(shí)的損傷及安裝誤差等。診斷失效的原因并不困難，因?yàn)楦鶕?jù)軸承上留下的痕跡可以確定軸承失效的原因。然而，當(dāng)事后的調(diào)查分析提供出珍貴的信息時(shí)，最好首

2、先通過正確地選定軸承來完全防止失效的發(fā)生。為了做到這一點(diǎn)，再考察一下制造廠商的尺寸定位指南和所選軸承的使用特點(diǎn)是非常重要的。1 軸承失效的原因在球軸承的失效中約有40%是由灰塵、臟物、碎屑的污染以及腐蝕造成的。污染通常是由不正確的使用和不良的使用環(huán)境造成的，它還會(huì)引起扭矩和噪聲的問題。由環(huán)境和污染所產(chǎn)生的軸承失效是可以預(yù)防的，而且通過簡單的肉眼觀察是可以確定產(chǎn)生這類失效的原因。通過失效后的分析可以得知對(duì)已經(jīng)失效的或?qū)⒁У妮S承應(yīng)該在哪些方面進(jìn)行查看。弄清諸如剝蝕和疲勞破壞一類失效的機(jī)理，有助于消除問題的根源。只要使用和安裝合理，軸承的剝蝕是容易防止的。剝蝕的特征是在軸承圈滾道上留有由沖擊載荷

3、或不正確的安裝產(chǎn)生的壓痕。剝蝕通常是在載荷超過材料屈服極限時(shí)發(fā)生的。如果安裝不正確從而使某一載荷橫穿軸承圈也會(huì)產(chǎn)生剝蝕。軸承圈上的壓坑還會(huì)產(chǎn)生噪聲、振動(dòng)和附加扭矩。類似的一種缺陷是當(dāng)軸承不旋轉(zhuǎn)時(shí)由于滾珠在軸承圈間振動(dòng)而產(chǎn)生的橢圓形壓痕。這種破壞稱為低荷振蝕。這種破壞在運(yùn)輸中的設(shè)備和不工作時(shí)仍振動(dòng)的設(shè)備中都會(huì)產(chǎn)生。此外，低荷振蝕產(chǎn)生的碎屑的作用就象磨粒一樣，會(huì)進(jìn)一步損害軸承。與剝蝕不同，低荷振蝕的特征通常是由于微振磨損腐蝕在潤滑劑中會(huì)產(chǎn)生淡紅色。消除振動(dòng)源并保持良好的軸承潤滑可以防止低荷振蝕。給設(shè)備加隔離墊或?qū)Φ鬃M(jìn)行隔離可以減輕環(huán)境的振動(dòng)。另外在軸承上加一個(gè)較小的預(yù)載荷不僅有助于滾珠和軸承圈保

4、持緊密的接觸，并且對(duì)防止在設(shè)備運(yùn)輸中產(chǎn)生的低荷振蝕也有幫助。造成軸承卡住的原因 是缺少內(nèi)隙、潤滑不當(dāng)和載荷過大。在卡住之前，過大的摩擦 和熱量使軸承鋼軟化。 過熱的軸承通常會(huì)改變顏色，一般會(huì)變成藍(lán)黑色或淡黃色。摩擦 還會(huì)使保持架受力，這會(huì)破 壞支承架，并加速軸承的失效。材料過早出現(xiàn)疲勞破壞是由重載后過大的預(yù)載引起的。如果這些條件不可防止，就應(yīng)仔細(xì)計(jì)算軸承壽命，以制定一個(gè)維護(hù)方案。另一個(gè)解決方法是更換材料。假設(shè)標(biāo)準(zhǔn)的軸承材料不能保證足夠的軸承壽命，就應(yīng)當(dāng)采用特殊的材料。另外，如果這個(gè)問題是由于載荷過大造成的，就應(yīng)該采用抗載能力更強(qiáng)或其他結(jié)構(gòu)的軸承。蠕動(dòng)不象過早疲勞那樣普遍。軸承的蠕動(dòng)是由于軸和內(nèi)

5、圈之間的間隙過大造成的。蠕動(dòng)的害處很大，它不僅損害軸承，也破壞其他零件。蠕動(dòng)的明顯特征是劃痕、擦痕或軸與內(nèi)圈的顏色變化。為了防止蠕動(dòng)，應(yīng)該先用肉眼檢查一下軸承箱件和軸的配件。，軸承就會(huì)過早地失效。檢查潤滑劑的污染比檢查裝配不正或蠕動(dòng)要困難得多。污染的特征是使軸承過早的出現(xiàn)磨損。潤滑劑中的固體雜質(zhì)就象磨粒一樣。如果滾珠和保持架之間潤滑不良也會(huì)磨損并削弱保持架。在這種情況下，潤滑對(duì)于完全加工形式的保持架來說是至關(guān)重要的。相比之下，帶狀或冠狀保持架能較容易地使?jié)櫥瑒┑竭_(dá)全部外表。銹是濕氣污染的一種形式，它的出現(xiàn)常常說明材料選擇不當(dāng)。如果某一材料經(jīng)檢驗(yàn)適合工作要求，那么防止生銹的最簡單的方法是給軸承包

6、裝起來，直到安裝使用時(shí)才翻開包裝。2 防止失效的方法解決軸承失效問題的最好方法就是防止失效發(fā)生。這可以在選用過程中通過考慮關(guān)鍵性能特征來實(shí)現(xiàn)。這些特征包括噪聲、起動(dòng)和運(yùn)轉(zhuǎn)扭矩、剛性、非重復(fù)性振擺以及徑向和軸向間隙。扭矩要求是由潤滑劑、保持架、軸承圈質(zhì)量 彎曲局部的圓度和外表加工質(zhì)量 以及是否使用密封或遮護(hù)裝置來決定。潤滑劑的粘度必須認(rèn)真加以選擇，因?yàn)椴贿m宜的潤滑劑會(huì)產(chǎn)生過大的扭矩，這在小型軸承中尤其如此。另外，不同的潤滑劑的噪聲特性也不一樣。舉例來說，潤滑脂產(chǎn)生的噪聲比潤滑油大一些。因此，要根據(jù)不同的用途來選用潤滑劑。在軸承轉(zhuǎn)動(dòng)過程中，如果內(nèi)圈和外圈之間存在一個(gè)隨機(jī)的偏心距，就會(huì)產(chǎn)生與凸輪運(yùn)動(dòng)

7、非常相似的非重復(fù)性振擺 NRR。保持架的尺寸誤差和軸承圈與滾珠的偏心都會(huì)引起NRR。和重復(fù)性振擺不同的是， NRR 是沒有方法進(jìn)行補(bǔ)償?shù)?。在工業(yè)中一般是根據(jù)具體的應(yīng)用來選擇不同類型和精度等級(jí)的軸承。例如，當(dāng)要求 振擺最小時(shí)，軸承的非重復(fù)性振擺不能超過0.3 微米。同樣，機(jī)床主軸只能容許最小的振 擺，以保證切削精度。因此在機(jī)床的應(yīng)用中應(yīng)該使用非重復(fù)性振擺較小的軸承。在許多工業(yè)產(chǎn)品中，污染是不可防止的，因此常用密封或遮護(hù)裝置來保護(hù)軸承，使其免受灰塵或臟物的侵蝕。但是，由于軸承內(nèi)外圈的運(yùn)動(dòng)，使軸承的密封不可能到達(dá)完美的程度，因此潤滑油的泄漏和污染始終是一個(gè)未能解決的問題。一旦軸承受到污染，潤滑劑就要

8、變質(zhì)，運(yùn)行噪聲也隨之變大。如果軸承過熱，它將會(huì)卡住。當(dāng)污染物處于滾珠和軸承圈之間時(shí)，其作用和金屬外表之間的磨粒一樣，會(huì)使軸承磨損。采用密封和遮護(hù)裝置來擋開臟物是控制污染的一種方法。噪聲是反映軸承質(zhì)量的一個(gè)指標(biāo)。軸承的性能可以用不同的噪聲等級(jí)來表示。噪聲的分析是用安德遜計(jì)進(jìn)行的，該儀器在軸承生產(chǎn)中可用來控制質(zhì)量，也可對(duì)失效的軸承進(jìn)行分析。將一傳感器連接在軸承外圈上，而內(nèi)圈在心軸以 1800r/min 的轉(zhuǎn)速旋轉(zhuǎn)。測(cè)量噪聲的單位為anderon。即用um/rad 表示的軸承位移。根據(jù)經(jīng)驗(yàn)，觀察者可以根據(jù)聲音區(qū)分出微小的缺陷。例如，灰塵產(chǎn)生的是不規(guī)那么的劈啪聲；滾珠劃痕產(chǎn)生一種連續(xù)的爆破聲，確定這種

9、劃痕最困難；內(nèi)圈損傷通常產(chǎn)生連續(xù)的高頻噪聲，而外圈損傷那么產(chǎn)生一種間歇的聲音。軸承缺陷可以通過其頻率特性進(jìn)一步加以鑒定。通常軸承缺陷被分為低、中、高三個(gè)波段。缺陷還可以根據(jù)軸承每轉(zhuǎn)動(dòng)一周出現(xiàn)的不規(guī)那么變化的次數(shù)加以鑒定。低頻噪聲是長波段不規(guī)那么變化的結(jié)果。軸承每轉(zhuǎn)一周這種不規(guī)那么變化可出現(xiàn)1.610 次，它們是由各種干預(yù) 例如 軸承圈滾道上的凹坑 引起的。可發(fā)覺的凹坑是一種制造缺陷，它是在制造過程中由于多爪卡盤夾的太緊而形成的。中頻噪聲的特征是軸承每旋轉(zhuǎn)一周不規(guī)那么變化出現(xiàn) 1060 次。這種缺陷是由在軸承圈和滾珠的磨削加工中出現(xiàn)的振動(dòng)引起的。軸承每旋轉(zhuǎn)一周高頻不規(guī)那么變化出現(xiàn) 60300次，

10、它說明軸承上存在著密集的振痕或大面積的粗糙不平。利用軸承的噪聲特性對(duì)軸承進(jìn)行分類，用戶除了可以確定大多數(shù)廠商所使用的 ABEC標(biāo)準(zhǔn)外，還可確定軸承的噪聲等級(jí)。 ABEC 標(biāo)準(zhǔn)只定義了諸如孔、外徑、振擺等尺寸公差。隨著ABEC 級(jí)別的增加從3 增到9，公差逐漸變小。但ABEC 等級(jí)并不能反映其他軸承特性，如軸承圈質(zhì)量、粗糙度、噪聲等。因此，噪聲等級(jí)的劃分有助于工業(yè)標(biāo)準(zhǔn)的改良。畢業(yè)設(shè)計(jì)論文外文翻譯原文EXTENDING BEARING LIFEAbstract：Nature works hard to destroy bearings, but their chances of survival

11、can be improved by following a few simple guidelines. Extreme neglect in a bearing leads to overheating and possibly seizure or, at worst, an explosion. But even a failed bearing leaves clues as to what went wrong. After a little detective work, action can be taken to avoid a repeat performance.Keyw

12、ords: bearings failures lifeBearings fail for a number of reasons，but the most common are misapplication，contamination，improper lubricant，shipping or handling damage，and misalignment. The problem is often not difficult to diagnose because a failed bearing usually leaves telltale signs about what wen

13、t wrongHowever，while a postmortem yields good information，it is better to avoid the process altogether by specifying the bearing correctly in The first placeTo do this，it is useful to review the manufacturers sizing guidelines and operating characteristics for the selected bearing.Equally critical i

14、s a study of requirements for noise, torque, and runout, as well as possible exposure to contaminants, hostile liquids, and temperature extremes. This can provide further clues as to whether a bearing is right for a job.1 Why bearings failAbout 40% of ball bearing failures are caused by contaminatio

15、n from dust, dirt, shavings, and corrosion. Contamination also causes torque and noise problems, and is often the result of improper handling or the application environmentFortunately, a bearing failure caused by environment or handling contamination is preventable，and a simple visual examination ca

16、n easily identify the causeConducting a postmortem il1ustrates what to look for on a failed or failing bearingThen，understanding the mechanism behind the failure, such as brinelling or fatigue, helps eliminate the source of the problem.Brinelling is one type of bearing failure easily avoided by prop

17、er handing and assembly. It is characterized by indentations in the bearing raceway caused by shock loadingsuch as when a bearing is dropped-or incorrect assembly. Brinelling usually occurs when loads exceed the material yield point(350,000 psi in SAE 52100 chrome steel)It may also be caused by impr

18、oper assembly, Which places a load across the racesRaceway dents also produce noise，vibration，and increased torque.A similar defect is a pattern of elliptical dents caused by balls vibrating between raceways while the bearing is not turningThis problem is called false brinelling. It occurs on equipm

19、ent in transit or that vibrates when not in operation. In addition, debris created by false brinelling acts like an abrasive, further contaminating the bearing. Unlike brinelling, false binelling is often indicated by a reddish color from fretting corrosion in the lubricant.False brinelling is preve

20、nted by eliminating vibration sources and keeping the bearing well lubricated. Isolation pads on the equipment or a separate foundation may be required to reduce environmental vibration. Also a light preload on the bearing helps keep the balls and raceway in tight contact. Preloading also helps prev

21、ent false brinelling during transit.Seizures can be caused by a lack of internal clearance, improper lubrication, or excessive loading. Before seizing, excessive, friction and heat softens the bearing steel. Overheated bearings often change color，usually to blue-black or straw coloredFriction also c

22、auses stress in the retainer，which can break and hasten bearing failurePremature material fatigue is caused by a high load or excessive preloadWhen these conditions are unavoidable，bearing life should be carefully calculated so that a maintenance scheme can be worked outAnother solution for fighting

23、 premature fatigue is changing materialWhen standard bearing materials，such as 440C or SAE 52100，do not guarantee sufficient life，specialty materials can be recommended. In addition，when the problem is traced back to excessive loading，a higher capacity bearing or different configuration may be usedC

24、reep is less common than premature fatigueIn bearingsit is caused by excessive clearance between bore and shaft that allows the bore to rotate on the shaftCreep can be expensive because it causes damage to other components in addition to the bearing0ther more likely creep indicators are scratches，sc

25、uff marks，or discoloration to shaft and boreTo prevent creep damage，the bearing housing and shaft fittings should be visually checkedMisalignment is related to creep in that it is mounting relatedIf races are misaligned or cockedThe balls track in a noncircumferencial pathThe problem is incorrect mo

26、unting or tolerancing，or insufficient squareness of the bearing mounting siteMisalignment of more than 1/4can cause an early failureContaminated lubricant is often more difficult to detect than misalignment or creepContamination shows as premature wearSolid contaminants become an abrasive in the lub

27、ricantIn addition。insufficient lubrication between ball and retainer wears and weakens the retainerIn this situation，lubrication is critical if the retainer is a fully machined typeRibbon or crown retainers，in contrast，allow lubricants to more easily reach all surfaces Rust is a form of moisture con

28、tamination and often indicates the wrong material for the applicationIf the material checks out for the job，the easiest way to prevent rust is to keep bearings in their packaging，until just before installation2 Avoiding failuresThe best way to handle bearing failures is to avoid themThis can be done

29、 in the selection process by recognizing critical performance characteristicsThese include noise，starting and running torque，stiffness，nonrepetitive runout，and radial and axial playIn some applications, these items are so critical that specifying an ABEC level alone is not sufficientTorque requireme

30、nts are determined by the lubricant，retainer，raceway quality(roundness cross curvature and surface finish)，and whether seals or shields are usedLubricant viscosity must be selected carefully because inappropriate lubricant，especially in miniature bearings，causes excessive torqueAlso，different lubric

31、ants have varying noise characteristics that should be matched to the application. For example，greases produce more noise than oilNonrepetitive runout(NRR)occurs during rotation as a random eccentricity between the inner and outer races，much like a cam actionNRR can be caused by retainer tolerance o

32、r eccentricities of the raceways and ballsUnlike repetitive runout, no compensation can be made for NRR.NRR is reflected in the cost of the bearingIt is common in the industry to provide different bearing types and grades for specific applicationsFor example，a bearing with an NRR of less than 0.3um

33、is used when minimal runout is needed，such as in diskdrive spindle motorsSimilarly，machinetool spindles tolerate only minimal deflections to maintain precision cutsConsequently, bearings are manufactured with low NRR just for machine-tool applicationsContamination is unavoidable in many industrial p

34、roducts，and shields and seals are commonly used to protect bearings from dust and dirtHowever，a perfect bearing seal is not possible because of the movement between inner and outer racesConsequently，lubrication migration and contamination are always problemsOnce a bearing is contaminated, its lubric

35、ant deteriorates and operation becomes noisierIf it overheats，the bearing can seizeAt the very least，contamination causes wear as it works between balls and the raceway，becoming imbedded in the races and acting as an abrasive between metal surfacesFending off dirt with seals and shields illustrates

36、some methods for controlling contaminationNoise is as an indicator of bearing qualityVarious noise grades have been developed to classify bearing performance capabilitiesNoise analysis is done with an Anderonmeter, which is used for quality control in bearing production and also when failed bearings

37、 are returned for analysis. A transducer is attached to the outer ring and the inner race is turned at 1,800rpm on an air spindle. Noise is measured in andirons, which represent ball displacement in m/rad.With experience, inspectors can identify the smallest flaw from their sound. Dust, for example,

38、 makes an irregular crackling. Ball scratches make a consistent popping and are the most difficult to identify. Inner-race damage is normally a constant high-pitched noise, while a damaged outer race makes an intermittent sound as it rotates.Bearing defects are further identified by their frequencie

39、s. Generally, defects are separated into low, medium, and high wavelengths. Defects are also referenced to the number of irregularities per revolution.Low-band noise is the effect of long-wavelength irregularities that occur about 1.6 to 10 times per revolution. These are caused by a variety of inco

40、nsistencies, such as pockets in the race. Detectable pockets are manufacturing flaws and result when the race is mounted too tightly in multiplejaw chucks.Medium-hand noise is characterized by irregularities that occur 10 to 60 times per revolution. It is caused by vibration in the grinding operatio

41、n that produces balls and raceways. High-hand irregularities occur at 60 to 300 times per revolution and indicate closely spaced chatter marks or widely spaced, rough irregularities.Classifying bearings by their noise characteristics allows users to specify a noise grade in addition to the ABEC stan

42、dards used by most manufacturers. ABEC defines physical tolerances such as bore, outer diameter, and runout. As the ABEC class number increase (from 3 to 9), tolerances are tightened. ABEC class, however, does not specify other bearing characteristics such as raceway quality, finish, or noise. Hence

43、, a noise classification helps improve on the industry standard.付：外文翻譯CuttiingTool Geometrgy Shape of cutting tools ,particularyn the angles ,and tool material are very important factors. Angles determine greatiy not only tool life butfinish quality as well.general principles upon which cutting tool

44、 angles are based do not depend on the particular tool .basically ,the same considerations hold ture whether a lather tool ,a milling cutter,a drill,or even a grinding wheel are being designed.Since,however,the lathe(turnign)tool,depicted in Fig. Tool features have been identified by mant names.Thet

45、echnical literature is full of confusingterminology.Thus in the attempt to clear p existing disorganized conceptions and nomenclature,the American Society of Mechanical Engineers published ASA Standard B5-22-1950.What follows is based on it. A single-point tool is a cutting tool having one face and

46、one continuous cutting edge.Tool angles idingtified in Fig.18.2 are as follows: Tool angle 1,on front view,is the back-rake angle. It is the angle between the tool face and a line parallel to the base of theshank in a longitudinal plane perpendicular to the tool base.When this angle isdownward from

47、front to rear of the cutting edge,the rake ispositive;when upward from front to back, the rake is negative; This angle is most sgnnificant in the machining process, because it directly affects the cutting force, finesh,and tool life. The side-rake angle, numbered 2, measures the slope of the face on

48、 a cross plane perpendiclar to the tool base. It, also, is an important angle, because it directs chip flow to the side of the tool post and permits the tool to feed more easily into the work. The end-relief angle is measured between a line perpendicular to the base and the end flank immediately bel

49、ow the end cutting edge ;it is numbered 3 in the figure .It provides clearance between work and tool so that its crt surface can flow by with minium rubbing against the tool.To save time ,a portion of the end flank of the tool may sometimes be left unground, having been previously forged to size. In

50、 such case,this end-clearance angle, numbered 4, measured to the end flank surface below the ground portion, would be larger than the relief angle. Often the end cutting edge is oblique to the flank. The relief angle is then best measured in plane mormal to the end cutting edge angle.Relief also expressed as viewed from side and end of the tool. The side-relief angle, indicated as 5, is measured between the side flank, just below the tutting edge, and a line through the cutting edge perpendicular to the base of the tool. This clearance permits the tool to advance