3532 提升機制動系統(tǒng)(液壓盤式制動器)設(shè)計,提升,晉升,機制,系統(tǒng),液壓,制動器,設(shè)計 河南理工大學(xué)萬方科技學(xué)院本科畢業(yè)設(shè)計（論文）中期檢查表指導(dǎo)教師：張 躍 敏 職稱： 副 教 授 所在系部（單位）：機械與動力工程系 教研室（研究室）： 題 目 提升機制動系統(tǒng)的設(shè)計學(xué)生姓名 高金濤 專業(yè)班級 08 機制 04 班 學(xué)號 0828030014一、選題質(zhì)量1）該選題是提升機自動系統(tǒng)的設(shè)計，可以對我們大學(xué)四年所學(xué)知識進行一次全面的綜合能力的練習(xí)，將對我們以后工作起到十分有效的幫助，加強了實際的動手動腦能力。題目的難易程度很適中，對我既是一個挑戰(zhàn)也是一個很好的鍛煉提高過程。2）題目的工作量：要求完成 3.5 張 A0 圖紙，50 頁左右設(shè)計說明書一份。二、開題報告完成情況在指導(dǎo)老師和同學(xué)們的幫助之下，經(jīng)過一番查閱資料，我順利的開始了本次畢業(yè)設(shè)計。雖然我平常生活中經(jīng)常聽說有關(guān)提升絞車的各方面東西，但我對這方面的了解是明顯的不夠多。所以在剛開始不是很順利，甚至無從入手。但經(jīng)過指導(dǎo)老師的引導(dǎo)和在網(wǎng)上查找相關(guān)資料，我逐漸找到了設(shè)計的切入點，順利得完成了開題報告。并有了一定的成果和進行了一些前期的工作，并使本次設(shè)計有了一個良好的開始。最后我在查閱了一些資料以后，現(xiàn)在已經(jīng)進入了計算設(shè)計過程，我將在以后工作中繼續(xù)努力，認真完成這次畢業(yè)設(shè)計。三、階段性成果目前主要有以下成果：1、掌握了提升機基本使用工況，特點2、完成提升機的選型計算3、完成提升機的制動裝置的結(jié)構(gòu)設(shè)計4、完成提升機制動系統(tǒng)的可靠性評定四、存在主要問題由于之前沒有接觸過提升機制動系統(tǒng)設(shè)計，對涉及內(nèi)容了解的不多，前期進展較為緩慢。之后通過大量的查閱資料，對提升機制動系統(tǒng)進行更深入的了解。對多種加工方法的學(xué)習(xí)、選擇入手，并對車床進給系統(tǒng)重新進行了學(xué)習(xí)。在使用 AutoCAD 繪制圖紙時，由于平常操作較少，熟練程度不高，繪制時間較長。五、指導(dǎo)教師對學(xué)生在畢業(yè)實習(xí)中，勞動、學(xué)習(xí)紀律及畢業(yè)設(shè)計（論文）進展等方面的評語指導(dǎo)教師： （簽名）年 月 日河南理工大學(xué)萬方科技學(xué)院1萬方科技學(xué)院 本科畢業(yè)論文（英文翻譯）院（系部） 機械與動力工程系 專業(yè)名稱 機械設(shè)計制造及自動化 年級班級 2008 級機制 04 班 學(xué)生名稱 高 金 濤 指導(dǎo)老師 張 躍 敏 河南理工大學(xué)萬方科技學(xué)院2Reflections regarding uncertainty of measurement, on the results of a Nordic fatigue test interlaboratory comparisonMagnus Holmgren, Thomas Svensson, Erland Johnson, Klas JohanssonAbstract This paper presents the experiences of calculation and reporting uncertainty of measurement in fatigue testing. Six Nordic laboratories performed fatigue tests on steel specimens. The laboratories also reported their results concerning uncertainty of measurement and how they calculated it. The results show large differences in the way the uncertainties of measurement were calculated and reported. No laboratory included the most significant uncertainty source, bending stress (due to misalignment of the testing machine, “incorrect” specimens and/or incorrectly mounted specimens), when calculating the uncertainty of measurement. Several laboratories did not calculate the uncertainty of measurement in accordance with the Guide to the Expression of Uncertainty in Measurement (GUM) [1].Keyword Uncertainty of measurement, Calculation, Report, Fatigue test, Laboratory intercomparisonDefinitions R Stress ratio Fmin/Fmax · F Force (nektons) · A and B Fatigue strength parameters · s and S Stress (megapascals) · N Number of cycles. IntroductionThe correct or best method of calculating and reporting uncertainty of measurement in testing has been the subject of discussion for many years. The issue became even more relevant in connection with the introduction of ISO standards, e.g. ISO17025 [2]. The discussion, as well as implementation of the uncertainty of measurement concept, has often been concentrated on which equation to use or on administrative handling of the issue. There has been less interest in the technical problem and how to handle uncertainty of measurement in the actual experimental situation, and how to learn from the uncertainty of measurement calculation when improving the experimental technique. One reason for this may be that the accreditation bodies have concentrated on the very existence of uncertainty of measurement 河南理工大學(xué)萬方科技學(xué)院3calculations for an accredited test method, instead of on whether the calculations are performed in a sound technical way. The present investigation emphasizes the need for a more technical focus.One testing area where it is difficult to do uncertainty of measurement calculations is fatigue testing. However, there is guidance on how to perform such calculations, e.g. in Refs. [3, 4]. To investigate how uncertainty of measurement calculations are performed for fatigue tests in real life, UTMIS (the Swedish fatigue network) started an interlaboratory comparison where one of the most essential parts was to calculate and report the uncertainty of measurement of a typical fatigue test that could have been ordered by a customer of the participating laboratories. For cost reasons, customers often ask for a limited number of test specimens but, at the same time, they request a lot of information about a large portion of the possible stress-life area [from few cycles (high stresses) to millions of cycles (low stresses) and even run-outs]. The way the calculation was made should also be reported. The outcome concerning the uncertainty of measurement from the project is reported in this article.ParticipantsSix Nordic laboratories participated in the interlaboratory comparison: one industrial laboratory, two research institutes, two university laboratories and one laboratory in a consultancy company. Two of the laboratories are accredited for fatigue testing, and a third laboratory is accredited for other tests. Each participant was randomly assigned a number between 1 and 6, and this notification will be used in the rest of this paper.Experimental procedureThe participants received information about the test specimens (without material data), together with instructions on the way to perform the test and how to report the results.The instructions were that tests should be performed as constant load amplitude tests, with R=0.1 at three different stress levels, 460, 430 and 400 Map, with four specimens at each stress level, at a test frequency between 10 and 30 Hz, with a run-out limit at cycles and in a normal laboratory 6510?climate ( and relative humidity). This was considered as a 023C?%河南理工大學(xué)萬方科技學(xué)院4typical customer ordered test.The test results were to be used to calculate estimates of the two fatigue strength parameters, A and B, according to linear regression of the logs and long variables, i.e. . The reported result should include loglogBN???both the estimated parameters A and B and the uncertainties in them due to measurement errors. The report should also include the considerations and calculations behind the results, especially those concerning uncertainty of measurement.Several properties were to be reported for each specimen. The most important one was the number of cycles until fracture or if the specimen was a run-out (i.e. survived for cycles).6510?The tests were to be performed in accordance with ASTM E-466–96 [5] and ISO5725-2 [6]. ASTM E-466-96 does not take uncertainty of measurement into account;However, ASTM E-466-96 mentions that the bending stress introduced owing to misalignment must not exceed 5% of the greater of the range, maximum or minimum stresses. There are also requirements for the accuracy of the dimensional measurement of the test specimen.All participants used hydraulic testing machines. The test specimens were made of steel (yield stress 375–390 Map, and tensile strength 670–690 Map, tabulated values). The test specimens were distributed to the participants by the organizer.ResultsThe primary laboratory results that should be compared are the estimated Whaler curves. In order to present all results in the same way, the organizer transformed some of the results. The Whaler curves reported by the participants are shown in Fig. 1.It can be seen that there are considerable differences between laboratories. An approximate statistical test shows a significant laboratory effect. Material scatter alone cannot explain the differences in the Whaler curves. In order to investigate if the laboratory effect was solely caused by the modeling uncertainty, we estimated new parameters from the raw data with a 河南理工大學(xué)萬方科技學(xué)院5common algorithm. We then chose to use only the failed specimens and to make the minimization in the logarithmic life direction. The results are shown in Fig. 2. A formal statistical significance test was then made, and the result of such a test shows that the differences between the laboratories shown in Fig. 1 could be attributed only to modeling.Uncertainty of measurement calculationsOne of the most important objectives with this investigation was to compare the observed differences between laboratory test results with their estimated uncertainties of measurement. The intention was to analyze the uncertainty analyses as such, and to compare them to the standard procedure recommended in the ISO guide: Guide to the Expression of Uncertainty in Measurement (GUM) [1].The laboratories identified different sources of uncertainty and treated them in different ways. These sources are the load measurement, the load control, the superimposed bending stresses because of misalignment and the dimensional measurements. Implicitly, laboratory temperature and humidity, specimen temperature and corrosion effects are also considered. In addition, the results show a modeling effect. The different laboratory treatments of these sources are summarized in Table 1.Specific comments on the different laboratoriesAll laboratories gave their laboratory temperature and humidity, but did not consider these values as sources of uncertainty, i.e. the influence of temperature and humidity was neglected. This conclusion is reasonable for steel in the temperature range and humidity range in question [7].Laboratory 1. The uncertainty due to the applied stress was determined taking load cell and dimensional uncertainties into account. The mathematical evaluation was made in accordance with the GUM. Specimen temperature was measured, but was implicitly neglected. The modeling problem was mentioned, but not considered as an uncertainty source. Laboratory 2. The report contains no uncertainty evaluation. The uncertainties in the load cell and the micrometer are considered, but neglected with reference to the large material scatter. Specimen temperature was measured. Modeling problems are mentioned by a comment regarding 河南理工大學(xué)萬方科技學(xué)院6the choice of load levels.Laboratory 3. The report contains no uncertainty evaluation. However, the accuracy of the machine is given and the load was controlled during the tests to be within specified limits. The bending stresses were measured on one specimen, but their influence on the fatigue result was not taken into consideration. Laboratory 4. The uncertainties in the load cell and the dimensional measurements are considered in an evaluation of stress uncertainty. The method for the evaluation is not in accordance with the GUM method, but was performed by adding absolute errors. The bending stress influence and the control system deviations are considered, but not included in the uncertainty evaluation. The failure criterion is mentioned and regarded as negligible, and corrosion is mentioned as a possible source of uncertainty. Laboratory 5. Uncertainties in the load cell and the load control were considered, and the laboratory stated in the report that the evaluation of the load uncertainty was performed according to the CIPM method. Laboratory 6. No report was provided, but only experimental results and a Whaler curve estimate.No laboratory reported the uncertainty in the estimated material properties, the Whaler parameters, but at most the uncertainty in the applied stress. The overall picture of the uncertainty considerations is that only uncertainty sources that are possible to estimate from calibration reports were taken into account in the final evaluation.Fig. 1 All experimental results and estimated Whole curves from the different laboratories河南理工大學(xué)萬方科技學(xué)院7Number of cycles to failureOne important source that several laboratories mentioned is the bending stresses induced by misalignment in the testing machine, incorrectly mounted test specimens or “incorrect” specimens. The amount of bending stress was also estimated in some cases, but its influence on the uncertainty in the final Whole curve was not investigated.The results from this experimental investigation show that there are different ways of determining the Whole curve from the experimental result. One problem is the surviving specimens, the run-out results. Four laboratories used only the failed specimens’ results for the curve-fit, one laboratory neglected all results at the lowest level, and one laboratory included the run-outs in the estimation. Another problem is the mathematical procedure for estimating the curve. Common practice, and the recommendation in the ASTM standard, is that the curve should be estimated by minimizing the squared errors in log life, i.e. the statistical model is河南理工大學(xué)萬方科技學(xué)院8, (1)logllogNabS????Where e is a random error, assumed to have constant variance, and where log stands for the logarithm with base 10. E can be interpreted as the combination of at least two types of errors: namely (1) a random error due to the scatter in the material properties, and (2) a measurement error due to uncertainties in the measurement procedures.Fig. 2 All experimental results and estimated Whole curves using the common procedureNumber of cycles to failureTable 1 Sources of uncertainty and laboratory treatment河南理工大學(xué)萬方科技學(xué)院9C The laboratory report considers the source explicitly or implicitly, N the laboratory report neglects the source, A the laboratory report takes the source into account in the uncertainty of measurement calculationWhere e is a random error, assumed to have constant variance, and where log stands for the logarithm with base 10. E can be interpreted as the combination of at least two types of errors: namely (1) a random error due to the scatter in the material properties, and (2) a measurement error due to uncertainties in the measurement procedures. Stress was minimized, which led to a model discrepancy as discussed in the following.DiscussionExperimental resultsMost laboratories performed estimations of the Whaler curve parameters. Visual comparison of their estimated curves suggests differences, and a statistical test verified the conclusion that there is a statistically significant laboratory effect. A closer study of each participant’s procedure for determining the Whaler curve shows that the differences seem to be caused by different modeling of the curve.Since the test was intended to simulate a customer ordered test, some specific problems occurred. First, the number of test specimens is limited and therefore one should be careful when drawing conclusions from the results, since the scatter is considerable in fatigue and the number of specimens are limited.Another problem that occurred was that, since run-outs were wanted, two different failure criteria (failure mechanisms) were used to halt the test: fracture of the test specimen or cycles. In the latter case, the use of the 6510?equation may cause problems, see later.loglogABN???河南理工大學(xué)萬方科技學(xué)院10The investigator then looked at whether any laboratory differences remained after excluding the model interpretation effects. This was accomplished in two ways:Namely, firstly by direct comparison of the experimental fatigue lives obtained, and secondly by using the same estimating procedure on all data sets. This therefore tested whether any laboratory differences remained or not. The first comparison was done on the two higher load levels. For these, no statistically significant differences were found. The second comparison, which included the failuresOn the lowest level, verified the result. Since the variation between laboratories is larger than the variation within a laboratory no statistically significant variation within a laboratory can be distinguished from the totalVariation in material.The conclusion is that no systematic errors in measurements were detected, but different modeling techniques give significant differences in the results. This in fact indicates that when different fitting models are used different quantities are measured even though they have the same name. Before any agreement is reached about the way of reporting fatigue data, it is of utmost importance that the modeling procedure is clearly defined in the test report. It is very important for the laboratories’ customers to be aware of this fact and, when requesting a test, to ask for a preferred modeling procedure as well as to be aware of the modeling procedure used by the laboratory when using fatigue data in design.Uncertainty evaluationAll laboratories made some considerations regarding the uncertainties of measurement. However, none of them evaluated uncertainties for the resulting Whole parameters, but only for the applied stress. However, none of the measurement uncertainties reported are unrealistic considering the factors taken into account, this is based inexperience. Since the specimens were destroyed during the tests it is not possible to separate the material variation from the repeatability. An estimate of the combined measurement uncertainty and the variation in material isAbout 30% of the lifetime and the major contribution are from the material 河南理工大學(xué)萬方科技學(xué)院11variation and therefore one conclusion is that the measurement uncertainty in this test could be neglected during this test. This is not true for all fatigue tests and it is therefore anyhow interesting to study how the participants treated measurement uncertainty.Only one participant used the method recommended by the ISO guide GUM. This is surprising, since European accreditation authorities have recommended the GUM for several years. Among the uncertainty sources that were identified by the laboratories, only load cell measurement uncertainties and dimensional measurement uncertainties were taken into account. Important sources such as misalignment and load control were identified by some participants but were not included in the evaluation of stress uncertainty. Apparently only calibrated devices were considered for the overall uncertainty, and other sources, more difficult to evaluate, were excluded. No motivation for these exclusions can be found in the reports. One participant rejected the uncertainty evaluation with reference to the large scatter in fatigue lives. Our overall conclusion from the laboratory comparisons, that there are no detectable systematic effects, may be seen as verification of this rejection, but it is questionable if this was an obvious result beforehand. In contrast, for instance, uncertainties due to misalignment are not obviously negligible in comparison with the material scatter, and should be considered in an uncertainty analysis. This investigation, together with other observations [8, 9], shows problems with the introduction of the ISO17025 requirement for uncertainty of measurement statements. The reasons for this may be that the uncertainty of measurement discussion during recent years has concentrated very much on which equation to use and on administrative aspects, e.g. whether the uncertainty of measurement should always be reported directly in the report, or only when the customer requests it, etc., instead of on the ‘real’ technical issues. Hopefully, the introduction of the pragmatic ILAC-G17:2002, a document about the introduction of the concept of uncertainty of measurement in association with testing [10], will improve the situation.ConclusionsThe way to define, calculate, and interpret uncertainty of measurement 河南理工大學(xué)萬方科技學(xué)院12and to use it in Whaler-curve determination is poorly understood among the participants, in spite of the fact that they consist of a group with significant experienceOf fatigue testing, and that some of them were also accredited for fatigue tests. An important overall tendency is that the laboratories only include uncertaintySources that are easily obtained, e.g. from calibrated gauges where calibration certificates exist.關(guān)于北歐的疲勞實驗室的比較—測量結(jié)果不確定值的反映摘要：這篇論文介紹了關(guān)于疲勞檢測的不確定性的計算和報告的實驗。6 個北歐實驗室對鋼性元件進行了疲勞實驗，他們也報告了疲勞測量不確定性的結(jié)果和計算方法。實驗結(jié)果表明大量的測量不確定性結(jié)果是可以計算和報告的。沒有實驗室包括最重要的不確定源，當它們進行不確定值的計算時，有幾個實驗室沒有計算符合從指導(dǎo)到結(jié)果的測量的不確定性值。關(guān)鍵詞：測量，計算，不確定性報告，疲勞測試，聯(lián)合實驗室介紹：計算和報告測量的不確定性值的最好或者正確的方法一直是許多年來討論的問題,隨著 ISO(例如 ISO17025)的引進這個問題更加突出。關(guān)于測量的不確定性值的討論和鑒定與這個問題息息相關(guān)。在發(fā)展實驗技術(shù)的時候已經(jīng)有很少人對技術(shù)問題和在實驗條件下如何處理測量的不確定性值和如何從測量的不確定性值可以學(xué)到什么感興趣了。這種現(xiàn)象可能的一個原因是合格的物體已經(jīng)集中在用精確的方法計算測量的不確定性值上，而不是集中在用這種方法是不是合理的問題上了。目前的方法集中在一種更加科學(xué)的方法上。對測量的不確定性值計算比較困難的一個領(lǐng)域是疲勞測量。但是，對于這樣的計算有一個指導(dǎo)，研究如何確定測量不確定性值的方法是研究現(xiàn)實生活中物體的疲勞檢測。瑞典疲勞網(wǎng)站開設(shè)了一家聯(lián)合實驗室公司，它的最重要的一部分就是計算和報告重要疲勞實驗的不確定性值，這些實驗是由實驗室的參與者進行的。最重要的原因是顧客們索要有限個測量模型，同時，他們也需要大量的信息。所用的計算方法也要報告，河南理工大學(xué)萬方科技學(xué)院13關(guān)于工程測量的不確定性值的結(jié)果也在這篇文章中報告。六個北歐的實驗室都參加了這個聯(lián)合實驗室，一個工業(yè)實驗室，兩個研究院，兩個大學(xué)實驗室，一個咨詢公司實驗室。其中兩個實驗室研究疲勞實驗，第三個研究其他的實驗，每個參與者被隨意指派 1—6 的編號，這個報告被用在這篇文章的其他部分。實驗程序：參與者收到了沒有數(shù)據(jù)的材料模型，及其如何進行測量和如何報告結(jié)果的信息。要求是在固定載荷下進行多次實驗，用半徑為 1mm 的在三種壓力（460，430，400MP）下，每種壓力下都進行試驗的 4 種模型，頻率在 10---30Hz 之間，在室溫下旋轉(zhuǎn) 5 百萬轉(zhuǎn)。這就是客戶要求的測量。這種測量結(jié)果被用來計算兩個物體的疲勞增長的參數(shù)，A 和 B,和由于測量錯誤而引起的不確定性值，報告的結(jié)果應(yīng)該包括 A 和 B 的結(jié)果和這種不確定性值，在結(jié)果的后面尤其是這些不確定性值每個模型的這幾種特性都應(yīng)該報告。最重要的是模型達到疲勞時的周期數(shù)，或者是模型報廢的周期數(shù)。做這個測量時 ASTM E-466-96、ISO-5725-2.、ASTM E-466-96 并沒有考慮到測量的不確定性值，由于誤差不能超過最大和最小值的范圍的百分之五，所以，ASTM-466-96 參照彎曲壓力，對模型的測量也有一些精度要求。所有的參加者都用液壓疲勞機，測量模型是由鋼制成的，它的表面的壓力范圍是 375-390Mp,拉伸力壓強的范圍是670-690Mp.測量模型由組織者分發(fā)給參加者。結(jié)果：為了用同一種方法表示出所有的結(jié)果，初級實驗結(jié)果應(yīng)該用 Whole表格來進行比較，參與者報告的 Whole 表格見圖 1。它顯示了各實驗室之間的顯著的差別。一個大概統(tǒng)計的實驗結(jié)果表明了各實驗室的顯著差別，分散的材料不能單獨解釋 Whole 表格的區(qū)別，為了研究各實驗室的差別是否是因為模型的不確定造成的，我們比較了由原始數(shù)據(jù)得出的新數(shù)據(jù)，當我們使用那些不合格的模型時，對結(jié)果進行對數(shù)運算后，結(jié)果如 2 圖所示。以