博碩士論文 90323009 完整後設資料紀錄

DC 欄位 語言
DC.contributor機械工程學系zh_TW
DC.creator吳思漢zh_TW
DC.creatorSzu-han Wuen_US
dc.date.accessioned2009-7-29T07:39:07Z
dc.date.available2009-7-29T07:39:07Z
dc.date.issued2009
dc.identifier.urihttp://ir.lib.ncu.edu.tw:88/thesis/view_etd.asp?URN=90323009
dc.contributor.department機械工程學系zh_TW
DC.description國立中央大學zh_TW
DC.descriptionNational Central Universityen_US
dc.description.abstract漸開線錐形齒輪在空間齒輪機構之應用具有多種組合可能,尤其可應用於小軸交角場合,並具有加工容易、組裝誤差敏感度低、背隙可以控制等優點,為漸開線特殊齒輪中應用最廣的一種。歪斜軸組合之錐形齒輪對由於點接觸的嚙合特性,因此具有低組裝誤差敏感度的優點,然而卻也因此有接觸應力過大的問題,而仍無法廣泛地應用於重負載動力傳動的場合。本研究從幾何設計著手,透過「移位嚙合設計」與「近似線接觸」兩個方法來達到增加接觸斑的面積、從而降低齒面接觸應力的目的。利用錐形齒輪沿齒面寬連續移位之特性,本研究有系統地建立完整計算流程,可以使錐形齒輪嚙合位置改變,而形成正移位嚙合,即以其具有較小主曲率的齒面來進行傳動。另一方面,則透過齒輪參數的設計,使錐形齒輪之接觸斑形成點接觸,但是形狀為扁長之橢圓形式。因此在受負載情況下,接觸斑會因為齒面彈性變形而形成近似於線接觸的型態。此種接觸即為所謂「近似線接觸」。 針對此「近似線接觸」嚙合型態的歪斜軸錐形齒輪對,本研究系統化地分析不同的齒輪參數組合,探討因組裝誤差或加工誤差而發生齒端邊緣接觸的敏感度,以及齒輪參數與齒面承載能力的關係。並根據此分析結果歸納出一「近似線接觸」嚙合的設計方法,包括錐形齒輪對移位嚙合設計流程,以及建議的設計準則。 為了能確實評斷齒面的承載能力,本研究對此近似線接觸設計進行受負載輪齒接觸分析。由於近似線接觸的接觸斑在負載下可超過齒面寬,係屬於非赫茲接觸問題,以及輪齒的彎曲變形會影響其接觸應力分佈。因此本研究首先建立一以漸開線齒輪對的作用線為基礎的嚙合模型,可適用於嚙合齒面之曲率很接近的近似線接觸情況。其次再利用影響係數法的概念發展一齒面接觸應力計算模型。其中不但考慮齒面接觸變形的效應,亦將輪齒彎曲撓曲的影響納入考慮。此齒面接觸應力計算模型可應用於點接觸、線接觸、單齒對嚙合、多齒對嚙合、乃至於具齒面修整之齒面等各種不同的接觸情況。同時並採用有限元素方法來驗證接觸應力計算結果的可靠度。 本文中提供一設計實例,從幾何設計到受負載輪齒接觸分析作一完整地分析和討論。此設計實例的容許組裝誤差、以及容許加工誤差皆符合一般實務應用需求,而且其承載能力亦足夠應用於重負載傳動。使用接觸應力計算模型所得到的結果與有限元素方法的結果誤差約5%,證明此計算模型的可靠度,而且具有比有限元素方法更有效率的優點。 為了驗證此近似線接觸嚙合型態的歪斜軸齒輪對的齒面承載能力適用於重負載傳動,本研究開發一功率封閉型齒輪試驗裝置,實際進行107負載循環齒輪失效檢驗之實驗。被測齒輪的材料為中碳鋼S45C、且進行調質熱處理,但不作表面硬化。實驗以三組齒輪對,分別進行扭矩為200、300、350Nm負載等級(最大接觸應力分別為892、1021、1074 N/mm2)之試驗。由於本實驗屬於高負載低速、錐形齒輪的齒面粗糙度不佳、以及齒輪僅作調質熱處理而無表面硬化處理等因素,齒面破壞的型態除了屬於疲勞破壞的點蝕之外,更嚴重的破壞形式為冷刮痕(cold scoring)或是磨耗(wear)。 針對「近似線接觸」嚙合型態的歪斜軸錐形齒輪對,本研究提出有效且可靠的設計方法、嚙合模型、以及齒面接觸應力計算模型。經過實驗驗證,近似線接觸設計之錐形齒輪對,確實具有更佳的齒面承載能力。 zh_TW
dc.description.abstractOf all the different types of gears, conical gears as the special type of general spatial gearing makes them not only suitable for parallel axis transmission, but also for cases with intersecting or skew axes. However, one of the weak spots of conical gears is less surface durability in spatial applications due to point contact problems, although transmission accuracy is not correspondingly sensitive to assembly error. From the viewpoint of design, this study suggested two concepts to increase the surface durability of conical gears. Skew conical gear drives can be designed as gear pairs, with either “profile-shifted transmission”, or “approximate line contact”. The profile-shifted transmission can give us the possibility to adjust the contact position of a conical gear pair for better tooth contact bearing just only through changing certain gearing or assembly data. On the other hand, an approximate line contact drive has a contact ellipse with a large major-to-minor-axis ratio, which allows it to overcome the weakness of conical gear drives for application in power transmission. This gearing design approach is characterized by reduced edge contact sensitivity and increased surface durability. The edge contact sensitivity that can arise with this kind of gear drive due to assembly or manufacturing errors is evaluated by analyzing the value of the shift of the line of action caused by such errors. The surface durability is evaluated by calculating the Hertz stress. Some guidelines are developed based on the analysis of the influence of the gearing parameters on the edge contact sensitivity and the surface durability made possible using this design approach for conical gear drives in the approximate line contact. An efficient approach for loaded tooth contact analysis (LTCA) of conical gear drives is developed. Two new models are developed for the meshing and contact stress anslyses. This approach differs from conventional TCA methods in that the meshing analysis is based on the line of action characteristic of involute gearing. A numerical method is applied to calculate the contact stress. The non-Hertzian contact problem is solved giving due consideration to the influences of the tooth contact deformation and tooth bending deflection. The approach is not only suitable for application for cases of non-Hertzian contact, but also for practical cases, such as in gear drives with end-relief. A practical example is given to demonstrate the feasibility of the approximate line contact design. The LTCA results of the example are also compared with those of solved by the finite element method (FEM) to which they are in good consistence. Finally, a back-to-back testing equipment was developed for testing the surface fatigue strength of a skew conical gear drive. The objective of the tests was to determine the limited service life (number of load cycles) of the skew conical gear drive in approximate line contact for tooth pitting fatigue failure under several load levels. Three test gear pairs (S45C, hardening and tempering, but no case hardening) with different applied torques were tested: 200 Nm, 300 Nm, and 350 Nm. The results indicated that the surface durability of the approximate line contact design is indeed increased. Furthermore, the kinds of gear surface failures for the test were pitting, cold scuffing, and wear. en_US
DC.subject齒面破壞試驗zh_TW
DC.subject齒面疲勞強度zh_TW
DC.subject錐形齒輪zh_TW
DC.subject受負載輪齒接觸分析zh_TW
DC.subject齒端邊緣接觸zh_TW
DC.subject近似線接觸zh_TW
DC.subjectconical gearen_US
DC.subjectapproximate line contacten_US
DC.subjectedge contacten_US
DC.subjectloaded tooth contact analysisen_US
DC.subjectsurface fatigue strengthen_US
DC.subjectgear tooth surface failureen_US
DC.title近似線接觸型態之歪斜軸漸開線錐形齒輪對齒面接觸強度之研究zh_TW
dc.language.isozh-TWzh-TW
DC.titleContact Strength of a Skew Conical Involute Gear Drive in Approximate Line Contacten_US
DC.type博碩士論文zh_TW
DC.typethesisen_US
DC.publisherNational Central Universityen_US

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