連桿機構運動分析 ������ 上海申弘閥門有限公司 ABSTRACT: ������In this paper, it had predominantly discussed ������swing-type feeding mechanism for design of the model by Math ������CAD software, and takes it as the example typically; it also ����focused on contemporary international research on the swing type �����feeding mechanism, contributing original views on the scope ���������of its analytical procedure. By the kinetics standpoint it had built �����up a position expression type of the link mechanism, in addition, �������explained clearly the automatic computation its data of ���movement analysis and the result process in graph, finally, there �����alization method about the link mechanism movement simulation had been introduced. KEY WORDS: link mechanism; math CAD; slipper block; movement analysis; simulation. I. INTRODUCTION ������Over the past few decades, engineering schools have ������placed a high priority on incorporating computer technology �������into the engineering curriculum and this has been no incidental achievement ������Specially, this article take swings feeds in the analysis of ����mechanism as an example, introduced using the Math CAD ������software to carry on the movement analysis and the ��������simulation method to analyze the swing-type feeding �����mechanism, and explain the theories analytical method of ��������these type of engineering problem thereby. ����II. MOVEMENT ANALYSIS OF LINK MECHANISM ���������This swing-type feeding in the mechanism, the anti clock �������wise rate of angular motion of original moving parts is:ω1= 40rad/s ,and its structure with various components ����size as shown in Fig.1.In Fig.1 above the swing-type feeding in the mechanisms consist of the crank original moving parts 1 i.e. _grade �������pole group and the _ grade pole group. In which, component2 and component 3 is belong to the RRR type of _ grade ���������pole group; but the component 4 and component 5 is belong �������to the RRP type of _ grade pole group. Using the tool �������platform of the MathCAD software to analyze the original �������moving parts and The move position relationship of _ grade ������pole group separay; and establishes its various hinge ������points the position relational expression, according to the �������above and solution mechanism movement analysis result �����III. LINK MECHANISM MOVEMENT SIMULATION ������The mechanism simulation is changed by the quantity off �����rame variable into to realize In the MathCAD soft �������ware environment. The frame is an internal variable in Math CAD, ���what it represents is the static picture frame serial number, �����and according to convention from zero start. Through the �������computation production continual serial number picture frame ������broadcast, it may produce the mechanism animation simulation results. IV. CONCLUSIONS �����Simulation by MathCAD, our new heuristic for extreme �����programming, is the solution to all of these obstacles about ������dynamic analysis in swing-type feeding mechanism. �������By incorporating and combining the calculations, graphs, �������text and images in the paper above, the MathCAD enables us ����knowledge capture、movement design and aid management �����of engineering analysis projects, and the dynamic simulate ��������or demonstrates high integrity of accuracy while compressing computational time. Moreover, the frame animation in simulating for step loads, changing input time varying quantity, stability, and steady state transient analysis for expediting design completion, and optimizing on the dimensions or size of cost efficiency. In fact, the main contribution of our work is that we introduced a system for swing-type feeding mechanism with MathCAD software. The investigation of dynamic analysis in animation is more theoretical than ever, and our approach helps our Research Team to do just that. Although there were a few disadvantages associated with the others, in the opinion of us those disadvantages were more than offset by the numerous advantages provided by MathCAD. The MathCAD is the industry standard technical calculation tool for engineer’s world wide; it provides powerful combination of rapid solution prototyping and experimentation in analysis of mechanism. IV. CONCLUSIONS �������Simulation by MathCAD, our new heuristic for extreme �������programming, is the solution to all of these obstacles about ��������dynamic analysis in swing-type feeding mechanism.By incorporating and combining the calculations, graphs,text and images in the paper above, the MathCAD enables us ���knowledge capture、movement design and aid management ����of engineering analysis projects, and the dynamic simulator ��������demonstrates high integrity of accuracy while compressing ������computational time. Moreover, the frame animation in �������simulating for step loads, changing input time varying ������quantity, stability, and steady state transient analysis for ����expediting design completion, and optimizing on the �����dimensions or size of cost efficiency.In fact, the main contribution of our work is that we �����introduced a system for swing-type feeding mechanism with ������MathCAD software. The investigation of dynamic analysis ����in animation is more theoretical than ever, and our approach �����helps our Research Team to do just that.Although there were a few disadvantages associated with ����the others, in the opinion of us those disadvantages were �����more than offset by the numerous advantages provided by ������MathCAD. The MathCAD is the industry standard technical �����calculation tool for engineer’s world wide; it provides a ���������powerful combination of rapid solution prototyping and ����experimentation in analysis of mechanism. 譯文: 基于對Mathcad的連桿機構運動分析 摘要: �������本文主要討論了擺動式送料機構的CAD軟件數學模型設計,并作為例子,它通常也對當代上的搖擺式送料機構的研究重點,促進上的獨到見解其分析程序的范圍。由動力學的角度來看,它已建立了鏈接機制的立場表達類型,此外,解釋清楚自動計算其運動分析數據和圖中的結果的過程,后,已經有alization方法對連桿機構運動仿真介紹。上海申弘閥門有限公司主營閥門有:減壓閥(氣體減壓閥,可調式減壓閥,波紋管減壓閥,活塞式減壓閥,蒸汽減壓閥,先導式減壓閥,空氣減壓閥,氮氣減壓閥,水用減壓閥,自力式減壓閥,比例減壓閥)、安全閥、保溫閥、低溫閥、球閥、截止閥、閘閥、止回閥、蝶閥、過濾器、放料閥、隔膜閥、旋塞閥、柱塞閥、平衡閥、調節閥、疏水閥、管夾閥、排污閥、排氣閥、排泥閥、氣動閥門、電動閥門、高壓閥門、中壓閥門、低壓閥門、水力控制閥、真空閥門、襯膠閥門、襯氟閥門。關鍵詞:鏈接機制;數學CAD;拖鞋塊;運動分析;模擬。 關鍵詞:鏈接機制;數學CAD;拖鞋塊;運動分析;模擬。
一導言
����在過去的幾十年中,工程學校工程課程納入計算機技術放在一個高度優先事項,這一直是noincidental成就。
��������特別,本文在分析機制作為一個例子波動飼料,使用數學CAD軟件進行運動分析和介紹模擬方法,分析了擺動式送料機構,并解釋這些工程問題的類型,從而理論的分析方法。
二連桿機構的運動分析
����這種機制的擺動式飼養,反時鐘原來的運動部件的角運動的明智率是:ω1=40rad/秒,并與各部件的結構。
上述機制的擺動式飼養的規模包括移動部件的曲軸原1即等級���������桿組和_級桿組。其中,分量2和第3部分是屬于存款準備金率_級類型桿組;但組件4和5組件是屬于_級桿組的定價類型。使用的Mathcad軟件分析原始的運動部件的工具平臺_級桿組分別移動位置關系,并建立各種鉸鏈點的位置關系的表達,根據以上和解決方案的機構運動分析結果 。 第三連桿機構運動仿真
�����關閉拉梅變量的數量來實現的Mathcad軟件環境的改變機制模擬。該框架是在內部變量數學的CAD,它代表的是靜態圖像幀的序號,并按照約定由零開始。通過不斷的計算生產序號相框廣播,它可能會產生機制的動畫模擬結果。 四結論 ������Mathcad中,我們新的啟發,編程的仿真是左右擺動式送料機構的動態分析所有這些障礙的解決方案。通過整合,并結合計算,圖表,文字和圖像在紙張上面,以MathCAD使我們獲取知識,運動的設計和援助管理
�����工程分析項目,動態模擬演示精度高的完整性,同時壓縮計算時間。此外,在階躍載荷模擬幀動畫,改變輸入隨時間變化的加快完成設計量,穩定性和穩態瞬態分析,優化的尺寸或成本效益的大小。事實上,我們的工作的主要貢獻是,我們介紹了擺動式送料機構與Mathcad軟件系統。動畫中的動態分析調查比以往任何時候都更理論,我們的方法可以幫助我們的研究團隊能夠做到這一點。雖然有一些缺點,在我們看來,與其他相關的優缺點,超過抵消Mathcad中提供的眾多優勢。 Mathcad是工程師的世界各地的行業標準技術的計算工具,它提供了解決方案的快速原型設計和實驗分析機制的強大組合。 四結論
�����Mathcad中,我們新的啟發,編程的仿真是左右擺動式喂養結合,結合上面的計算,圖形,文字和圖像的文件機構����動態分析所有這些障礙的解決方案,MathCAD使我們獲取知識,運動的設計和工程分析項目援助管理,動態仿真演示精度高的完整性,同時壓縮計算時間。此外,在階躍載荷模擬幀動畫,改變輸入隨時間變化的量,穩定性和穩態瞬態分析加快設計完成,并優化成本效率�������事實的尺寸或大小,我們工作的主要貢獻是我們介紹了擺動式送料機構與Mathcad軟件系統。動畫中的動態分析調查比以往任何時候都更理論,我們的方法可以幫助我們的研究團隊做雖然������有與其他相關的一些缺點,這些缺點在我們看來是由無數足以抵消Mathcad中提供的優勢。 Mathcad是行業標準的技術
工程師的世界各地的計算工具,它提供了一個解決方案的快速原型設計和實驗分析機制的強強聯合。與本文相關的論文有:安全閥定期檢驗辦事指南 參考文獻 ���[1] Benaroya H, Rehak M. “Finite element methods in probabilistic struc-tural ��������analysis: a selective review” [J]. Applied Mechanics Review, 1988, 41: pp. pp. 201-213. ������[2] Katica (Stevanovic) Hedrih (Nis, Yugoslavia), “Trigger of Coupled ��Singularities (invited plenary lecture) Dynamical Systems-Theory and ���Applications”[M], Edited By J. Awrejcewicz, J. Grabski And ����J.Nowakowski, Lodz 2001, pp. 51-78 ����[3] Shimansky V.E. Detection of Chaotic Signals by Matched Filtering ��������“Modern Problems of Mathematics and Information ��������Science”[J],Transactions of young scientists and graduate students.Vol.3. �����Yaroslavl State University, Yaroslavl, 2000, pp.136-144. ������[4] Zhang Fajun, “The Analysis od eooor for Spling Shaping” [J]. China Three ��������Gorges University Yichang journal (2000), pp.46-49 �������[5] Gao Huiming,Zeng Jianchao. “Modeling and simulation of finishing mill �����group of hot strip Mill ”[J] . Journal of System Simulation,2000,12(1):5, pp.51-53. ��������[6] Rahman S, Rao B N. “A perturbation method for stochastic meshless ������analysis in elastostatics ”[J] . International Journal for Numerical Meth-ods �������in Engineering, 2001, 50: pp.1969-1991 |
