Td250型斗式提升機的設(shè)計【含7張CAD圖帶開題報告-獨家】.zip
Td250型斗式提升機的設(shè)計【含7張CAD圖帶開題報告-獨家】.zip,含7張CAD圖帶開題報告-獨家,Td250,型斗式,提升,設(shè)計,CAD,開題,報告,獨家
1 英文文獻翻譯
1.1 Micro Shot Blasting of Machine Toolss
D.M. Kennedy *, J. Vahey, D. Hanney
Faculty of Engineering, Dublin Institute of Technology, Bolton Street, Dublin 1, Ireland
Received 5 January 2004; accepted 3 February 2004
Available online 13 April 2004
Abstract
Micro blasting of cutting tips and tools is a very effective and reliable method of advancing the life of tools under the action of turning, milling, drilling, punching and cutting. This paper outlines the ways in which micro blasted tools, both coated and uncoated have benefited from shot blasting and resulted in greater productivity, lower cutting forces, improved surface finish of the work pieces and less machine downtime. The process of micro blasting is discussed in the paper. Its effectiveness depends on many parameters including the shot media and size, the mechanics of impact and the application of the shot via the micro shot blasting unit.
Control of the process to provide repeatability and reliability in the shot blasting unit is discussed. Comparisons between treated and untreated cutting tools are made and results of tool life for these cutting tips outlined. The process has shown to be of major benefitto tool life improvement. 2004 Elsevier Ltd. All rights reserved.
Keywords: Micro shot blasting; Surface finish; Machine tools
1. Introduction
Many modern techniques have been developed to enhance the life of components in service, such as alloying additions, heat treatment, surface engineering, surface coating, implantation processes, laser treatment and surface shape
design. Processes such as thin film technology, plasma spraying, vacuum techniques depositing a range of multi-layered coatings have greatly enhanced the life, use and applications of engineering components and machine tools. Bombardment with millions of micro shot ranging in size from 4 to 50 lm with a controlled process can lead to dramatic operating life improvements of components. Standard shot peening was first used in a production process to extend the life of valve springs for Buick and Cadillac engines in the early 1930s [1,2] but prior to this it was a well known process used by blacksmiths and sword makers overtime to improve the toughness of the cutting edges of their tools and weapons. Today, cutting tips and tools can be greatly improved by the process of micro shot blasting their surfaces to induce compressive residual stresses. The operating life of tools such as drills, turning tips,milling tips, punches, knife edges, slicers, blades, and a range of other working parts can also benefit from this process.Standard components, such as springs, dies, shafts, cams, and dynamic components in machines and engines can be enhanced by this process. The fatigue life of compressor components for example, treated by shot peening have increased dramatically as reported by Eckersley and Ferrelli [3]. Other factors such as improved fatigue resistance, micro crack closure, reduced corrosion and an improved surface finish can also be designed into components as a result of this the peening process. Not only can improvements be made to the surface finish of the cutting tips and tools but also the surface finish of the work pieces machined with these tools have improved as a result of this technique. Engineering materials such as tools steels, carbides, ceramics, coated carbides, through to polymers and even rubbers (elastomers) can benefit. The key requirement for this process is to develop anautomated micro blasting process to fit inside a spraybooth or standard shot blasting booth. Shot material, size and mass, operating pressures, operating velocities, kinetic energy, density and coverage time will need to be perfected and optimised for a range of materials. The process is a line of sight method but can be applied to complex surface shapes such as the tips of drill bits.
2. Method of operation
One of the primary ways that components fail in ervice is through fatigue. This is closely associated with cyclic stresses and accelerated by tensile stresses, micro crack propagation and stress corrosion cracking. Cracks reduce the cross section of a material and eventually it will fail to support the applied loads. One simple method of reducing failure by fatigue is to arrest these tensile stresses by inducing compressive stresses into a surface. The benefits obtained with shot peening are a direct result of the residual compressive stresses produced in a component. A typical shot striking a surface is shown in Fig. 1. Any applied tensile loads would have to overcome the residual compressive stresses before a crack could initiate as described by Almen [4].
Poor machining of materials can result in residual stresses accruing at the surface. Rough surfaces have deeper notches, where cracks can initiate due to tensile stress concentrations at these points. Many standard machining processes such as grinding, milling, turning, and coating processes such as electroplating induce residual tensile stresses in surfaces and this can lead to early failure of components. Further tensile loading in service would lead to early failure and this can be prevented by shot peening and micro blasting of component surfaces. Micro shot blasting will change the following in a materials surface:
(i) resistance to fatigue fracture;
(ii) resistance to stress corrosion;
(iii) a change in residual stresses;
(iv) modification of surface finish.
It is a cold working process involving bombarding powders such as ceramics, glass and metals of mainly spherical shapes against surfaces and can be used in conjunction with other processes. The main stages involved in this dynamic process include elastic recovery of the substrate after impact, some plastic deformation of the substrate if the impact pressure exceeds the yield stress, increased plastic deformation due to an increase in impact pressure and finally some rebound of the shot due to a release of elastic energy. Some critical design characteristics of the micro shot peening process include the shot size, shape, hardness, density, durability, angle of impact, velocity and intensity. All of these parameters will influence the residual compressive stresses produced in the substrate.
3. Experimental work
Tool materials such as Tungsten Carbide, High Speed Steels used in milling and turning tools were subjected to the micro peening process using different shot media (ceramic and glass bead) and shot size. Tests prior to and following the blasting process were conducted to ascertain any improvements resulting from the process.
The micro shot peening unit is shown in Photo 1 it incorporates an air filter, pressure regulator and gauge, air flow regulator, pressurised blast media container and a venturi blast nozzle for directing the stream of micro shot. The unit is PLC controlled and a stepper motor, used to drive a lead screw, is used to move the blast nozzle across the sample in order to control media shot coverage.
The blast nozzle can also be rotated to allow shot media to strike the samples at different angles. Tests undertaken include surface finish and roughness measurement, machining tests on standard lathes and mills, hardness tests, cutting forces on turning operations, tool wear and the determination of surface finish of the work pieces machined. Figs. 2 and 3 show a typical high speed steel (HSS) tip prior to and following the micro shot peening process using ceramic bead at a pressure of 5.5 bar.
4. Experimental results
Testing of treated and untreated cutting tips and tools was conducted on HSSs for turning and milling as well as coated and uncoated carbide inserts. A dynamometer was used to measure cutting forces on the turning tool (Lathe). The cutting process consisted of a depth of cut of 2 mm on a standard bright mild steel specimen over a length of 750 mm while milling tests consisted of machining a 25_25_150 mm piece of mild steel using a depth of cut of 1 mm with a slot milling cutter of 18 mm diameter. Surface roughness measurements were conducted on the machined components prior to and after machining to establish whether the treated cutting tips had superior performance to the untreated tips. Micro Hardness testing was also carried out to establish if there was any increase in surface hardness due to the micro shot peening process. The impact angle of the shot was set at 90_ as this provides the optimum compressive layer [5]. The shot velocity on impact with a surface is largely dependent on the nozzle size, the air pressure and the distance from the substrate. The exposure time was adequate to give sufficient coverage of the substrate and this was determined by the Almen strip saturation time, work piece indentation time and visual appearance. Harder materials such as carbides will obviously require longer exposure time or harder shot media. The micro peening media used was a ceramic bead of approximately 40 lm diameter providing high impact strength and hardness (NF L 06-824, approximately 60 HRc).
4.1. Micro hardness tests
Combined Vickers micro hardness tests gave the results in Table 1. for both treated and untreated HSS cutting tips.
4.2. Surface roughness values
In all surface roughness tests conducted, the micro blasted surface gave an improved surface roughness value. Surface roughness and profile tests were carried out on both a Talyor Hobson Tallysurf instrument and a non contact surface profileometer. Surface roughness details of a typical untreated HSS cutting tip and a treated one are shown in Figs. 4 and5 and Table 2 shows the results of surface measurement values for other cutting tips and tools and workpieces. Fig. 6 shows an uncoated carbide cutting tip which was not subjected to micro blasting. The flank wear was measured using an optical microscope and the value recorded was 150 lm after 676 s of machining. Fig. 7 shows an uncoated carbide tip subjected to micro blasting. The flank wear in this case is only 90 lm for the same machining time.
and5 and Table 2 shows the results of surface measurement values for other cutting tips and tools and workpieces. Fig. 6 shows an uncoated carbide cutting tip which was not subjected to micro blasting. The flank wear was measured using an optical microscope and the value recorded was 150 lm after 676 s of machining. Fig. 7 shows an uncoated carbide tip subjected to micro blasting. The flank wear in this case is only 90 lm for the same machining time.
4.3. Dynamometer tests
Figs. 8 and 9 show the comparison for Dynamometer results for HSS in the treated (micro blasted) and untreated states with relevant comments.
Similar profiles are shown for coated and uncoated turning tips in both the treated (micro blasted) and untreated conditions in Figs. 10–13. In all cases, the micro blasted tips provided an increase in cutting tip life with lower cutting forces recorded.
5. Conclusions
This research work has shown that micro shot blasting of cutting tips and tools has a very positive effect on component surfaces by increasing toughness, operating life, improving hardness and surface finish. From the tests conducted, it is obvious that the process affects the residual stresses at or near the surface in a beneficial way by inducing compressive stresses on the substrates tested. The micro blasting process is very simple to apply and economical to use. The mechanical properties of the substrates will determine the type of treatment, i.e. shot hardness, velocity and duration of application in order to obtain maximum benefits from this process. In some cases, authors have reported a 4– 10 fold improvement in fatigue life in a range of dynamic machine parts subjected to standard shot blasting. Further testing will need to be conducted at the micro shot blasting stage to obtain similar benefits. Other applications for the micro blasting process are currently being investigated and rubber based products that are subjected to fatigue and wear are being tested in order to remove the surface voids that act as stress concentrations in these materials.
References
[1] Impact. Bloomfield, CT: Metal Improvement Company; Fall 1989.
[2] Zimmerli FP. Heat treating, setting and shot-peening of mechanical
springs. Metal process; June 1952.
[3] Eckersley JS, Ferrelli B. Using shot-peening to multiply the life of
compressor components. In: The shot peener, International newsletter
for shot-peening surface finishing industry, vol. 9, Issue No.
1; March 1995.
[4] Almen JC. J.O. Almen on hot blasting. General motors test, US
Patent 2,350,440.
[5] Champaigne J. Controlled shot peening. Elec Inc., Report; 1989.
1.2 中文翻譯
摘要
在旋轉(zhuǎn),銑削,鉆孔,沖孔和切削運動中,微拋丸切削技巧和工具是一種提高工具壽命的非常高效并且可靠的方法。本文概述了應(yīng)用微拋丸工具的方式,微拋丸對有無鍍膜工件的益處,并且創(chuàng)造了更大的生產(chǎn)力,降低了切應(yīng)力,提高了工件的表面光潔度,減少了機器的停機時間。本文對微拋丸過程進行了討論。它的效率取決于包括彈丸媒體和型號在內(nèi)的許多參數(shù),碰撞力學和通過微拋丸單元的彈丸的應(yīng)用程序。對控制流程提供的可重復性和可靠性的爆破裝置進行了探討。處理和未經(jīng)處理的刀具的做出了對比,切割技巧對刀具壽命的影響做出了概述。這個過程體現(xiàn)了提高工具壽命的主要好處。
關(guān)鍵詞:微噴丸清理,表面光潔度;機床
介紹
許多現(xiàn)代技術(shù)已經(jīng)開發(fā)出來加強服務(wù)組件的壽命,例如添加合金,熱處理,表面工程,表面涂層,移植過程,激光治療以及表面外形設(shè)計。例如薄膜技術(shù),等離子噴涂,沉淀多層涂料的真空技術(shù)都大大加強了壽命,工程和應(yīng)用程序組件和機床使用。通過控制過程用數(shù)以百萬計的大小在4到50微米的微拋丸撞擊可以顯著提高組件的使用壽命。標準噴丸技術(shù)首次使用時在20世紀30年代提高別克和凱迪拉克引擎氣門彈簧的生產(chǎn)過程中,但在此之前該技術(shù)就是被鐵匠和刀制造商所熟知的來提高他們工具和武器切削刃韌性的過程。當今,切割技巧和工具可以通過微拋丸清理它們的表面的過程來引導壓縮參與應(yīng)力而被大大提高。鉆頭,車削頭,銑削頭,沖頭,刀刃,切片機,葉片以及一系列的其他工作部分都可以受益于該過程。
機器和引擎中的標準組件,例如離合器,柴油機,軸,凸輪以及動態(tài)組件等都可以通過該過程提高。由Eckersley和Ferrelli所述,例如壓縮機組件的疲勞壽命通過拋丸處理可以顯著增加。其他因素,例如抗疲勞強度,微裂紋閉合,減少腐蝕以及提高表面光潔度都可以被作為噴丸的結(jié)果而被設(shè)計進組件當中。不僅可以做到切削刀具表面光潔度的提高模塊化特點和生產(chǎn)模塊化發(fā)展,使得汽車制造企業(yè)的知識呈現(xiàn)出模塊系統(tǒng)的知識結(jié)構(gòu)特性。
模塊系統(tǒng)的知識以信息的形式存在,系統(tǒng)內(nèi)部信息(系統(tǒng)內(nèi)部規(guī)則)是模塊系統(tǒng)的存在和發(fā)展的基礎(chǔ)。Baldwin和Clark借用計算機科學的類似思想,將模塊系統(tǒng)的信息分為系統(tǒng)信息(可視設(shè)計規(guī)則)和模塊信息(隱形的設(shè)計規(guī)則)。系統(tǒng)信息結(jié)構(gòu)信息來構(gòu)成的。
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