數(shù)控立鉆電氣部分設(shè)計含開題及4張CAD圖
數(shù)控立鉆電氣部分設(shè)計含開題及4張CAD圖,數(shù)控,電氣,部分,部份,設(shè)計,開題,cad
XX設(shè)計(XXX)中期檢查表(指導(dǎo)教師)
指導(dǎo)教師姓名: 填表日期: 20XX年 4 月 20 日
學(xué)生學(xué)號
學(xué)生姓名
題目名稱
數(shù)控立鉆電氣部分設(shè)計
已完成內(nèi)容
參觀調(diào)研,查閱資料;
到生產(chǎn)、制造企業(yè)調(diào)研,了解生產(chǎn)、制造、加工情況。結(jié)合本設(shè)計課題,查閱相關(guān)資料。
完成機(jī)床電器控制電路的設(shè)計(電器原理圖),包括各種保護(hù)。
完成數(shù)控機(jī)床總體的電氣控制設(shè)計。
ZK5132數(shù)控立鉆機(jī)床電氣外觀圖(附見圖紙)
完成相關(guān)計算;
完成英文翻譯;
撰寫論文;
完成畢業(yè)設(shè)計。
檢查日期:2014-4-20
完成情況
t全部完成
□按進(jìn)度完成
□滯后進(jìn)度安排
存在困難
組態(tài)控制較復(fù)雜,如不能完成將用硬件表達(dá)。
解決辦法
查閱相關(guān)資料,并且與指導(dǎo)老師和同學(xué)們一起討論解決方案。
預(yù)期成績
□優(yōu) 秀
t良 好
□中 等
□及 格
□不及格
建
議
教師簽名:
教務(wù)處實踐教學(xué)科制表
說明:1、本表由檢查畢業(yè)設(shè)計的指導(dǎo)教師如實填寫;2、此表要放入畢業(yè)設(shè)計(論文)檔案袋中;
3、各院(系)分類匯總后報教務(wù)處實踐教學(xué)科備案
一、 畢業(yè)設(shè)計(論文)的內(nèi)容
1、數(shù)控機(jī)床常用電氣控制元件的應(yīng)用。
2、數(shù)控系統(tǒng)。
3、步進(jìn)電動機(jī)驅(qū)動進(jìn)給系統(tǒng)。
4、主軸電機(jī)控制。
5、機(jī)床電氣控制系統(tǒng)設(shè)計。
二、 畢業(yè)設(shè)計(論文)的要求與數(shù)據(jù)
1、參觀調(diào)研,查閱資料。到生產(chǎn)、制造企業(yè)調(diào)研,了解生產(chǎn)、制造、加工情況。 結(jié)合本設(shè)計課題,查閱相關(guān)資料。
2、完成機(jī)床電器控制電路的設(shè)計(電器原理圖),包括各種保護(hù)。
3、根據(jù)步進(jìn)電機(jī)的特點(diǎn):完成對電機(jī)的精度控制(α= 0.36°)。
4、完成數(shù)控機(jī)床總體的電氣控制設(shè)計。ZK5132數(shù)控立鉆機(jī)床電氣外觀圖(附見圖紙)。
三、畢業(yè)設(shè)計(論文)應(yīng)完成的工作
1、完成二萬字左右的畢業(yè)設(shè)計說明書(論文);在畢業(yè)設(shè)計說明書(論文)中必須包括詳細(xì)的300-500個單詞的英文摘要;
2、獨(dú)立完成與課題相關(guān),不少于四萬字符的指定英文資料翻譯(附英文原文);
3、對于機(jī)電結(jié)合類課題,必須完成繪圖工作量折合A0圖紙1張以上,其中必須包含兩張A3以上的計算機(jī)繪圖圖紙;
四、應(yīng)收集的資料及主要參考文獻(xiàn)
[1] 蔣大明,戴勝華.自動控制原理[M].北京: 北京交通大學(xué)出版社. 2003.3.
[2] 劉元揚(yáng)主編. 自動檢測和過程控制[M].北京: 冶金工業(yè)出版社. 2005.8.
[3] 李曉輝,薛欣.計算機(jī)輔助設(shè)計與繪圖[M].北京:清華大學(xué)出版社. 2006.6.
[4] 陳遠(yuǎn)齡主編 機(jī)床電氣自動控制[M].重慶:重慶大學(xué)出版社. 2008.
[5] 彭榮濟(jì). 機(jī)械設(shè)計手冊[M].北京: 北京出版社. 2002.1
[6] 董杰主編.機(jī)械設(shè)計工藝性手冊[M].北京: 上海交道大學(xué)出版社. 2004.2
[7] 宋寶玉主編.機(jī)械設(shè)計基礎(chǔ)[M].哈爾濱: 哈爾濱工業(yè)大學(xué)出版社. 2006.3
[8] 邱公偉.可編程控制器網(wǎng)絡(luò)通信及應(yīng)用[M].北京:清華大學(xué)出版社. 2001.1
[9] 高兆安譯. 自動化中的液壓機(jī)構(gòu)[M].北京: 機(jī)械工業(yè)出版社. 2007.2
[10] Design of machine elements / zhai wenjie and Ao hongrui [monograpn]. 2007.
五、試驗、測試、試制加工所需主要儀器設(shè)備及條件
計算機(jī)(autoCAD,及pro/E,protel軟件)。
任務(wù)下達(dá)時間:
2013年12月9日
畢業(yè)設(shè)計開始與完成時間:
2013年12月9日至 2014年5 月4日
組織實施單位:
教研室主任意見:
簽字: 2013年12月10日
院領(lǐng)導(dǎo)小組意見:
簽字: 2013年12月12日
2013年機(jī)電工程學(xué)院畢業(yè)設(shè)計(論文)進(jìn)度計劃表
學(xué)生姓名: 學(xué)號:
序號
起止日期
計劃完成內(nèi)容
實際完成內(nèi)容
檢查日期
檢查人簽名
1
2013.12.9-2013.12.15
任務(wù)下達(dá)書
2
2013.12.16-2013.12.22
查閱資料
3
2013.12.23-2013.12.29
調(diào)研
4
2013.12.30-2014.1.5
寫開題報告
5
2014.1.6-2014.1.12
寫外文原文及翻譯
6
2014.1.13-2014.1.19
寫外文原文及翻譯
7
2014.2.24-2014.3.2
寫論文說明書
8
2014.3.3-2014.3.9
完成框圖設(shè)計
(本表同時作為指導(dǎo)教師對學(xué)生的16次考勤記錄)
2013年機(jī)電工程學(xué)院畢業(yè)設(shè)計進(jìn)度計劃表(續(xù))
學(xué)生姓名: 學(xué)號:
序號
起止日期
計劃完成內(nèi)容
實際完成內(nèi)容
檢查日期
檢查人簽名
9
2014.3.10-2014.3.16
完成圖紙設(shè)計
10
2014.3.17-2014.3.23
完成說明書初稿
11
2014.3.24-2014.3.30
交老師檢查
12
2014.3.31-2014.4.6
第一次回作者修改
13
2014.4.7-2014.4.13
第二次交老師檢查
14
2014.4.14-2014.4.20
第二次回作者修改
15
2014.4.21-2014.4.27
打印修改
16
2014.4.28-2014.5.4
完成畢業(yè)設(shè)計,提交論文
任務(wù)下達(dá)時間:2013年12月9日 (本表同時作為指導(dǎo)教師對學(xué)生的16次考勤記錄)
TC No. 9-524
JOEL B.HUDSON, DENNIS J.REIMER Washington,DC, 29 October 1996
ATTN: ATCL-AO, 801 Lee Avenue, Fort Lee, Virginia 23801-1713.
FUNDAMENTALS OF MACHINE TOOLS
Chapter 4
DRILLING MACHINES
GENERAL INFORMATION
PURPOSE
This chapter contains basic information pertaining to drilling machines. A drilling machine comes in many shapes and sizes, from small hand-held power drills to bench mounted and finally floor-mounted models. They can perform operations other than drilling, such as countersinking, counter boring, reaming, and tapping large or small holes. Because the drilling machines can perform all of these operations, this chapter will also cover the types of drill bits, took, and shop formulas for setting up each operation.
Safety plays a critical part in any operation involving power equipment. This chapter will cover procedures for servicing, maintaining, and setting up the work, proper methods of selecting tools, and work holding devices to get the job done safely without causing damage to the equipment, yourself, or someone nearby.
USES
A drilling machine, called a drill press, is used to cut holes into or through metal, wood, or other materials (Figure 4-1).Drilling machines use a drilling tool that has cutting edges at its point. This cutting tool is held in the drill press by a chuck or Morse taper and is rotated and fed into the work at variable speeds. Drilling machines may be used to perform other operations. They can perform countersinking, boring, counter boring, spot facing, reaming, and tapping (Figure 4-2).
Drill press operators must know how to set up the work, set speed and feed, and provide for coolant to get an acceptable finished product. The size or capacity of the drilling machine is usually determined by the largest piece of stock that can be center-drilled (Figure 4-3). For instance, a 15-inch drilling machine can center-drill a 30-inch-diameter piece of stock.
Other ways to determine the size of the drill press are by the largest hole that can be drilled, the distance between the spindle and column, and the vertical distance between the worktable and spindle.
CHARACTERISTICS
All drilling machines have the following construction characteristics (Figure 4-4): a spindle. sleeve or quill. column, head, worktable, and base.
The spindle holds the drill or cutting tools and revolves in a fixed position in a sleeve. In most drilling machines, the spindle is vertical and the work is supported on a horizontal table.
The sleeve or quill assembly does not revolve but may slide in its bearing in a direction parallel to its axis. When the sleeve carrying the spindle with a cutting tool is lowered, the cutting tool is fed into the work: and when it is moved upward, the cutting tool is withdrawn from the work. Feed pressure applied to the sleeve by hand or power causes the revolving drill to cut its way into the work a few thousandths of an inch per revolution.
The column of most drill presses is circular and built rugged and solid. The column supports the head and the sleeve or quill assembly.
The head of the drill press is composed of the sleeve, spindle, electric motor, and feed mechanism. The head is bolted to the column.
The worktable is supported on an arm mounted to the Column. The worktable can be adjusted vertically to accommodate different heights of work. or it may be swung completely out of the way. It may be tilted up to 90° in either direction, to allow for long pieces to be end or angled drilled.
The base of the drilling machine supports the entire Machine and when bolted to the floor, provides for Vibration-free operation and best machining accuracy.
The top of the base is similar to a worktable and maybe equipped with T-slots for mounting work too large for the table.
CARE OF DRILLING MACHINES
Lubrication
Lubrication is important because of the heat and friction
Generated by the moving parts. Follow the manufacturer’s manual for proper lubrication methods. Clean each machine after use. Clean T-slots. grooves. And dirt from belts and pulleys. Remove chips to avoid damage to moving parts.
Wipe all spindles and sleeves free of grit to avoid damaging The precision fit. Put a light coat of oil on all unpainted surfaces to prevent rust. Operate all machines with care to avoid overworking the electric motor.
Special Care
Operations under adverse conditions require special care. If machines are operated under extremely dusty conditions. Operate at the slowest speeds to avoid rapid abrasive wear on the moving parts and lubricate the machines more often.
Under extreme cold conditions, start the machines at a slow speed and allow the parts and lubricants to warm up before increasing the speeds. Metal becomes very brittle in extreme cold. so do not strike the machines with hard tools. Extreme heat may cause the motor to overheat. so use intermittent. Or on and off, operations to keep the motor running cool.
TYPES OF DRILLING MACHINES
There are two types of drilling machines used by maintenance personnel for repairing and fabricating needed parts: hand-feed or power-feed. Other types of drilling machines, such as the radial drill press. Numerically controlled drilling machine. Multiple spindle drilling machine, gang drilling machine, and turret drill press, are all variations of the basic hand and power-feed drilling machines. They are designed for high-speed production and industrial shops.
Drilling depth is controlled by a depth-stop mechanism located on the side of the spindle. The operator of the machine must use a sense of feel while feeding the cutting tool into the work. The operator must pay attention and be alert. to when the drill breaks through the work, because of the tendency of the drill to grab or snag the work piece, of these machines, operations that require drilling speeds less than 450 revolutions per minute cannot be performed.
Reaming, counter boring, and counter-sinking may require slower speeds than drilling and may not be able to be performed for all materials on these machines.
Hand-Feed
The hand-feed drilling machines (Figure 4-5) are the simplest and most common type of drilling machines in use today. These are light duty machines that are hand-fed by the operator, using a feed handle. so that the operator is able to “feel” the action of the cutting tool as it cuts through the work piece. These drilling machines can be bench or floor-mounted.
They are driven by an electric motor that turns a drive belt on a motor pulley that connects to the spindle pulley. Hand-feed machines are essentially high-speed machines and are used on small workplaces that require holes 1/2 inch or smaller. Normally, the head can be moved up and down on the column by loosening the locking bolts. Which allows the drilling machine to drill different heights of work.
Power-Feed
The power-feed drilling machines (Figure 4-6) are usually larger and heavier than the hand-feed. They are equipped with the ability to feed the cutting tool into the work automatically, at a preset depth of cut per revolution of the spindle, usually in thousandths of an inch per revolution. These machines are used in maintenance shops for medium duty work, or work that uses large drills that require power feeds. The power-feed capability is needed for drills or cutting took that are over 1/2 inch in diameter, because they require more force to cut than that which can be provided by using hand pressure. The speeds available on power-feed machines can vary from about 50 RPM to about 1,800 RPM. The slower speeds allow for special operations, such as counter boring, countersinking, and reaming.
The sizes of these machines generally range from 17-inch to a 22-inch center-drilling capacity, and are usually floor mounted. They can handle drills up to 2 inches in diameter, which mount into tapered Morse sockets. Larger workplaces are usually clamped directly to the table or base using T-bolts and clamps, while small workplaces are held in a vise. A depth-stop mechanism is located on the head, near the spindle, to aid in drilling to a precise depth.
SAFETY PRECAUTIONS
DRILLING MACHINE SAFETY
Drilling machines are one of the most dangerous hand operated pieces of equipment in the shop area. Following safety procedures during drilling operations will help eliminate accidents, loss of time, and materials. Listed below Keep all loose clothing away from turning tools. Are safety procedures common to most types of drilling a chines found in the machine shop. Make sure that the cutting tools are running straight before starting the operation.
Do not support the workplaces by hand. Never make any adjustments while the machine is operating. Never clean away chips with your hand. Use a brush.
Never place tools or equipment on the drilling tables. Keep all guards in place while operating.
Ease up on the feed as the drill breaks through the work to avoid damaged tools or workplaces.
Remove all chuck keys and wrenches before operating.
Always wear eye protection while operating any drilling machines.
TOOLS AND EQUIPMENT
TWIST DRILLS
Twist drills are the most common cutting tools used with drilling machines. Twist drills are designed to make round holes quickly and accurately in all materials. They are called twist drills mainly because of the helical flutes or grooves that wind around the body from the point to the neck of the drill and appear to be twisted (Figure 4-7). Twist drills are simply constructed but designed very tough to withstand the high torque of turning, the downward pressure on the drill, and the high heat generated by friction.
There are two common types of twist drills, high-speed steel drills, and carbide-tipped drills. The most common type used for field and maintenance shop work is the high-speed steel twist drill because of its low cost. Carbide-tipped metal drills are used in production work where the drill must remain sharp for extended periods, such as in a numerically controlled drilling machine. Other types of drills available are: carbide tipped masonry drills, solid carbide drills, TiN coated drills, parabolic drills and split point drills. Twist drills are classified as straight shank or tapered shank (Figure 4-7). Straight shank twist drills are usually l/2-inch or smaller and tit into geared drill chucks, while tapered shank drills are usually for the larger drills that need more strength which is provided by the taper socket chucks.
Common twist drill sizes range from 0.0135 (wire gage size No. 80) to 3.500 inches in diameter. Larger holes are cut by special drills that are not considered as twist drills. The standard sizes used in the United States are the wire gage numbered drills, letter drills, fractional drills, and metric drills (See Table 4-1, in Appendix A). Twist drills can also be classified by the diameter and length of the shank and by the length of the fluted portion of the twist drill.
Wire gage twist drills and letter twist drills are generally used where other than standard fractional sizes are required, such as drilling holes for tapping. In this case, the drilled hole forms the minor diameter of the thread to be cut, and the major diameter which is cut by tapping corresponds to the common fractional size of the screw. Wire gage twist drills range from the smallest to the largest size; from No 80(0.0135 inch) to No 1 (0.2280 inch).
The larger the number, the smaller the diameter of the drill. Letter size twists drills range from A (0.234 inch) to Z (0.413 inch). As the letters progress, the diameters become larger.
Fractional drills range from 1/64 to 1 3/4 inches in l/64-inch units; from 1/32 to 2 1/4 inches in 1/32-inch units, and from 1/1 6 to 3 1/2 inches in 1/16-inch units.
Metric twist drills are ranged in three ways: miniature set, straight shank, and taper shank. Miniature metric drill sets range from 0.04 mm to 0.99 mm in units of 0.01 mm. Straight shank metric drills range from 0.05 mm to 20.0 mm in units from 0.02 mm to 0.05 mm depending on the size of the drill.
Taper shank: drills range in size from 8 mm to 80 mm in units from 0.01 mm to 0.05 mm depending on the size of the drill.
The drill gage (Figure 4-8) is used to check the diameter size of a twist drill. The gage consists of a plate having a series of holes. These holes can be numbered, lettered, fractional, or metric-sized twist drills. The cutting end of the drill is placed into the hole to check the size. A micrometer can also be used to check the size of a twist drill by measuring over the margins of the drill (Figure 4-9). The smaller sizes of drills are not usually marked with the drill size or worn drills may have the drill size rubbed off, thus a drill gage or micrometer must be used to check the size.
It is important to know the parts of the twist drill for proper identification and sharpening (Figure 4-7).
The point is the entire conical shaped end of the drill containing the cutting edges and chisel edge. The body is the part of the drill that is fluted and relieved.
The shank is the part that fits into the holding device, whether it is a straight shank or a tapered shank. The chisel edge is the point at which the two lips meet. The chisel edge acts as a chisel when the drill is turning and cuts into the work piece. The chisel edge must always be centered exactly on the drill’s axis for accurate cutting action.
The cutting edge lips cut like knives when fed and rotated into the work piece. The lips are sharp edges formed by grinding the flutes to a conical point.
The heel is the conical shaped portion of the point in back of the cutting edge lips. The amount of slope given to the heel in back of the drill lips is called lip clearance. This clearance is necessary to keep the heel from rubbing the bottom of the hole being drilled. Rubbing would prevent the drill from cutting.
The flute is the helical groove on the drill. It carries out the chips and admits coolant to the cutting edges. The margin is the narrow surface along the flutes that determines the size of the drill and keeps the drill aligned.
The portion of the drill body that is relieved behind the margin is known as the body clearance. The diameter of this part is less than that of the margin and provides clearance so that all of the body does not rub against the side of the hole and cause friction. The body clearance also permits passage of lubricants around the drill.
The narrowed end of the tapered shank drill is called the tang. The tang fits the slot in the innermost end of the drill spindle, drill chuck, or other drill holding device and aids in driving the tool. It also prevents the drill from slipping.
The web of the drill is the metal section separating the flutes. It runs the length of the body between the flutes. The web gradually increases in thickness toward the shank, increasing the rigidity of the drill.
An imaginary line through the center of the drill from end to end is the axis. The drill must rotate evenly about the axis at all times.
SPECIAL DRILLS
Special drills are needed for some applications that a normal high-speed industrial operations. Other types of special drills general purpose drill cannot accomplish quickly or accurately. Are: left hand drill, Silver and Deming, spotting, slow spiral, Special drills can be twist drill type, straight fluted type, or fast spiral, half round, die, flat, and core drills. The general special fluted. Special drills can be known by the job that they purpose high-speed drill, which is the common twist drill used are designed for, such as aircraft length drills, which have an for most field and maintenance shops, can be reground and extended shank. Special drills are usually used in adapted for most special drilling needs.
SHARPENING TWIST DRILLS
Twist drills become dull and must be resharpened. The preferred method of resharpening a twist drill is with the drill grinding machine, but this machine is not always available in field and maintenance units, so the offhand method of drill sharpening must be used (Figure 4-10). The off hand method requires that the operator have a knowledge of the drilling geometry (Figure 4-11) and how to change drill angles as needed for any drilling job (see Table 4-2 in Appendix A).
Tools needed are a utility or bench grinder with a dressed wheel and a drill point gage (Figure 4-12) or protractor head on the combination square. The drill point gage is set at 59° and adjusted along the steel rule to fit the drill to be sharpened. The cutting lips must be of the same angle, the lip clearance angle must be within a specific degree range, and the cutting lips must be of an equal length. There are several basic characteristics that all twist drills must have to cut properly. The following will cover those characteristics.
PRECHECK
Before sharpening a twist drill, the operator must check the condition of the drill for chipped and cracked lips or edges that must be ground off during the sharpening process. The operator must also check the references for the proper lip angle and lip clearance angle for the material to be drilled. After setting up the bench grinder for offhand drill sharpening, the operator assumes a comfortable stance in front of the grinding wheel to sharpen the twist drill. The suggested method is to grind the lip angle first, then concentrate on grinding the lip clearance angle, which will then determine the lip length. The usual lip angle is an included angle of 118°(59° x 2) (Figure 4-13), which is the lip angle of general purpose drills. Use the drill point gage frequently to check lip angle and lip length. When grinding, do not allow the drill to become overheated. Overheating will cause the drill edges to become blue which is an indication that the drill’s temper has been lost. The blue area must be ground completely away to reestablish the drill’s temper. If a drill becomes too hot during sharpening, the lips can crack when dipped into cold water or coolant.
DRILL POINT
When grinding the lip angle, use the drill point gage and grind one lip perfectly straight and at the required angle (usually 590). Then flip the drill over and grind the other lip.
Once the angle is established, then the lip clearance angle and lip length can be ground. If both lips are not straight and of the same angle, then the chisel edge (Figure 4-14) will not be established.
It is it important to have a sharp and centered chisel edge or the drill will not rotate exactly on its center and the hole will be oversized. If the drill point is too steep, the drill will require more power and cut slowly. When the angles of the cutting lips are different, then the drill will only have one lip cutting as it revolves. The hole will be oversized and the drill will wear very rapidly.
When both the angles and the length of the angles are incorrect, then excessive wear is put on both the drill and machine, which will result in poor workmanship (Figure 4-15).
CLEARANCE ANGLE
When grinding the lip clearance angle, (Figure 4-13), relief must be given to both cutting edges allowing them to enter into the work piece to do the cutting. General purpose drills have a clearance of 8° to 12°. The chisel edge of a correctly ground drill should be at an angle of about 45° with the line of the cutting edges. The angle of the chisel edge to the lips is a guide to the clearance (Figure 4-16).
Too much clearance will cause the drill to break down because of insufficient support of the lip, and there will not be enough lip thickness to carry away the generated heat. Too little clearance will result in the drill having little or no cutting edges, and the increased pressure required to feed it into the hole will cause the drill to break. By looking straight onto the cutting tip of the drill, th
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