manual2.html

<!DOCTYPE html>
<html lang="en">

<head>
    <meta charset="UTF-8">
    <meta name="viewport" content="width=device-width, initial-scale=1.0">

    <!--=============== FAVICON ===============-->
    <link rel="shortcut icon" href="assets/img/favicon.png" type="image/x-icon">

    <!--=============== BOXICONS ===============-->
    <link rel="stylesheet" href="https://cdn.jsdelivr.net/npm/boxicons@latest/css/boxicons.min.css">

    <!--=============== SWIPER CSS ===============-->
    <link rel="stylesheet" href="assets/css/swiper-bundle.min.css">

    <!--=============== CSS ===============-->
    <link rel="stylesheet" href="assets/css/stylemanual1.css">

    <script type="module" src="https://unpkg.com/@google/model-viewer/dist/model-viewer.min.js"></script>

    <script nomodule src="https://unpkg.com/@google/model-viewer/dist/model-viewer-legacy.js"></script>

    <link href="https://fonts.googleapis.com/icon?family=Material+Icons" rel="stylesheet">

    <title>Learn Through AR</title>
</head>

<body>

    <!--==================== HEADER ====================-->
    <header class="header" id="header">
        <nav class="nav container">
            <a href="./index copy.html" class="nav__logo">
                <img src="assets/lg1.png" alt="" class="nav__logo-img"> Learn Through AR
            </a>

            <div class="nav__menu" id="nav-menu">
                <ul class="nav__list">
                    <li class="nav__item">
                        <a href="./index copy.html" class="nav__link active-link">Home</a>
                    </li>

                    <li class="nav__item">
                        <a href="./index copy.html" class="nav__link">About</a>
                    </li>

        </nav>
    </header>

    <main class="main">
        <div id="content">
            <h2>Lathe Machine</h2>
            <div class="home__buttons">
                <a href="./arpage1.html" class="button">Show AR</a>
            </div>

            <h4>INTRODUCTION</h4>
                
            <h5>Lathe is one of the most versatile and widely used machine tools all over the world. It is
                    commonly known as the mother of all other machine tool. The main function of a lathe is to
                    remove metal from a job to give it the required shape and size. The job is securely and rigidly
                    held in the chuck or in between centers on the lathe machine and then turn it against a single
                    point cutting tool which will remove metal from the job in the form of chips.
                </h5>

        </div>
        <div id="manual1">
            <h4>TYPES OF LATHE</h4>
            <h5>Lathes are manufactured in a variety of types and sizes, from very small bench lathes used for
                precision work to huge lathes used for turning large steel shafts. But the principle ofoperation
                and function of all types of lathes are same. The different types of lathes are:
            </h5>
            <ol>1. Speed lathe<br>
                2. Centre or Engine lathe<br>
                3. Bench lathe<br>
                4. Tool Room Lathe<br>
                5. Capstan and Turret lathe<br>
                6. Special purpose lathe<br>
                7. Automatic lathe<br>
            </ol>
        </div>
        <div id="manual2">
            <h4>Speed Lathe</h4>

            <h5>Speed lathe is simplest of all types of lathes in construction and operation. It consists of a Bed,
                Headstock, Tailstock and Tool post mounted on an adjustable slide. There is no feed box,
                leadscrew or conventional type of carriage. The tool is mounted on the adjustable slide and is
                fed into the work by hand control. The speed lathe finds applications where cutting force is
                least such as in wood working, spinning, centering, polishing, winding etc.
            </h5>

            <h4>Centre or Engine Lathe</h4>

            <h5>The term “engine” is associated with this lathe due to the fact that in the very early days of its
                development it was driven by steam engine. This lathe is the important member of the lathe
                family and is the most widely used. Similar to the speed lathe, the engine lathe has all the basic
                parts, e.g., bed, headstock, and tailstock. An engine lathe is shown in Fig. 4. Unlike the speed
                lathe, the engine lathe can feed the cutting tool both in cross and longitudinal direction with
                reference to the lathe axis with the help of a carriage, feed rod and lead screw. The power may
                be transmitted by means of belt, electric motor or through gears.
            </h5>
            
            <h4>Bench Lathe</h4>

            <h5>This is a small lathe usually mounted on a bench. It has practically all the parts of an engine
                lathe or speed lathe and it performs almost all the operations. This is used for small and
                precision work.
            </h5>

            <h4>Room Lathe</h4>

            <h5>This lathe has features similar to an engine lathe but it is much more accurately built. It has a
                wide range of spindle speeds ranging from a very low to a quite high speed up to 2500 rpm.
                This lathe is mainly used for precision work on tools, dies, gauges and in machining work
                where accuracy is needed.
            </h5>   

            <h4>Capstan and Turret Lathe</h4>

            <h5>The distinguishing feature of this type of lathe is that the tailstock of an engine lathe is replaced
                by a hexagonal turret, on the face of which multiple tools may be fitted and fed into the work
                in proper sequence. Due to this arrangement, several different types of operations can be done
                on a job without re-setting of work or tools, and a number of identical parts can be produced
                in the minimum time.
            </h5>

            <h4>Special Purpose Lathes</h4>

            <h5>These lathes are constructed for special purposes and for jobs, which cannot be accommodated
                or conveniently machined on a standard lathe. The wheel lathe is made for finishing the
                journals and turning the tread on railroad car and locomotive wheels. The gap bed lathe, in
                which a section of the bed adjacent to the headstock is removable, is used to swing extra-largediameter pieces.
            </h5>

            <h4>Automatic Lathes</h4>

            <h5>These lathes are so designed that all the working and job handling movements of the complete
                manufacturing process for a job are done automatically. These are high speed, heavy duty, mass
                production lathes with complete automatic control.
            </h5>

            <h4>PRINCIPLE FUNCTIONS OF LATHE PARTS</h4>

            <h5>A simple lathe comprises of a bed made of grey cast iron on which headstock, tailstock,
                carriage and other components of lathe are mounted. Figure l shows the different parts of
                engine lathe or central lathe.<br>
                <br>
                The major parts of lathe machine are given as under:<br>
                <ol>1. Speed lathe<br>
                    2. Centre or Engine lathe<br>
                    3. Bench lathe<br>
                    4. Tool Room Lathe<br>
                    5. Capstan and Turret lathe<br>
                    6. Special purpose lathe<br>
                    7. Automatic lathe
                </ol>
            </h5>
            <div class="home__group">
                <img src="assets/img/manual1/fig1.png" alt="" class="home__img">
                
            </div>

            <h6><i>Figure 1: Different parts of engine lathe or central lathe</i></h6>
        </div>
       

        <div id="manual3">
            <h4>Bed</h4>

            <h5>The bed of a lathe machine isthe base on which all other parts of lathe are mounted. It is massive
                and rigid single piece casting made to support other active parts of lathe. On left end of the bed,
                headstock of lathe machine is located while on right side tailstock is located. The carriage of
                the machine rests over the bed and slides on it. On the top of the bed there are two sets of
                guideways - innerways and outerways. The innerways provide sliding surfaces for the tailstock
                and the outerways for the carriage. The guideways of the lathe bed may be flat and inverted V
                shape. Generally cast iron alloyed with nickel and chromium material is used for manufacturing
                of the lathe bed.
            </h5>

            <h4>Head Stock</h4>

            <h5>The main function of headstock is to transmit power to the different parts of a lathe. It
                comprises of the headstock casting to accommodate all the parts within it including gear train
                arrangement. The main spindle is adjusted in it, which possesses live centre to which the work
                can be attached. It supports the work and revolves with the work, fitted into the main spindle
                of the headstock. The cone pulley is also attached with this arrangement, which is used to get
                various spindle speed through electric motor. The back gear arrangement is used for obtaining
                a wide range of slower speeds. Some gears called change wheels are used to produce different
                velocity ratio required for thread cutting.
            </h5>

            <h4>Tail Stock</h4>

            <h5>Figure 2 shows the tail stock of central lathe, which is commonly used for the objective of
                primarily giving an outer bearing and support the circular job being turned on centers. Tail
                stock can be easily set or adjusted for alignment or non-alignment with respect to the spindle
                Workshop and Machine shop practice centre and carries a centre called dead centre for supporting one end of the work. Both live and
                dead centers have 60° conical pointsto fit centre holes in the circular job, the other end tapering
                to allow for good fitting into the spindles. The dead centre can be mounted in ball bearing so
                that it rotates with the job avoiding friction of the job with dead centre as it important to hold
                heavy jobs.
            </h5>

            <div class="home__group">
                <img src="assets/img/manual1/fig2.png" alt="" class="home__img">
            </div>

            <h6><i>Figure 2: Tailed stock of central lathe</i></h6>

            <h4>Carriage</h4>

            <h5>
                Carriage is mounted on the outer guide ways of lathe bed and it can move in a direction parallel
                to the spindle axis. It comprises of important parts such as apron, cross-slide, saddle, compound
                rest, and tool post. The lower part of the carriage is termed the apron in which there are gears
                to constitute apron mechanism for adjusting the direction of the feed using clutch mechanism
                and the split half nut for automatic feed. The cross-slide is basically mounted on the carriage,
                which generally travels at right angles to the spindle axis. On the cross-slide, a saddle is
                mounted in which the compound rest is adjusted which can rotate and fix to any desired angle.
                The compound rest slide is actuated by a screw, which rotates in a nut fixed to the saddle. The
                tool post is an important part of carriage, which fits in a tee-slot in the compound rest and holds
                the tool holder in place by the tool post screw.
                  
            </h5>

            <h4>Feed Mechanism</h4>

            <h5>
                Feed mechanism is the combination of different units through which motion of headstock
                spindle is transmitted to the carriage of lathe machine. Following units play role in feed
                mechanism of a lathe machine.
                <br>
                <ol>1. End of bed gearing<br>
                    2. Feed gear box<br>
                    3. Lead screw and feed rod<br>
                    4. Apron mechanism<br>
                </ol>
                <br>
                The gearing at the end of bed transmits the rotary motion of headstock spindle to the feed gear
                box. Through the feed gear box the motion is further transmitted either to the feed shaft or leadscrew, depending on whether the lathe machine is being used for plain turning or screw
                cutting.<br>
                <br>
                The feed gear box contains a number of different sizes of gears. The feed gear box provides
                a means to alter the rate of feed, and the ration between revolutions of the headstock spindle
                and the movement of carriage for thread cutting by changing the speed of rotation of the feed
                rod or lead screw. <br>
                <br>The apron is fitted to the saddle. It contains gears and clutches to transmit motion from the
                feed rod to the carriage, and the half nut which engages with the lead screw during cutting
                threads.
                
            </h5>

            <h4>WORK HOLDING DEVICES:</h4>

            <h5>
                <ol>1. Work is held between the centres<br>       
                        --> Live centre - head stock spindle and Dead centre - tail stock spindle.<br>
                        --> Driven by catch plate and carrier <br> <br>
                    
                    2. Work piece held in chuck<br>
                        --> Four jaw independent chuck<br>
                        --> Three jaw universal self centering chuck<br>
                        --> Magnetic chuck<br>
                        --> Collet chuck<br>
                        --> Drill chuck<br> <br>
                    
                
                    3. Work held in face plate.<br> <br>
                    4. Work held in mandrel<br>
                        --> Plain Mandrel<br>
                        --> Step mandrel<br>
                        --> Collar Mandrel<br> 
                        -->Screwed Mandrel<br>
                        --> Cope Mandrel<br>
                        --> Gang Mandrel<br>
                        --> Expansion Mandrel<br> <br>
                    
                        5. Work held in turning fixture<br>
                        --> Steady Rest<br>
                        --> Follower Rest<br>
                                               
                </ol>
            </h5>
            <div class="home__group">
                <img src="assets/img/manual1/fig3.png" alt="" class="home__img">
            </div>

            <h6><i>Figure 3: Three Jaw Universal Self Centering Chunk</i></h6>

            <div class="home__group">
                <img src="assets/img/manual1/fig4.png" alt="" class="home__img">
            </div>
            <h6><i>Figure 4: Four Jaw Independent Chunk</i></h6>

            <h4>LATHE OPERATIONS:</h4>

            <h5>
1. Straight Turning Or Plain Turning<br>
2. Facing<br>
3. Shoulder turning<br>
4. Chamfering<br>
5. Knurling<br>
6. Forming<br>
7. Parting off (grooving)<br>
8. Spinning<br>
9. Eccentric turning<br>
10. Drilling<br>
11. Boring<br>
12. Centering<br>
13. Thread cutting<br>
14. Taper turning<br>
            </h5>
            <div class="home__group">
                <img src="assets/img/manual1/fig5.1.png" alt="" class="home__img">
            </div>
            <h6><i>Some common machining operations done in center lathers.</i></h6>

            <h5>
                For performing the various machining operations in a lathe, the job is being supported
                and driven by anyone of the following methods.<br><br>
                1.   Job is held and driven by chuck with the other end supported on the tail stock
                centre.<br><br>
                2. Job is held between centers and driven by carriers and catch plates.<br><br>
                3. Job is held on a mandrel, which is supported between centers and driven by
                carriers and catch plates.<br><br>
                4. Job is held and driven by a chuck or a faceplate or an angle plate.<br><br>
                    The above methods for holding the job can be classified under two headings namely job
                held between centers and job held by a chuck or any other fixture. The various important
                lathe operations are depicted through figure 4.
            </h5>
            <div class="home__group">
                <img src="assets/img/manual1/fig5.png" alt="" class="home__img">
            </div>
            <h6><i>Figure 5: Various lathe operations</i></h6>

            <h4>Taper Turning</h4>

            <h5>
                A taper is defined as a uniform increase or decrease in diameter of a piece of work measured
                along its length. In a lathe machine, taper turning meansto produce a conical surface by gradual
                reduction in diameter from a cylindrical job. The taper angle (α) for conical surface is given
                by: <br>
                Where,
                <div class="home__group">
                    <img src="assets/img/manual1/tan.png" alt="" class="home__img">
                </div><br>

                D <i>: diameter of the large end,</i><br> 
                d <i>: the dia of the small end of the cylindrical job,</i><br>
                l <i>: the length of the taper of cylindrical job.</i><br><br>
                A taper is generally turned in a lathe by feeding the tool at an angle to the axis of rotation
                of the workpiece. The angle formed by the path of the tool with the axis of the workpiece
                should correspond to the half taper angle. A taper can be turned by anyone of the following
                methods:<br><br>
                1. By swiveling the compound rest,<br>
                2. By setting over the tailstock centre,<br>
                3. By a broad nose form tool,<br>
                4. By a taper turning attachment,<br>
                5. By combining longitudinal and cross feed in a special lathe and<br>
                6. By using numerical control lathe<br><br><br>

                <i><u>Taper Turning by Swivelling the Compound Rest</u></i></h5>
                <h5>This method uses the principle of turning taper by rotating the workpiece on the lathe axis and
                feeding the tool at an angle to the axis of rotation of the workpiece. The tool is mounted on the
                compound rest which is attached to a circular base, graduated in degrees.<br>
                </h5>
                <div class="home__group">
                    <img src="assets/img/manual1/Fig6.png" alt="" class="home__img">
                </div>
                <h6><i>Figure 6: Taper turning by swiveling compund rest</i></h6>
                <h5>
                    The compound rest can easily be swiveled or rotated and clamped at any desired angle as
                    shown in Fig. 4. Once the compound rest is set at the desired half taper angle, rotation of the
                    compound slide screw will cause the tool to be fed at that angle and generate a corresponding
                    taper. This method is limited to turn a short but steep taper because of the limited movement
                    of the cross-slide. The positioning or setting of the compound rest is accomplished by
                    swiveling the rest at the half taper angle, if this is already known. If the diameter of the small
                    and large end and length of taper are known, the half taper angle can be calculated. <br>
                </h5>
                <div class="home__group">
                    <img src="assets/img/manual1/fig7.png" alt="" class="home__img">
                </div>
                <h6><i>Figure 7: Thread Cutting</i></h6> 
                <h5>Figure 5 shows the setup of thread cutting on a lathe. Thread of any pitch, shape and size can
                    be cut on a lathe using single point cutting tool. Thread cutting is operation of producing a
                    helical groove on spindle shape such as V, square or power threads on a cylindrical surface.
                    The job is held in between centres or in a chuck and the cutting tool is held on tool post. The
                    cutting tool must travel a distance equal to the pitch (in mm) as the work piece completes a
                    revolution. The definite relative rotary and linear motion between job and cutting tool is
                    achieved by locking or engaging a carriage motion with lead screw and nut mechanism and
                    fixing a gear ratio between head stock spindle and lead screw. To make or cut threads, the
                    cutting tool is brought to the start of job and a small depth of cut is given to cutting tool using
                    cross slide. The equation for thread cutting calculation is given by;
                </h5>
                <div class="home__group">
                    <img src="assets/img/manual1/eq2.png" alt="" class="home__img">
                </div>
                <h4>DRILLING ON A LATHE</h4>
                <h5>
                    For producing holes in jobs on lathe, the job is held in a chuck or on a face plate. The drill is
                held in the position of tailstock and which is brought nearer the job by moving the tailstock
                along the guide ways, the thus drill is fed against the rotating job.
                </h5>
                <div class="home__group">
                    <img src="assets/img/manual1/fig8.png" alt="" class="home__img">
                </div>
                <h6><i>Figure 8: Drilling on lathe</i></h6><br>

                <h4>CUTTING PARAMETERS</h4>
                <h4>1. Cutting speed</h4>
                <h5>
                    Cutting speed for lathe work may be defined as the rate in meters per minute at which the
                    surface of the job moves past the cutting tool. Machining at a correct cutting speed is highly
                    important for good tool life and efficient cutting. Too slow cutting speeds reduce productivity
                    and increase manufacturing costs whereas too high cutting speeds result in overheating of the
                    tool and premature failure of the cutting edge of the tool. <br><br>
                    <i>The following factors affect the cutting speed:</i>  <br>
                    i. Kind of material being cut<br>
                    ii. Cutting tool material<br>
                    iii. Shape of cutting tool<br>
                    iv. Rigidity of machine tool and the job piece and<br>
                    v. Type of cutting fluid being used.<br>
                </h5>

                <h4>2. Feed</h4>
                <h5>
                    It is the distance the tool advances for every revolution of the workpiece. It is expressed in
                    mm/rev.<br>
                </h5>

                <h4>3.  Depth of Cut</h4>
                <h5>
                    It is perpendicular distance measured from the machined surface to the uncut surface of work.
It is expressed in mm.<br>
                </h5> 
                
                <h4>DIFFERENT MECHANISMS:</h4>
                <h4>1. Apron Mechanisum:</h4>
                <h5>
                    when a spindle rotates, the LEAD screw and the feed rod will rotate through the tumbler gear.
This, Apron Mechanism provided in the carriage is connected to the LEAD Screw through the
half nut engaged in the carriage, from which auto feed of the longitudinal and the cross feed
mechanism is obtained.<br>
                </h5>

                <h4>2. Back Gear Mechanism:</h4>
                <h5>Back gear arrangement is used for reducing the spindle speed, which is necessary for thread
                    cutting and knurling.<br>
                </h5>
                <div class="home__group">
                    <img src="assets/img/manual1/fig9.png" alt="" class="home__img">
                </div>
                <h6><i>Figure 8: Black Gear Mechanism</i></h6><br>
                <h5>
                    There is one stepped cone pulley in the lathe spindle. This pulley can freely rotate on the
spindle. A pinion gear Pl is connected to small end of the cone pulley. Pl will rotate when cone
pulley rotates. Bull gear Gl is keyed to lathe spindle such that the spindle will rotate when Gear
Gl rotates. Speed changes can be obtained by changing the flat belt on the steps. A bull gear Gl
may be locked or unlocked with this cone pulley by a lock pin. There are two back gears Bl
and B2 on a back shaft. It is operated by means of hand lever L; back gears Bl and B2 can be
engaged or disengaged with Gl and Pl. For getting direct speed, back gear is not engaged. The
step cone pulley is locked with the main spindle by using the lock pin. The flat belt is changed
for different steps. Thus three or four ranges ofspeed can be obtained directly. For getting slow
or indirect speeds, back gear is engaged by lever L and lock pin is disengaged. Now, power
will flow from Pl to Bl. Bl to B2 (same shaft), B2 to Gl to spindle. As gear Bl is larger than Pl,
the speed will further be reduced at Bl. Bl and B2 will have the same speeds. The speed will
further be reduced at Gl because gear Gl is larger than B2. So, the speed of spindle is reduced
by engaging the back gear.
                </h5>

                <h4>3. Tumbler Gear Mechanism</h4>
                <h5>
                    Tumbler gear mechanism is used to change the direction of lead screw and feed rod. By
changing tumbler gear, the carriage can be moved automatically from tailstock end toheadstock end or moved from head stock end to tailstock end. Usually during thread cutting
and automatic feed, tumbler gear is used.
<br><br><br><br><br>
                </h5>
        </div>
    </div>
    <!--==================== FOOTER ====================-->
    <footer class="footer section">

        <img src="assets/ar1.png" alt="" class="footer__img-one">

    </footer>


        <!--=============== SCROLL REVEAL ===============-->
        <script src="assets/js/scrollreveal.min.js"></script>

        <!--=============== SWIPER JS ===============-->
        <script src="assets/js/swiper-bundle.min.js"></script>

        <!--=============== MAIN JS ===============-->
        <script src="assets/js/main.js"></script>
</body>

</html>