DE709297C - Electrically controlled automatic lathe - Google Patents

Description

Electrically controlled automatic lathe It is an electric one controlled automatic lathe known, in which the drive is one spindle for each the longitudinal pull and the face pull from the main spindle drive via electromagnetic Couplings is derived. Here, these couplings are on the frame and Longitudinal slide or on the longitudinal slide and cross slide can be adjusted relative to one another Arranged stops are automatically controlled in a 7cTer way, that - if at the end : A contact is switched to the forward movement of the cross slide, this does not only the forward movement of the cross slide is ended, but at the same time the longitudinal feed After turning off a certain length of the workpiece, the longitudinal slide then runs against a stop. The switchings brought about by this switch the longitudinal feed and at the same time switch on the retraction.

The present one also relates to such an automatic lathe Invention. It is based on the task of controlling so. train that one stepped workpiece of gradually changing diameter completely automatically can be machined, the diameters and lengths of each step through adjustable stops can be set. The known machine is Such a way of working is not possible, since there the turning tool only in one Rectangle is guided to a certain length of the workpiece of a certain diameter to turn off and then to run back to the starting position after the tool has been withdrawn.

The object of the invention is achieved in that the cross slide to Retracted beyond the next larger diameter, by means of a plan retraction switch stopped and again until the contact for the forward movement of the Cross slide is advanced, which then initiates the longitudinal feed. Through this, that the turning steel is withdrawn further after turning off each step than it is for the next step is necessary, and then adjusted again down to its diameter the game is automatically recorded in the engine of the cross slide.

The step diameters determining the step diameters are preferably adjustable Stops on the cross slide and the plan feed switch with the plan retraction switch attached to the slide guided on the longitudinal slide, which is in cycle with the successive Withdrawal movements of the cross slide the switches one after the other in the effective range of the stops brings.

Further features of the invention relate to the gradually mutual Adjustment through which the stops come into effect one after the other.

In the drawings, Fig. I shows a plan view of a lathe below partial omission of some details, FIG. 2 shows a vertical cross section seen through the longitudinal slide with reference to Fig. i from the right, one of the Contact switch in its - outermost rear position is illustrated, Fig. 3 shows a larger-scale plan of the longitudinal slide and the cross slide, Fig. 4 shows a cam switch mechanism, seen from the rear, in a section along the line 4-4 of Fig.3, ters, which is arranged on the longitudinal slide and with the contact finger group cooperates, which determines the positions of the longitudinal slide in which a Cross feed of the tool takes place, FIG. 5 shows a horizontal section according to the Line 5-5 of Fig. 2 to illustrate the switch in plan, the cross feeds of the tool is determined for successive positions of the longitudinal slide, 6 shows the vertical section along the line 6-6 in FIG. 5 for illustration of the switch shown there in elevation, a diagram to illustrate the movements of the tool for the production of a step-wise stepped shaft, Fig. 8 the Circuit diagram of the electrical control, FIG. 9 a schematic representation of the mechanically driven switching elements of the machine and the associated circuit holder, Fig. Io the representation given in Fig. I and 2 of the contacts _-i and B controlling Attacks on a larger scale and Fig. I i the section along the line i i-1 i of the Fig. 6.

As can be seen from the description below, it is In the exemplary embodiment, the task is to make the movements of a turning tool automatically to be controlled in such a way that this step-shaped the workpiece clamped in the lathe turns off, as Fig. 7 shows. On the longitudinal guides 2 and 3 of the bed i slides Longitudinal slide,.,. the. with a front plate 5 and downwardly protruding lugs 6 (Fig.2) is provided. The approaches are provided with threaded holes and form 'the nuts for a lead screw 7, through the rotation of which the carriage q. To the right or shifted to the left and thus brought about the longitudinal shift of the turning tool Io will.

The cross slide 8 slides for the cross feed of the tool Io on guides 9 of the longitudinal slide 4. The turning tool Io of usual design is clamped in a holder 11 of the cross slide 8, as shown in FIG. the The cross slide is displaced by a lead screw 12 which drives it Received via bevel gears 13 from a riser shaft 14, which in bearing lugs 15 of the Front plate 5 of the longitudinal slide 4 rests.

The climbing wave 1: 1 is longitudinally via bevel gears 16 and 17 driven by the machine extending grooved shaft i8 on which the lower bevel gear 17 can be displaced secured by a spring and moves with the longitudinal slide 4. For this purpose, an approach 19 of the longitudinal slide engages in an annular groove in the hub of the bevel gear 17. The bearing shoulder 15, the shaft 14. and the bevel gears 16 and 17 So they move in the longitudinal direction with the slide ¢ and get their drive by the rotation of the grooved shaft 18, which is mounted on the bed of the machine. With each adjustment of the longitudinal slide 4. the required movement of the cross slide 8.

The lathe is provided with the usual tips 2o for mounting the workpiece, the guide stick and its tip not being illustrated in more detail. A disk 21 is used for most of the work, the workpiece being set in rotation by driving the spindle 22. The spindle 22 rests in the usual way in bearings 23 and carries a gear 24, which is driven by the pinion 26 of a motor shaft 27 via change gears 25. The lead screw 7 for the longitudinal slide and the splined shaft i8 for the cross slide can be driven in any way via change gears to set the desired advance and retraction speed of the tool. In the present case, the drive is derived from the motor 27. For this purpose the spindle 22 is provided with a gear 28 (FIGS. i and 2) which cooperates with intermediate gears 29, 30 and 31 which sit on a vertical bearing block 32, as shown in broken lines in FIG. 2) sits on a shaft 33 extending in the longitudinal direction of the machine, so that it rotates together with the work piece spindle 22. As shown in FIG its right end is provided with a bevel gear 34 which meshes with a bevel gear 35 of a shaft 38. The shaft 38 rotates in a bearing block 37, which is provided on the end face of the bed i, and in a em bearing block 39, which lies in front of it and also sits on the bed (cf. Fig. I).

At its left end, the longitudinal shaft 33 carries a smaller bevel gear 4o which meshes with a bevel gear 41. This sits on a pin 42, which in a bearing block 43 rests, which is attached to the left front side of the bed and also the bearing for the end of the shaft 33 carries. Further is on the short wave 4a a spur gear 44 attached, which with a spur gear 45 on the end of a transverse shaft 46 combs. This cross shaft runs in bearings of the bearing block 43 and the front left curved bearing arm 47 attached to the bed. The end of shaft 46 carries a change gear 48 which meshes with a change gear .49 on the end of an auxiliary shaft 50. This is running in bearings of the bearing block 47 and an arm 5 i of the bearing block 43.

The forwardly extending bearing blocks 39 and 47 carry the bearings for the lead screw 7 of the longitudinal slide 4 and for the splined shaft 18 from which the Drive of the cross slide 8 is derived. Also carry the bearing blocks 39 and 47 an auxiliary shaft 52 extending in the longitudinal direction of the machine (Fig. 1, 2 and 3), which, as shown in Fig. i shows through spur gears 53, 54 with the lead screw 7 is coupled. The drive of the lead screw? can therefore differ from that of the auxiliary shaft 52 can be derived.

The shaft 38 carries on its right end bevel gears 55 and 56, the mesh with bevel gears 57 and 58, which are attached to clutch magnets 59 and 6o are. The clutch magnets 59 and 6o run freely rotatably on the right ends of the Auxiliary shaft 52 and the splined shaft 18. They are assigned armature disks 6I and 62, which are guided with tongue and groove on the shafts 52 and i8 and when they are excited of the associated clutch magnet 59 or 6o are attracted by this by Friction are entrained and then drive their shafts 52 and 18.

Will the lead screw? Driven by the coupling magnet 59 via the gears 53 and 54, it guides the longitudinal slide 4 back to the right in its starting position at a relatively high speed. In a corresponding manner, the drive of the shaft 18 by the magnetic coupling 6o results in the cross slide 8 being withdrawn from the workpiece at high speed via the gear wheels 13, 16 and 17.

At the left end of the shaft 59 according to FIG. 1, bevel gears 63 and 64 are fastened, 63 and 64 which mesh with bevel gears 65 and 66 which are fastened to clutch magnets 67 and 68. These run freely on the ends of the auxiliary shaft 52 and the splined shaft i8 and cooperate with coupling armature disks 69 and 70 , which are slidably seated on the left ends of the shafts 52 and i8 and are used to drive them when the relevant coupling magnets 67 and 68 are excited . The gear drives 4.4, 45, 48, 49, 63 and 64 are used to significantly reduce the rotational speed. The drive of the coupling 67 is transmitted to the lead screw 7 when it is energized, so that it slowly moves the longitudinal slide ¢ to the left. In a corresponding manner, when the magnetic coupling 68 is excited, the lead screw r2 for the cross slide 8 is driven in such a way that the latter moves inward at the normal feed rate.

With lathes. manufacture the workpieces of a certain size and shape, It is advisable to use the lead screws for the transverse and Longitudinal movements at normal speed during employment and the goal push to drive, but to rotate at high speed. when the workpiece Io is withdrawn after each cut and the carriages 4 and 8 in their starting position to return. Accordingly, the gears 34, 35, 55, 56 serve between the right End of shaft 33 and clutches 59 and 6o for high speed subsequent return of the longitudinal slide 4 to the right and the cross slide 8 to the outside, while the gear 44, 45, 48 and 49, which is shown in Fig. I on the left is, the relatively slow feed is used by the clutch magnets 67 and 68 is transmitted. With the help of the change gears 48 and 49, the normal The feed and pitch speed can be adjusted inwards and to the left as desired will.

The use of electrical couplings to drive the lead screws for the longitudinal and transverse movement of the tool 1o offers a simple possibility to control these movements automatically. For this purpose, you need the relevant Magnetic clutches only in the correct order and at the correct times to be switched. There are then movements in a fixed sequence, starting with an initial position of the turning tool, which then gradually moves the workpiece processed and finally migrates back to the starting position.

In the present case, the turning tool starts moving from the external starting days off by going through the one electromagnet initially up to the correct distance from the workpiece axis for the first cut is employed. Then the longitudinal slide is fed: I to the left, turn the first step 2u. Did this happen. so the tool will be back in withdrawn in the radial direction away from the workpiece, to then again to be employed to the depth required for the second stage. First after this has happened, the longitudinal slide is restarted and effected the feed to the left for the second stage cut. This order of Longitudinal and radial movements are then repeated as often as turning in steps are. .

When the last longitudinal feed of the turning tool is finished, it will withdrawn to the outside, then freely past the workpiece in its starting position to be able to run back. This return movement of the tool to its starting position ends the work cycle, the machine then stops, so that a new workpiece clamped and the work cycle can be repeated.

For automatic control of the sequentially herbeizuführenden feeds and employment of the turning tool on a series serve v K ontaktfingern and switches. These are arranged so that they are switched by the transverse and longitudinal feeds of the tool and accordingly control the successive feeds of the carriages. In the present exemplary embodiment, the cross slide 8 has a forwardly protruding extension 71 which is provided with a series of T-slots 72 which extend transversely to the bed, i.e. parallel to the cross slide guide (see FIGS. 1 and 3) In the present case, eight such T-slots are provided. Adjustable laser blocks 73 (FIGS. 5 and 6), the number of which corresponds to that of the stages to be rotated, are located in these slots 72. They are held in the respective setting position on the cross slide by clamping bolts 74 Bearing block 73 carries a stop finger 7.5 of any shape, preferably in the form of a micrometer screw76, which allows a particularly precise setting of the point at which the contact is switched. The number of micrometer stops 75 corresponds to the number of Eilr and outward movements of the cross slide. that is to say the number of steps to be turned in. In the present case, eight stop fingers 75 are again provided, each one Control the inward movement of the cross slide 8 and also serve to limit the retraction of the cross slide when a collar is to be turned on the tool and for this purpose the cross slide 8 has to be set for a different diameter.

In FIGS. 1 and 3, some of the connections75 are shown as short rods which are clamped adjustably in bearing blocks, similar to bearing blocks73. These simplified stop fingers can be used where an exact setting is not important. The stop fingers 75 work with two switches A and B together. The switch e4 limits the advance inward and the switch P the retraction (les cross slide outward. As FIGS. 5 and 6 show, these switches consist of levers 77 and 78, which in the manner shown in FIGS Trunnions 79 and 8o rest and are held by springs 81 and 82 in the position usually to close contacts 83 and 84. As will be discussed later, these contacts are used to control relays which control the in and out movement of the cross slide 8. The switch B (FIGS. 3 and 5) is provided with a laterally bent hook 85 at its front end, which can be placed under the stop finger 75. The upper side of the bent end 85 is bevelled so that the When the cross slide 8 is advanced, the cranked end 85 lies under a finger 7 5 and is pressed down by it, whereby the contacts 84 of the switch B in FIG ought to be kept open.

Switches A and B are surrounded by housings 86 and 87 (Figures 5 and 6) and are mounted on a cantilevered arm 88, which is shown in FIG. i and 3 in the longitudinal direction of the machine, i.e. at right angles to the Oderschlide 8 extends. The arm 88 sits on a special carriage 89 on longitudinal guides 9o at the front on the longitudinal slide .l runs. As a result, they are older. -1 and B adjustable in the longitudinal direction of the machine compared to the cross slide. These Adjustment takes place in increments. The contact fingers 7 5 take part in the movement of the Cross slide 8 part. Read through (read the interaction of switches A and 13 finitely Contact fingers - the positions of the turning tool Io are determined.

To control the longitudinal feeds of the slide. + Is used hurriedly by others Contact finger group. For this purpose the lathe below is finitely a consul () t provided. on which groove rail 02 (V ig. 2 and,;) with a: I in (leg Longitudinally extending T-slot (l3 al1gel) r: lcllt is. On the Schielle () _ 1'1atte (>> liefesti # -lt, the vain reilie of Slitting 96 has, in the present case eight such slots, which extend in the longitudinal direction extend. In the T-slots 96 are seated pedestals 97 (Figs. 2 and 4a) that are similar As shown in Fig. 6, are secured in their setting positions by clamping screws. Each of the bearing blocks 97 carries a stop finger 98, which is guided by a micrometer screw 99 is adjustable (see. Fig. i and 3). The number of slots 96 depends on the maximum number of levels to be turned on. It can therefore be turned on up to eight levels will. How many stop fingers 98 are provided depends on the stages of the workpiece away.

The stop fingers 98 controlling the longitudinal feed interact with a switch C, and they can accordingly strike its contact lever Ioo (FIGS. 2 and 4a), which is rotatably mounted in a housing IoI and can close contacts Io2 under the action of a spring 103. The contacts are in circuits to be explained later. The contact lever Ioo of the switch C is attached within a housing IoI to the end of a support arm i o4, which sits in a cantilevered manner on a slide 105 and extends backwards over the longitudinal slotted plate 95. The carriage Io5 runs on guides Io6 of the longitudinal carriage .4 transversely to .this (see. Fig. I and 3).

To initiate the retreat of the carriage 4 is on the front the plate 95 also an adjustable bearing block 107 (Fig. 3) is arranged and provided with a metallic approach. its cylindrical or spherical head Io8 is isolated and is able to slide between two contact springs Io9 that on the back of the slide: 4 are attached. This closes a circuit the retraction movement of the tool holder to its starting position j to the right causes the machine to be ready for a new work cycle is located.

The carriages 89 and Io5, also designated with _D and E, are automatic shifted in such a way that they gradually bring switches A, B and C into the position in which these the transverse and longitudinal movements of the tool elder for the Workpiece to be attached steps can control in a fixed order. For this purpose, the carriages D and L can move one step at the same time move from one job to the next and then to their starting point to return. With each of the successive settings of the carriages D and E the switches.-L, L3 and C are brought into positions, in which they are put through the fingers 75 and 98 that become effective are switched one after the other .. To the drive of the bumpy slide, these are provided with racks IIo and III, each with mesh with a pinion 112 or 113, the drive of which is provided by a common transverse shaftII4 of the carriage 4 is derived (Fig. 2 and 3). The pinion 113 for the drive of the carriage E sits on a short shaft 115, which is driven by bevel gears 116 and 117 is coupled to the shaft 114 (see. Fig. 3).

The shaft 114 rests in bearings 118 of the longitudinal slide 4 and extends transversely to this Abis in a housing i i9, which is seated on the slide at the rear. There the shaft 114 carries on its end a gear wheel I2o which meshes with a gear wheel 121 (FIGS. 2, 3 and 4) on a short shaft 122. The shaft 122 is mounted inside the housing i i9 and at its rear end 'is provided with a larger gear 123 which meshes with a pinion i24 in a ratio of 1: 8. The shaft 125 of this pinion is also mounted in the housing and is coupled by bevel gears I26 and 127 to a vertical shaft 128 which carries a magnetic coupling armature 130. This belongs to a reversing clutch I20 which is attached to the rear of the longitudinal slide 4 (see Fig. 2). The armature disk 130 is guided on the shaft 128 with a tongue and groove and can either rest against one or the other of two coupling magnets 131. These are freely rotatably mounted on the shaft 128 and are provided with bevel gears 132 which rotate in opposite directions through a common bevel pinion 133 of the Shaft of the motor 134. Depending on which of the two magnets 131 is excited, the armature 13o rests against one or the other magnet and is therefore driven in one or the other direction together with the shaft 128. This reversing clutch the direction of movement by-the successive switching steps of the carriage D and e as well as their return movement determined. the slides D and e for each adjusting position of the switches A, B and C and their home positions are two thrust curves M and N dominated (Fig. 4 The cam disk i35 is finitely provided with a single cam N (FIGS. 4 and 8), the finitely one at 138 on a frame n 139 within the housing II9 supported contact lever 137 interacts. A spring I: 40 seeks to press the cam roller 136 against the cam disk 135 and thus to close the contacts 141. As a result, N control current circuits are switched together with the thrust curve.

The shaft 125 with the N-cam disk c35: and the pinion 124 is rotated fully for each setting position of the slide D-89 and E-IO5. The cam projection of the disk 135 limits the rotation. As will be explained later, as many positions can be provided for the switches A, B and C as is necessary for the number of steps to be turned on, up to the maximum number limited by the working capacity of the machine. In the present case, eight successive setting positions come into consideration, since the plate 71 of the cross slide and the plate 25 of the longitudinal slide are provided with eight slots for the stop fingers. The retraction of the slide ¢ to the starting position is controlled by the contact finger Io8.

With each revolution of the thrust curve N, the switches A, B and C move to the next setting in contact with the stop fingers 75 and 98 the carriages D and E returned to the starting position.

In the present case, the cam M leads seven steps forward because it sits on the shaft 122, the N one for each revolution of the cam eighth of a turn. The cam plate 142 has a single projection M, which acts on a cam roller 143 of a contact lever 144, which in a Switch box 146 (Fig. 4) is rotatably mounted at point 145 and under the effect a spring 147 stands. If the cam roller 143 runs off the projection, so the contact lever 144 closes two contacts 148, whereby the later to be explained Circuits are brought about.

Contacts 1-.8 are usually closed, except when the tool is in the starting position. Then namely the cam projection is M of the cam disc 1.1.2 under the cam roller 143. The contact switches A, B and C take seven different switch positions one after the other, and accordingly is the gear 123 for driving the cam I42-M with eight times as many teeth provided like the Ritze '124. So while the cam 135-N one revolution for every switch position the switch A, B and C executes, the cam disc makes I42-M one eighth of a turn for each switch position. Thus completes the cam 142-1W does not complete the revolution after seven consecutive settings. This rotation to close contacts 1.18 is only completed on return in the starting position.

The cross slide 8 is; as Fig. i shows, with a limit switch provided for the retraction movement. This consists of an arm sitting on the cross slide 14.9 with a ball I5o made of insulating material, which is between two contact springs 151 and thereby bring it out of contact. This will make the Circuit of the magnetic coupling causing the retraction movement of the cross slide 8 separately, which will be explained in more detail later with reference to FIG.

Furthermore, the longitudinal slide .4 is provided with a pivotable limit switch arm 152 (FIG. I) for the retraction movement which carries a cam roller 153 which can run onto an adjustable stop finger 154. The finger 154 is clamped firmly on a longitudinal rod 15.5, adjustable by means of a screw 156. Its adjustment limits the retraction movement of the longitudinal slide and thereby determines the initial position of the tool holder. In FIG. 9, the mechanical switching means explained above are shown again schematically, that is to say the switches A, B and C and the thrust curves 111 and N which control the carriages D and E.

The circuit diagram of FIG. 8 will now be explained in more detail. It is between distinguish between two circuits, namely between the control circuits and the drive circuits. The control circuits run through various relays and assume an electricity generator 163. They are shown in thin lines. The drive circuits run over the clutch magnets and are more powerful Lines shown. As shown in Fig. 8, the system of control lines is grounded. Accordingly, one terminal of the generator 163 is at 234. to the 'ground of' machine connected, so that it is only necessary to close the circuit, the relevant Port of line 235 to connect to any part of the machine.

The drive circuits, on the other hand, are not earthed.

The line 235 is connected on the one hand to the generator 163 and on the other hand to the windings of the relays Oh, Ih, IR, LF, START, STOP, (> S, SK, RQ and Lli. These relays monitor the magnetic clutches to induce the movements of the longitudinal slide 4, the cross slide 8 and the cams 3I and N. To switch these relays, which are connected to the line a35 with one pulse, the other pulse is connected to the machine's class 57 the circuit of the relays L K and IR. If this happens, the relay switch IR is closed and the relay switch LK is opened .. The switch B grounds the relay windings QS, STOP and OK via the line 2.49, which can also be grounded via the lever 137 of the cam disk N. The switch C grounds the relay windings LF, START and IK via the line 241. The line 262 for grounding the relay windings RQ and SK runs via one of the limit switch 152, controlled th contact 263 and also via the contacts 148 of the cam 11T. For the drive circuits, the lines L -f- and L- initially run through a circuit breaker 157. From there, the L + line runs to one terminal of the motor 162 of the generator and to one side of each of the clutch magnets IN OUT, LEFT, RIEHT, SS and RS. These are permanent connections; because the magnets are controlled via the L - line. Further branches of the L + line lead to one terminal of the coil of a main relay MK, to one terminal of the coil I70 of a reversing switch RSw, to a contact spring of the limit switch 1o9 and to one pole of a manual switch 182 with three settings.

The line L leads from the main disconnector 157 to the contact 185 of the main relay MK and to the rocker arm 222 of the reversing switch RSw 'and from there via a resistor 173, to the upper terminal of the coil 175 of the reversing switch. From here a line 18o runs to the right pole of the hand switch 182. The lower terminals of windings 170 and 175 of the reversing switch are through a Line Ni connected to one another, from which a branch to the upper contact spring 1o9 and from there to the switching lever 181-. of the hand switch 182 leads. . The windings 17o and 175 of the reversing switch RSw are connected in series, as shown in FIG. The line N1 is connected to the line 18o via the manual switch 182, see above that winding 175 can be short-circuited and therefore not energized. Of the Circuit then runs from L- as follows: resistor 173, line 18o; Gear lever 181 of manual switch 182, line N r; lower terminal of winding 170, winding 170, L + line. The short-circuiting of the winding 175 has the consequence that the `winding 17o lifts the armature 22o of the rocker arm 222 and thereby the L-line with the Line 166 connects. The armature 221 is raised by the winding 170 is short-circuited. For this purpose, the line N 1 is connected to L. And indeed either via the limit switch Io9 or via the switching lever 181 of the hand switch i82. The circuit of the winding of the main relay MK is made by lifting the armature 22o and closed by connecting the L lead to wire 166.

One branch of the L - line is connected to contact 185 of the main relay MK. When the main relay switch closes, the L-line is connected to the wire 186, which feeds the armature of the relay OK, from where the circuit via line 189 to the armature of the relay IK, to the line 192, to the armature of the relay IR and from there to the clutch magnet IN leads. The L-line also has a connection to the wire 197 when the interlock MK is closed. The wire 197 leads over one branch to the armature of the relay LK, over another branch to the armature of the relays START, STOP and over a third branch to the armature of the relay QS.

The line 197 runs over the armature of the relay LK to the wire 2o1, and this is connected to the armature of the relay LF and runs from there to the Wire 204, which feeds the LEFT magnetic coupling, which, when excited, drives the longitudinal slide 4 drives to the left. Wire 197 is also across the armature of the START-STOP relay connected to the line 217, which is connected via the outer limit switch 151 the magnetic coupling O UT - is connected. The line 197 also runs over the armature of the relay QS to the line 21o that to the magnet SS of the clutch 131 leads.

- If the armature 221 of the reversing switch RSw is pushed up in order to make the connection to the wire 226, two circuits result. One runs from 226 via the armature of the relay RQ, the line 232, directly to the magnet winding RS of the coupling 13: 1 and from there back to the L + line. The other circuit runs via the contacts 227 of the limit switch 152 and the line 228 directly to the winding RIEHT of the magnetic coupling, which allows the carriage 4 to run back to the right.

To the machine during an operation at any point in time -stop and move the tool 1o to its starting position, needs you just move the shift lever 181 from its neutral central position to the left into its Tml; eJlrstellun.g to kill. The shift lever 181 is resilient in its central position by a spring held and immediately returned to this position by this when you touch him lets go.

8 shows the circuit diagram, the longitudinal slide 4 being in its right end position and the transverse slide 8 being in its outer retracted position. The main switch 157 is closed and the starter switch 181 is in its central neutral disconnected position. The relays LK and IR are energized via switch A. The contact of relay LK * is therefore separated and that of relay IR is closed. The START- STOP relay is also excited via switch B and line 249 and opens its contact. Furthermore, the contact of the relay SK is also open, since its winding is excited via the ending on the right limit switch 152, the contacts 263 and the line 262. The contact switch of the START-ST OP relay is open because the START winding is energized via line 241 and switch C. The relay switches LF and IK are both closed because their windings are energized in parallel with the START winding via: switch C. The relay switch OK is closed because the circuit of its winding is separated by the relay switch SA. The main relay switch MK is also in the disconnected position.

To start the machine, the hand lever 181. Of the switch 182 is temporarily moved to the right so that its switching arm rests on the terminal 18o and connects the line N i with the line 18o, whereby the winding 175 of the reversing switch RSw is short-circuited. This has the consequence that the armature 22o establishes the connection with the line 166 and thereby closes the circuit for the winding of the main relay MK. This circuit remains closed until coil 170 is energized in the manner discussed below. The relay switches QS, STOP and LK are open so that no current flows in line 197. However, the relay switches OK, IK and IR are still closed. As a result, a closed circuit runs from L- through 185, 186, 189, 192, 255 and magnet IN to line L +. By energizing the magnet winding IN ', the cross slide is advanced inward, the first contact finger 75 sliding over the hook 85 of the switch B and opening it. The advance of the cross slide continues until the switch A is opened by the first stop 75. This disconnects the circuit of the magnet winding IN at the relay switch IR and the cross slide stops. But the relay switch LK closes and creates the following circuit: line 197, armature of relay LK, line toi, armature of relay LF, line 204, magnet winding; LEFT, head of L +. The excitation of the magnetic winding LEFT has the consequence that the longitudinal slide now runs to the left. As a result, returns. the limit switch 152 returns to its initial position and separates the contacts 263, whereby the relay switch SK is closed. The longitudinal slide now continues its movement until switch C opens.

This disconnects the LF relay winding circuit. The switch of this relay opens and disconnects the circuit of the magnetic winding LEFT, whereby the longitudinal slide stops. This also opens the relay switch IK and closes the START-STOP relay switch. This has the consequence that the line 197 is connected to the magnet winding OUT via the line 217 and the closed limit switch 151. This is therefore excited and has the effect that the cross slide 8 is retracted outwards and the switch A can be closed. The withdrawal continues until the finger 75 releases the switch lever B and this closes its contacts itself. When this happens, the windings of the relays QS and OK are energized, so that the switch of QS is closed and that of OK is opened. By closing the relay switch QS, a circuit is established which runs as follows: line 197, line 210, magnet winding SS of clutch 131, line L +. The excitation of the winding SS of the magnetic coupling 131 causes the carriages D and E to be set in motion from their starting position until they reach their second switching position. During the advance of this carriage, the cams M and N revolve; the cam 17 initially closes its contacts 148, thereby preparing the circuit for the relay RQ. This circuit is closed, however, not yet because of the separation of the contacts 263, so that. - the winding or the armature of the relay RQ is not energized and the reversal of the cams M and N has not yet taken place. The cam disk N also closes its contacts. Finally, the switch B is opened again because the bend 85 slides laterally under the next stop finger 75. The carriages D and E continue their movement until they are stopped by the fact that the cam disk N separates its contacts again. This causes the QS relay to drop out, so that the relay switch QS is opened. During the advance of the carriages D and E, the switch C is closed again as a result of its adjustment. The cross slide S and the longitudinal slide 4 now perform the same work cycle again. The tool holder moves to the left, then stops and then goes outwards, whereupon the carriages D and R move again. This work cycle continues until - the limit switch Io9 is closed by the contact ball Io8. As a result, the winding 170 of the reversing switch is short-circuited, and the armature 221 connects the line 226. As a result, the following circuit is closed: contacts 227, line 228, winding RIGHT of the magnetic coupling. - The carriage .4 now moves to the right until it is stopped by opening the contacts 227 of the limit switch 152. If the contacts 227 are opened, the contacts 263 close and thereby open the relay switch SK. The relay switch RQ closes because the contacts 148 are closed because the roller has run off the projection of the cam 1I. As a result, the relay RQ connects the line 226 to the line 232, which leads to the winding RS of the magnetic coupling 131. As a result, the carriages D and E run back until they are stopped by opening the contacts 148 of the cam disk 1111. By opening these contacts, the relay RQ also drops out. The 'machine is now ready to process the next workpiece and is back in its starting position.

By returning the setting slides D and E to their starting positions, switches A, B and C are all closed. Now you can take the finished workpiece out of the lathe and clamp a new one in order to then repeat the work cycle by temporarily switching the hand switch I8I to the right.

Claims (3)

PATENT CLAIMS: i. Electrically controlled automatic lathe for Machining of workpieces with a graduated, gradually increasing diameter with one spindle each for longitudinal and horizontal tension, the rotary movement of which is controlled by the main spindle drive is derived via electromagnetic clutches, which through .am the frame and longitudinal slide or stops arranged on the longitudinal slide and cross slide so that they can be adjusted relative to one another can be controlled automatically in such a way that when a contact is switched off the longitudinal feed is switched on for the forward movement of the cross slide and .The longitudinal slide after turning off a certain length of the workpiece against a The stop is running and thereby the longitudinal feed is switched off and the face retraction switched on, characterized in that the cross slide to the next --- larger diameter withdrawn, stopped by a plan retraction switch (B) and again until the contact (A) for the forward movement of the cross slide is switched off which then initiates the longitudinal feed. 2. Lathe according to claim i, characterized in that the adjustable stops (75) determining the step diameter on the face slide (8) and the face feed switch (A) with the face retraction switch (B) on the slide (D) guided on the longitudinal slide (.4) ) are attached, which brings the switches (A and B) one after the other into the effective range of the stops (75) in cycle with the successive retraction movements of the cross slide. 3. Lathe according to claim i and 2, characterized in that the step lengths defining stops (98) on the bed of the lathe and the longitudinal feed switch (C, IoI) is attached to a slide (1o5, E) that is transversely guided on the longitudinal slide (.4) are in time with the successive retraction movements of the cross slide the switch (C) successively brings into the range of action of the stops (98). q .. Lathe according to Claims i to 3, characterized in that for the step-by-step shifting the slide (DundE) an auxiliary drive (13q.) controlled by the plan retraction switch (B) is provided, which at the same time drives a cam disk (N, 135), which the Auxiliary drive stops after a university run via a further switch (137).