DE3333243A1 - Multi-spindle automatic lathe - Google Patents

Abstract

In a multi-spindle automatic lathe with, for example, six tool spindles, the intention is, by simplifying the movement of the tools, to make it possible to manufacture a high number of workpieces per unit time and allow rapid replacement if a tool wears out or breaks. For this purpose, the invention envisages mounting the tools 81 on tool shafts which can be moved axially backwards and forwards along axes 66 parallel to the axis 8 of the drum, can be pivoted about the axes 66 and can be moved by the control cams. The rapid pivoting movement thereby possible and the rapid axial movement of the tools by means of the tool shafts makes it possible rapidly to machine workpieces held in the workpiece spindles. <IMAGE>

Description

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Wilhelm Moeltzner, Eichkampstr. 148, 1000 Berlin 19

Multi-spindle automatic lathe

The invention relates to a multi-spindle lathe

mat according to the category of claim 1.

5-In a generic multi-spindle automatic lathe according to DE-AS 20 36 766, the tools are arranged on a support group, which has a longitudinal support and a pair of transverse supports having. The latter are mounted on a common slide. The support group is moved

7 (2-with the help of tie rods attached at one end to the slide the longitudinal supports and the transverse supports and kinematically connected to a fixed control cam at the other end attached to the column of the automatic lathe. A ^ machining of a recorded in a workpiece spindle

ORiGINAL INSPECTED

Workpiece requires a complicated and combined movement of the slides of the longitudinal and transverse supports With the help of the tie rods kinematically connected to the control cam. It is therefore necessary for both the longitudinal supports 5 - as well as the cross supports radially or axially with respect to FIG to move the workpiece located in the four-part spindle. Furthermore, a change of tools requires both Separate assemblies on the longitudinal support and on the transverse support for exchanging the various longitudinal and transverse machining tools. In addition, due to the different longitudinal and transverse movements, a relatively long movement is required Processing time necessary.

The invention is therefore based on the object of the generic in accordance with multi-spindle automatic lathes to the extent 75 -that, through simplified movements of the tools, a faster processing, i.e. a high number of pieces per unit of time is possible, and that in the event of wear or breakage tools can be changed quickly in just a few simple steps.

Solution to this problem results from the characteristic Features of claim 1. According to the invention are the Tools arranged on the axially movable and pivotably mounted tool shafts in the drum, which of the '' Control cams are moved axially back and forth and swiveled

ORIGINAL INSPECTED

can. As a result, only a single tool receiving element, namely a single tool head, is required, which is mounted so as to be axially movable and pivotable by means of the tool shafts. Thus, the radial infeed of the tool to the workpiece stored in the workpiece spindle takes place by simply pivoting the tool shaft, which can be moved axially for longitudinal machining of the workpieces. In this way, however, processes such as longitudinal and face turning, but also through combined pivoting and axial movement of the tools, profile turning, copying and the like, can be carried out with a large number of pieces per unit of time.

In a particularly preferred manner, the tool heads carrying the tools are according to the features of the dependent claim 2 force-controlled swiveling and moving axially

] 5 ~ dex tool shafts by means of link guides, the axes of the links being inclined at small angles relative to the radial axis of the guide carriages assigned to them. This allows radial machining operations in one direction and radial grooving operations in the

JPO reverse direction can be executed. These machining operations Axial movements of the tool shafts and thus the tools can be assigned.

The gate controls enable the setting of 'the' gate at a small angle against the radial J? 5-axis the assigned guide carriage is a translation

ORIGINAL HNSPECTED

relationship between the control cams and the effective

Tool machining movement e.g. in a ratio of 1:10. :

In another embodiment, the tool shafts are under action of spring elements and the tool shafts are] - mounted on the drum, associated axially displaceable plunger which are axially movable by means fixed to the housing cams against the action of the spring elements of the tool shafts. In this way, the tools for longitudinal machining of the shafts of workpieces can be moved axially, the tool shafts being reset under the action of the spring elements. If a "pivoting movement of the tool shafts takes place at the same time as the axial movement, bevels, points, roundings and the like can be formed.

For longer workpieces, the workpiece spindles on the drum-5-mel are assigned axially moveable counterholders for the workpieces. These are used to guide the workpiece shafts during machining by means of the swiveling tools. The counterholders can also be designed as rotationally driven collets for the workpieces. In this case, for example, a workpiece can be reclamped within the automatic lathe in order to e.g. In the case of turned parts with a collar arranged in the longitudinal center, first of all machining one shaft part and after reclamping the other shaft part without having to remove the workpiece from the rffa automatic lathe. The counterholders can also -Ä

5-serve as a tool carrier, being in the manner of a tailstock

BATH ORIGINAL

machining of the end face of the workpiece by chamfering,

Facing or drilling becomes possible. The counterholders are purposeful

moderately on the drum mounted, axially movable, Rotary driven shafts arranged and axially controllable via guide cams fixed to the housing by means of guide elements.

The invention thus enables a multiplicity of machining operations on the workpieces clamped in the workpiece spindles at high working speed, both on the Outer sides and front surfaces as well as on the inner surfaces without having to reclamp or remove the workpiece from the automatic lathe becomes necessary. For every tool shaft with tool

/ (9-tool head, the automatic lathe has its own tool set, which is aligned outside of the automatic lathe according to the required tolerances and light in the event of breakage or wear can be exchanged. The tool set can be corrected in addition to the properties of the tool heads.

75-Such an adjustment does not affect the other, means of the other tool sets still to be machined A tool set preferably has a ground surface with a continuous groove. The different tool holder nests are worked into these e.g. by spark erosion.

.20-th. If a cutting edge of an indexable insert is worn, it can after loosening the fastening, they can be turned and clamped again.

COPY B ^AD ORIGINAL

From DE-AS 24 49 860 workpiece spindles are multi-spindle. Automatic lathes previously known, but in which, because of a twenty-five-gend ' necessary guidance of the tool shafts also only one machining

AO

Or the like. Is possible.

Further advantageous refinements of the invention emerge from the further subclaims.

The invention is illustrated below with reference to two in the drawings 5- illustrated. Exemplary embodiments of a six-spindle automatic lathe explained in more detail. Show it :

Fig. 1 is a longitudinal section along the line A-A in Fig.2 through the first embodiment a six-spindle automatic lathe,

] FIG. 2 is a view according to the line AA in FIG

on the drum of the automatic lathe,

Fig. 3 is a partial section along the line B-B in - 'Fig. 1,

Fig. 4 is a view in the direction of arrow C in Fig. 3,

15 ~ Fig. 5 shows a view according to Fig. 2 of the drum

of the automatic lathe in the second. 'form,

ORIGINAL INSPECTED

Fig. 6 shows a section along the line A-B in Fig. 5,

7 shows an enlarged detail X from FIG. 5,

FIG. 8 the view X according to FIG. 6,

9 shows the view Z according to FIG. 6,

5- Fig. 10 the view Y according to Fig. 6,

Fig. 11 various working examples and

• ~ - Fig. 12 a special working example.

The machine shown in FIGS. 1 and 2 for reworking pre-machined, especially extruded, rotationally symmetrical workpieces, such as screws, wheel and welding studs _f hollow bodies and the like, comprises a housing 1 made up of a base plate 2 and four housing walls 3 to 6, which are fixedly mounted parallel to one another and at different distances from one another on the * ^% ^ - 75 base plate 2. As shown in section according to FIG. 2 _; the housing walls 3 to 6 are rounded at the top in a semicircle. In the housing walls 3, 4 and 4, a drum shaft 7 with drum axis 8 is mounted in radial ball bearings 9, 10 or two ^ "needle bearings 11 arranged next to one another The ball bearing 9 rests with its outer ring on a further Seeger ring 13. A shaft nut 14 tensions the ball bearings 9, 10 in such a way that

ORIGINAL INSPECTED

that the drum shaft 7 is axially fixed. The needle bearings 11 on the opposite side allow the necessary axial shaft play End of the drum shaft 7.

In the area of approximately in the middle between the outer housing 5 walls 3 and 6 arranged "housing wall 5 is arranged on the drum shaft 7 a drum 15 and by means of a Feather key 16 rotatably connected to the drum shaft 7. The drum 15 consists of two spaced apart Face plates 17,18, which by a hub body 19, the

7 £) -2ug! Eich accommodates the key 16, in one piece with one another are connected. The face plate 18 is mounted via a ball bearing 20 within the housing wall 5 and on its outer circumference Provided with a spur toothing 21 directly in the area of the ball bearing 20. A pinion engages in this

] 5-22 with · its corresponding face teeth. The pinion 22 is firmly connected to a pinion shaft 23, which has a shaft end via a needle bearing. 24 in the middle housing wall 5 and with its opposite end via a ball bearing 25 in a fixed to the base plate 2

2 (9-bound bearing block 26 is mounted. On the free end of the pinion shaft 23, a belt pulley 27 is non-rotatably arranged, which to a drive, not shown in detail

leads. In this way, by means of the drive, not shown, via the belt pulley 27, the pinion shaft 23,

ORIGINAL INSPECTED

the pinion 22 and the spur toothing 21, the drum 15 and with this at the same time the drum shaft 7 are driven in rotation. For the embodiment of the multi-spindle automatic lathe shown, a speed of 10 rpm S ~ is provided.

* ("Workpiece spindles)

In the rotationally driven drum 15 are six recording

devices 28 for workpieces 29 distributed symmetrically on the circumference of the drum 15 and with the drum axis 8 parallel Axes 30 arranged. The receiving devices 28 are as

70-rotationally driven collets 31 formed and include an outer sleeve 32, an inner sleeve 33 rotatably mounted in this, and an actuating mandrel mounted in this 34, a drive pinion 36 mounted on the inner sleeve 33 by means of ball bearings 35, one the drive pinion 5-36 with · the inner sleeve 33 connecting electromagnetic Clutch'3 ?, a control mandrel 34 controlling Control head 38, which is arranged on the free end of the actuating mandrel 34 and opposite the inner sleeve 33 is supported by means of a disk spring assembly 50, as well as

J? £) - at the opposite end forming the collet 31., resilient collet elements 39, which are inserted with their base collar 40 in the inner sleeve 33 and below Effect of a clamping cone 41, which is formed at the free end of the actuating mandrel 34. A closure

25- nut 4 2 secures the collet elements 39 in the axial

ORIGINAL INSPECTED

Direction.

The longitudinally slotted / resilient collet elements 39 emanating from the base collar 40 receive the annular workpiece 29 on an outer collar 42. By axial displacement 5 ~ of the clamping cone 41 to the left (seen in FIG. 1) within a corresponding conical inner bore of the collet elements 39, these are pressed radially outward and clamp the circular disk-shaped workpiece 29 on its inner circumference. The clamping force is applied by the disk spring assembly 50, which is under the action of the control head 38. This comprises an annular body 44 which is axially fixed on the actuating mandrel 34 and which can be radially slidably moved 43 with DU.

75 "46 are attached. The radial bearing 45 is in axial grooves one with a DU sliding bearing on a gear hub 55 rotatable mounted sliding ring 48, which is rotatably fixed between the pinions 36 with the drum 15 via a carrier shown in dashed lines connected is . The radial bearing 46 runs along a curve 49,

^ 0-which is fixed on the housing wall 4. That way you can the control head 38 by means of its axially movable ball bearing 45 within the axial grooves 47 during the rotation of the Drum 15 in the direction of the axis 30 of the receiving device 28 back and forth under the action of the cam 49.

be moved. A rotation of the ring body 44 itself

ORDINAL INSPECTED

-W-

however, it is not possible. By means of the curved path 4 9 is thus when the collet 31 rotates together with the Drum 15 an opening and closing movement of the collet 31 generated, the closing force exclusively through

5-the relaxing disc spring package 50 caused is., since the curve 49 - as shown in Fig. 2 - extends only by an angle of rotation of about 120. The inner sleeve '(Work spindle). the collet 31 is mounted by means of radial bearings 51 within the outer sleeve 32, which

7 £} - is inserted into a longitudinal bore within the drum 15. A circumferential collar 52 of the outer sleeve 32 rests on the outside of the drum 15 in the area of the housing wall 5. On the opposite side of the drum 15, the outer sleeve 3 2 is fixed by a shaft nut 53.

(Workpiece spindle)
/ 5-The inner sleeve 33 / is connected via the electromagnetic clutch 37 to the drive pinion 36 which meshes with a gear 54 which is freely rotatably mounted on the drum shaft 7. For this purpose, a gear wheel hub 55 is radial by means of bearings 56 and Seeger rings 57 on the drum shaft 7

, 2 (9 "rotatable but axially immovable. The gear hub has a further gear 58 at a distance from the gear 54, which is arranged directly next to the housing wall 4 and which is in engagement with a pinion 59. This is cantilevered on a pinion shaft 60, which

25-in turn, by means of bearings 61 and 62 in the housing walls 3

BAD ORIGINAL ORIGINAL INSPECTED

or 4 is stored. The bearings 61, 62 are circlips 63rd held. On the end of the shaft 60 opposite the pinion 59 is a pulley 64 cantilevered / leading to another, not closer

5-illustrated drive leads. This drives over the pulley 64, the pinion shaft 60, the pinion 59, the gear hub 55 with the gears 58 and 54, the drive pinion 36, which is on the inner sleeve 33 of each receiving device 28 by means of the bearings 35

70-stored. With activated electromagnetic Coupling 37 can, by means of the constantly rotating drive pinion 36, the inner sleeve 33 and thus the Collet 31 are driven in rotation. In the embodiment, the collet 31 is at a speed between

75-1500 and 3000 U / min driven, whereby depending on the size of the workpiece 29 cutting speeds of about 100 / min result. By switching off the electromagnetic clutch 37 of a collet 31, it can be briefly stopped because then the drive pinion

J? £) -36 'runs freely on the inner sleeve 33.

Also parallel to the drum axis 8 and symmetrical on the Circumference of the drum 15 'distributed between the receiving devices 28 for the workpieces 29 six tool shafts 65 with tool 25 parallel to the drum axis 8 ~~ schwenkach.se 66 stored within the drum 15. For this

COPY 'ORIGINAL INSPECTED

'15 sliding bushings 67 and 68 are inserted into the face plates 17, 18 of the drum, in which the tool shafts 6 5 are guided so that they can pivot and move axially. Between the face plates 17, 18 is on each tool shaft 6 5 a torsion spring 69 applied with axial tension, which is between the face plate 17 and a axially supported on the tool shaft 65 by means of a circlip 71 and on the face plate 17 as well as on the tool shaft'65 in the area of the

10 ~ thrust washer 70 is set to cause torsional stress. On the side of the face plate 17 opposite the torsion spring 69, a shaft nut 72 is screwed onto the tool shaft 65, which limits the axial movement of the tool shaft in the right direction (in

] 5 ~ Fig. 1 seen) causes.

Outside of the face plate 18 of the drum 15, each tool shaft carries 65 a tool head 73, which under the action of the torsion spring 69 by means of a guide roller 74 on a Control cam 75 is applied, which by means of a slide bearing 76

.2CKaUf the drum shaft 7 slidable and between a shoulder the drum shaft 7 and a Seeger ring 78 is axially fixed. The control cam 75 is via a support arm 79 with the Base plate 2 of the housing T firmly connected. The support arm is angled in the area of the control cam 75 and lies

J? 5-right (seen in Fig. 1) outside the range of

BAD ORIGINAL _Copy

Control cam 75.

Each tool head 73 carries a tool carrier 80 with it a cutting tool 81. This is in particular as an indexable insert or cutter head with, for example, 40 cutter-5 ^ combinations designed, which enables an accuracy of 1 0.01 mm even in rough factory operation. The top of the Cutting tool 81 points radially to the axis of rotation of workpiece 29, which is axis 30 of the receiving device 28.

7 (9 'As shown in Fig. 2 , the drum rotates counterclockwise according to arrow 82 - whereas the collets 31 with the workpieces 29 rotate clockwise according to arrow 108. A feed rail 83 is about 60 ° in front of the upper position .of the reception facilities

15 ~ 28 are provided for the workpieces 29, which are removed again after an angle of rotation of the receiving devices 28 of approximately 330 ° in the removal position 84.

A working process with the part of the multi-spindle automatic lathe described so far runs as follows: A non-cutting, pre-machined, in particular extruded, rotationally symmetrical workpiece 29, such as hollow bodies, screws, wheel or welding studs or the like, is fed to a collet 31 via the feed rail 83

ORIGINAL INSPECTED

and received by the collar 42 of the clamping elements 39. In this position, under the action of the cam 49, the control head 38 is driven to the right (as seen in FIG. 1) against the action of the disk spring assembly 50, whereby the 5 ~ clamping cone 41 releases the collet elements 39, which are pressed inward under the action of their spring force.

29
As soon as the workpiece supplied has been picked up by the collet chuck elements, the control head 38 is turned to the left when leaving the short curved path 49 (as seen in FIG. 1)

70 moved under the action of the disk spring assembly 50, whereby the workpiece 29 is clamped by the collet elements 39 of the collet 31. While the drum 15 rotates counterclockwise (arrow 82), is now under the action of the electromagnetic clutch 3 7 the

75-inner sleeve 33 of the collet 31 in working rotary motion

driven clockwise according to arrow 108. The drive "" "" takes place via the belt pulley 6 4 arranged on the left • and the teeth 59/58 and · 54/36.

As FIG. 2 shows, the radial distance of the control curve 20 increases 75 starting from the drum axis 8 when the drum 15 rotates counterclockwise according to arrow 82 from the feed rail 83 to, whereby each tool head 73 with its cutting tool 81 against the workpiece is pivoted for machining. About after one

BATH ORIGINAL

Rotation of the drum 15 of 240 ° is the machining completed. In this area, the control cam 75 has a sharp drop in the direction of the drum axis 8 to have, whereby the tool head 73 under action 5- the torsion spring 79 out of engagement with the finished machined workpiece 29 comes, which is ejected in the discharge position 84 as a finished workpiece will. In this way, several working operations can be carried out radially on the tool shank.

70-To work operations also in the longitudinal direction of the tool shank and to be able to run on the face as well as inside, is between the middle housing wall 5 and. the right outer housing wall 6 on the drum shaft 7 a further face plate 85 non-rotatably by means of a feather key 86

75 and axially immovable by means of a shaft nut 87 stored. In this third belonging to the drum 15 Face plate 85 are located opposite the receiving devices 28 and thus the collets 31 for the workpieces 29 Counterholder 88 and the tool shafts 65

20-overlying tappet 89 mounted, both by means of cams 90 or cams fastened to the housing wall 6 91 are axially · movably guided.

Each counter holder 88 consists of a mandrel 92 which is attached to the associated,

ORIGINAL INSPECTED

axially directed cam 90 rests and at its other end a partially slotted receiving bore for a further tool 9 5 which is inserted into the receiving bore 94 in an exchangeable manner. The mandrel 9 2 5 ″ is axially displaceable in an axial bore of the face plate 85 by means of guide bushes 96,97, but below Effect of a feather key 98 within the .guide bushing non-rotatable. · guided. On the inner face of the Guide bushing 96 is supported by an axial spiral spring 99 7 £) - the other end of which is against one on the mandrel 9 2 by means of a Seeger ring fixed support disc 100 presses. In this way the mandrel becomes

93
via his leadership role / constantly against the axially directed

Cam 90 pressed and can under the action of the 75-cam 101 of the guide cam 90 axially against the workpiece 29 'are advanced against the action of the spring 99.

In the same way as the mandrel 9 2, the ram 89 is also supported on it via a guide roller 102 associated cam 91 from which the cam path

03 describes. The ram is at its other end 89 on the face 104 of the tool head 73 assigned to it. The ram 89-is also via guide bushes 105, 106 mounted within an axial bore in the face plate 85 belonging to the drum 15 and by means of a

BATH ORIGINAL

Coil spring 107 constantly on its guide roller 102 pressed against its guideway 103. The spiral spring 107 is supported on the inner face of the Guide bush 105 and rests with its other end 5 ~ on a support disk 108, which by means of a Seeger ring is set on the ram 89.

It is essential that the face plate 85 rotatably with it the drum shaft 7 is connected and thus rotates synchronously with the drum 15. Thus, the tool heads 73 can under

/ ^ - Effect of the control cam 91 in the direction of the tool pivot axis 66 are axially moved back and forth, whereby longitudinal machining of the workpieces 29 is made possible. By a simultaneous radial movement of the tool heads 73 can thus also be inclined surfaces, points and the like 5 "work pieces 29 can be formed.

The shown in the figures ^ 3 and 4 in principle as a partial section Guide device for the control head 38 of the collet 31 of the workpiece holding device 28 shows the radial restraint of the control heads 38y by means of the j? 0-; radial grooves 47 of the sliding ring 48 guided bearings 4 5, wherein the sliding ring 48 itself with the drum 15 via in-Fig. 1 only The carrier shown in dashed lines is firmly connected. The curve 49 for guiding and axial movement of the control head 38 via its bearing 46 extends only over a small circumferential -part between the discharge position 84 and "the feed rail 83 for workpieces 29 'or 29.

A summary of the function of the multi-spindle automatic lathe described is given below. The constantly rotating drum 15 / that from the face plates 17/18 on the one hand and 85 on the other hand ..

5 ~ and with the six workpiece holding devices .28 equipped / which is controlled by the curve piece; 4 9, successively open their collets 31 and after opening ■ would take the workpieces 29 close again, needed about 2/6 of the cycle for changing workpieces in the area

10-dex curve 49, while the remaining 4 / 6ths of the revolution are used for the actual machining process. Each workpiece holding device 28 is assigned a tool carrier 73 which is designed so that the actual tool set is adjusted outside the machine and with a single tool

75 handle can be exchanged. Everyone has to do this Tool head 73 is a ground plane surface with a continuous groove for receiving the tool carrier 80. In These are, in particular due to spark erosion, the different receiving nests for the tools 81, in particular, 20 Indexable inserts, incorporated. If a cutting edge of the insert is worn, it can after loosening its .The restraint must be turned and fastened again.

• Rotates together with each tool holding device 28

on. on the same axis a corresponding counter-holder 88, the J? 5-both as a counter-bearing (tailstock) and as a holder

BATH ORIGINAL

for a tool 95, such as a drill, internal turning tool and the like. Applies. The combination of the tool 8.1 acting radially via the central curve 75 with the axially displaceable tailstock, which is also controlled via a curve 5 "91, results in a variety of Possible applications in radial and axial directions. For example, with a single profile tool, any Contour can be produced within the working area of the automatic lathe.

/ 0-By arranging the. Curves 90.91 can for example, fully automatically - only through appropriate axial and radial movement the cutting Design of a tip on a workpiece 29 can be carried out, and the first machining - short and deep, each

] 5 ~ others, however, take place longer and at a lower feed rate. Any programming with all its sources of error can be dispensed with. Since the actual work process, die'zerspanung, takes place within fractions of a second, the output per unit of time is only dependent on the difficulty of the feed and the robust tension of the to be machined. Work pieces 29.

The tool head controlled by the central curve 75 is located outside of the when the workpiece is taken over

ORIGINAL INSPECTED

Change area and does not approach the workpiece 29 until it has been securely gripped by the collet 31. While the machining process is now starting, the next collet 31 is already taking over the next workpiece

5-29 .. Distributed over the circumference of 360 ° there is always a collet 31 in the workpiece receiving station 83,. four collets 31 with their assigned workpieces are in the machining process and one collet is in the ejection position 84 for a finished

7 (9-machined workpiece 29 '.. The actual machining work takes place within a circumferential angle of about 240 ° an average cutting speed of 100 m / min, a workpiece about 20 mm in diameter and a rotational speed of the drum 15 of 10rpm are thus 100 revolutions

75 "rotations per minute available for one chip thickness 0.1 mm axially or radially a working travel of 10 mm to 'proceed. With an appropriate arrangement, the axial Feed can be replaced by a radial feed, . whereby a total of 10 mm of feed can also be achieved.

'20-The' automatic lathe is. designed so that at the same time a centering or a hole in the workpiece 29 can be formed, in the case of hollow bodies a recess, the The contour is determined by the shape of the tool. The automatic lathe comes to an achievement in the described way of working

25- of "at least 60 workpieces / per / min.

BATH ORIGINAL

• a * -

The multi-spindle automatic lathe described can also be used as a double-sided six-spindle automatic lathe for all-round machining are used by pressed parts. Here is the one to the right of section line A-A in FIG

, However, is accurately formed in mirror image to the 5-face plate 85 replaced with their associated components through a Trommelanorndung corresponding to the drum assembly on the left side located on the section line AA. The left-hand part of the

70 automatic lathes and clamps the workpieces as above described- for editing. After machining, the respective collet 31 is opened and that .on the one Side machined workpiece to the one already opposite Work spindle of the other spindle set pushed.

75 ~ For a short period of time, the workpiece is both Collets taken. But then the left one opens Collet, while the right one moves back with the automatically closed collet and to the one there in Stand-by tool set in working position

20-arrived. The for the machining process provided for the left side of the workpiece. Only then will the workpiece - after thus two turns on the two facing each other

Drums! Orders- ejected.

ORIGINAL INSPECTED

In the second embodiment of a six-spindle automatic lathe shown in FIGS. 5 to 11, the tool shafts 65 ^{'are rotatably and axially movably supported in the face plates 17', 1S 1 of} the drum 15 'by means of needle bearings 67', 68 '.

5 ~ The face plates 17 ', 18' of the drum 15 'mounted on the drum shaft 7' are surrounded by segment pieces 110, 111 in which the closed. Guide grooves 112, 113 are each formed on the end face, which form the control cams 75 '. The segment pieces 110,111 surround the drum 15 '

7ö'Uia the scope necessary for machining a workpiece and are set on housing walls 5 ', 5' ', which with the Base plate 2 of the automatic lathe are firmly connected.

Each tool shaft 65 'carries by means of a spline 114. A segment-shaped tool head 73, which is the actual

] 5-inch tool 81 which is assigned to a workpiece spindle 28 in each case. Radially to the drum axis 8 and to the axis 66 of each tool shaft 65, each tool shaft 65 is assigned a guide slide 115 which has the shape of a double V in cross section, as FIG. 8 shows. Every leadership

J? 0 slide 115 is mounted in two guide rails 116, which form an M shape. The two guide rails 116 are inserted within a recess 117 of the 'face plate 18'. The axis 118 of the guide carriage 115 runs radially to the axis of the drum 15 'and the axis 66 of the associated

Tool shaft 65 '

BATH ORIGINAL

The guide carriage 115 carries a at the outer end Guide roller 119, which in the guide groove 113 of the segment piece 111 is performed. The guide carriage 115 carries a backdrop piece 120 on its front, which

5 ″ with three threaded screws 121 lying in the axis of the guide carriage 115. The link piece 120 has a link 122 at the end opposite the guide roller 119, the axis of which is directed at a small angle cC against the radial axis 118 of the guide carriage 115

7Ö is. The backdrop 122 sits within the backdrop piece 120 in a slot 123, which gives the opportunity to Adjustment of the width of the link 122 is made possible by means of clamping screws, not shown.

Another guide roller 124 is guided / 5 ^ in the setting 122, . Which on the inside facing the drum 15 ' of the segment-like tool head 73 'is fixed.

According to FIG. 2, in the second exemplary embodiment according to FIGS. 5 and 6, too, each of the six workpiece spindles 28 has a tool shaft 65 ′ with a tool head 73 ′ and a tool 81 arranged in a pulling manner. During one revolution of the drum 15 "of the guide groove is caused to a radial movement of the guide block 115 to the drum axis 8 under the action of different radial distances. This radial movement causes due to the inclined as' the angle cC against the radial axis 118 backdrop

ORIGINAL INSPECTED

122 a pivoting movement of the tool head 73 '.

For the axial movement of the tool shaft 65 ', two M-shaped guide rails 130, 131 are fixed ^{on the faceplate 17 1, which guide rails between them}

5 ″ 3 slide 132, which has a double V shape. The guide carriage 132 carries at its outer end a guide roller 133 which is inserted into the guide groove 112 of the segment piece 110 intervenes. On the outside of the guide carriage 132 carries a link piece 134, which by means of two

/ ^ 'Bolts 135 is fixed. The link piece 134 has a Link 135, the axis 136 of which is directed at a small angle against the axis 137, in which the guide carriage 132 is movable. The axes 118, 137 of the guide carriage 115 and of the guide carriage 132 run

75 ^"e J weils radially to '-Trommelachse 8 and through the pivot axis 66 of the tool shaft 65th

A guide roller 138 engages in the link 136 and is mounted 20 ″ by means of a bearing pin 140 within a slotted sleeve 139 rotatably mounted in the tool shaft 65. The sleeve 139 is axially fixed in the shaft 65 ′.

A sliding movement of the guide carriage 132 in its

it little Vi BATH ORIGINAL

Radial axis 137 causes due to the small angle β , below

which the link 135 is employed with respect to the radial axis 137 is an axial displacement of the tool shaft 65 '. The engagement of the radially movable link piece 134 in the tool shaft 65 'does not hinder its pivotability, 5 ^ because the tool shaft 65 'can be pivoted relative to the sleeve 139 remain.

The link piece 120 with the link 122 lies in a plane parallel to the faceplate 18 'and parallel to the tool head 73', so that the working plane of the 'Ö-Külisse 122 open on one side is also in this plane. The displacement plane of the link 122 lies in one to the axis 66 of the tool shaft 6 5 ^; vertical plane.

In contrast, the Verschiebeebene.des sliding piece 134 and the sliding 135'in the plane der.Achse is ^66} 5- ~ tool shafts 65, so that the displacement plane of the slide is 135 in this plane, which coincides with the radial axis 137 of the guide carriage 132nd

The link piece 134 also has a slot 141 extending from the inner end of the link 135, the slot of which ? 0-width can be adjusted by means of a screw 142, so that the width of the backdrop 135 can also be adjusted or adjusted. '

The angles of inclination oC and ß of the scenes 122 and 135, respectively

ORIGINAL INSPECTED

determine the swivel path or the axial stroke of the tool shaft 65 ',

Fig. 11 shows various working examples for workpieces, which by means of the six-spindle 5 'automatic lathe described are editable. In all examples there are top views of the several tool cutting edges Tool 81 shown together with the respective workpiece before and after machining. By means of arrows they are successive work steps in the order

] 0 ~~ 0 to 4 and backwards (Re 4-0). The vertical arrows each mean a pivoting movement of the tool head 73, 73 'about the axis 66 of the tool shaft 65, 65'. The horizontal arrow means an 'axial movement of the tool head 73, 73' in the direction of the axis 66 of the tool shaft

75-65.65 '. · An oblique arrow line means a superimposed one Movement in both directions.

11a shows the chamfering and undercutting of a workpiece. 11b shows piercing, longitudinal machining and crowning of a workpiece end face. Figure 11c

J? 0- and 11d show an external chamfering and internal grooving. 1J e shows the production of an expansion screw Grooving, longitudinal machining with the formation of an inclined surface and back turning of the end face of a screw head . ,. The workpiece is in the tip of a whipstick

- recorded. BATH ORIGINAL

J -t

11f shows the manufacture of a spark plug body. The radial movement from 0 to 1 can be carried out in an oscillating manner in order to achieve up to to work towards the core diameter of the groove. This will be

5-so-called D. three-flank chips avoided the tool Load unnecessarily, generate a great deal of heat and the chip would only solidify unnecessarily. The tool 81 oscillates back and forth in the axial plane with a short stroke, with the commenced chip breaks off and then the

7 (9-other flank is machined. The result is short, good Removable chips. Here, too, the workpiece is from one

Tailstock tip added. 11g shows the production of wheel bolts, the contour of which is worked out from groove and radius. Here, too, is the workpiece again / 5 ~ "added to the tailstock center.

Finally, FIG. 12 shows the production of a sleeve body which is particularly difficult to machine, the a cutting ring profile is obtained, which must have the best possible tip while avoiding the formation of a degree. ~ Here, the profile is first prepared using the grooving process and finely finished with the same tool in the same operation. The, thereby achieved peak at the The inner edge of the cutting ring is extremely sharp.

ORIGINAL INSPECTED

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Claims (1)

Claims mV) multi-spindle automatic lathe, especially for post-processing of non-cutting, pre-machined, extruded, rotationally symmetrical Workpieces such as screws, wheel and welding studs, hollow bodies, rings and the like, as well as separators from 5- bar material, with a rotating drum, with several rotationally driven symmetrically arranged on the circumference of the drum and with axes parallel to the drum axis Workpiece spindles, with these assigned, mounted on the drum, in the direction of the drum axis and transversely to this ■ J (^ -movable tools and with control cams fixed to the housing for the movement of the tools in relation to the workpiece spindles, characterized, that the tools (81) are parallel to the drum axis (8) ORiGiNAL INSPECTED -λ- J NACi '' -3-I ·· 'J Axles (66) axially reciprocable about the axes (66) pivotable and movable by the control cams (75, 75 ') Tool shafts (65) are mounted. 2. Multi-spindle automatic lathe according to claim 1, characterized in that on the drum (15) radially to the axes (8,66) of the drum (15) and the tool shafts (66) of each tool shaft (6 5) associated guide carriage (115,132) are guided, one end of which engages by means of a guide roller (119,133) in the closed guide groove 113,112) 7 ^ -a control cam (75 ') and the other end via a link (122,136) with a guide roller (1 24, 138) is connected to the tool shaft (65 ') , the axis (118,137) gate (122,136 behind a small angle ( Jl ₁ β') is inclined to the radial axis of the guide carriage. ~ 2>. Multi-spindle automatic lathe according to Claim 2, characterized in that the tools (81) are mounted on segment-shaped tool heads (73 ') attached to the tool shafts (6 5 ^), on which the guide rollers 124) ₍ for the pivoting movement of the tool shaft (65 /) is attached, and that the 2ö-associated link (122) is arranged and movable in a plane perpendicular to the axis (66) of the tool shaft (65 /). 4. Multi-spindle automatic lathe according to claim 2, characterized in that that the leadership role. (138) for the to and fro ' copy j -3- - 3243 Continuous movement of the tool shafts (65) within a slotted sleeve (139 is arranged and that the associated link (136} is arranged in the plane of the axis (66) of the tool shafts (65 ') and 5-movable. 5. Multi-spindle automatic lathe according to one of claims 1 to 4, characterized in that the closed guide grooves (112, 113). the control cams (75 ') on the front sides of the housing walls (17J18 ') are arranged and can only be accessed via the 70-processing of the workpieces (29) necessary part of the scope of the Extend the drum (15). 6. Multi-spindle automatic lathe according to claim 1, characterized in that that the tool grooves- (65) themselves on the drum (15) supporting spring elements for pressing on 75-the control cam (75) are assigned. 7. Multi-spindle automatic lathe according to claim 6, characterized that the spring elements are designed as torsion springs (69) which surround the tool shafts (65) and are provided with axial tension are . ~ 8. Multi-spindle automatic lathe according to Claim 7, characterized that under the action of the axially and radially acting torsion springs (69) standing tool shafts (65) on the drum (15) mounted, axially displaceable plunger (89) assigned: are which by means of a guide curve (91) fixed to the housing »jeα en the COPY "BAD ORIGINAL I SUBMITTED 9. Multi-spindle automatic lathe according to one of claims 1 to 8, characterized in that the workpiece spindles provided with collets (31) on the drum (15) are axially movably mounted counterholders (88) for the workpieces £ f- (29) are assigned. 10. Multi-spindle automatic lathe according to claim 9, characterized in that that the counterholders (8) are designed as rotationally driven collets (31 ') for the workpieces (29) are. IQ-AA . Multi-spindle automatic lathe according to claim, characterized in that the counterholders (88) are arranged on axially movable shafts (92) mounted on the drum (15) and are axially controlled by means of guide elements (93) via a guide cam (90) fixed to the housing . ORiGiNAL INSPECTED