DE3816708A1 - DEVICE FOR ADJUSTING THE PILOT OF A PUNCHING MACHINE - Google Patents

Abstract

The pivot block 2 of the ball end 3 of the push rod 4 is provided with an outer thread 8. This thread engages into the inner thread 9 of a threaded sleeve 10 which is connected to the ram 1 at 31. The block 2 is guided by means 34-36 for longitudinal movement in a slide sleeve 6 which is longitudinally fixed but rotatable relative to the machine frame 7. The sleeve 6 can be rotated by a drive shaft 16 supported within the machine frame and via a gear wheel assembly 17, 18. If the drive shaft is rotated the block 2 is rotated via the sleeve 6 and means 34-36. Accordingly, a longitudinal displacing movement of the threaded sleeve including the ram rigidly mounted thereto is achieved. This leads to an adjustment of the height position of the ram. The adjustment means are located within the machine frame such that its operating members are not subjected to the impacts generated during the punching and dynamic forces. Furthermore, the adjustment can be made during operation of the machine. <IMAGE>

Description

The invention relates to a device for Height adjustment of the ram of a punching machine at least one with one in a spherical cap Ball head equipped connecting rod.

In known punching machines with a Ball end equipped connecting rods, the Height adjustment of the ram by thread, which are arranged either on the connecting rod or in the tappet. Here is the entire adjustment device in the ram arranged. This has the disadvantage that the Adjustment devices on the one hand by punching and on the other hand strained by the dynamic forces will. Furthermore, the height adjustment of the ram is the aforementioned arrangement of the adjusting device in Ram only possible when the machine is at a standstill been.

Purpose of the invention, the cited parts to fix.  

The device according to the invention is through characterized the features of claim 1.

As a result, the height adjustment of the Plunger also be possible in operation because the Ver adjustment device can be moved into the machine housing can.

The subject of the invention is as follows based on the drawings, for example. It shows

Fig. 1 simplifies a section through a punching machine having a connecting rod equipped with a ball head;

Fig. 2 shows a section through an embodiment of the device according to the invention, and

Fig. 3 is a view of the crank-side end face of the embodiment shown in FIG. 2.

In Fig. 1, a simplified sectional view of the most important area of a punching machine is shown for general illustration. The connecting rod 4 is driven by the machine shaft via an eccentric device 28 . The connecting rod 4 is equipped at the bottom with a ball head 3 which is arranged in a spherical cap 2 . The plunger 1 is thus driven, which is guided through an upper guide 12 in the machine housing 7 and via guide columns 29 in a lower guide 26 of the machine housing 7 . Reference numeral 14 denotes the upper seal and reference numeral 27 the lower seals. A respective punching tool is arranged in space 30 under the plunger 1 .

Reference is now made to FIG. 2. FIG. 3 shows the right half of a connecting rod 4, which terminates in a spherical head 3. This ball head 3 is mounted in a spherical cap 2 . The bearing is such that the connecting rod 4 can perform swiveling movements on the one hand relative to the cap 2 , and on the other hand that a relative rotation between the ball head 3 and the cap 2 can take place. The calotte 2 has an external thread 8 . This external thread 8 meshes with the internal thread 9 of a threaded sleeve 10 . The threaded sleeve 10 is screwed to the plunger 1 at the bottom via screw bolts 31 . The reference number 32 denotes an oil gutter, which is sealed at the top by means of a seal 33 against the threaded sleeve 10 . A first section 11 of the threaded sleeve 10 forms part of the upper guide 12 (see FIG. 1) of the plunger 1 . Underneath, a second section 13 of the threaded sleeve 10 forms part of the upper seal 14 , for which reference is also made to FIG. 1.

At its upper end, the spherical cap 2 is screwed to a transition piece 35 via bolts 34 . This transition piece 35 ends in a slider 36 which is guided in longitudinal guides 37 of a sliding bush 6 in the direction of the connecting rod axis 5 sliding.

The sliding bush 6 is in turn supported by a roller bearing 38 in the machine housing 7 .

A threaded ring 15 is arranged under the cap 2 , which also meshes with the internal thread 9 of the threaded sleeve 10 . This threaded ring 15 can be locked via bolts 39 . This rotatable threaded ring 15 is used for adjusting the thread play between the calotte 2 and the threaded sleeve 10 .

The part of the device described so far works as follows. The movement of the connecting rod 4 is converted via the ball head 3 and the spherical cap 2 into a reciprocating movement of the plunger 1 , since the spherical cap 2 with its external thread 8 is in screw engagement with the threaded sleeve 10 . The threaded sleeve 10 can not be rotated relative to the sliding bush 6 since it is slidably guided over the sliding piece 36 and the guides 37 in the direction of the connecting rod axis 5 .

The height of the plunger 1 is now adjusted by the components arranged on the right on the machine housing 7 in FIG. 2. The drive shaft 16 can be rotated by means of an attachable hand crank 40 . It should be noted here, however, that the plug-on hand crank 40 forms only one of the drive options 16 provided for the drive shaft 16 . The drive shaft 16 could also be rotated by a motor or other drive devices.

The drive shaft 16 ends with a bevel gear 17 . This bevel gear 17 meshes with an internal bevel gear 18 of the sliding bush 6 . Thus, rotating the drive shaft 16 causes rotation of the sliding sleeve 6 . It should also be noted here that the drawn bevel gear or the bevel gear 17 is only a possible execution. The transmission between the drive shaft 16 and the sliding sleeve 6 can also be carried out by worm gear or by spur gears.

If the slide bushing is now rotated about the connecting rod axis 5 , it being noted that it is mounted in the machine housing 7 via a roller bearing 38 , it takes the calotte 2 with it via the guides 37 and the slide 36 and the transition piece 35 . Since the threaded sleeve 10 is firmly connected to the plunger 1 , it cannot rotate, since this is not possible due to the guide columns 29 and lower guides 26 (see FIG. 1). So the dome 2 is rotated around the ball head 3 . The dome 2 thus carries out a screwing movement in the threaded sleeve 10 . Now that the ball head 3 is not longitudinally displaceable relative to the plunger 1 via the connecting rod 4, the screwing movement mentioned causes the threaded sleeve 10 and thus the plunger 1 to perform a displacement in the direction of the connecting rod axis 5 . By shifting the plunger 1 in particular, the height of the plunger 1 is now changed, ie the height adjustment of the plunger 1 is carried out.

Since the sliding piece 36, which is connected to the calotte 2 in a manner fixed in terms of movement, is guided in a longitudinally displaceable manner along the guides 37 of the sliding bush 6 , it is obvious that the height adjustment of the ram 1 can be carried out during operation of the punching machine and from the outside. It is therefore not necessary to switch off the punching machine to adjust the height of the ram.

Obviously, the drive shaft 16 of the adjustment mechanism must be lockable for fixing the respective height adjustment of the plunger 1 . For this purpose, the drive shaft 16 is connected to a ratchet gear 19 . This ratchet gear 19 cooperates with a locking slide 20 . This locking slide 20 is biased by a helical spring 41 for engagement in the locking gear 19 , this locking.

Unlocking is carried out by supplying compressed air to act on the piston 43 in the channel 42 in a manner still to be described, the loaded piston surface being arranged opposite the spring 41 of the screw. The compressed air supplied through the channel 42 to the piston 43 causes a compressive force on the locking slide 20 which is greater than the biasing force of the coil spring 41 , so that the locking slide 20 is moved down out of engagement with the locking gear 19 .

The compressed air supply is controlled by a control valve 21 , in which compressed air is supplied from the pneumatic control circuit of the punching machine through the inlet 44 . This supplied compressed air acts on a plate 45 of the control valve 21 , which blocks the compressed air supply from the inlet 44 to the channel 42 .

The crank handle 40 has a hub 46 equipped with a control bevel 22 . If the hand crank 40 is placed on the driver 47 of the drive shaft 16 , the control bevel 22 is pushed against a pin 48 of the control valve 21 to the system. So that the pin 48 is moved downward so that it rests on the plate 45 and a further displacement of the pin 48 , caused by the complete insertion of the hub 46 of the crank handle 40 , causes the plate 45 to be lifted off its seat, and consequently the compressed air entering through inlet 44 comes around plate 45 and through channel 42 to act on piston 43 . Then the drive shaft 16 is released by the gate valve 20 . The channel 42 is vented when the hand crank 40 is removed by a channel 49 which passes through the pin 48 .

The respective height adjustment of the plunger 1 is displayed by a display device, which is shown in FIG. 3. The display device 23 is drawn rotated to 90 ° for the sake of clarity. In the Fig. 3 and the control valve 21 and the pin 48 are visible.

The illustration in FIG. 2 shows that the drive shaft 16 is connected to the ratchet gear 19 via a tongue and groove connection 50 . Furthermore, the drive shaft 16 is connected via the same tongue and groove connection 50 to a washer 51 .

The adjustment mechanism is now such that a suitable choice of the number of teeth from the bevel gear 17 and internal bevel gear 18 and the slope of the singe thread 8 and internal thread 9 , a complete 360 ° rotation of the crank handle 40 causes an adjustment of the height of the plunger 1 by exactly 1 mm. On the disc 51, a scale 52 is now arranged with a pitch of hundreds, so that in the lower window 53 of the display device 23 in each case the position of the plunger 1 in _^1/100 mm can be read.

Referring back to Fig. 2, it is evident that a ratchet gear 19 right an eccentric section 54 connects, on which the sun gear 25 of a planetary gear is mounted, which meshes with an internal toothing 55 . When the drive shaft 16 rotates, the sun gear 25 rolls on the internal toothing 55 and drives the ring-shaped carrier of the display scale 24 via the toothing 56 (see FIG. 3). This display scale 24 is provided in whole millimeters to indicate the height of the plunger 1 . Thus, the height position of the plunger 1 in millimeters and on the lower scale 52 can be on the top scale 24 to _^1/100 millimeters precisely read.

Although particular Fig. 2 shows only one connecting rod and a sliding sleeve, is to be understood that, when 2-connecting rod engine, the coupling of the two sleeves can be provided in the machine housing.

So it can be seen that the whole Adjustment mechanism in or on the machine housing and not, as before, arranged in the plunger. The heights adjustment of the plunger can be done during operation perform the punching machine and adjust the height can be easily read from the outside.

Claims (6)

1. Device for adjusting the height of the plunger ( 1 ) of a punching machine, which has at least one connecting rod ( 4 ) equipped with a spherical head ( 3 ) mounted in a spherical cap ( 2 ), characterized in that the spherical cap ( 2 ) is connected to the connecting rod axis ( 5 ) centric slide bush ( 6 ) is mounted in the machine housing ( 7 ), which calotte ( 2 ) in the slide bush ( 6 ) is rotatable with it and slidably guided in the direction of the connecting rod axis ( 5 ), which slide bush ( 6 ) in the machine housing ( 7 ) is rotatably mounted about the connecting rod axis ( 5 ) in such a way that the calotte ( 2 ) has an external thread ( 8 ) which meshes with the internal thread ( 9 ) of a threaded sleeve ( 10 ) firmly connected to the tappet ( 1 ) in such a way that the cap (2) is rotatable in the threaded sleeve (10), and that a first portion (11) of the threaded bush (10) is part of the upper guide (12) of the plunger (1) and a second portion (13) of the plunger (1 ) Part of the seal ( 14 ) of the plunger ( 1 ) g form the machine housing ( 7 ). 2. Device according to claim 1, characterized in that at the lower end of the spherical cap ( 2 ) with the threaded sleeve ( 10 ) meshing relative to the spherical cap ( 2 ) rotatable threaded ring ( 15 ) adjoins to adjust the thread clearance between the spherical cap ( 2 ) and the threaded sleeve ( 10 ) is used. 3. Apparatus according to claim 1, characterized in that the sliding bush ( 6 ) is drive-connected to a drive shaft ( 16 ) mounted in the machine housing ( 7 ). 4. The device according to claim 3, characterized in that the drive shaft ( 16 ) is equipped with a bevel gear ( 17 ) which meshes with a cone internal toothing ( 18 ) of the sliding sleeve ( 6 ). 5. The device according to claim 3, wherein the drive of the drive shaft ( 16 ) by a hand crank ( 40 ), characterized in that the drive shaft ( 16 ) has a locking gear ( 19 ) which cooperates with a locking slide ( 20 ) which can be moved into its release position by spring force against its blocking position and by compressed air acting against the spring force, the compressed air supply being controlled by a control valve ( 21 ) actuated by the hand crank ( 40 ) such that when the hand crank ( 16 ) is attached to the drive shaft ( 16 ) 40 ) a control slope ( 22 ) presses the control valve ( 21 ) into its open position. 6. The device according to claim 5, characterized marked by a height adjustment of the plunger ( 1 ) indicating the display device ( 23 ), the display scale ( 24 ) is actuated by a planetary gear with an eccentrically mounted on the drive shaft sun gear ( 25 ).