The invention relates to a drive system for a multipoint forming press.
According to WO 2004/056559, a press apparatus having one pressure point is known in which a direct drive that is arranged directly on the eccentric shaft and that is in the form of a frequency-controlled three-phase motor controls the movement of the slide via a connecting rod. No arrangement of this direct drive in the entire structure of the press, especially in large presses with a plurality of pressure points, is disclosed.
DE 10 2004 009 256 is a mechanical multi-servopress having a drive for a press with two pressure points in which one or a plurality of servomotors are allocated to each eccentric element for the stroke movement of the slide.
Known from JP 2000288792 is another servopress having one or a plurality of direct drives, each in the form of a servomotor on a crank mechanism, the crankshaft of which acts on the slide via a connecting rod.
Known from EP 1 082 185 is a press in which the drive of the slide is created using tension from below by four threaded spindles that are each arranged vertically in the guide corners and that are mounted in the table and driven by a servomotor. This press, which is essentially free of head pieces, makes low structural height possible. The attainable pressing force and cycle rate for the system are limited by the performance of the threaded spindles. Regardless of the pressing force and the size of the tool clamping surface, this solution always requires four not inexpensive drive systems.
A reduced structural height is attained in a press according to DE 10 2004 052 007 in that the drive for the articulated lever mechanism mounted in the head piece is each arranged vertically through the drive modules, which comprise a linear motor or rotating servomotor with downstream linear converter, laterally adjacent to the head piece in the area of the press supports.
The underlying object of the invention is to create a drive system for a multipoint forming press for flexible movements and tilt control for the slide such that it is possible to attain a low structural height for the press, high accuracy in the guidance of the slide, and high pressing forces and numbers of strokes with the available torques of servomotors and with reduced technical complexity.
The core idea of the invention is to furnish the drive for the slide by means of direct drive modules, preferably without upstream toothed wheel gearing, and, for a space-saving construction with a low structural height of the press, to arrange the pressure points of the slide with the associated direct drive modules laterally adjacent to the tool clamping surface in the vertical plane of the drive supports, wherein the direct drive modules, each comprising servomotor, stroke mechanism, and holding brake, are aligned coaxially in the press longitudinal axis or in the press transverse axis. With the availability of high-performance servomotors, the stroke mechanism may be driven directly, without upstream toothed wheel gearing that creates additional complexity.
The stroke mechanism transforms the rotating drive movement of the servomotor into a linear drive movement of the slide.
In addition to the principle of the crank mechanism comprising an eccentric shaft with a mechanically linked crankshaft, for a space-saving construction a crank shifter may be used in which the eccentric element of the crankshaft is connected to a sliding block that is guided in a guide unit for the block that is mechanically linked to the pressure point of the slide.
By using the crank mechanism, it is possible to use the advantages of the distance-dependent passage through the lower reverse point for a high cycle rate so that the risks of getting stuck, which the known direct spindle drives suffer from, are avoided, especially at the lower reverse point in the high-pressure phase when the rotational direction of the spindle is reversed.
Activating the servomotor or servomotors allows the creation of flexible movement profiles for the slide. It is possible to attain different stroke heights for the slide by selecting a 360° circular mode or a <360° pendulum mode on the crankshaft.
Because of the direct drive modules separately allocated to each pressure point, it is possible to regulate the spatial tilt of the slide in two planes.
One additional spindle drive for adjusting the height of the slide and one pressure pad for protecting against hydraulic overload are integrated in a known manner at each pressure point for the slide.
Depending on the number of direct drive modules, presses may be configured with different pressing forces and expansion of the tool clamping surface.
In addition to using two or four direct drive modules arranged in the press longitudinal axis, in the press transverse axis four direct drive modules may be advantageously employed for the arrangement. Moreover, especially when the arrangement is in the press transverse axis, six or eight direct drive modules are even possible, especially in presses that have a high pressing force.
When the direct drive modules are aligned in the press longitudinal axis, they are advantageously mounted in the drive supports, which are each positioned bilaterally adjacent to the slide in the press transverse axis. Moreover, it is also possible for them to be mounted in drive supports positioned in the press longitudinal axis.
When the direct drive modules are aligned in the press transverse axis, in a first instance they may be mounted on the drive supports oriented bilaterally in front of and behind the slide in the press longitudinal axis. In a second case the direct drive modules are each positioned on the drive supports aligned transverse to the press longitudinal axis.
In every case the pressure points for the slide and its pressure point frames are arranged laterally adjacent to or in front of and behind the tool clamping surface in the vertical plane of the drive supports.
The compact construction of this mounting of the direct drive modules on the drive supports makes possible reduced structural height of the press and also permits the former limit from the monolithic construction of table, supports, and drive housing to shift towards longer lengths of the tool clamping surface.
It is possible to use a hybrid structure for the press frame in larger presses, depending on the pressing force and extension of the tool clamping surface. In a first instance the drive supports embodied as monoliths may be secured to the press table by means of tension rods. The press supports and the drive housing arranged in their vertical plane form one unit. In a second case, press supports and the drive housing, also arranged in their vertical plane, are separated and secured to the press table jointly by means of tension rods.
During the pressing process, the flux of force between the upper tool arranged on the slide and the lower die positioned on the pressing table is closed via the press supports, which also assume the guide function for the slide. With the arrangement of the direct drive modules in the vertical plane of the press supports, the elastic deformation of the press supports in the horizontal plane may be reduced during the pressing process, which increases the accuracy of the guidance of the slide. The more the pressure points are positioned in the area of the line of the vertical flux of force of the support, the lower the horizontal deformation of the press support towards the press longitudinal axis and the press transverse axis.
The direct drive modules may be employed either as an upper drive with pressing action or as a lower drive with tension action on the pressure points of the slide. The direct drive modules may be used in two-point or four-point presses that are preferably controllable in an electronically synchronized manner. It is also possible to synchronize adjacent direct drive modules mechanically as a group and in the case of a four-point press to control both groups relative to one another in an electronically synchronized manner.
In the case of mechanical synchronization in four-point presses, the group is preferably formed by two direct drive modules aligned in the press transverse axis.
When there is mechanical synchronization, each group of adjacent direct drive modules that are coupled via a shaft are jointly controllable by at least one servomotor. When using a servomotor, the latter may be arranged either on the input side or on the output side of the group or between the direct drive modules. When two servomotors per group are used, either both may be arranged between the direct drive modules or a first servomotor may be arranged on the input side and a second servomotor may be arranged on the output side of the group of direct drive modules. It is also possible to position a first servomotor on the input side of the group and a second servomotor between the direct drive modules.
If all of the direct drive modules are electronically synchronized, the servomotors may be arranged either in a mirror image on the sides facing towards or away from the two direct drive modules or a first servomotor may be arranged on the input side of the group and a second servomotor may be arranged between the direct drive modules.
Two independently acting frictional safety brakes may be employed as mechanical holding devices to satisfy mechanical and personal safety requirements. The brakes may be integrated in the motor or may be positioned separately at the free end of the crankshaft.
The invention shall be explained in greater detail in the following using exemplary embodiments.
In the first exemplary embodiment, a two-point forming press can be seen in
While the servomotors 7.1, 7.2 in
The freely programmable servomotors 7 may produce a synchronous movement of the slide 3 using electronic coupling, and may compensate a tilt in the slide 3 using a spatial tilt control in two planes as a result of the elastic resilience when there is an off-center load or may create a target tilt.
It is also possible for both direct drive modules 2 to be jointly controllable either via a couplable shaft from both servomotors 7.1, 7.2 or from one servomotor 7.
A two-point forming press with the two direct drive modules 2 for an upper drive 4 aligned in the press transverse axis 19 may be seen in the second exemplary embodiment according to
This embodiment may be expanded to a four-point forming press in that two direct drive modules 2 are arranged one after the other in the press transverse axis 19. In this case, then, two pressure point frames 15, each allocated to a pressure point 12, project into the space 16 of the drive supports 5 aligned in the press transverse 19 axis. Either a separate servomotor 7 may be allocated to each direct drive module 2, or both direct drive modules 2 are jointly driven by one or two servomotors 7 that are mechanically coupled.
In the third exemplary embodiment according to
The fourth exemplary embodiment according to
In a third embodiment of a four-point forming press according to
This possible arrangement of the servomotors 7 according to
One drive system for a lower drive in a four-point forming press can be seen in
It is common to all of the embodiments that the direct drive modules 2 are arranged in the vertical place of the drive supports 26. Thus drive supports 5 in one case may be connected to the table 2 either monolithically or by means of tension rods 22. In another case, the drive supports 5 are each divided into a drive housing 27 and associated press supports 28 that are jointly connected to the table 2 by means of tension rods 22. As can be seen in drawings, it is also common to all the embodiments that the drive supports 5 are situated adjacent the space 16 which has as its upper extremity the tool mounting surface of the slide and as its lateral extremities innermost edges of vertical, upright supports, such as the legs of the monolithic body or the press supports 28, supporting the drive supports 5 and which innermost edges are vertical projections of innermost extremities of the drive supports 5. Allocated to all of the direct drive modules 2 are servomotors 7 with which it is possible to achieve flexible path and speed profiles for the movement of the slide 3, the target positions of the slide 3 preferably being produced using guide wave-controlled electronic cams. With respect to the path profile, a 360° circular movement, a reversing movement at an angle <360° that passes through the bottom reverse point, or a movement at an angle <180° that reverses in the area of the bottom reverse point may be selected. The latter mode may preferably be used in conjunction with the tilt regulation of the slide 3 that is possible with electronic synchronization of the pressure points 12, in one plane for a two-point forming press or in two planes for a four-point forming press.
Number | Date | Country | Kind |
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10 2008 034 971 | Jul 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2009/000913 | 6/29/2009 | WO | 00 | 1/25/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/009694 | 1/28/2010 | WO | A |
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Number | Date | Country |
---|---|---|
10 2004 009 256 | Sep 2005 | DE |
10 2007 026 727 | Dec 2007 | DE |
1 082 185 | Mar 2001 | EP |
2000-288792 | Oct 2000 | JP |
WO-2004056559 | Jul 2004 | WO |
WO-2006045279 | May 2006 | WO |
WO 2007140765 | Dec 2007 | WO |
Number | Date | Country | |
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20110126649 A1 | Jun 2011 | US |