This invention relates to a toggle press with two levers which are pivotably connected by means of a joint, the first of which is connected at its free end to a pressing tool, and the second of which is rotation-resistantly mounted at its free end on a shaft which can be rotated by a drive unit.
A toggle press comprises a toggle lever mechanism with two levers connected by means of a joint, whose free ends are connected with the associated machine frame on the one hand and with a tool or ram on the other. The ram can be moved in the direction of a workpiece by extending the toggle joint. The press can be driven by exerting pressure on the toggle joint, as well as by pivoting the lever mounted on the frame with the aid of a driven shaft. This invention is concerned with the latter type of construction.
Toggle presses can be built in a very stable fashion to permit the transmission of large forces. The design of a toggle press becomes complicated when workpieces of varying thicknesses require processing because the adjustment of the stroke and, in particular, the fine adjustment for adaptation to differing material thicknesses cannot be achieved without costly additional constructions. This is because, in the final phase of its movement through to complete extension of the two levers, a toggle press develops very high forces which can, in theory, be of an infinite order. A slightly wrong adjustment of a toggle press can therefore lead either to the destruction of the press, or to the application of insufficient machining force. Toggle presses are not, therefore, necessarily suitable for processes requiring only a relatively short working stroke applied with high force consecutive to a longish approach stroke.
There are prior art drive systems for presses whose stroke is composed of a larger approach stroke executed rapidly and with relatively low force followed by a short working stroke executed with high force. This is described with reference to a hydraulic-pneumatic press in the applicant's patent 100 51 042. The problem of adjusting the working stroke can be solved relatively easily in this case.
Hydraulic or pneumatic systems are not, however, available in every business, and in many cases, hydraulic drive systems cannot, or should not, be employed because of the constant risk of workplace contamination from leaking oil; in the food industry, for example, they are not generally permitted under existing legislation.
This invention is therefore based on the task of providing a toggle press of the above-mentioned type with a purely mechanical drive system whose stroke is composed of an approach stroke executed relatively quickly with relatively low force followed by a shorter working stroke executed with high force, and which permits an adjustment of the stroke path and the force applied at the end of the stroke path using relatively simple means.
According to the invention this task is solved in a toggle press of the above type in that the rotation-resistant connection between the second lever and the shaft is releasable, and in that the second lever is disposed on a section of the shaft contrived as an eccentric cam.
As long as the second lever is disposed rotation-resistantly on the rotatable shaft, rotating the shaft merely pivots the second lever which either prompts the extension or retraction of the toggle lever. If, on the other hand, the rotation-resistant connection between the shaft and the second lever is released, rotating the shaft will cause the second lever to move in its longitudinal direction due to the action of the eccentric cam. If the rotation-resistant connection between the second lever and the shaft is released when the toggle lever is essentially in its extended position, the eccentric cam causes a slight longitudinal movement of the tool attached to the outer end of the first lever in combination with a high pressing force.
Whilst when the second lever is pivoted, i.e. when the toggle lever is extended or retracted, the torque of the shaft acts on a stroke length equal to the distance of the axle of the shaft to the axle of the toggle joint, the lever arm is much smaller when the eccentric cam rotates in relation to the second lever.
This means that during the pressing process, the toggle joint is extended relatively quickly, and with a relatively low force, whilst a very high force develops during the intervention of the eccentric cam.
The combination according to the invention of a toggle press with an eccentric press affords the particular advantage over normal toggle presses that it permits adjustment/fine adjustment of the working stroke phase. Given that the working stroke starts when the toggle lever is already in its completely extended position, and therefore depends only on the angular position of the eccentric cam, it is possible to adjust the working stroke both regard to force and path solely via the rotation of the shaft which alters the angular position of the eccentric cam.
The occasional blocking of the second lever on the shaft may be achieved in various ways. By means of a spring, for example, which rests between a shoulder on the shaft and a point on the second lever. Hence the shaft can only rotate relative to the second lever after overcoming the elastic force.
One might also consider a magnetic block between the shaft and the second lever, or a purely mechanical block which is e.g. released when the toggle lever approaches the extended position.
Within the meaning of this description of the invention, the connection between the second lever and the shaft is thus only rotation-resistant to the extent that the rotation-resistant connection can be released under certain conditions. When the rotation-resistant connection is released, the press according to the invention is transformed from a toggle press into an eccentric press.
It is preferable to provide a stopper element on the machine frame which retains the toggle lever in the essentially extended position. When the toggle lever reaches this position the rotation-resistant connection between the shaft and the second lever is released.
This can take place in that the shaft overcomes the force of a spring which previously assured the rotation-resistant connection between the shaft and the second lever, or in that when contact occurs with the stopper element, a signal is generated which triggers an electrically controlled block. One could also provide a mechanical block which disengages when the toggle lever comes into contact with the stopper element.
Attached to the shaft there is preferably at least one radial arm which accommodates one fixation point of a compression spring, the other fixation point being provided on the second lever.
Preferred embodiments of the invention will be described below in more detail with reference to the enclosed drawings, in which
Furthermore, the first lever 14 is connected in the vicinity of its free end by means of axle 20 to a pressing tool 22 which can be displaced up and down along press frame 10 along a guide 24. As mentioned, pressing tool 22 is shown in its highest position in
The second lever 16 is attached to a shaft 28 which is rotatably mounted in press frame 10 and can be rotated by means of a drive unit (100).
The second lever 16 is attached to shaft 28 in a releasably rotation-resistant manner. In the embodiment shown here, the block between shaft 28 and the second lever 16 is created by means of a pressure spring 30 which may be a compressed gas spring, a screw pressure spring or some other kind of spring element. The pressure spring 30 is mounted in a first bearing 32 on the second lever 16 and in a second bearing 34 on an arm 36 which is rotation-resistantly mounted on shaft 28 and projects radially upwards from the latter and to the right in
The compressive force of pressure spring 30 is absorbed by a stopper element 38 located on the second lever 16 close to shaft 28. This stopper element is shown particularly clearly in
During the approach movement of pressing tool 22, i.e. when the pressing tool is lowered as per
When shaft 28 in
In the position in
The same reference numerals have been used in
In
The execution of the working stroke is explained diagrammatically in
Hence toggle lever 12 is maintained in the extended position. The second lever 16 cannot pivot further in an anticlockwise direction.
As, however, shaft 28 continues to be driven anticlockwise, arm 36, which is rotation-resistantly attached to shaft 28, is pivoted anticlockwise, as a comparison of
One might consider a magnetic coupling or a mechanical bolt, both of which could be released when the two stopper elements 40, 42 come into contact.
Further rotation of shaft 28 causes not only the compression of pressure spring 30. Disposed on shaft 28 there is an eccentric cam 44. When shaft 28 is rotated, the projecting portion of eccentric cam 44 moves downwards in
Hence the toggle press according to the invention is supplemented by an eccentric press for part of the stroke. Whilst the relatively rapid approach stroke is executed by means of the toggle press, the eccentric press takes care of the short working stroke requiring a high force.
The working stroke can be finely adjusted by changing the angular position of eccentric cam 44 in relation to shaft 28. A suitable drive system might be provided by a motor which rotates shaft 28 to and fro through pre-defined angular positions. The press can also be designed as a manual crank press.
A further advantage of the pressure spring is that the eccentric cam is pressed back into the starting position on completion of the working stroke.
This is why bearings 32, 34 are located on the side of the toggle lever furthest from counter-stopper element 42. Bearing 32 attached to the second lever 16 is located on a shoulder 48 projecting in this direction, and the other bearing 34 is disposed on the arm 36 whose pivoting movement also takes place on the side of the second lever 16 furthest from counter-stopper element 42.
In the drawings the toggle press is shown so that pressing tool 22 is moved from top to bottom. This orientation is not, however, the only application of the toggle press according to the invention. The stroke movement of pressing tool 22 can also take place in the horizontal direction, or from bottom to top. Pressing tool 22 can be a press stamp, an embossing stamp, a punching tool, a knife or similar.
Number | Date | Country | Kind |
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103 09 030 | Mar 2003 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
3763689 | Bridges | Oct 1973 | A |
3785282 | Kamelander | Jan 1974 | A |
4034666 | Bigun et al. | Jul 1977 | A |
5916345 | Kobayashi | Jun 1999 | A |
Number | Date | Country |
---|---|---|
37 03 413 | Aug 1988 | DE |
198 10 487 | Sep 1999 | DE |
101 12 983 | Jul 2002 | DE |
100 51 042 | Nov 2002 | DE |
11058078 | Mar 1999 | JP |
Number | Date | Country | |
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20040168502 A1 | Sep 2004 | US |