The invention relates to a clamping system for clamping a number of tools wherein said system comprises:
Such clamping systems are well-known, for example for use in bending machines, like press brakes swivel bending brakes, or folding presses. It is common to insert tools into the clamping system of a bending machine and clamp the tools in the clamping system. For clamping the clamping parts of the tools, a pusher element is extended into the groove such that the clamping part of the tool is pushed against a wall of the groove and therewith clamped. The force necessary to extend the pusher element into the groove is commonly derived from pressurized air. It is known to incorporate a bellow into the clamping system which after filling the bellow with pressurized air, pushes the pusher element into the groove. It is also known to use a hydraulic pressure to clamp the tools into the clamping system.
The advantage of such a conventional system is that all tools arranged in the clamping system can be clamped all at once, by a central control.
Other systems are known for clamping tools onto a device, such as a bending machine, but with these systems each tool has to be clamped separately by for example tightening a bolt or operating an excenter. Such clamping systems are furthermore limited to a clamping width of about 150 mm-200 mm. When using longer tools, more separate clamps have to be tightened, before such a tool is clamped safely.
The disadvantage of systems using pressurized air or a hydraulic fluid is that a compressor is necessary to provide the pressurized air or the pressurized hydraulic fluid. Especially for smaller devices having a clamping system such an additional arrangement increases costs and is not always directly available.
It is therefore an object of the invention to provide a clamping system, which has the advantages of clamping systems using pressurized air or hydraulic fluid in particular the advantage of the operation of the clamping by a central control, but which do not have the related disadvantages or at least has only part of these disadvantages.
This object is achieved by a clamping system according to the invention, which is characterized by shape imposed displacement means, for displacing the at least one pusher element from a first position substantially freeing the groove, enabling insertion of the clamping part of a tool into the groove, towards a second position, in which the at least one pusher element extends into the groove.
Operation of the displacement means enable a central control with which all the pusher elements can be operated at once.
The shape imposed displacement means make it possible to move the pusher element from a first position to a second position. The shape imposed displacement means must be understood as means which move the pusher element based on the shape of the displacement means. This is in contrast to displacement means used in conventional clamping systems, which use pressurized air or hydraulic fluid. Displacement of a pusher element is not guaranteed when pressurized air is arranged onto the pusher element. With a shape imposed displacement means the position of the shape dictates the position of the pusher element. So there is always a direct feedback between the position of the shape imposed displacement means and the pusher element.
In an embodiment of the clamping system according to the invention, the clamping system further comprises central control means for operating the shape imposed displacement means. With these central control means it is possible to operate the shape imposed displacement means such that all tools arranged in the elongated groove are clamped all at once. This avoids the need for tightening for example a bolt for each tool, as is common in the prior art.
In a preferred embodiment of the clamping system according to the invention, the shape imposed displacement means comprise at least one pair of wedge shaped elements, wherein the wedge shaped elements shift along each other, and are arranged between the body and the at least one pusher element.
With wedge shaped elements it is possible to generate a high force onto the at least one pusher element, while the force necessary to shift the wedge shaped elements along each other can be kept low.
In a further preferred embodiment of the clamping system according to the invention, the central control means comprise:
With such a control means it is possible to move the wedge shaped elements over a long distance just by pivoting the lever such that the axle is moved in longitudinal direction and then a force can be built up by the wedge shaped elements by rotating the axis which moves the wedge shaped elements even further, generating a high clamping force, to the position in which the tools are safely clamped.
In another preferred embodiment of the clamping system according to the invention, the control means comprise:
When rotating the axle, rotation will occur along the thread having generally the largest pitch. This results in a quick displacement over a distance of the wedge shaped elements towards a position in which the wedge shaped elements clamp the tools. As soon as the wedge shaped elements start up building pressure to clamp the tools, rotation will occur around the other thread having the smaller pitch. Due to the smaller pitch it is possible to generate at the wedge shaped elements a high clamping force for clamping the tools into the clamping system.
Preferably the first sleeve comprises a flange for limiting the movement of the second sleeve, relative to the first sleeve. This avoids the possibility that the second sleeve runs off from the first sleeve.
In another embodiment of the clamping system according to the invention, the shape imposed displacement means comprise a camshaft with at least one cam on which the at least one pusher element abuts.
Also with a camshaft it is possible to generate a high force on the pusher elements, while the force necessary for rotating the camshaft is kept low.
In still another embodiment of the clamping system according to the invention, in combination with the embodiments having a central control means, the control means comprise a lever arranged on the camshaft. With such a lever it is possible to rotate the camshaft and operate the pusher elements.
In yet another embodiment of the clamping system according to the invention, the at least one pusher element comprises a pin extendable into the groove and a first spring arranged between the pin and the shape imposed displacement means.
With the spring it is possible to absorb small dimensional differences, ensuring a maximum clamping force of the pin onto the tool. In yet another embodiment of the clamping beam according to the invention the at least one pusher element further comprises a second spring arranged between the body and the pin for urging the pusher element towards the first position. This second spring ensures that the pusher elements are retracted to the first position clearing the groove, such that the clamping part of the tools can be easily inserted or extracted from the groove.
In a further embodiment of the clamping system according to the invention the end of the pin extending into the groove is provided with a shaped surface suitable for cooperating with a groove in the clamping part of the tool for pushing the tool into the groove of the clamping system.
It is clear that operating of the shape imposed displacement means may take place by the central control means described above, but it is also possible to have an hydraulic cylinder providing the movement for the wedge shaped elements or the rotation for the camshaft. Other possibilities include an electric motor or other drive means.
Furthermore, the disclosed clamping system according to the invention is able to clamp any kind of tooling. In case of a bending machine like press brakes or swivel bending brakes American style tooling, European style tooling, New Standard tooling or any other type of bottom or top tooling can be clamped in the clamping system according the invention.
These and other advantages of the invention will be elucidated in conjunction with the accompanying drawings.
Each pin 6 is part of a pusher element. Such a pusher element further comprises a spring 12 and a cup 13, which is in direct contact with rack 10. The spring 12 compensates for differences in dimension for example of the groove, the clamping part 3 or the pins 6.
In
Each pin 6 is provided with a flange 14 which prevents the pin 6 to be pushed completely in groove 2. A second spring 15 has been arranged to retract pin 6 from the groove 2, when the rack 8 is shifted such that the rack 10 approaches rack 8.
In
In
By rotating the lever 25 in the direction of the arrow 27 a quick displacement of the axle 24 is achieved moving the rack 22 to the left as shown in
In order to achieve a pressure build up on the pusher elements 28 the lever 25 is then rotated along the longitudinal axis of the shaft 24 in the direction of the arrow 29. As the axle 24 is arranged by a thread into the housing 21 a small displacement is achieved, providing in combination with the wedges of the rack 22 and rack 30 a pressure build up enabling the clamping system to clamp tools.
In
In this example, the pitch of the second thread on the first sleeve 43 is larger than the pitch of the first thread onto the axle 41. Now when rotating the axle 41 the second sleeve 44 will move to the left in the drawing as a result of the friction differences between the first and second thread. This friction difference can also be provided by design, for example by prestressing the first thread. When the second sleeve 44 reaches its end position defined by the flange 47 and by continued rotation of the axle 41 the first sleeve 43 starts to move to the left as a result of the abutment of the second sleeve 44 against the flange 47. As the pitch of the thread on the axle 41 is smaller than the pitch of the thread on the first sleeve 43, a pressure can be built up which is exerted by the wedges and corresponding pins.
Number | Name | Date | Kind |
---|---|---|---|
3656773 | Blattry et al. | Apr 1972 | A |
4315425 | Zbornik et al. | Feb 1982 | A |
5245854 | Bruggink et al. | Sep 1993 | A |
6000273 | Stover | Dec 1999 | A |
6003360 | Runk et al. | Dec 1999 | A |
6732564 | Runk et al. | May 2004 | B2 |
6928852 | Enderink | Aug 2005 | B2 |
7152453 | Johnson et al. | Dec 2006 | B2 |
7308817 | Shimota et al. | Dec 2007 | B2 |
7632224 | Rouweler et al. | Dec 2009 | B2 |
7634935 | Mazzocchi | Dec 2009 | B2 |
7721586 | Pabich et al. | May 2010 | B2 |
7810369 | Rouweler et al. | Oct 2010 | B2 |
8099992 | Rouweler et al. | Jan 2012 | B2 |
20030033846 | Runk et al. | Feb 2003 | A1 |
20040187552 | Enderink | Sep 2004 | A1 |
20050000267 | Harrington et al. | Jan 2005 | A1 |
20050132772 | Harrington et al. | Jun 2005 | A1 |
20060174679 | Pabich et al. | Aug 2006 | A1 |
20060174680 | Shimota et al. | Aug 2006 | A1 |
20060191313 | Harrington et al. | Aug 2006 | A1 |
Number | Date | Country |
---|---|---|
2818189 | Jun 2002 | FR |
62267019 | Nov 1987 | JP |
10249439 | Sep 1998 | JP |
Number | Date | Country | |
---|---|---|---|
20080252024 A1 | Oct 2008 | US |