NO823008L - HYDRAULIC PRESSURE INCLUDING A FIXED PLATE BEAM AND A MOVABLE PLATE BEAM. - Google Patents

Description

With hydraulic presses, especially with those of large dimen-

tions, the deformations that occur in the two slab beams are of very great importance. They change with each operation according to the shape, dimension and quality of the material to be bent.

Today, systems are known which seek to compensate for the negative effects of the bending of the fixed plate beam and the movable plate beam: Swiss patent no. 411755,

Swiss Patent Patent No. 508426 and French Patent No.

2078874.

These mechanical and hydraulic devices have the disadvantage that the user must determine in advance the deformation that will occur in the fixed plate girder and the movable plate girder in order for it to be compensated for before the bending operation. They necessitate a long trial period before durable results are achieved. The result achieved is often not completely satisfactory.

It is indeed very difficult, in the case of a bend-

pressure, to determine with accuracy the deflection that one will get under the pressure of the visual aids during the working phase and immediately after. And even if you want to achieve a result by analytical calculation, which is entirely possible, you would have to redo the calculations every time one of the parameters changes: the shape, the bending angle, the thickness, the resistance of the material, the tool used or the length of the bend. Moreover, if one calculates in this way the emergency bending due to bending in the fixed and movable plate beam, there will still be significant errors due to deformation of the control system.

On the other hand, the deflection changes continuously during the working phase. Because the calculation only gives the final deflection, the result will be very uncertain all the time sheet metal of the same dimension and quality shows differences in resistance and thickness due to production tolerances.

Before a bending press can work within reduced tolerance limits, it is thus necessary that the operator is given a long adjustment period and its precision depends on the latter's skill.

The above-mentioned disadvantages are very clearly overcome according to the present invention. The purpose of the invention is to determine the deflection due to the deformation of a bending press, not before the working period under load, but during the entire working phase.

The idea consists in determining bg to compensate this deformation

during the bending cycle, as accurate measurements are made of the simultaneously achieved deflection under the influence of force. These measurements are analyzed by a center during and/or immediately after the work phase, and the deformations are compensated at the same time by a counter-deformation that is applied until the matrix and the tool are parallel.

The present invention thus relates to a hydraulic press

which includes a fixed plate beam and a movable plate beam as defined in claim 1.

The invention also relates to an embodiment as defined

in claim 15.

The advantages of a hydraulic press working according to the present invention are obvious. You can very accurately correct the deformation of the fixed plate beam and/or the movable plate beam on the basis that you know the exact size of the deflection. This correction is made automatically and instantly by the machine as a result of signals given by an analysis center without depending on the skill of the operator.

The correction can be made either during the work phase or during and after the work phase, or only after the work phase.

The choice only restored technical problems that arise from the shape of the press, the shape of the tool, the shape that will be achieved after shaping and the materials used.

The invention will be better understood with the help of the accompanying drawings which, for example, show the press with the device according to the present invention. The drawings show

fig. 1 a view 3/4 from the front in perspective of a hydraulic press with two cylinders and with compensation opening,

in its working position without tools,

fig. 2 a 3/4 front view of a hydraulic press with two cylinders and with two compensating openings, in its

working position without tools, and

fig. 3 a vertical section along A-A of an embodiment of

the press shown in fig. 1.

Fig. 1 shows a hydraulic press in which the pistons of the working cylinders 6 are in their power-exerting position, and consequently with the movable plate beam 5 in the working phase.

In this phase, it is clear that the movable plate beam 5 will tend to curve, as the middle point of

the movable plate beam 5 is located higher than the two ends.

For the same reason, the fixed plate beam 4 will have . tendency to curve in such a way that the center point of the fixed plate beam 4 is lower than the ends of said plate beam.

This results in the working surface of the two plate beams

4 and 5 and consequently the surfaces of the two tool carriers, the matrix carrier 8 and the patrice carrier 9, are no longer parallel.

The measuring devices 3 allow measurement of the deflection caused by these deformations. They transfer their information to an analysis center 7. This center analyzes the obtained information and controls compensation cylinders 2 which are located in a compensation opening 1, because thereby

to provide a complementary driving force to the interior of the fixed plate beam 4 to achieve a curvature of the surface of the matrix carrier 8, which curvature will be exactly the same as

and parallel to the curvature on the surface of the patrice carrier 9. The operation continues during the entire working phase as a permanent total correction is produced.

As a result of this, the deformations caused by the bending in the fixed and movable plate beam, which deformations are in the opposite direction and which give a significant error in the areas farthest from the working cylinders 6, can be corrected by means of a counter-deformation obtained through the pressure from the compensation cylinders 2 in the compensation opening 1.

Fig. 2 shows another embodiment of the invention. It concerns a hydraulic press in which there are two compensation openings 1, one in the fixed plate beam 4 and the other in the movable plate beam 5.

The press is shown in its working phase in which the working cylinders 6 have their pistons in the force-exerting position. In this position, the matrix carrier 8 tends to deform in its central part in the downward direction in relation to its end parts, while the movable plate beam 5 and especially the patrice carrier 9

tends to deform so that the central part of the tool is higher than the end parts of said patrice carrier.

For this reason, if the entire length of the press is used or if the forming piece is centered on the press, the bending will be irregular due to insufficient penetration of the tool on the center of the press.

When the two plate beams, the fixed 4 and the movable 5, are under the influence of force, the devices 3 for measuring the deformation, based on parameters such as the penetration depth of the tool or the bending angle of the piece, send the data to the analysis center 7 which is necessary to determine with what force the pistons 2 in the upper and lower compensation opening 1 must contribute to undo the deformation on the edges of the two plate beams.

With the help of a hydraulic circuit, the analysis center controls the s♦tem<p>len<e>to the compensating cylinders 2 to thereby compensate the entire bending in the movable plate beam 5 and in the fixed plate beam 4. The matrix carrier 8 and the patrice carrier 9 are each pulled back to a straight line, exactly parallel to each other.

In the presses shown in fig. 1 and 2 exercise the compensation cylinders

2, which are located inside the compensation opening 1, their pressure on the surface "a" in the opening of the fixed plate beam as they are supported by the surface "b" in this opening.

In an embodiment variant represented in fig. 3, the compensating cylinders 2 exert their pressure on the plate a in the opening 1 as they are supported by lateral support plates placed parallel to the fixed plate beam.

In another embodiment, which is not shown, the compensation opening is only arranged in the movable plate beam 5 and no compensation opening is provided in the fixed plate beam 4.

In this case, the fixed plate beam 4, and especially

its working surface, namely the matrix carrier 8, will tend to deform and its middle part will then be further down than its end parts. At the same time, the working surface of the movable plate beam 5, namely the patrice carrier 9, will deform and its middle part will then be in a position that is higher than that of its end parts.

At that moment, the devices 3 for deformation measurement will transmit information to the analysis center 7 which, with the help of the hydraulic circuit, will give the pistons in the compensation cylinders 2, located in the compensation opening 1 in the movable plate beam 5, an order to modify the curvature of the edge of the movable plate beam 5, namely the matrix carrier 9, so that it exactly corresponds to the curvature of the fixed plate beam 4 at its edge, namely the matrix carrier 8.

In the above-mentioned embodiments, the correction system is placed in a compensation opening 1 arranged in the plate beam. The same correction system can be placed between the tool carrier and the tool, i.e. between the matrix carrier and the matrix and/or the patrice carrier and the patrice.

The invention has been described with special embodiments, but it is obvious that changes in design, such as turning the fixed and movable plate beam, or the use of multi-cylinder machines and special machines, have no influence on the idea of using a compensating opening which is managed by an analysis centre.

Claims (18)

1. (modified) Hydraulic press comprising a fixed plate beam and a movable plate beam, with at least one of the plate beams carrying a tool, and at least one pressure device (2) which is supported by at least one of the plate beams, characterized in that at least one of the plate beams on its edge is provided with at least one measuring device. 2. (deleted) 3. Hydraulic press according to claim 1, characterized in that at least one pressure device (2) is supported by at least one of the tool carriers. 4. (modified) Hydraulic press according to one of the claims log 3, characterized in that the pressure devices are arranged inside an opening. 5. Hydraulic press according to claim 4, characterized in that the pressure devices are mounted so that they exert their pressure on a. first surface (a) in the opening as they abut against another surface (b) in the opening. 6. Hydraulic press according to claim 4, characterized in that the pressure devices are mounted so that they exert their pressure on a first surface (a) in the opening as they bear against at least one lateral plate which is parallel to the fixed plate beam. 7. (deleted) 8. (modified) Hydraulic press according to one of claims 1-6, characterized in that the measuring device is a device that measures the penetration of the tool. 9. (modified) Hydraulic press according to one of claims 1-6, characterized in that the measuring device is a device that measures the bending angle of the piece to be bent. 10. (modified) Hydraulic press according to one of claims 1-9, characterized in that it is connected to a center for analyzing information obtained by means of the devices for measuring the deformation. 11. Hydraulic press according to claim 10, characterized in that the analysis center is electronic. 12. Hydraulic press according to one of claims 10 or 11, characterized in that the pressure devices act on command from the analysis center so that a constant distance is achieved along the entire length between the two tool carriers. 13. (deleted) 14. (deleted) 15. (modified) Method for using the press according to one of claims 1-12, characterized in that the deformation is compensated during at least part of the period covering the work phase extended up to the moment of reversal of the work movement. 16. Method for using the press according to claim 15, characterized in that the deformation is compensated during the entire work phase. 17. Method for using the press according to claim 15, characterized by compensating the deformation during the working phase extended until the moment of reversal of the working movement. 18. Method for using the press according to claim 15, characterized in that the deformation is compensated after the work phase, up to the moment of reversal of the work movement.