EP0058828B1 - Lever tool with progressive transmission - Google Patents

Description

The invention relates to a lever tool with progressive translation to increase the force in presses and the like. Consisting of a holding plate fastened to the ram of the machine, an associated movable tool part and a receiving plate for a stationary tool part.

A press for punching, embossing, deep drawing and the like consists, among other things, of a ram driven in various ways and of a base plate which is firmly connected to the frame. The ram and base plate have facilities for holding interchangeable tools. The usability of the press is limited, among other things, by the maximum pressing force and the stroke. For cost reasons, the machines required by industry are usually purchased in accordance with the current products in terms of their performance. It is not uncommon for products to be produced that can no longer be processed with the existing machine equipment because the requirements exceed the technical data of the press. This is particularly often the case with regard to the available pressing force.

A high-pressure press is known from CH-A75 027, in which a toggle lever system is used which generates a high pressure, particularly at the end of the pressing process. However, the stroke between the movable and the stationary tool plate of this known embodiment is very small and must in any case be generated by a much larger stroke movement of the drive piston. As a result, this press cannot be used for the intended purpose.

The object of the invention is to provide a lever tool as an auxiliary device for presses, with which the pressing force can be increased without having to make major changes to the press itself and without significantly reducing the stroke of the ram.

The object is achieved by an essentially triangular lever rocker with pivot points provided in the region of the corners of this triangle, of which the lower pivot point is articulated via a compensating arm with the movable tool part, the internal articulated with the holding plate and the outer articulated via a further compensating arm with the Recording plate are connected, wherein the lower pivot point is arranged in the starting position inside and with the plunger lowered outside the connecting line between the pivot point and that on the movable tool part, and by an axial guide extending in the direction of the plunger for the movable tool part.

With this simple design, an increase in the pressing force is achieved according to the lever law. The force is applied through the ram via the retaining plate attached to one of the corner pivot points of the lever arm. Since the second pivot point of the rocker arm is connected to the mounting plate via a compensating arm, the third pivot point pivots about the second and moves the movable tool part via a compensating arm. During the uniform stroke movement of the ram, the constantly changing lever ratios of the lever system result in different transmission ratios for the distance traveled by the movable tool part. This advantageously results in a translation of the pressing force which is dependent on the position of the movable tool part and which can be selected by changing the lever ratios so that a very large increase in force only occurs during the actual machining of the workpiece, namely in the last part of the stroke range. Practically no force is required while the movable tool part is being moved towards the workpiece, so that this process can also take place more quickly. For this reason, the lever ratios can be selected so that in this area the movable tool part covers a greater distance than the ram. In this way, the stroke loss due to the increase in force during the working phase of the tool parts is advantageously compensated for by the extension of the stroke while the movable tool part is being brought closer to the workpiece. Depending on the design of the lever system, it can be achieved that the maximum stroke of the ram specified by the press is shortened only slightly, although the pressing tool according to the invention increases the pressing force many times over.

For applications in which the two tool parts have to work with each other very precisely, for example when punching, the lever tool is provided with an additional axial guide for the movable tool part. For example, a guide pin can be attached in the extension of the plunger, on which the movable tool part can slide in the axial direction. The levers then only have the task of power transmission.

According to a further feature of the invention, the receiving plate for the fixed tool part is made separately from the frame.

The stability of the press frame is often not sufficient, so that this must be reinforced by suitable measures. One possibility is to provide a separate plate corresponding to the requirements for receiving the fixed tool part. The second corner pivot point of the lever arm is attached to this via the compensating arm. The mounting plate itself is detachably anchored to the press frame. In this case, the pressing force obtained by the lever tool according to the invention is transmitted as a tensile force via the compensating arm to the separate mounting plate, so that no overloading of the press frame occurs.

In another preferred exemplary embodiment, at least two lever systems arranged symmetrically to the axis of the tool parts are provided. As a result, the forces can be sensibly divided at relatively high forces, so that the individual pivot points only have to transmit a corresponding proportion of the total force and can therefore also be made weaker. Another advantage is that with a uniform arrangement of several lever systems around the axis of the tools, the movable tool part is guided well at the same time.

According to a further feature of the invention, the holding plate, the receiving plate, the two tool parts, the lever arms and the compensating arms form an exchangeable unit. This preferred version can be installed in the press in a few simple steps. The balance of forces is matched to the two tool parts and the workpiece to be manufactured. Thus, an optimized lever tool can be provided as an interchangeable component.

The invention shows a solution which can be used for many cases and which is economically effective in particular when the existing mechanical devices are overwhelmed with regard to power reserves.

The invention is described below with reference to the example shown in the drawing.

• Fig. 1 ein Hebelwerkzeug mit zwei Hebelsystemen in Seitenansicht in verschiedenen Arbeitsstellungen und
• Fig. 2 ein Presskraft/Hub-Diagramm.

Show it:

• Fig. 1 shows a lever tool with two lever systems in side view in different working positions and
• Fig. 2 is a press force / stroke diagram.

In the lever tool shown in FIG. 1, only the essentials for the function are shown. Two lever systems of the same design are arranged symmetrically to the axis of the tool parts. In the right half of the picture, the plunger 1 is lowered, while the left half of the picture shows the starting position.

The lever tool essentially consists of a holding plate 2, a movable tool part 3, a receiving plate 4 and the two lever systems 6, 9, 12.

On the holding plate 2, two opposite pivot points 7 are provided, which form the bearing points of two identical lever arms 6 via bolts. The lever arms 6 are essentially triangular, a pivot point 7, 8, 11 being arranged at each corner. The inner corner pivot 7 shown in the right half of the figure is articulated to the holding plate 2, the lower corner pivot 8 is articulated to the movable tool part 3 via a compensating arm 9 and the outer corner pivot 11 is also articulated to the mounting plate 4 via a further compensating arm 12. The compensating arms 9, 12 have the task of compensating for the horizontal displacement of the other corner pivot points 8, 11 when the lever rockers 6 move about their inner pivot point 7. This is clear from the comparison - the right half with the left half. The mounting plate 4 is here firmly connected to the frame of the press and receives a fixed (not shown) tool part. The holding plate 2 is firmly connected to the plunger 1 of the press. The plunger 1 is axially extended by sliding bolts 13 on which the movable tool part 3 is guided axially.

During operation, caused by the plunger 1 of the press, the pressing force acts on the holding plate 2 on the inside (above in the left half of the figure) corner pivot points 7 of the lever rockers 6. Since the outer corner pivot points 11 are connected to the mounting plate 4 via the compensating arms 12 and cannot change their position in the direction of the pressing force, the lower corner pivot points 8 of the lever rockers 6 pivot about the outer corner pivot points 11. An additional axial movement thereby takes place via the compensating arms 9 of the tool part 3 relative to the holding plate 2, or relative to the slide 1 of the press, the additional movement being added vectorially to the slide movement. In the starting position shown in the left half of the figure, the lower corner pivot 8 of the lever arm 6 is still inside. When the ram 1 is lowered, this corner pivot 8 moves outwards and first reaches the connecting line between the corner pivot 7 located on the inside (in the left half of the figure) and the pivot point on the movable tool part 3. During this movement, the distance of the movable tool part 3 from the Holding plate 2 steadily enlarged. In this case, this additional movement is added to the downward movement of the plunger 1, as a result of which the tool holder 3 covers a greater distance than the plunger 1. According to the lever law, this means that the pressing force acting on the movable tool part 3 is smaller in this partial region of the ram stroke than the maximum pressing force of the ram 1.

When the plunger 1 is lowered further, the lower corner pivot 8 of the lever rocker 6 moves away from the connecting line "inside (top) corner pivot 7 - pivot point on the movable tool part 3 _" to the outside. As a result, the distance between the movable tool part 3 and the holding plate 2 becomes smaller and smaller. In this case, this movement counteracts the downward movement of the plunger 1, as a result of which the movable tool part 3 travels a smaller distance than the plunger 1. According to the lever law, this means that the pressing force acting on the movable tool part 3 is greater in this partial region of the plunger stroke than the maximum pressing force of the ram 1. The right half of the figure clearly shows the lower corner pivot 8 of the lever arm 6, which is moved outwards, compared to the left.

In the example shown, this is achieved by increasing the pressing force in the second. Sub-area occurring stroke loss due to a relative to Ram 1 compensates for a larger stroke in the first section, so that almost the entire maximum stroke of the press is retained.

2 shows the course of the pressing force resulting from the lever tool according to the invention (curve B). For the sake of clarity, the press force of the press remained constant over the entire stroke s of the ram 1 (curve A). In the first section up to point B1 there is a lower pressing force, while in the second section up to the lower reversal point B2 of the ram 1, the pressing force increases continuously.

The embodiment described and illustrated is an example of the lever tool according to the invention. However, it is possible at any time to adapt to the respective application by changing the leverage ratios and forms.

Claims (4)

1. Lever tool with progressive transmission to increase the force of presses and similar equipment, consisting of a retaining plate (2) attached to the ram (1) of the machine, a tool part (3) attached thereto and a receiving plate for a stationary tool part, characterized in that there is an essentially triangular tumbler lever (6) provided with pivots (7, 8, 11) in the corners of this triangle the lower pivot (8) of which is articulated at the moving tool part (3) by means of a compensating arm (9), the inside pivot (7) is articulated at the retaining plate (2) and the outside pivot (11) is articulated at the receiving plate (4) by means of another compensating arm (12), the lower pivot (8) being located in starting position inside and, with the ram (1) in lowered position, outside a connecting line between the pivot (7) and the pivot at the moving tool part (3), and in that there is an axial guiding element (13) for the moving part (3), extending in the direction of the ram (1).

2. Lever tool as claimed in claim 1, characterized in that the receiving plate (4) for the stationary tool part is formed separately from the frame.

3. Lever tool as claimed in one of the claims 1 or 2, characterized in that there are at least two lever systems (6, 9, 12) arranged symmetrically to the axis of the tool parts.

4. Lever tool as claimed in one of the claims 1 to 3, characterized in that the retaining plate (2), the receiving plate (4), the two tool parts (3), the tumbler levers (6) and the compensating arms (9, 12) form an interchangeable unit.

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