DE913851C - Pedal press - Google Patents

Description

Foot lever press The invention relates to an improvement on the known Pedal presses. In such presses, one is stored in the frame of the press Unequal-sided lever provided, its longer arm hanging down at its lower end a step plate for the foot drive and often an additional one Carrying a flywheel, while the short lever arm drives the ram of the press. Of the The fulcrum of this lever is in the fixed frame of the press, which is also the slide guide carries, stored. The force acting on the ram of such presses is partly through direct transformation of the foot force by means of the unequal Lever, partly gained by utilizing the work capacity, which is the flywheel mass of the Pendulum is issued by the foot drive. Depending on the version of the press or after one or the other part predominates in the applied working method. An economic one Utilization of the foot power output can only be achieved, especially with long-term work, if the size of the lever deflection at the kick matches the anatomical conditions of the Leg is adapted: This most favorable deflection of the foot lever is with the known Versions of foot pendulum presses are assigned the maximum stroke of the press ram, which is determined by the reduction ratio of the foot lever and possibly the further connected in the power path transmission means, z. B. toggle arrangements, results. Depending on the needs, the required for the particular work to be performed Tool path determined by limiting the ram stroke by means of adjustable stops.

Limiting the stroke by means of stops is disadvantageous when working running a small stroke at maximum working pressure require, such as B. stamping or embossing work. As with the limitation of the ram stroke too the pedal travel is reduced accordingly, if a flywheel is used, this the entire work capacity on a greatly shortened distance granted, i.e. an increased foot force in relation to the shortening of the path which experience has shown that the worker becomes fatigued quickly. In the case of particularly small strokes, it is often not possible at all to achieve the maximum working pressure, for which the press is built. You can get more favorable power ratios by doing work that only requires short ram strokes, z. B. when punching, works with a large ram stroke and thus a sufficiently large Enables power drive path at the foot step. To do this, however, anomalous punching tools must be used with a long and correspondingly expensive punch guide adapted to the large stroke to be provided. On the other hand, if the press is operated with a greater leverage ratio from which the short ram stroke suitable for punching with a large deflection of the Step plate results, so are the force-travel ratios both when working with utilization of the swing energy - as well as with direct lever transmission of the foot force favorable for the short ram stroke, but the press can then be used for work which require a large stroke; cannot be used.

For foot lever presses where the drive lever is not direct but Acts on the press ram via a toggle mechanism has already been proposed been to make the lever mechanism adjustable so that the toggle lever in the Rest position, which corresponds to the upper ram position, depending on requirements is more or less pushed through. This also changes the ram stroke, however, these proposals were also kept in detail so that the foot pedal deflection was reduced in accordance with the reduction in the ram stroke. Besides, would in these proposed designs just the last part of the foot drive path, which is more favorable for the use of leg strength, cut off.

The invention eliminates the disadvantages described by the proposal, Means for the kinematic coupling of the drive lever and press ram with such variable reduction to provide that when working with a smaller than the maximum ram stroke, the reduction ratio can be increased so that the pedal travel is not reduced to the same extent as the ram stroke. This makes it possible, especially with infinitely variable adjustability, for the different sizes of the ram stroke to choose that foot drive; the one for the work in question and is most favorable for the worker performing it. In in the majority of cases this will be the greatest way of the footplate, whichever way Operators can still work comfortably, as this is due to the flywheel As much as possible of the greatest possible amount of work ability. the greatest possible force when working without utilizing the centrifugal force on the ram can be exercised.

For the proposed according to the invention, on different reduction ratios adjustable coupling of drive lever and press ram can be both mechanical Transmission means, such as rolling gears or lever combinations with stepwise or stepless adjustment, as well as hydraulic transmissions are used. Will to simplify the press design instead of a continuously variable translation only two or more reduction ratios to be used optionally are provided, so the stops can be used to fine-tune the tool path according to the previous known execution can also be used.

For some of the work to be done on pedal presses, it is Advantageous, presses with a reduction ratio that can be changed over the stroke path to use in the first part of the stroke a relatively large way and to have a large reduction in the last part, as in the case of the ones already proposed Presses in which a pair of toggle levers are arranged between the drive lever and the ram is, is the case. In the known presses of this type, however, are through the Kinematic conditions, once the reduction values have been set, cannot be changed set. In the context of the invention, it is proposed also for foot lever presses with a total stroke that can be changed while the drive lever deflection remains the same, the reduction ratio to make variable over the stroke.

What has been said above for foot lever presses also applies accordingly for presses with hand lever drive.

Several examples are shown below; like the invention Proposals for the various types of foot lever presses are particularly advantageous and can be realized in a simple manner.

Several such embodiments are shown in the drawing, namely Fig. i shows an embodiment of a foot lever press according to the invention in Cut; Figs. 2 to 6 show further exemplary embodiments of the subject matter of the invention in a schematic representation.

In Fig. I i is the frame of a foot lever press, in which the plunger 2- carrying the tool (not shown) is guided in a longitudinally displaceable manner. The drive lever 3 with the step plate d. has two optionally usable pivot and suspension points in eyes 5 and 6, which are the bearing bores? and 8 are assigned in the frame i. Depending on whether the bearing pin g is inserted into the eye 5 of the drive lever and into the bearing bore 7 of the frame (as shown) or into the eye 6 and the bearing bore 8, the drive lever 3 acts when it is exerted by force on the step plate q. deflects in the direction of the arrow, hit the plunger 2 with the lever arm A or with the lever arm B. The effective lever arm H between the bearing point and the center of mass S of the drive lever remains almost unchanged in both cases. As a result of the different lever ratios H: A and H : B, the plunger 2 executes the larger working stroke a in the first case and the smaller stroke b in the second case.

The bearing bore 8 is expediently so much deeper than in the frame the hole 7 attached that the lowest position of the plunger in both cases is roughly the same. To make it easy to switch from one to the other To enable the lever ratio, the distance between the eyes 5 and 6 in the lever is from each other equal to the mutual spacing of the bearing bores 7 and 8 in the frame, so that at a certain deflection of the drive lever not even that as a fulcrum used eye 5 or 6 with the associated bearing bore 7 or 8 in alignment lies. With this deflection, an auxiliary bore io in the lever is also aligned with a Bore ii in the frame, so that the lever 3 by inserting a not shown Auxiliary bolt or a z. B. slidably mounted on the frame bolt in this Location can be set with a certain amount of play. The operator can now by acting on the step plate q. in the direction of the arrow the bearing pin 9 from the lever weight so that he can easily move from one bearing to the other leaves.

In Fig.2 is a schematic of the application of the invention to a pedal press shown, in which the lever 3 driven by foot force by means of the handlebar 14 acts on a pair of toggle levers 15, 16. Such foot presses are particularly advantageous used when the working pressure through direct lever transmission of the foot force, so should be applied without substantial use of the flywheel energy. they give due to their reduction ratio, which can be changed over the stroke, a relatively high rate large stroke and at the end of this stroke have close to the extended position of the toggle levers the large reduction ratio necessary for static power transmission.

The bearing 17 for the pivot point of the lever 3 is on the frame of the press firmly attached. The tappet 18 slides in the tappet guide i9. The one you want In this version, the reduction is achieved by using one of the bearing bores 20a to 20d. In the drawing, the press is near the lower end position of the plunger shown, in which the lever 3 has its greatest deflection. the Bearing bores 20a to 2od are advantageously located on an arc of a circle, the radius of which R the length of the handlebar 1q. corresponds to the bottom dead center of the ram at always has the same position in relation to the press body for all reductions.

Fig. 3 shows an embodiment of a press similar to Fig. 2 Pedal press with toggle levers, in which the reduction ratio is shifted of the pivot point 23 for the handlebar 14 on the lever 3 is changed. This type of execution is shown here with a straight sliding guide 24 in which the bearing body 22 for the handlebar 1q. can be adjusted by a screw 25 and a nut thread 26 can. The foot lever 3 is here in the rest position, which is the top dead center of the plunger and shown with a set average reduction ratio. For the largest and the smallest adjustable reduction ratio are the associated positions of the handlebar 14 and the pair of toggle levers 15, 16 are shown in dashed lines.

In the straight sliding guide 24 shown in Figure 3, the lower Dead center of the ram with different reductions is only approximately the same Location. Of course, a suitable curvature of the sliding guide can also be used here the exact equality of the bottom dead center can be achieved. Such a training is in Fig.q. shown, which the lever 3 of a press in a cutout shows according to Fig. 3 at the bottom dead center of the not shown plunger. It is of course also possible, similar to the examples in Fig. I and 2 provide several optionally usable bearing bores. The reverse is true for presses according to Fig. i or 2 instead of two or more than two holes for the drive lever mounting a stepless adjustment of the reduction ratio by appropriately trained Slideways are provided.

On presses with foot or hand drive, the ram in other than acts in the perpendicular direction, the invention is also applicable.

A particularly advantageous embodiment because of its simple structure the invention, which again contains the toggle lever pair 15, 16, is shown in FIG. The upper lever 15 of the pair of toggle levers is in one piece with the drive lever 3 executed. This design gives the same effect as that of the known, Pedal presses described at the outset with one connected between the foot pedal and the plunger Pair of toggle levers, but their design is considerably simpler than this. To also It is useful to make the reduction ratio changeable in this embodiment the effective length of the toggle lever, which is designed in one piece with the drive lever 15 changed. For this purpose, as shown in Fig. 5, several optional usable bearings 26a and 266, 27a and 27b are used for the knee joint. In Fig.6 it is shown how the change occurs in an arrangement that is basically the same the reduction ratio by means of sliding guides 28, 29 in the toggle levers 15, 16 can be effected.

The arrangement according to Fig. 5 and 6 also offers the particular advantage that the height of the plunger can be changed within certain limits without attaching further adjustment devices. The normal lower dead center position of the ram, which is the same for all reductions, is reached when, depending on the stroke size, point 26a with point 27d, point 26b with point 27b, etc. connected. If, on the other hand, the lower tappet dead center is higher with a smaller than the maximum stroke size, then z. B. Point 2611 of the plunger connected to 27b. With a corresponding length of the ram guide, the lower ram position can also be set lower for the larger strokes by z. B. 26b is connected to 27a. When using sliding guides according to Fig. 6, the slide adjustment is carried out in the same way, but continuously. Here, a fine adjustment of the height of the plunger can also take place without changing the reduction ratio on the lever 3, only by changing the length of the toggle lever 16. Such a slide adjustment can also be made with arrangements according to Fig. 2, 3 or 4.

Claims (7)

PATENT CLAIMS: r. Pedal press, characterized by an arrangement of means for the kinematic coupling of drive lever (3) and tappet (2, 18) with such variable reduction that when working with a smaller than the maximum slide stroke of the reduction ratio can be increased so that the drive lever deflection is not reduced or not reduced to the same extent as the slide stroke will. 2. Foot lever press according to claim z, wherein the shorter lever arm of a unequal arm drive lever directly or via a pair of toggle levers on the ram acts, characterized in that the parts forming the drive lever pivot point in the lever (3) and in the press frame (i) or only in the lever (3) in several effective positions are adjustable. 3. Foot lever press according to claim i or 2 with a toggle system between Drive lever and press ram, characterized in that the effective length of the arm of the drive lever which transmits the force to the toggle levers (15, 16) (3) is changeable. 4. Foot lever press according to claim: 2 or 3, characterized in that several optionally usable parts (9; 22, 23) which form the pivot point of the drive lever (3) or the parts (9; 22, 23) serving to transmit power to the toggle levers (15, 16) Bearing points (5-7, 6-8, 2o11 to 20d) or sliding guides (24) with adjusting and locking devices (25, 26 ) are arranged. 5 ,. Pedal press according to claim 2, 3 or 4 with power transmission between drive lever and plunger by a pair of toggle levers, characterized in that one or both toggle levers of the Pair of toggle levers to change the reduction ratio and / or the altitude the effective length of the plunger (18) can be changed in stages or continuously are. 6. foot lever press according to claim 5, characterized in that a lever (15) of the toggle lever pair (15, 16) is made in one piece with the drive lever (3). 7. foot lever press according to claim i to 6, characterized by a mutual spatial arrangement of the optionally adjustable hinge points, such that the same or approximately the same bottom dead center of the ram results in all adjustable ram strokes. B. foot lever press according to claim 7 with power transmission between the drive lever and toggle lever pair by a handlebar, characterized; that the optionally usable hinge points for the drive lever-side pivot point of the link (14) or the optionally usable points for the drive lever pivot point (2o11 to 2od) lie on a circular arc whose radius of curvature is equal to the length of the link (14) and is arranged so that with all adjustable reduction ratios with full drive lever deflection the extended position of the toggle lever pair (15, 16) is reached. G. Foot lever press according to claims i to 7, characterized in that means (bores 10, ii, auxiliary bolts or auxiliary levers) are arranged which make it possible to keep the parts to be changed in their position during stroke adjustment or to move them into the new one without great effort Able to bring. Cited publications: German Patent Specifications No. iil 198, 114 606, 1-2558, 361923.