DE854484C - Pit stamp - Google Patents

Description

Pit punch As a result of the new mining methods developed by the mining industry Recently, a pit stamp is required, which should be flexible, but in contrast to the previous designs, should achieve its full load capacity, without any noticeable sagging during this time. The load sinking path curve should therefore be a horizontal or slightly rising line represent, which in the ideal case already indicates the full punch load when the path is zero. Naturally such a stamp is supposed to be stolen by simple means, even under heavy loads can be.

The new stamp designs point towards achieving this goal a so-called work lock with loading element, d. H. during one possible With little sinking-in path, the sinking inner punch becomes a load-bearing element in the form of a drag wedge, swivel wedge, swivel bracket or the like, J% tightens the lock straps. This creates one of zero or A steeply increasing load sinking path curve starting from a low load, the at the end of the movement of the loading element, the full punch load is reached and then with further sinking of the inner punch horizontally or depending on its shape gently ascending. By hitting the set wedge and robbery wedge or by the use of a setting device is looking for the starting point of the load-bearing element resulting increase in the load sinking path curve, if possible, use a larger value admit.

The second way to achieve the required load sinking path curve is in just striking a wedge and a robbery wedge in the lock and opening it these Way an initial jamming in the lock and thereby pretensioning of the lock straps to achieve the maximum stamp load right from the start. As a result the relationship between the number of friction surfaces between punch and lock parts the coefficient of friction, the locking force and the sinking load, the necessity arises the number of friction surfaces made to work by the setting wedge and robbery wedge should be enlarged if possible. Such a stamp accordingly has a certain number of lamellar belts running parallel to the inner punch, with whose help the necessary number of friction surfaces to achieve the punch load is achieved. Since in this way the high required for some stamps Stamp loads cannot be achieved, one still has such lamellar stamps additionally provided with a loading element and thus achieved a relatively large setting load, but can increase from this load to the full punch load Do not avoid over a certain sinking path. These lamellar stamps also have still the disadvantage that the lamellas are in full length next to the inner punch, thus increasing the weight of the stamp and causing considerable soiling, especially in the case of blow-off, which jeopardizes their function will.

The invention aims to avoid all of these disadvantages and to create a multi-part pit punch, which the well-known ideal sinking curve can be achieved without having other operational disadvantages or through adversely affects the conditions of practical operation in its pressure curve to become. According to the invention, this can essentially be achieved in that the pit punch parts are under the action of a friction lock, which as is formed outside the inner punch arranged multi-disc brake. The slats are therefore in the pit punch according to the invention within the punch lock and thus protected from contamination. You are as a result of the operating conditions independent, and their friction values cannot be changed by this either, while all other advantages of lamellar friction can be fully exploited are.

In detail, the pit punch according to the invention can be designed in this way be that the lamellae are arranged transversely to the punch axis and under the effect one or more inclined to the punch axis, for example arranged on the inner punch Standing areas. The slats can be divided into movable and fixed slats be, with the movable slats on the inner punch and the fixed slats Support on the outside ram or on the lock wall. The inner shift against each other under the action of the rock pressure, the aforementioned becomes a stamp axis inclined surfaces reached. This inclined surface can be one side of a be wedge inner punch; however, it can also be in the form of a helix around the inner stem. By being housed in the castle and with it Keeping the slats small, it is possible to use a large number of slats and thus to greatly increase the clamping force. So it can be the initial one Setting load can be kept very large. Can be guaranteed by springs or other means that all lamellas are in contact with the inner ram from the beginning of the sinking-in path, so that already at the beginning of the Eininkweges all friction surfaces are effective and the sinking path from the clamping load to reaching the full punch load at least theoretically equals zero. In addition, this path can largely be made by the incline the area mentioned can be shortened, which is also still in a known manner can be supported by an additional load-bearing element.

With an arrangement of the lamellae around a cylindrical inner punch as a central axis around and training the necessary for the movement of the slats The inclination of this surface to the punch axis can still be a surface as a helical surface significantly increased and thus the steepness of the load sinking path between the clamping load and full punch load can be practically brought to 9o °, creating the ideal curve can be reached.

Finally, within the scope of the invention, it is also possible for the slats to give a special spatial design, through which the sinking curve of the Inner punch is favorably influenced. For example, the slats can be wedge-shaped Maintain shape or be shaped in their friction surfaces according to a curve, which, for example, a rapid increase to the full punch load and then maintains this maximum load.

Within the scope of the basic idea of the invention, a lamella arrangement outside of the inner punch in the punch lock itself to bring it into effect possible in many different embodiments. Some of these will be on hand Drawing explained in more detail. It shows FIGS. I and 2 a preferred embodiment and 3 to 6 show two further exemplary embodiments of the invention.

In Fig. I and 2, i is the inner punch, 2 is the outer punch and 3 is the Lock body. In the lock body 3 are stored the fixed slats 4, the be secured against rotation by an approach 5 of the lock body 3. the loose lamellas 6 are by an engaging in them intermediate piece 7, which on the other hand, in a groove 8 of the inner punch which extends in the manner of a helical line i intervenes, moves. The intermediate piece 7 can also be omitted, and the inner lamellae 6 then engage with approaches directly into the groove 8 of the inner punch i. That whole lamella pack can by a threaded ring 9 via an intermediate ring io im Lock body 3 are put under pressure. The tensioning and loosening of the threaded ring 9 can be done by hitting the shoulder ir. One on the lock body 3 located stop 12, which engages in a slot of the ring 9, limited the movement of the threaded ring 9. The inner punch i is opposed by a plate 13 Twists in the outer punch 2 secured. Now sinks as a result of the Mountain pressure of the inner die i, it will, as it is opposite the outer die 2 can not twist, due to the spiral groove 8, the intermediate piece 7 and so that the loose slats 6 move relative to the fixed slats 4. To this Way is through the interaction of the friction between the intermediate piece 7 and the inner punch i, between the inner punch or the plate 13 and outer punch 2 and between the Slats 4 and 6 generate the necessary resistance to sinking. By replacing the intermediate ring io by a spring or its design as a resilient element can be applied to the The load acting on the slats can be kept almost constant, causing a drop in the Locking force and thus the sinking resistance and the ram load is avoided and errors when striking the ring 9 are compensated for. ,.

3 and 4 another embodiment of the new pit punch i means an inner punch with an angular cross-section, 2 the outer punch and 3 the lock body. The fixed slats are labeled 4 and the loose slats are labeled 6. The loose lamellae 6 rest on the inner punch i via an intermediate piece 7. The lamella pack is pressed together by a wedge 14, namely between the wedge and the disk pack an intermediate plate connected, which are also made resilient again can. The inclined surface of the inner punch required to move the loose lamellae 6 i can in this construction by a load element 15 in the form of a drag wedge get supported. After stealing the stamp by knocking off the wedge 14 the plate pack is loosened. The loose lamellas 6 and the intermediate piece 7 are in place under the pressure of a spring, not shown in the drawing, when pulling out of the inner punch i the loose lamellae 6 and the intermediate piece 7 always in the starting position brings back.

The function of the stamp according to FIGS. 5 and 6 corresponds to that in 4 and 5 match. Only the slats are designed differently. The slats in this case themselves form the actual lock body, namely the lamellae 4 attached as fixed lamellae on the lower punch, while the loose lamellae 6 with be connected to them by a wedge connection 14 frictionally when setting can. The wedge 14 acts on a bracket 17 encompassing the disk pack, to which the outer lamella 4 is welded at 18. Corresponding intermediate layers 16 between the slats 4 and 6 maintain the correct distance between them. Even in the embodiment according to FIGS. 5 and 6, the initial load can still go through an additional element 15 can be improved. While in the embodiment 3 and 4, the individual slats 4 and 6 under the effect of the punch load are moved against each other by thrust, takes place in the embodiment according to Fig. 5 and 6 the opposite movement of the slats by train.

The invention is with the illustrated and described embodiments not exhausted, and there are still the most varied of arrangements within their framework of lamellar bodies within the ram lock possible, which in detail also optionally arranged in a plane lying parallel to the punch axis can be and experience a different design and arrangement for themselves can.

For example, the slats can also be designed or wedge-shaped their friction surfaces be arranged in a curve, so that during the friction path of the lamellas as a result of this shape, an increasing compression of the lamellas results.

Claims (7)

PATENT CLAIMS: i. Multi-part pit punch with friction lock, characterized in that the friction lock is designed as a multi-disc brake arranged outside the inner punch. 2. Pit punch according to claim i, characterized in that that the lamellae under the action of one or more inclined to the punch axis, for example, are on the inner stamp arranged surfaces. 3. Pit stamp after Claims 1 and 2, characterized in that the lamellae are transverse to the punch axis are arranged. 4. Pit punch according to claim i to 3, characterized in that that the inclined surfaces on helically wound around the inner punch ribs or grooves machined into the inner punch are attached in the same form. 5. pit punch according to claim i to 3, characterized in that the inclined Surfaces are formed by the surfaces of a wedge-shaped inner punch. 6. Pit stamp according to claims i to 4, characterized in that the lamellae are in the form of rings arranged around the inner punch and alternating with respect to the inner punch and are secured against twisting in relation to the lock body. 7. Pit punch according to claim i, 2 and 5, characterized in that the slats are arranged vertically or horizontally in the lock such that they are pushed past each other when the punch is loaded by one or more inclined surfaces located on the inner punch. B. pit punch according to claim 1, 2 and 5, characterized in that the lamellae form a lock body in the manner of a multilayer, split lock strap and are arranged on one or more inclined surfaces located on the inner punch in such a way that they move past each other when the punch is loaded will. 9. Pit punch according to claim i to 8, characterized in that the lamellae are under the action of a releasable clamping element. ok Pit punch according to Claims 1 to 9, characterized in that springs are inserted between the tensioning element and the lamellae. ii. Pit punch according to claims i to io, characterized in that the lamellae are under the action of springs which automatically bring them into their starting position after the tensioning element has been released. 12. Pit punch according to claim i to ii, characterized in that the lamellae are inevitably coupled to the clamping element in such a way that they are brought into their starting position when the clamping element is loosened. 13. Pit punch according to claim i to 12, characterized in that the lamellae are wedge-shaped. 14. Pit punch according to claim r to 12, characterized in that the friction surfaces of the lamellae are designed like a curve. 15. Pit punch according to claim i to 14, characterized in that the lamellae under the action of a z. B. are working in the manner of a drag wedge loading element that brings them to function on a very short Eininkweg.