DE1183461B - Pit friction stamp - Google Patents

Description

Pit friction punch The invention relates to a friction punch with a tubular inner punch, which is in the back of the lock on a circular arc Supports contact surfaces and in which the clamping force is applied to the via a clamping plate Inner stamp is transferred.

There are friction stamps in various designs known at which in the castle a two-armed pivot lever mounted vertically or horizontally which can be acted upon by a horizontal wedge. When you hit the The pivot lever presses a wedge with one arm against an arm resting on the inner punch Clamping plate with almost the same force with which the lock wedge, which is on the engages other arm of the pivot lever, is supported on the clamping plate. It will be on in this way, the clamping effect on the inner punch is almost doubled. The disadvantage of this type of stamp is that the pivot lever is an additional one Component is brought into the lock, which, since it is subjected to bending, also still has to be carried out very vigorously. Furthermore, since the pivot lever is under the bending loads is elastically deformed, part of the amount to be applied for driving the lock wedge Striking power consumed as useless work of deformation. Another disadvantage is that in some of these lock constructions, the pivot lever is designed and is arranged that when the wedge is driven on the support surfaces of the pivot lever considerable friction paths result, which also result in energy losses and thus a bad one Condition efficiency of the lock construction.

Also known are pit punches, the torque clamping rings in the lock have, which enclose the inner punch and by driving the lock wedge be braced against the inner punch. The torque clamping rings acting as levers have to absorb considerable leverage. You must therefore run very vigorously will. So that the leverage forces approximately evenly over the 'on the circumference of the Transfer of friction surfaces distributed within the inner punch and thus local overstressing 'To be avoided, the torque clamping rings must also be machined very precisely will. When using tubular inner punches there is also the need to a number of strips protruding radially outward on the jacket of the punch tube to attach to which the torque clamping rings with radial arranged on them Attack noses.

Finally, a lock construction is also known in which two .horizontale wedges are provided in the lock, which have a clamping plate on the Inside stamp work. Both wedges can be driven independently of each other: Also With this lock construction, the clamping load can be approximately doubled, but it does exist here the disadvantage that the handling of the punch compared to a one-wedge punch is a little more cumbersome, and that the castle is a little bigger and heavier than the one of one-wedge punches.

The invention aims at an improved friction stamp that also of the lever principle to achieve a clamping effect that is several times greater served.

According to the invention, the lock is displaceable transversely to the punch axis arranged clamping plate so arranged that it is at an eccentric to the punch axis engages lying narrow friction surface of the inner punch. The arrangement is there taken in such a way that when driving the lock wedge of the inner punch with a second, also eccentrically arranged friction surface against one arranged in the lock Abutment rotates.

With such a design of the stamp and its lock construction the inner stamp is used to achieve the translation effect. A special pivoting lever in the lock is therefore not required. The lock can therefore easier, simpler and cheaper to run. It will also be used for driving of the lock wedge to be applied impact performance much better exploited, since on the one hand no significant deformation work is applied. must and on the other hand even the frictional forces on the wedge no longer represent a full loss of energy, but partly also in the sense of a bracing of the lock to the effect can be brought. Also means the use of a tubular inner punch an advantage, as this profile is due to its excellent static properties is particularly suitable for parts subject to buckling stress. The inventive In addition to the lock key, the stamp only needs a simple one in the lock Clamping plate and a component optionally combined with the clamping plate, said component being Forms abutment. Both lock parts are comparatively small in size and light weight.

The inner punch profile provided for the punch according to the invention expediently has two comparatively narrow friction surfaces, which with the distance are arranged side by side of approximately the length of the inner diameter of the profile. One of the mentioned friction surfaces serves as a point of application for the clamping plate, while the other for the support on the said abutment of the lock is determined. Both friction surfaces are preferably designed like a pan. the The clamping plate and the abutment have spherical surfaces that form the pan-like Surfaces of the profile are adapted and are accordingly supported on these surfaces can.

The wedge is expediently stored as a horizontal wedge in the lock, as which is common in stamp construction. Of course, it can also be used as a vertical wedge or arranged as an inclined wedge. The abutment is more suitable in the ram lock Way attached or hung. For example, the abutment can be fork-shaped be designed such that it engages around the clamping plate lying transversely in the lock and is carried by this. The abutment is based on the rear Lock housing from.

It is also advantageous if the clamping plate and the abutment transverse to the punch axis, d. H. move in the direction of the longitudinal axis of the horizontal wedge can. This not only results in an improvement in the adjustment options the lock parts on the inner stamp, but it can also be very simple Achieve way that the frictional forces on the lock wedge partially to a tension of the lock come into effect, as will be explained in more detail below.

It can also be very useful to have the abutment in the lock also designed as a wedge. The stamp has two, preferably horizontally mounted lock wedges, which, as with the well-known two-wedge stamp, can be driven independently of each other. However, this is useful Wedge forming abutments handled as a filling wedge, d. i.e., it is set when the The stamp is only struck so far that it closes without any appreciable tension bring, essentially only compensates for the game in the castle. The second wedge can then serve as a clamping wedge, which is driven with powerful blows when the stamp is set and is driven back when robbed. This way you can connect . With the lever principle an extraordinarily high clamping force can be achieved in the lock.

The drawing shows exemplary embodiments of the invention. It shows F i g. 1 shows a stamp according to the invention in side view, the lock being shown partly in section, FIG. 2 shows a horizontal section through the lock according to FIG. 1, Fig. 3 shows a detail of the lock mechanism, FIG. 4 shows a further exemplary embodiment of the invention, FIG. 5 and 6 two horizontal cuts through the ram lock according to FIG. 4. The punch according to the invention consists in the usual way of an outer punch 1, an inner punch 2 telescopically displaceable therein and a lock 3 which is firmly attached to the upper end of the outer punch and in which the inner punch 2 is frictionally set in - any Auszugstegjäg can be. The inner die t carries at its upper end a head plate 2 d (FIG. 4) for the support of a cap or the like.

The inner punch 2 has a tubular profile on which there are two friction surfaces 2a. The two friction surfaces 2 a are located next to one another at approximately the same distance as the inner diameter of the profile in order to achieve a long lever arm. They are designed like a pan and are arranged in such a way that the locking forces are introduced into the Proßl approximately tangentially. The profile has a bulge 2 b between the friction surfaces. The back 2 e of the profile is formed in the shape of a circular arc. It is supported on corresponding circular surfaces of the lock 3 so that the inner ram can rotate in the lock about .neige longitudinal axis. In horizontal longitudinal slots 3 a, a lock wedge 4 is mounted, which acts via a clamping plate 5 on one of four two reefs 2 a of the inner punch 2 (FIGS. 1 to 3). For this purpose, the clamping plate 5 has a friction surface S a, which lies in the pan-like Re> surface 2a of the inner punch. The arrangement is such that overall is rotated upon driving dea wedge 4 as a result of the eccentric Kraftangri% of Innenstempe12 about its longitudinal axis in the lock.

During this process, the inner punch 2 is rotated against an abutment 6 which, with spherical surfaces 6a, lies in the second friction surface 2a of the torn inner punch. The abutment 6 is, as shown in particular in FIG. 1 and 3 show, formed like a fork, and with its fork parts it engages around one of the two narrow lugs 5c of the clamping plate. In this way, the abutment is held by the clamping plate 5 in the lock. The Wi is supported on the back with a rounded surface 6 b on the lock.

The approaches 5 c of the clamping plate grip m the slots 3 a of the lock a. The clamping place S and the abutment 6 are in the seat strands 3a fa direction the wedge axis movable. The entrainment of the abutment 6 when the transverse displacement Clamping plate 5 takes place through an approach 5 b on the I plate. It is also an abutment 6 slightly movable with respect to the clamping plate 5 in order to allow the lock parts to be closed in relation to one another to enable.

As mentioned, the wedge 4 acts via the clamping plate 5 only on one of the two friction surfaces 2u of the inner punch. When the lock 4 is driven, the inner punch 3 is therefore rotated against the abutment 6, so that the support and the friction now take place on both friction surfaces 2a of the inner punch. The inner punch 2 is used by this measure to achieve the leverage effect. This means that the clamping effect achieved by the wedge drive in the lock is doubled, since the full wedge force acts on both friction surfaces 2a.

Due to the transverse mobility of the clamping plate 5 and the abutment 6 in the direction of the wedge axis is also achieved that in the direction of Arrow A (F i g. 2) acting friction on the wedge partially to brace the Stamp lock can be used. The frictional force A acts in the sense of entrainment, d. H. a transverse displacement of the clamping plate 5 and the abutment 6 and thus in the Meaning a rotation of the inner punch around its longitudinal axis, as the abutment 6 laterally on the projection 2 b of the inner punch profile 2 as well as the parts 5 a and 6 a in the pans 2 a and can therefore transmit the torque. It is therefore superimposed when driving the lock wedge 4 on the one hand by the Pressing the clamping plate 5 against the inner punch 2 caused clamping forces and on the other hand by the transverse displacement of the clamping plate 5 and the abutment 6 frictional forces acting in the direction of the wedge axis, both of which result in a rotation of the Induce inner punch 2 against the abutment 6.

In the embodiment according to FIG. 4 to 6, the abutment 6 is formed by a second lock wedge 4 a, which lies below the first-mentioned lock wedge 4 and is also mounted as a horizontal wedge in longitudinal slots 3 a of the lock 3. The two wedges 4 and 4a act on a common clamping plate 5, which lies with the spherical surfaces 5a in the two pan-like friction surfaces 2a of the inner punch profile. Of course, a special clamping plate can also be provided for each wedge.

The wedges are supported on the rear with spherical surfaces 4 b on pan-like Abutment surfaces in the lock, as in particular F i g. 4 shows. On the other On the side, the wedges are supported on the clamping plate 5. The arrangement is like this taken that when driving the wedges 4 and 4 a, the power transmission only takes place on one of the two friction surfaces 2a of the inner punch. To this end are the wedges 4 and 4 a slightly inclined relative to the clamping plate 5, so that they are only on one side rest against the clamping plate (Figs. 5 and 6). It is from FIG. 5 it can be seen that the wedge 4 when driving acts on the inner punch 2 that this in the direction of the arrow B is rotated. In contrast, the arrangement is made for the wedge 4a that a The inner punch 2 is rotated in the direction of arrow C (FIG. 6).

If the wedge 4 is first driven, the inner punch rotates in the direction of arrow B against the surface 5 a of the friction plate 5 which forms the abutment for tightening the wedge 4 and via which the wedge 4 a acts on the inner punch. The wedge 4 a thus forms the abutment for the rotation of the inner punch caused by the action of the wedge 4. On the other hand, the wedge 4 forms the abutment for the torsional forces that are generated when the wedge 4a is driven. Through this interaction, using the lever principle, an extraordinarily high degree of tensioning of the lock can be achieved by first driving in one of the two wedges and then hammering in the second wedge, which first forms the abutment.

Even with the arrangement according to FIG. 4 to 6 is the clamping plate 5 can be moved transversely in the direction of the wedge axis in the lock. So here too the Frictional forces acting on the wedge surfaces for additional bracing of the lock be made effective. To achieve this, the wedge 4 a is first used as a filling wedge, d. H. driven so far that it essentially only compensates for the play in the castle. For the further bracing, only the wedge 4 is then driven, whereby the mentioned utilization of the frictional force results.

In the exemplary embodiments described, the inner punch is supported 2 at the rear immediately in the castle. It is of course possible for that Provide a pan-like friction insert to support the inner punch, which is can rotate on lubricated surfaces in the lock together with the inner punch. It This reduces the friction on the support surface of the inner punch that occurs during rotation considerably reduced, so there (the lock mechanism has an extraordinarily high degree of efficiency receives.

The rotation that the inner punch executes when the lock is tightened, is of course only very small. She goes through the required game in the Lock and the elastic deformation of the lock parts given measure not or not substantially beyond.

It goes without saying that the hearing finish does not match the inner punch profile described give. Other profiles can also be used for this purpose, in which the clamping forces can be introduced mentrically into the profile that a Twisting against an abutment is achieved.

Horizontal wedges are also not absolutely necessary for bracing the lock to be used, although this is generally particularly convenient. It can also vertically arranged in the lock wedges or other clamping means, for example Eccentrics, clamping screws and the like are provided. The term "wedge" is therefore to be understood in the most general sense.

Claims (14)

Claims: 1. Friction punch with a tubular inner punch which is supported at the back of the lock on circular arc-shaped contact surfaces and in which the clamping force is transmitted to the inner punch via a clamping plate, characterized in that the clamping plate (5), which is arranged in the lock and can be displaced transversely to the punch axis engages a narrow friction surface of the inner punch eccentrically to the punch axis so that when the lock wedge (4) is driven, the inner punch rotates with a second, also eccentrically arranged friction surface of the inner punch against an abutment located in the lock. 2. Stamp according to claim 1, characterized in that the clamping plate (5) is independent of the abutment (6) is movable in the lock. 3. Stamp according to claim 1 or 2, characterized characterized in that the support of the clamping plate (5) and / or the abutment (6) is crowned. 4. Stamp according to one of claims 1 to 3, characterized in that the clamping plate (5) and the abutment (6) are supported with spherical surfaces (5 a, 6 a) on pan-like friction surfaces (2 a) of the inner punch (2) . 5. Stamp according to one of claims 1 to 4, characterized in that that the friction surfaces (2a) on the tubular inner punch (2) at a distance side by side of approximately the length of the inner diameter of the inner punch tube (2) are arranged. 6. Stamp according to one of claims 1 to 4, characterized characterized in that the wedge (4) is mounted as a horizontal wedge in the lock (3). 7. Stamp according to one of claims 1 to 6, characterized in that the clamping plate (5) is movable together with the abutment (6) transversely to the punch axis. B. rubber stamp according to one of claims 1 to 7, characterized in that the inner punch (2) is supported at the rear on a pan-shaped friction insert that is lubricated on Areas in the lock (3) is rotatable. 9. Stamp according to one of claims 1 to 8, characterized in that the abutment (6) is fork-shaped and the Clamping plate (5) engages. 10. Stamp according to one of claims 1 to 9, characterized in that the abutment is connected to the clamping plate so that it is carried along by the clamping plate when the clamping plate (5) is moved transversely in the direction of the longitudinal axis of the wedge (4). 11. Stamp after one or more of claims 1 to 10, characterized in that the abutment (6) in the lock (3) consists of a second lock wedge (4a). 12. Stamp according to claim 11, characterized characterized in that the second lock wedge (4 a) can be driven and the clamping plate (5) engages the inner punch (2) in such a way that the direction of rotation of the inner punch opposite to the rotation caused by the wedge (4) under the action of the wedge (4a) is. 13. Stamp according to claim 11 or 12, characterized in that also the Wedge (4a) is formed from the horizontal wedge, both wedges (4, 4a) in the lock (3) are stacked on top of each other and on a common or on independent Clamping plates (5) act. 14. Stamp according to one of claims Il to 13, characterized in that the clamping plate (5) rests against both friction surfaces (2a) of the inner stamp (2), the wedges au on the back surface of the clamping plate (5) so angrei that when driving the same the power transmission takes place only on one of the two friction rakes (2a). --.- 15. Stamp according to Claim 14, characterized in that the wedges (4, 4a) are inclined with respect to the clamping plate (5) in such a way that they rest against the clamping plate over only part of the length of the latter. Considered publications: German Auslegeschriften Nos. 1008 684, 1020 294, 1094 210.