CH623762A5 - - Google Patents

Description

623 762

Claims (6)

1. Pulled biconical collet comprising, at one end, a first multi-element cone intended to be introduced into a female cone of a spindle and, at the other end, a second multi-element cone, characterized in that the two cones are inclined towards each other and in that there is a connecting element to a tie rod, the connecting element being provided inside with a conical part cooperating with the second cone. 2. Clamp according to claim 1, characterized in that the second cone has slots. 3. Clamp according to claim 1, characterized in that the sum of the elements of the second cone represents less than half of the circumference and in that the conical part of the connecting element comprises recesses corresponding to the elements of the second cone. 4. Clamping pliers according to claims 1 and 3, characterized in that it further comprises a pin sleeve to block the conical part of the connecting element opposite the elements of the second cone. 5. Clamp according to claim 1, characterized in that the inclination of a cone is different from that of the other cone. The invention relates to a drawn biconical gripper. Biconical pliers are generally known. They are used to increase the clamping force, particularly when exerting a large axial force on the material to be machined, for example when drilling. Collets can be separated into two large families, pull collets and push collets. Due to the principle that actuates them, the push pliers lend themselves more easily to the realization of a biconical tightening. As an example, we cite Swiss patent No. 175086 which presents a relatively simple solution using two clamps one behind the other with a clamping tube that pushes on the cone of the first clamp and a small tube between the two clamps which pushes on the other clamp, when the pressure is transmitted to it from the first clamp. The more recent British patent No. 1422323 uses two sets of jaws instead of conventional pliers and provides for their use with their cones in the same direction, in the opposite direction, once the cones are inclined inwards and a times the cones being tilted outwards. These two examples show that several solutions have been found in the field of pushed biconical grippers. These pushed collets are used especially in single-spindle automatic lathes. Because these push collets must be cleaned very often, push collet clamping mechanisms have not been provided on multi-spindle lathes. The cleaning would in fact have to be carried out much more often because there is not just one gripper, but six or eight, and because the removal of chips is done in a more intense way, with more advances stronger than on single-spindle lathes, which causes more deposits. For these reasons, drawn collets are essentially used on multi-spindle automatic lathes. In these lathes, it is particularly advantageous to have grippers whose clamping force is very high because the axial forces are greater than on single-spindle lathes. Practice shows on the other hand that there is no drawn biconical clamping on multi-spindle lathes. On the other hand, there is Swiss patent No. 279981 which presents a drawn biconical collet. If this gripper has not found a field of application on multi-spindle lathes, it is certainly because it has the major drawback of requiring a special spindle with additional mechanical elements. It is therefore not possible to use this collet instead of a normal collet in a lathe spindle, without major modifications. The aim of the present invention is to provide the user of drawn pliers with a drawn biconical plier that can be adapted without modification in a spindle provided for simple pliers. The drawn biconical collet according to the invention is arranged according to claim 1. The accompanying drawings show, by way of example, two embodiments of clamps according to the invention. fig. 1 is a perspective view with parts cut away of the first embodiment, and FIG. 2 is an exploded perspective view of the second embodiment. In fig. 1, an execution of a simple biconical clamp is presented. The front cone is designated by 1 and the rear cone by 2. The particularly wide slots to allow the rear cone to be tightened are designated by 3. The connection of the clamp to the tightening rod not shown is designated by 4. This connection 4 comprises a female cone 5 which acts jointly with the cone 2. The tension rod is fixed to the clamp by the thread 6. 7 designates the spring which pushes the connector 4 against the cone 2. This cone 2 comprises an inclined heel 8 intended to facilitate the passage of the connector 4 on the cone 2 for its installation. fig. 2 presents a slightly more elaborate execution which does not require tightening of the rear of the clamp for the passage of the connector. In this figure, the front cone is designated by 11, the rear cone by 12. Slots 13 allow the rear of the gripper to clamp the material. The function of the connector 14 consists in resting by its female cone 15 on the cone 12 of the pliers. The thread 16 is used to connect the clamp to the tightening tie rod, not shown. The connector 14 must be threaded onto the rear of the clamp by passing the cones 12 through the clearances 17. It is by a slight rotation that the cones 12 and 15 are placed opposite each other. In order to maintain these parts in this position, the sleeve 18 must first be slipped onto the pliers, the inlets 19 of which pass through the cones 12 and remain engaged on the studs 20 which prevent the sleeve 18 from rotating. The lug 21 holds the connector 14 through the opening 22; the springs 23 in their bores 24 push the sleeve 18 against the coupling and ensure its position, preventing it from rotating. 2 5 10 15 20 25 30 35 40 45 50 55 R 1 drawing sheet