SU1433564A1 - Blanking die - Google Patents

Abstract

The invention relates to the processing of metals by pressure and can be used in dies for punching sheets of magnetic circuits of electrical machines. The goal is to increase the reliability and durability of the stamp. Cut stamp contains a matrix 2, the punch (P) 4, the ejector 5, placed inside the P 4. P 4 has two additional cavities in which the ejector drive mechanism is placed. The ejector drive mechanism is designed as a pair of double-arm levers 8 and 9 placed symmetrically with respect to the vertical axis of the P 4. The levers are equipped with pivot bearings 10 and 11. The smaller shoulders 12 and 13 of the levers are equipped with adjustable stops 14 and 15 that are outside the cavity of the P 4 and interacting directly with the mirror matrix. The large arms 17 and 18 of the arms are also provided with stops 19 and 20, which interact directly with the ejector 5. The design of the ejector driving mechanism allows the forcible pushing of the cut sheet with a sufficiently large force that overcomes the force of friction. The latter occurs in a stacking mandrel filled with cut-out sheets, and, therefore, reliably prevents sheets from reaching the matrix mirror. 3 il. с со (П

Description

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The invention relates to the processing of metals by pressure and can be used in dies for cutting sheets of magnetic circuits of electric machines.

The aim of the invention is to increase die resistance.

FIG. 1 shows a stamp, in the initial position, a slit; in fig. 2 - section A-A in FIG. one; in fig. 3 - stamp at the moment of pushing the cut foxes.

The cutting die includes a fixed plate 1, a non-drying matrix 2, a movable plate 3, a layer, a punch 4, an ejector 5 placed inside the punch. The punch 4 is also provided with two additional cavities 6 and 7, in which the pushing mechanism is ejected, made in the form of a pair of double-arm levers 8 and 9 arranged symmetrically with respect to the vertical axis of the punch. The levers are equipped with articulated supports 10 and 11, which are located in cavities 6 and 7. The smaller arms 12 and 13 of the levers are equipped with adjustable stops 14 and 15, respectively, that are outside the cavity of the punch and interact directly with the mirror of the matrix 2. To provide additional of the ejector 5, these stops are installed in such a way that when cutting a sheet they advance the punch to the thickness of the material being pushed 16. The large shoulders 17 and 18 of the levers are also provided with stops 19 and 20, which interact directly with the ejector 5. In mortars 2 and 22 at large lever arm is determined by their original position relative to the movable plate 3. The spring-loaded screw 23 binds ejector 5 with a movable plate 3.

The magnitude of the stroke of the ejector 5 is determined primarily by the ratio of the arms of the levers of the drive mechanism and the magnitude of the stroke of the punch, which determines the movement of the small arm of each of the levers.

Cutting stamp works in the following way.

In the initial (open) position of the pitch, the adjustable stops 14 and 15 are adjusted so that they advance the punch by the thickness of the material to be stamped 16. When the part is cut, the movable plate 3 with the punch 4 is lowered. The levers 8 and 9, resting against the lugs 14 and 15 in the mirror of the matrix 2, rotate around the hinge supports 10 and P. The lugs 19 and 20 interact with the ejector 5 and move it down to the size, which is so many times more than the slide stroke. each shoulder

leverage more than his smaller shoulder. Since the hubs begin to work simultaneously with the start of the cutting process, the stroke of the ejector 5 is increased. In practice, in a sequential die for cutting sheets of magnetic cores when the punch penetrates the matrix by 0.5 to 1.5 mm, it is possible to reach the pusher depth to 5-6 mm, which is quite enough to reliably prevent the cut out of for releasing back to the mirror of the matrix. In addition, the amount of force transferred by the levers is sufficient to overcome the friction forces arising in hollow mandrel.

With the help of spring-loaded screws 23, the ejector 5 returns to its original position during the reverse course of the punch. The application of the invention improves reliability.

The application of the invention permits the forced pushing through of the cut-out sheet with a sufficiently large force, overcoming the frictional force arising in the building-up mandrel filled with the cut-out sheets, and, therefore, reliably prevents the embossing of the stamps from the hollow mandrel and the failed window of the stamp to the mirror .

Claims (1)

Invention Formula A punch die containing a fixed plate with a die mounted on it, a movable plate with a punch located on it, a pusher mounted inside the punch, a primer mechanism with a pusher with two shoulders with different shoulder lengths and a hinge support that is different in order to increase reliability and durability of the stamp, it is equipped at least with one more double-arm lever with different lengths of arms and with an articulated support that is installed symmetrically with the main two-arm lever relative to the axis of the punch on, adjustable lugs fixed on the shoulders of shorter length of two shoulders 5 levers are diametrically opposite to the punch symmetry axis and installed with the possibility of interaction with the matrix mirror, as well as at least one spring-loaded screw connecting the ejector to the movable plate, 0 in this case, the punch is made with additional cavities for accommodating shoulders of greater length of the double-arm levers installed with the possibility of interaction with the ejector, and the hinged supports are placed in the punch. Phi2.1 Aa