CS219989B1 - Vibration container mainly of the ring for festooning machine of the footwear uppers - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a vibratory container, and more particularly to rings for a shoe uppers, which comprises a container on the inner cylindrical wall of which a helical guideway is formed and which is connected by springs to the electromagnet support plate.

There are known magazines for shoe uppers, which consist of a cylindrical container in which a rotating brush is provided, which rotates the rings directly into the guide channel. The device for deriving the movement of the rotating brush is relatively complex and is a source of frequent disturbances. Direct accumulation of the rings into the guide channel does not preclude the blockage of the channel by accidentally occurring rings other than the dimensions specified by the manufacturer or by the manufacturer. different clusters of self-connected rings.

In addition, high-performance vibrating containers are known, such as fasteners, which are used in various fasteners, particularly in the electrical industry. The vibration containers very advantageously use the operation of an electromagnet which vibrates the cylindrical vessel at a frequency, e.g. 50 Hz. This vibration generates a centrifugal force that moves the individual connecting portions to the outer wall of the container, then along a helical guideway to the inlet of the guide channel. The main advantage of these vibrators is that they have no movement devices except the electromagnet, which greatly increases their reliability. In these vibration containers, the electromagnet is suspended on springs below the cylindrical vessel. This construction greatly reduces the overall height as well as the overall volume. Installing a too high and bulky vibrating hopper on the shoe up ringing machine is very difficult. E.g. it would be necessary to considerably increase the length of the guide channel so that the vibration container does not interfere with the movement area of the individual working devices of the ring-bending machine. However, the extension of the guide channel is undesirable since this increases the possibility of ring congestion disturbances. Conventional coupling parts for which known vibration containers are used are simple geometric formations which, when the container is vibrated, easily engage the helical guide track in the desired position (eg, the nut abuts the face). The rings used for shoe uppers have a relatively complicated shape and light weight with a large volume, which gives several positional possibilities when they contact the helical guideway. For this reason, the known vibration container cannot be used on the shoe uppers without the necessary modifications.

The above-mentioned disadvantages are overcome by the vibration container according to the invention, characterized in that an electromagnet is arranged in the center of the cylindrical vessel and a separating device of the rings to be processed is arranged on the helical guide path before the guide channel inlet. The separation device consists of a flat spring and a positional filter, against which positional slots are formed in the helical guideway. The flat spring has an overhung arm with a weight attached to its free end and which is set transversely above the helical guide track at the height of the prescribed rings.

A higher effect of the invention is that the cylindrical vessel, with the electromagnet located in its center, substantially reduces the overall height as well as the total volume of the vibration container. Thus it can be easily installed in the functionally suitable space of the shoe uppers. The separation device reliably provides access to the guide channel only for rings of the correct size and abutting the helical guideway with a flange surface. The flat spring reliably removes from the helical guide all rings which are higher than the prescribed height of the rings to be processed. The position filter, in conjunction with the position cut-outs, reliably removes the rings which move along the helical guideway through the shaft face and only pass to the guide channel inlet of specified size rings that move along the helical guideway through the flange face.

1 shows an overall plan view, FIG. 2 shows a section along line A - A according to FIG. 1 with a partial front view of the container, FIGS. 3 to 5 show a detail of the end part of the helical guideway in perspective; view of individual ring separations.

The vibration container consists of a cylindrical container 1 (FIG. 2) with an outer cylindrical wall 11 and a closed central part forming a cylindrical cover 12. The cylindrical cover 12 houses an electromagnet 2 whose anchor 21 is fixed directly to the top of the cylindrical cover 12 by means of upper screws 22. The core 23 of the electromagnet 2 is fixed to the support plate 3 by means of the lower screws 24. The outer shell of the cylindrical vessel 1 is connected to the support plate 3 of the electromagnet 2 by flat plate springs 31 and fastening screws 32. blocks 33 are connected to the base plate 4 by means of centering screws 34. The base plate 4 is secured to the frame 41 of the ringing machine by screws (not shown). The protective plate 43 is fastened to the base plate 4 by retaining screws 42, the upper part of which is terminated by the chute 44.

On the inner side of the outer cylindrical wall 11 of the cylindrical vessel 1, a helical guide path 13 is formed, on which a separating device 5 of the rings to be processed k is arranged before the entry (Fig. 1) of the guiding channel 6. The separating device 5 consists of a flat spring 51. 3) and positional passages 56 (FIG. 4), against which positional slots 14 are formed in the helical guide track 13. The flat spring 51 has an abutment arm 52, the free end of which is fixed with a weight 53 and which is transversely above the helical For this adjustment, the flat spring 51 is provided with a vertical groove 54 through which the adjusting screw 55 is fastened to the container body 1. The position passage 56 has a convex curvature 57 between which and the top surface of the helical guide track. 13 is a joint 58 that corresponds to the flange thickness of the prescribed rings k.

The operation of the vibrating hopper is as follows. The operator of the ringing machine puts the rings to be processed into the cylindrical container 1 and the electromagnet 2 is switched on by a switch (not shown). This causes the cylindrical container 1 to oscillate on the springs 31. The rings k are moved along the helical guide track 13 in various positions. In addition, rings of other sizes are rarely present among rings of the prescribed size. However, only those rings which are of the prescribed size and are displaced along the helical guideway 13 by the flange surface must be admitted to the inlet 61 of the guide channel 6. Only in this way is it ensured that the prescribed rings are reliably fed through the guide channel 6 into the ringing working device. machinery.

The flat spring 51 is rigidly connected to the cylindrical container 1 and therefore oscillates together. However, due to the weight of the weight 53, the overhung arm 52 oscillates at a different frequency. The oscillation direction of the arm 52 is parallel to the plane of the helical guide track 13. The flat spring 51 thus gradually drops back from the helical guide track 13 all rings that exceed the set height h of the gap between the helical guide track 13 and the lower edge of the arm 52. Fig. 3). These are various groups of rings spontaneously connected to each other by a shaft and a flange bore, as well as rings which slide along the helical guide track 13 and rings larger than a prescribed size. That is to say, below the oscillating arm 52 of the flat spring 51, only rings of the prescribed size pass through the helical guide track 13 through the shaft face or the flange face.

The rings, which are displaced by the shank face, are displaced by a convex curvature 57 at a further displacement 57 of the position passage 56 toward the edge of the helical guide track 13 where they engage the shank into one of the position slots 14. 4). The rings, which are moved by the flange surface along the helical guide track 13, with further displacement, insert a portion of the flange into the joint 58 below the position passage 56 (FIG. 5) and reach the inlet 61 of the guide channel 6.

When changing the type of prescribed rings, the position filter 56 is replaced and the flat spring 51 is adjusted by the adjusting screw 55 to the correct height h.

The invention can be used in the construction of reservoirs of various parts, e.g., connecting parts and in particular rings for the shoe uppers.

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Claims (3)

Subject A vibratory container, in particular rings for a shoe upper ringing machine, comprising a container, the inner cylindrical side of which is provided with a helical path and which is connected by springs to the electromagnet support plate, characterized in that in the center of the cylindrical container (1) The electromagnet (2) is mounted and on the helical guide track (13) a ring separator (5) is arranged before the inlet (61) of the guide channel (6). 2. A vibration container according to claim 1, characterized in that the separating means (5) consists of a flat spring (51) and a position passage (56) against which position slots (14) are formed in the helical guide track (13). Vibrating container according to claim 2, characterized in that the flat spring (51) has an overhung arm (52) at the free end of which a weight (53) is fixed and which is transversely above the helical track (13) at a height (h) prescribed rings (k). 2 sheets of drawings