DE1481374C - Device for feeding nuts or similar magnetizable objects were - Google Patents

Description

The invention relates to devices for feeding nuts or similar magnetizable Objects to a processing point, consisting of a driven magnetic disk with on her Poles of opposite magnetic polarity arranged on the edge, a device for bringing them closer the objects from a magazine via a channel to the magnetic disk and with one to the processing point leading channel, with the objects in a curved path at the edge of the disc guided along, held by the magnetic attraction of the magnetic disk, transported and removed from the disk at an outlet point and the one leading to the processing point Channel are fed.

When feeding punch nuts to a job, For example, a press, through a channel made of plastic or sheet metal, the nuts in the The channel slide freely up to a stop in the machine. In the machine they are one after the other removed and attached to a piece of sheet metal. Since the feeding is usually faster than the removal, the nuts can back up, so that when the channel is full, the feeder has to be temporarily stopped until nuts can be tracked again. Is the feeding force too large, the stop in the press can also be damaged. Occasionally a Clamp the nut in the channel by tilting it or by sharp nut corners. Even then should the Feed device run empty until the error is corrected, but if the feed force is too great, the Jammed nut presses itself into the channel and deforms it, so that nuts jam there again be able.

There is already a feed device with a magnetic disk with opposite pole edges Polarity of the type described above is known. The pole edges of the disc engage in the groove, with the Objects or workpieces held by the magnetic attraction on the edge and be transported. If the resistance acting on the workpieces exceeds the maximum available Propulsion force, e.g. B. in the event of a jamming, the disc simply slides on the workpieces over until the bug is fixed.

The object on which the invention is based is to identify the possible uses of such feed devices to make it more versatile in that the propulsive force exerted on the magnetizable objects is variable.

According to the invention, this object is achieved by mechanical means in a device of the type mentioned at the outset Adjustability of the length of the arcuate part lying in the effective area of the magnetic disk solved the path of the objects to change the effective magnetic propulsion force.

The device according to the invention has the advantage that when the channel length changes Propulsion force is adjustable accordingly. Furthermore, an adaptation to the requirements to be requested is simple Objects of different weights or different sizes are easily possible. This results in as a further advantage that there is a risk of damage to the channel when jamming Avoid nuts or similar objects due to an excessive propulsive force of the magnetic disk is.

The invention is explained below with reference to the drawing. It shows

F i g. 1 a schematic representation of the feed path for nuts,

F i g. Figure 2 is a schematic representation of the nut feed path from one magazine to four processing points,

F i g. 3 a perspective view of the channel,

F i g. 4 is a sectional view of a nut to be conveyed that is attached to a piece of sheet metal;

F i g. 5 is a perspective view of the magnetic disk;

F i g. 6 a sectional view of the magnetic disk;

F i g. Figure 7 is a side view, partly in section, of the magnetic conveyor with means for changing it the driving force supplied by the conveyor,

F i g. 8 is a side view of the magnetic conveyor with another device for changing the on the number of nuts held on the magnetic disk and

F i g. 9 shows a further embodiment of the magnetic conveyor in which the conveyor channel is opposite to that of FIG Magnetic disc is adjustable.

In Fig. 1 of the drawing, the nuts come out of the drum magazine driven by the motor 14 12 in the channel 16. In the drum magazine 12, the nuts ■ are thrown together and automatically entered one after the other into the channel 16. The nuts are then initially closed the magnetic conveyor 18 driven by the motor 20. The nuts are from the magnetic conveyor 18 pushed up through the part 17 of the gutter to an upper suspension point 22 from which then pass the nuts by gravity in part 19 of the channel to a press 24 in which they are individually be attached to a piece of sheet metal. The nuts thus pass through the parts 16 by gravity and 19 of the chute and are pushed up in part 17 of the chute by the magnetic conveyor 18.

In Fig. 3, a portion of the channel 16 is shown with the nuts 26 lying side by side. The gutter 16 is formed channel-shaped and made of plastic or sheet metal, but plastic is preferred is because the gutter can then more easily be bent in the manner shown in FIG. The edges 27 prevent the nuts from falling out. In Fig. 4 is an inserted into a piece of sheet metal 25 Pierce nut 26 shown.

In Fi g. 2, the nuts come from a single magazine 36 via four channels 28, 30, 32 and 34 four different consumption locations 38, 40, 42 and 44. The four magnetic conveyors 46, 50, 52 and 54 slide the nuts through the gutters, one or all of which are those shown in FIG. 1 have the shape shown the places of consumption. The grooves are of different lengths, so that the ones opposite to the nuts Resistances are different. Here, too, it is required that the pressure exerted by the magnetic conveyor Thrust is adjustable.

Also, for example, a magnetic washer can have fairly large nuts and another washer promote quite small nuts with less weight. This latter magnetic disk should have a lower thrust exert on the small nuts so that there is a risk of damage from jamming the Nuts in the gutter is as small as possible.

One of the advantages conveyed by the magnetic disk is that one on the nuts acting resistance which is greater than that on the

The thrust force exerted on the nuts is the magnetic disc simply passes the nuts until the error occurs is fixed.

However, if the driving force is too great, it can even promote jamming, so that in expediently only as much thrust force is exerted as the size of the to be pushed Nuts is adapted.

In Fig. 7 is an embodiment of the magnetic disk with an adjustable finger 100 for adjustment the number of nuts detected by the washer 18 shown, whereby the on the nuts for pushing through The force exerted by the channel 17 can be changed. The disk 18 sits on the shaft 60. According to FIG. 6, the disk consists of two wheel disks 66 fastened to one another by means of screws 70 and 68. A ring magnet 72 is held between the two wheel disks 66 and 68. A sleeve 61 out non-magnetic material, e.g. B. aluminum, separates the shaft 60 from the magnetizable material of the wheel disks 66 and 68. The magnet 72 is a permanent magnet with opposite one another Poles 74 and 76. A partial flux of the magnet goes through the wheel disc 66 to its outer edge 78, then penetrates the gap between the edges 78 and 80 and closes on the wheel disc 68 to opposite magnetic pole. Two opposing poles 78 and 80 are thus formed at the edge of the pane from, of which according to FIG. 6 a nut 26 is tightened. The magnetic attraction is like that large that the nut 26 is held on the edge of the disc, so that this nut as a drive body for the other nuts located in the channel 17, which are no longer covered by the magnetic disk serves.

The number of nuts detected by the magnetic force of attraction on the edge of the washer sets the Size of the driving force for pushing the nuts through the channel 17 fixed. In Fig. 7 extends the edge of the disc 18 in a channel 86, which is an extension of the channel between the Sections 16 and 17 forms. The poles 78 and 80 on the washer edge 80 engage various nuts 26 in the channel and hold it on the edge. The nuts emerge from the channel section 16 at the feed point 88 into the channel 86 and leave it at the outlet 90, from the they pass into the channel 17. The channel is flanged 92 corresponding to flanges 27 in Fig. 3 provided. While the nuts 26 migrate through the channel 86, they are in the Space between the flanges 92 and the bottom 94 of the channel. A mother reaches the outlet point 90, it is stripped from the disc 18 through the flanges 92 and into the channel 17 through the behind her nuts pushed. The channel 86 and the gutters 16 and 17 are with the foundation 64 connected by a frame 95.

The number of nuts held by the washer can be adjusted by adjusting the position of the finger 100 be changed, which is shown in FIG. 7 is in a raised position. The finger reaches through an opening in one Block 101 which is attached to the wall of the frame 95. An adjusting screw 103 enables the longitudinal adjustment of the finger 100. The tip of the Fingers 100 can be flanged in the space / wipe 92 read channel 86 to be advanced some of the nuts 26 in the channel from the Kami Keep washer 18 away. Thus, the number of nuts held on the washer is dependent how far the finger 100 into the channel from the in FIG. 7 is advanced position shown. the Finger is resilient enough to adjust to the curve of the canal and around the nuts from the To keep the edge of the disc 18.

In Fig. 8 shows another setting option. Here are the channel 86 and its frame 95 arranged rotatably about the pin 106, so that only a narrow section of the edge of the disc 18 next to the outlet point 90 engages in the channel between the flanges 92. The rest of the edge of the disc cannot grip the nuts in the channel and therefore cannot hold the nuts on the washer. The adjustment of the channel 86 and its frame 95 can be effected by the device 107. An adjustment screw 109 passes through a block 111 attached to the foundation 105 and sits in a movable block 113. When the screw 109 is rotated, the movable block moves 113 in the longitudinal direction of the screw. This axial displacement causes the channel to rotate 86 and the frame 95 by means of a joint consisting of the arms 115 and 117. The arm 115 is attached to the sliding block 113, while the arm 117 at one end of the arm 115 and with its other end is attached to the frame 95. The arm 115 moves through in FIG Rotation of the screw 109 upwards, the articulated arm 117 pulls the frame 95 upwards and behind on the right in a more level position.

In Fig. 9 shows a further setting option by simply opening the channel 86 or the disk 18 moves against each other in the horizontal direction. In the illustration is the entire channel 86 and its frame 95 shifted to the right against one side of the pane so that only part of the washer engages in the channel on its left-hand side and engages the nuts, causing only the Nuts that come into contact with the edge of the washer are held.

The device 114 for moving the frame and the channel consists of a block 116 on the foundation 64, another block attached to the frame 95 and an adjusting screw 120, which engages through block 116 and is screwed into block 118. The screw is partly in block 116 such that it is held in place when rotating in the axial direction. Move while turning screw 120 thus the block 118, the frame 95 and the channel 86 in the longitudinal direction of the screw, and this causes the channel to be positioned horizontally with respect to the disk 18.

The magnetic disk slips past the nuts when the force exerted on the nuts when pushing through Resistance is greater than the force supplied to drive the nuts.

Claims (7)

Patent claims: 1. Device for feeding nuts or similar identifiable objects • to a processing agency. consisting of a driven magnetic disk with opposing magnetise poles arranged on its edge for polarity, a facility for bringing up of the objects ans a muga / iu over a groove / u of the magnetic disk and with one The channel leading to the processing point, with the objects in a curved path on the Along the edge of the disc by the magnetic Attraction of the magnetic disk held, transported and at an outlet point removed from the disc and fed to the channel leading to the processing point are characterized by the mechanical adjustability of the arched, part of the path of the objects to be changed in the effective area of the magnetic disk (18) the effective magnetic propulsion force. 2. Apparatus according to claim 1, characterized in that the channel (16, 17) and the magnetic disc (18) against each other to adjust the distance between the outlet point and the Feed point are displaceable. 3. Apparatus according to claim 1 or 2, characterized in that the channel in the area the magnetic disk (18) is designed in the form of a flanged channel (86) and the channel can be displaced in relation to the disk to adjust its magnetically effective path length is. 4. Apparatus according to claim 1 or 3, characterized characterized in that the channel (86) is pivotably mounted. 5. Device according to claims 1 to 3, characterized in that in the region of the beginning or end of the channel a tangentially between the objects and the circumference of the magnetic disc (18) insertable separating finger (100) is arranged, the edge along the disc to adjust the distance is displaceable and lockable between the acceptance point (88) and the delivery point (90) of the magnetic disc (18). 6. Apparatus according to claim 5, characterized in that the separating finger (100) is arranged at the feed point. 7. Device according to one of claims 1 to 3, characterized in that the channel (86) and the magnetic disk (18) are displaceable relative to one another in the horizontal direction. For this purpose 2 sheets of drawings