DE1030943B - Inductive bolt heating device for the horizontal advance of a row of axially mounted bolts - Google Patents

Description

In inductive stud heating devices with a known horizontal feed Row of axially mounted one behind the other, mutually advancing through a cylindrical induction coil ! A piercing bolt occurs, especially with 5 light metal and with smaller diameters, the Difficulty that the axially acting on the bolt column electrodynamic field forces the bolt column or to hurl parts of it towards one of the open ends of the coil. If those electrodynamic field forces are greater than the friction of the bolts on their base or else especially if the bolt column is already in the same position due to a movement of the feed device Direction is set in motion, this phenomenon can lead to unpleasant disturbances in an automatic Guide the bolt push-through device.

For this reason, in the past, such facilities have generally not been used during the To leave the heating power switched on. However, this does not only lead to a reduction the performance, but also to a switching frequency that is undesirable for the switching elements. That's why The present invention has set itself the task of creating devices which allow the power supply not only when the bolt column is idle, but also when the To leave the feed switched on without the electrodynamic field forces acting on the bolt column still acting in the axial direction, an unintentional ejection of one or more Effect bolts on one of the open sides of the coil.

The starting point is first of all the fact that in the case of an asymmetrical position of a bolt column within an induction coil with non-magnetic material of the bolt column the electrodynamic field forces try to throw the bolt column or parts of it out in the direction of the protruding part; Furthermore, it can be assumed that the bolt column by inserting an air gap between the individual Bolt can be effectively interrupted for the electrodynamic effect. Particularly It is important to prevent unintentional bolt ejection on the open removal side. Therefor you can use known mechanical braking or locking means, which in the idle state on the bolt closest to the exit and, after a certain actuation of the feed, on the next following bolt attack, the braking or locking effect must be greater than the axially acting field forces, but smaller than the feed force itself. These braking or locking means can consist of resiliently pressing Devices, e.g. B. rollers or pawls exist, which close the induction coil Inductive billet heating device for horizontal feed

a row axially one behind the other

bearing bolt

Applicant:

Otto Junker, Lammersdorf via Aachen 1

Otto Junker, Gustav Ritzerfeld, Dipl.-Ing. Robert Lethen and Dr. Josef Putz,

Lammersdorf over Aachen have been named as the inventor

Pass through the outlet opening and clamp the bolt against its base. You can also call it from two or more sides acting braking and locking means can be formed, so that the braking or locking effect is not affected by an increase in ground friction.

Instead of a mechanical braking or locking device, success can also be achieved with an electrical one Ways can be achieved in that at each point in time during the current feed There is an extension of the bolt column beyond the insertion opening of the coil, so that the protruding The length of the bolt column beyond the entry coil end is always greater than the removal side, so that the ejecting field forces only have a harmless effect against the feed device and be caught by it. The extension of the bolt column over the input coil end can also be achieved in that the loading ram is set back further, see above that between the last bolt in the coil and that of the plunger touched directly Bolts there are still one or more intermediate bolts. A clamping device must be attached to this bolt be attached, which is designed so that it exposes the bolts in the piercing direction, in the opposite direction, however, locks, e.g. B. an eccentric roller.

However, this method can only be used where the bolts in the coil are such Partial lengths have that when put together they completely fill the coil. The intermediate bolt is still immersed

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does not enter the bobbin, but lies with its front end right up to the bobbin edge.

If you are dealing with different lengths, like this It can of course happen that the intermediate bolt partially protrudes into the coil and with the front one At the end, it stays in the oven one bar length longer than at the end. The bolt would become uneven warmed up. If the coil is provided with several taps on the input side, it can the coil length can be adapted to the possibly possible different bolt lengths.

The measures described above belong to the state of the art. According to the invention, the Solution of the problem achieved in the following way: The held by the bolt feed device and guided feed ram is an electrodynamically acting extension of the bolt column trained, e.g. B. by similar properties of material and strength as with the bolts themselves or as a hollow cylinder with appropriately selected material properties, wall thicknesses, and diameters or conductivity. If the feed is stationary but the feed ram is still attached, an asymmetrical The position of the bolt column including the plunger itself is set in relation to the coil length so that there is always an overpressure on the inlet side. The asymmetrical position of the Bolt column within the coil can also be shortened by electrical shortening of the induction coil, for example can be achieved by short-circuiting a few turns of the coil at the end, both on the entry as well as on the exit side, depending on the desired success.

Since it is inevitable with an automatic bolt puncture device that soon the removal, soon the feed side has a free end of the bolt column lying in the coil, it is in particular without the use of special braking or locking devices that attack the circumference of the bolt, It is necessary to temporarily block the outlet opening to prevent the bolt from being ejected. this happens after removing the bolt to be ejected by swiveling in a known locking device, which z. B. can be connected to a contact thermocouple against the exposed face the bolt pillar attacks on the removal side and also with electrodynamic excess weight this side blocks the ejection.

In order to line up a fresh bolt between the ram and the bolt column on the feed side, it is necessary that the plunger is separated from the bolt column by retraction. So now like that trained plunger does not follow the whole bolt column, it will in its retraction movement out with such an acceleration that it is greater than the field forces acting in the same direction. In this way, an air gap is created between the plunger and the bolt column, which prevents the following of the Prevents remaining bolts, because as a result, an electrodynamic excess weight on this side no longer exists.

The same process is necessary on the removal side, namely when discharging a to Ejection and removal of certain bolts. Here, too, the evacuation device must be marked with a Approach acceleration as it corresponds to the acceleration by the field forces, so that the The bolt to be driven off is separated from the rest of the bolt column by an air gap and so their Succession prevented. If then on the removal side the locking device acting on the front side swiveled in and if at the same time the ram is separated from the bolt column by moving back, should be the bolt column relative to the coil in the axial direction so asymmetrically shifted that a electrodynamic overpressure towards the outlet side, i.e. against the front-side locking device he follows.

An exemplary embodiment is shown in the schematic diagram in three stages. In all stages they mean: 1 the feed ram, which is attached to the feed device 1 α , 2 the fresh bolts in the magazine that have not yet entered the coil, 3 the bolts that are axially united to form a column within the coil, 4 the induction coil , which has a multiple of the length of the individual bolt, 5 the swiveling in and out, frontally engaging locking device, 6 the removal device for the bolt to be ejected, 7 the bolt intended for ejection from the bolt column.

Stage 1 shows the normal state of heating. The bolt pillar is inside the induction coil 4 axially asymmetrical, so that an electrodynamic overpressure against the end face Locking device 5 takes place.

In stage 2, the moment is shown in which a fully heated bolt is to be ejected. The locking device 5 swings from its locking position (vertical) to the position shown (horizontal). Before that, the shock device ία. with the plunger 1, which also acts as a bolt, is placed against the rolled-up fresh bolt 2 and thus forms a column with electrodynamic preponderance against the impact device. This excess weight remains until the bolt to be ejected is on the evacuation device (stage 3), whereupon the evacuation device 6 starts moving at such an acceleration that an air gap is created between the bolt 7 and the bolt column 3, so that an electrodynamic preponderance against the impact device remains. The front locking device 5 (possibly connected to the contact thermocouple) can be swiveled in again, and the state stage 1 is reached.

Claims (7)

Patent claims: 1. Inductive stud heating device for the horizontal feed of a row axially one behind the other, mutually advancing through a cylindrical induction coil piercing bolt, with the power supply uninterrupted even when the feed is actuated can remain switched on and one as a result of the axially acting electrodynamic Forces unintentional ejection of one or more bolts on one of the open sides of the Coil does not occur, characterized in that the held by the bolt feed device and guided feed ram designed as an electrodynamically acting extension of the bolt column is e.g. B. by similar properties of material and strength as with the bolts themselves or as a hollow cylinder with appropriately selected material properties, wall thicknesses, and diameters or conductivity. 2. Implementation of the method by means of the device according to claim 1, characterized in that that with stationary feed, but with the ram still attached, an asymmetrical position of the Bolt column including the plunger itself is adjusted with respect to the coil length, which results in an electrodynamic overpressure of the bolt column towards the inlet side. 3. The method according to claim 2, characterized by an electrical shortening of the cylindrical Induction coil (e.g. by short-circuiting a number of coil turns) on the entry side. 4. Implementation of the method by means of the device according to claim 1, characterized by an acceleration of the retraction movement of the feed ram that is greater than the acceleration by the field forces, so that the retracting ram through an air gap is separated from the rest of the bolt column. 5. Implementation of the method by means of the device according to claim 1, characterized in that that the removal device for the ejected bolt with greater acceleration moves away than it corresponds to the acceleration due to the field forces, so that the bolt to be driven down is separated from the rest of the column by an air gap. 6. Implementation of the method by means of the device according to claim 1 and the method according to Claim 2 and 3, characterized in that when the locking device is attached on the removal side and, while the feed ram is withdrawn from the column of bolts, the column of bolts itself is opposite the spool in FIG axial direction is so asymmetrically shifted that an electrodynamic overpressure on the Bolt column acts in the direction against the locking device on the exit side. 7. Implementation of the method by means of the device according to claim 1 and the method according to claim 2 to 6, characterized by the simultaneous or correct combination of several of the prescribed means. Considered publications:
German Patent Nos. 855 607, 859 031;
U.S. Patent No. 2,676,234. 1 sheet of drawings t 809 528/370 5.58