DE3608961A1 - Shaft having adjustable annular tools for the preparation of corrugated cardboard for its further processing for machines for the production of corrugated cardboard - Google Patents

Abstract

For the positioning, displacement and retention of annular tools (4) for the processing of corrugated cardboard on a shaft (1), the tools are held on the shaft, at points determined by air gaps of magnetic systems, by means of generated magnetic fields. <IMAGE>

Description

The invention relates to a shaft with a

Number of annular grooving or cutting tools arranged on this to prepare, such as pre-folding or cutting, corrugated cardboard for further processing for machines for the production of corrugated cardboard, in which the ring-shaped tools in the axial direction are adjustable.

Depending on the desired position of a creased edge or one to be cut off Edge on a corrugated cardboard, these tools have to be placed in certain positions, thus adjusted, can and must then be locked.

In known devices of this type, the ring-shaped tools are fixed on the shaft using an air hose attached to the surface area of the shaft, which is wound spirally around the shaft, or by means of ring-shaped air hoses that are arranged at short distances from one another and that are connected to one another via a main air hose . These creasing and cutting tools are used to prepare corrugated cardboard when it is to be processed further. Corrugated cardboard webs are pre-folded by means of the creasing tools, while the cutting tools are used to cut the corrugated cardboard. The disadvantage of using air hoses is their high susceptibility to failure and the relatively large amount of time required if the distance or the position of the cutting tools is to be changed; because for this the air has to be let out of the air hoses and then the air hose system filled again with air or compressed air when the cutting tools have been readjusted.

The invention is based on the problem of making the use more susceptible to failure Avoid air hoses and change positions quickly and safely of the ring-shaped tools and their fixation in the new position.

This task is characterized by that in claim 1 Features solved, the embodiment according to claim 2 being particularly advantageous is, after which the annular tools, at least in part, made of magnetic material exist whereby in the shaft a magnet system is attached, which corresponds to a Multiple circumferential lines of the shaft can produce a magnetic field with which a ring-shaped tool can be locked on the shaft. When using a magnetic Moving field, the tool and the shaft are designed in the manner of a linear motor.

The ring-shaped tools can be made of iron or in the usual way Made of steel; their surface can be thin, the magnetic lines of force not be provided with a significantly impairing coating. By the majority The shaft can be divided into a number of sections by circumferential lines, in which optionally a ring-shaped tool is attached and through the magnetic field can be held.

The magnet systems are preferably close to one another at the same distance attached so that this creates a periodic structure of positions for the tools is specified.

The outer surface of the shaft can also be provided with a thin layer of a special material if this is necessary for the treatment of the passing webs of the to be folded. the material to be cut or to be cut.

The current for the electromagnetic systems is fed to the shaft via slip rings fed.

The invention is illustrated below with reference to the drawing, for example explained in more detail, the in F i g. 1 a shaft with annular tools approximately respectively shows in the side view, while in F i g. 2 in a section along the axis a magnet system is shown on the shaft and FIG. 3 shows a section through the shaft perpendicular to the axis.

Fig. 1 shows a shaft 1 with its axis 2. On the circumferential surface 3 ring-shaped tools 4, such as cutting and grooving bodies, are attached to the shaft, which have approximately a round material cross-section and their inner diameter is only slightly wider than the outer diameter of the circumferential surface 3 of the shaft 1. The Rings 4 can thus be moved in the axial direction. With these rings you can grooves are pressed into a sheet of corrugated cardboard for folding. The ring-shaped tools 4 can also be provided with outwardly directed knife-shaped cutting edges, that they can cut the corrugated cardboard. This corrugated cardboard becomes parallel to the peripheral surface 3 passed the shaft 1.

According to the invention, magnet systems are attached within the shaft 1, due to a occurring at certain points on the circumference 3 of the shaft, preferably a circular magnetic field arises, which is indicated by dashed lines 5 is. Corresponding magnetic fields are also shown below Rings 4 effective.

The magnet systems within the shaft 1 can by not shown Leads supplied from one or the other or both ends of the shaft 1 current be, so that a system on a line 5 above the magnet in question Ring 4 is held in place by magnetic force.

If the position of one of the rings 4 is now to be changed, needs only the current for the winding of the associated magnet system to be switched off. Then the ring can be moved. For this purpose, the shaft 1 is preferably stopped; but also by means of a suitable gripper the ring could while running of the wave.

After the ring to the new intended location according to a Magnet gap 5 is brought, the current required for it is switched on, so that the ring 4 is then held in the new location.

Fig. 3 shows a section along the axis 2 through the shaft 1. This consists in the embodiment of FIG. 2 from a tubular casing 6 from non-magnetic material, e.g. a hard aluminum or brass alloy. Outside of of this tube 6, a ring 4 is shown in section. Inside the pipe - accordingly a line 5 of Fig. 1 - a magnet system is attached, which shoes from two pole 7 and 8 consists, at their outer ends on the inside of the tube 6 a Leave the narrow air gap 9 free. A core 10 is attached within the pole shoes 7 and 8. Since the pole pieces 7 and 8 are designed that they are inside of the tube have a greater distance next to the core 10, there is room for one Wire winding 11 attached around core 10.

This winding has winding ends 12 and 13 with slip rings 14 and 15 are connected, which are attached to a part of the shaft 1, not shown are. These slip rings 14 and 15 are connected to power supply elements, e.g. carbon brushes, 16 or 17 in contact, which via lines 18 and 19 from a battery 20 Electricity can be supplied. To switch the magnetic field on and off, the Line 19 a switch 21 was added.

When the switch 21 is closed and current flows, it is through the magnetic field developed at the air gap 9 is held by the ring 4 arranged there. To move the ring, the switch 21 is opened: the magnetic field then falls away and the ring 4 can be moved loosely.

According to the width between the pole shoes 7 and 8 can magnet systems 7 to 11 are arranged close together within the tube. So can he Right-hand pole shoe arranged to the left of the magnet system shown Another magnet system assume the position shown in dashed lines at 22. The magnetic field lines 5 would then be considerably closer than is shown in FIG.

In principle, all windings 11 can be used together - if necessary electrically in series - are excited.

Since in each winding 11 energy losses due to the flowing current are caused, the entire arrangement heats up. This can be done by be kept within limits that each winding is performed on its own slip ring 15 is and can be switched on or off by means of a switch 21. It is natural also possible to use only two slip rings for power supply and the individual ones Switching the magnet windings on or off using switches on the shaft.

In operation, the tools 4 are not used when folding or cutting only loaded radially, but optionally also in the circumferential direction, so that they could slide on shaft 1. It can therefore be useful to counter this in Forces acting in the circumferential direction to arrange drivers.

Fig. 3 shows such an embodiment as a section through a Shaft 1 perpendicular to the axis according to the arrow B indicated in FIG. 2. Inside of Fig. 3, the plan view of a pole piece 7 is shown with dashed lines inside, which indicate a winding ll and a core 10.

The tube 3 forming the outer limit of the shaft 1 is attached to the by 23, 24 and 25 designated points with a groove-like running parallel to the axis Provided recess. The ring-shaped tool 4 is with at corresponding points inwardly protruding projections 26,27 and 28, which are inserted into the grooves 23,24,25 intervention.

The rings 4 can - when the magnetic field is switched off - freely in the axial direction due to the interacting projections and grooves 23-28 the tool 4 can not slip in the circumferential direction, so that it is from the rotating Wave is safely taken.

The pole shoes 7, 8 preferably rest firmly against the tube 6 from the inside, so that they contribute to mechanical stiffening. If necessary, between special support disks can be inserted into the magnet systems.

The arrangement of the magnet systems within the tube 6 provides in fixed distances one behind the other magnetic gaps, as is the case with a linear motor is known. In the invention, however, in addition to a linear displacement Aiming for locking in certain predetermined positions.

Due to the design according to the invention, there is more than just a locking the ring-shaped tools 4 on the shaft 1 possible, but the that A device that generates a magnetic field, namely the linear motor, also enables a Positioning the tool 4, because by using a traveling magnetic field the tools 4 are guided along the shaft 1, so that both a positioning as well as locking the tool is possible, in the latter case the Tool can stop between two magnetic fields or magnets.

Claims (9)

Title: Wave with adjustable, ring-shaped tools for preparation of corrugated cardboard for further processing for machines for the manufacture of corrugated cardboard Development claims: 1. Shaft with a number of annular rings arranged on it Creasing or cutting tools for preparation, such as pre-folding or cutting, of Corrugated cardboard for further processing for machines for the production of corrugated cardboard, in which the annular tools are adjustable in the direction of the axis, thereby characterized in that the tools (4) made of magnetizable material on the shaft (1) by means of several magnetic fields formed one behind the other or held by means of a traveling magnetic field, in the longitudinal direction of the wavelength movable and can be positioned and / or locked. 2. Shaft according to claim 1, characterized in that the annular Tools (4), at least in part, consist of magnetic material and that in the shaft magnet systems (7 to 11) are attached, which correspond to a plurality of circumferential lines (5) of the shaft (1) each cause a magnetic field with which an annular Tool (4) can be locked on the shaft. 3. Shaft according to claim 1 and 2, characterized in that the magnetic fields (5) are arranged at equal distances from one another. 4. Shaft according to claim 1, 2 or 3, characterized in that the Magnetic field between two pole pieces located on the inner circumference of the shaft (1; 6) (7,8) of an electromagnet (10,11) occurs, and that the associated magnetizing winding (11) is attached inside the pole shoes (7, 8). 5. Shaft according to one of the preceding claims 1 to 4, characterized characterized in that its outer surface (6) consists of non-magnetic material. 6. Shaft according to one of the preceding claims 1 to 5, characterized characterized in that supporting disks are arranged between the magnet systems (7 to 11) are. 7. Shaft according to one of the preceding claims 1 to 6, characterized characterized in that switches (21) are arranged on the shaft (1) with which the Magnetizing windings can be activated. 8. Shaft according to one of the preceding claims 1 to 7, characterized characterized in that the supply of the current (from 20) to the magnet windings (11) takes place via slip rings (14, 15). 9. Shaft according to one of the preceding claims 1 to 8, characterized characterized in that the shaft has an axially parallel profile on the surface, e.g. grooves, (23,24,25) and that the annular tools (4) on their inner surfaces a matching, inverted profile, e.g. protrusions (26,27,28) wear in such a way that the rings (4) from the shaft (1; 6) in the direction of rotation to be taken.