DE3927776A1 - Coupling or brake laminar packet - has spreading devices to open up laminae in friction packet and realised as magnetic bodies - Google Patents

Abstract

The packet has spreading devices and laminae and laminae carriers. Magnetic fields (16) are used to spread the laminae and have radial poles. Magnetic bodies (8) with poles parallel to the friction faces of the laminae are located in the region of support profiles (3 etc.) for the laminae (4) in the laminae carrier (1). The magnetic bodies are arranged radially opposite magnetisable edge zones of the laminae. The magnetic bodies are distributed around the periphery of the laminar packet (4). The magnetic bodies may be set into radial recesses in the laminae carrier. USE/ADVANTAGE - For clutch or brakes. Long life.

Description

The invention relates to a clutch or Brake disk pack with spreaders after Preamble of claim 1, which starts from one e.g. B. in DE-C 26 01 507 described state of the Technology.

After that it was known to be in lamella packs from To provide clutches, brakes, etc. spreading devices, around the disks when the clutch or brake is opened to be separated quickly and reliably. In particular Oil-lubricated friction surfaces tend to stick together and also with a slat package that is not actually loaded to cause considerable residual friction or drag torque. With expansion elements in the open state of the Lamella pack a constant sufficient distance restored between them, the uncontrolled Stumbles prevented and also a cheaper to start Operating status after the vehicle has been shut down to be guaranteed. As a result, residual moments, Power losses, heating and wear when open Clutch are avoided.

In addition to spreading springs between the slats, which none completely avoid any further friction enabled, were through o. g. State of the art Centrifugal force-dependent spreading elements with radial balls guided between the individual slats known. To hold the balls there are holes in their area Driving profiles required, which the mechanical Weaken the strength of the slats and their manufacture make it more expensive. The positioning of the individual balls complicates the assembly of such plate packs and the selective overloading of individual slats or the Breaking individual bullets can result in such Heavy equipment equipped with lamella packs  Trigger consequential damage. Another disadvantage is that centrifugal force-dependent expansion elements only from one certain speed of rotation and thus respond at least in the start-up phase, do not fulfill their purpose can.

The object of the invention is based on this seen in it, a clutch or brake disk pack with To create spreaders, its spreaders are simpler and wear-free as well as over the entire Service life have approximately the same spreading forces.

The solution is based on the characteristics of the Claim 1 therein, for spreading the slats magnetic To provide fields with radially directed polarities, see above that these act particularly in the circumferential direction. It was namely found that with magnetization of the individual Friction plates over a circumferential air gap the individual, usually at a distance Slat edges, each one over the slat distances set opposite polarities in the same direction, with which then many individual axial plates in the entire plate package Repulsions of the individual slats to their neighbors are caused. The effective repulsive forces are on the one hand so low that it is caused by the operating forces are easily overcome, on the other hand they are sufficient in order to activate the plate pack after the discontinuation Actuating force the individual, possibly still together separating adhering slats reliably and until the actuation force is switched on again to keep. There is neither the contribution of centrifugal force (as in the case of the ball expansion elements), nor the Acceptance of mechanical residual friction (such as with Spring expansion elements) necessary.

Further advantages of the invention are given by the by means of the features specified for achieved special configurations:

• - A particularly favorable magnetic force effect reached when magnetic body in the area of Support profiles of the slats in the respective Disc carrier magnetic body with transverse to the axial direction (i.e. radial or tangential to the slats) facing polarity are provided.
• - If the slats are not already out anyway magnetizable material, it is sufficient even if the magnetic body is only in the radial opposite edge zones magnetizable Sub-areas are provided in or on the slats.
• - By distributing some magnetic bodies with the same effect on the circumference of the plate pack under axial majority coverage of the same becomes a uniform spreading force distribution achieved.
• - By embedding the magnetic body in radial The magnetic bodies are recesses in the disk carriers in a simple manner and without disadvantageous reduction the mechanically highly stressed slat drivers space-saving in the respective slat carriers of the Clutch or brakes can be accommodated. Even the assembly the magnetic body in the recesses of the Lamellar support is simple, and that Slat cross sections need to accommodate the Spreading elements can not be reduced.
• - By the magnetic body on the disk pack arranged evenly offset from each other Axially overlap the majority of the circumference, all slats of the entire package experience one about equally strong polarization according to the invention.
• - Provided that the slat carriers, if they are out non-magnetic material (e.g. aluminum) are not suitable for the magnetic field lines in the direction of the slat edges to continue, the magnetic body can also  simple way in pole pieces made of ferromagnetic Material are admitted, which in turn then in the Slat carriers are to be fastened.
• - Another intensification of the field lines is reachable if the front of the magnets which facing the opposite slats, from a circumferential air gap from the surrounding area in the respective disk carrier or pole piece are.
• - The generation of the magnetic field lines is both using permanent magnets or alternatively using Electromagnets possible in the same way.
• - When using electromagnets the Possibility at the initiation of the actuating force cancel the magnetic field and only when the Activate the actuating force again. With that needs the actuating force of the spreading force is not counteract and can be made smaller.
• - All versions have the advantage that in the spaces between slats and Slat supports have no constricted fixtures or movable components are narrowed so that the Coolant flows are more effective there can.

The invention is not based on the combination of features of claims limited. For the person skilled in the art further sensible combinations of requirements and individual claim characteristics from the task.

Further details of the invention are the To see explanations of drawings:

Fig. 1 shows a cross section through a plate pack.

Fig. 2 shows a longitudinal section of a spread plate pack.

Fig. 3 shows a longitudinal section of a closed plate pack.

FIGS. 4 and Fig. 5 show partial cutouts for the arrangement of an expanding element designed as an electromagnet.

In Fig. 1, a disk carrier 1 shown here as a hollow shaft is provided on its periphery with here wedge-shaped recesses 2 into which tooth-shaped inner drivers 3 of an inner disk 4 engage, the toothless outer edge 5 of which has a radial air gap 6 with respect to the front sides 7 of magnetic bodies facing the center , which are embedded in the inner lateral surface 9 of an outer disk carrier 10 shown here as a housing. The magnetic bodies 8 are provided with a uniformly distributed arrangement between inner recesses 11 on the inner circumferential surface of the outer disk carrier 10 , into which outer drivers 12 of the outer disks 13 engage, which form an array of disks with the inner disks 4 in alternating axial stratification. In the drawing, in the outer disk carrier 10 , assuming that it is an aluminum housing, they are equipped with magnetic bodies 8 , which are embedded in a pole piece 14 made of ferromagnetic material. The recesses, into which the magnetic bodies 8 and also their pole shoes 14 are inserted, can advantageously be designed to reduce scattering losses by providing a circumferential air gap 15 around the magnetic body 8 along the side surfaces located in disk carriers 10 and 1 , respectively , which is slightly larger than the air gap 6 to the opposite circumferential surfaces of the slats 4 and 13 , respectively.

In the left half of FIG. 1 and in the sections FIGS. 2 and 3, the course of the field lines 16 triggered by an outwardly directed magnetic body 8 in the inner disk carrier 1 is shown. According to the figures, a north pole N is formed in the horizontal axis above the magnetic bodies 8 and a south pole S is formed radially above the adjacent projections 17 of the associated disk carrier 1 . The situation is basically the same for an inward-pointing magnetic body 8 which is installed in the outer disk carrier 10 . In Fig. 2 it can be seen that radially between an inner disk carrier 1 , which has a relative rotatability with respect to an outer disk carrier 10, a disk pack is provided, which consists of alternately layered inner and outer disks 4 , 13 . The inner disk 4 has inner drivers 3 which engage in recesses in the inner disk carrier 1 (for example in a shaft external toothing formed by its radial projections 17 ), and the outer disk 13 has outer drivers 12 which engage between projections 18 of the outer disk carrier 10 , in which correspondingly large recesses 11 are incorporated.

The magnetization of the disks 4 , 13 in the area of their edges opposite the magnetic bodies 8, which originated from the magnetic body 8 , has here led to the formation of individual, rectified opposite poles on each disk friction surface. The rectified polarization does not weaken due to the relative rotation of the lamellae to one another, because a plurality of magnetic bodies 8 are arranged distributed around the circumference. The rectified magnetic poles repel each other in the axial direction so that the blades 4, are pushed apart axially 10 once they are no longer burdened by the retraction of the actuating piston 19 therethrough. The slats 4 , 10 can therefore easily separate themselves from one another again, and there is no drag friction during operation, since each slat is separated from its neighboring slat by a minimum distance.

So that approximately equal spreading forces occur on each lamella, it is advisable to make the magnet body 8 somewhat longer than the opened lamella package.

In Fig. 3 the area around the outer magnetic body 8 of the same disk pack is shown in the compressed state. The pressure of the piston 19 has overcome the spreading forces by the magnetic body 8 and presses the lamellae 4 , 13 without mechanically touching the magnetic body 8 , close together against a support disk 20 , which, for. B. is attached here by means of a locking ring on the outer disk carrier 10 in a rotationally fixed and axially fixed manner. Since the magnetic body 8 is also axially fixed with respect to the outer disk carrier 10 , the edges of the lamellae 4 , 10 always remain in its immediate effective area and the spreading force can be effective again immediately after each loss of the piston actuating force or can remain constantly effective. By means of this expansion device, neither friction nor clamping losses can arise, and there is no danger that the expansion elements will change their position or break. The magnetic body 8 can be fixed rigidly and shockproof on the respective associated disk carrier 1 or 10 captively. The application can be carried out with both dry and wet slats of all sizes running in oil and is an effective aid in preventing so-called drag moments, with unnecessary energy losses due to static friction between the slats.

A variant of the magnetic body 8 can also consist in that electromagnetic coils 8 A are used instead of permanent magnets.

In Fig. 4, a coil 8 A with a pole piece 14 in the outer disk carrier 10 is shown in cross section. The outer disk carrier 10 is to be regarded as a non-magnetizable workpiece. The field lines 16 therefore run from one pole over the air gap 6 into the magnetizable edge zones of the lamellae 4 , 13 and in the area of the opposite pole S of the same pole piece 14 again over the air gap 6 .

In Fig. 5 a longitudinal section of the pole piece 14 and the solenoid 8 A is shown. The pole shoe 14 can be fastened in the outer disk carrier, for example, by gluing or brackets (not shown). The axial length of the pole shoes 14 is sufficient to cover the entire length of the plate pack. The core of the pole piece 14 is encompassed by the magnetizing coil 8 A in the axial direction. This creates a north pole N over the end facing away from the piston and a south pole S over the piston-side end of the disk set 1 , 10 . The power supply to the coils can be done with normal cable connections for brakes, whose outer disk carrier is fixed. In the case of clutches whose outer disk carrier 10 can be rotated, sliding contacts are generally provided.

The electrical supply of the electromagnetic coils 8 A , not shown, makes it possible to provide a switch to be actuated together with the piston 19 , with which the electromagnetic coils 8 A are switched off during the activation of the disk pack 1 , 10 , and only switched on when the actuating force is lost by the piston 19 will. The use of 8 A electromagnetic coils also enables high static friction forces to be overcome between the lamellae 4 , 13 and offers the possibility of being able to work with a small piston 19 or a lower compressive force by switching off the spreading force.

Reference number:

1 inner disk carrier
2 cutouts on 1
3 internal drivers
4 inner slats
5 outer edge of 4
6 Radial air gap
7 front of 8
8 magnetic bodies
8 A magnetizing coils
9 inner surface
10 outer disk carriers
11 internal recesses of 10
12 external drivers of 13
13 outer slats
14 pole shoes
15 circumferential air gap
16 field lines
17 tabs from 1
18 tabs out of 10
19 pistons
20 support disc

Claims (10)

1. clutch or brake disk pack with spreading devices, which bring the mutually facing end faces of the mutually relatively rotatable disk carriers ( 1 , 10 ) axially guided disks ( 4 , 13 ) after removal of the compressive forces upon actuation, characterized in that magnetic fields ( 16 ) with radially directed poles are provided for spreading the lamellae ( 4 , 13 ). 2. disk pack according to claim 1, characterized in that the magnetic body ( 8 ) with polarities parallel to the friction surfaces of the lamellae ( N / S ) in the region of support profiles ( 3 , 12 or 17 , 18 ) of the lamellae ( 4 , 13 ) are provided in the respective disk carrier ( 1 , 10 ). 3. disk package according to claim 1, characterized in that the magnetic bodies ( 8 ) radially opposite magnetizable edge zones of the lamellae ( 4 , 13 ) are assigned. 4. disk pack according to claim 2, characterized in that the magnetic body ( 8 ) on the circumference of the disk pack ( 4 , 13 ) are arranged distributed and axially overlap it. 5. disk pack according to claim 2, characterized in that the magnetic body ( 8 ) are embedded in radial recesses of the disk carrier ( 1 , 10 ). 6. disk pack according to claim 2, characterized in that the or the magnetic body ( 8 ) carrying disk carrier ( 1 , 10 ) made of non-magnetic material and the magnetic body ( 8 ) are embedded in pole shoes ( 14 ) made of ferromagnetic material. 7. disk pack according to claim 2, characterized in that around the opposite slats ( 4 , 13 ) facing front sides ( 7 ) of the magnetic body ( 8 ) relative to the surrounding area in the respective disk carrier ( 1 or 10 ) or pole pieces ( 14 ) a circumference -Air gap ( 15 ) is kept open. 8. disk pack according to claim 1, characterized in that the magnetic field lines ( 16 ) by magnetic body ( 8 ) are generated in the form of permanent magnets. 9. disk pack according to claim 1, characterized in that the magnetic field lines ( 16 ) are generated by magnetic bodies ( 8 ) in the form of electromagnets. 10. disk pack according to claim 9, characterized in that electromagnetic coils ( 8 A ) having magnetic body ( 8 ) during the activation of the disk pack ( 4 , 13 ) by operation of the piston ( 19 ) are inoperative and are switched on when the actuating force is lost.