DE10049168A1 - Electromagnetic brake has friction lining carriers joined together so as to rotate together by bearing unit, one carrier axially flexibly positioned relative to bearing unit, the other is fixed to it - Google Patents

Abstract

The brake has a coil arrangement (3) with an armature plate (4) and an axially movable friction plate between two axially movable friction lining carriers (6,8). The friction lining carriers are joined together so as to rotate together by a bearing unit, whereby one carrier is axially flexibly positioned relative to the bearing unit and the other is fixed to the bearing unit. The bearing unit is a toothed element (10) whose axial length extends at least over the axial thickness of both friction lining carriers and the friction plate. The brake has a coil arrangement (3) with an armature plate (4) and an axially movable friction plate between two axially movable friction lining carriers (6,8). The friction lining carriers are joined together so as to rotate together by a bearing unit, whereby one carrier is axially flexibly positioned relative to the bearing unit and the other is fixed to the bearing unit. The bearing unit is a toothed element (10) whose axial length extends at least over the axial thickness of both friction lining carriers and the friction plate.

Description

The invention relates to an electromagnetic brake with egg ner coil arrangement, with an armature disk and with two Friction lining carriers and with one between the friction lining carriers arranged, axially movable friction disc, the friction brake pads are axially movable.

It is known (elevator brake NBH-Z4 from Stromag AG), to provide an elevator brake to increase safety in the event of a power failure, is provided with two friction lining carriers each have two friction surfaces. Between the friction lining carriers a friction disc is arranged. In the elevator brake an electromagnetic coil assembly is positioned that acts on an armature disk. The armature disk is through Compression springs loaded the anchors when de-energized Press the disc against the first friction lining carrier, which again to act on the friction disc and this against the second Friction lining carrier presses, which is on the back of a statio supported brake disc. Every friction lining carrier is by means of its own toothing carrier, the one inside has teeth, on an external toothing of a rotary Ren brake hub rotatably and axially movable. The both toothing carriers have a relatively short axial  Length on. It can therefore be tilted the Reibbelagträ ger and the associated gear carrier occur, the one Can cause jamming. Especially when clamping of the first friction lining carrier, which is adjacent to the armature disk and thus the first gear carrier, it is possible that only a single friction surface, namely the between the first friction lining carrier and the armature disk, one ent speaking frictional flow builds up with the armature plate, so that only a single friction surface is effective and therefore stable is.

The object of the invention is an electromagnetic brake to create the type mentioned in the ver clamping increased compared to the prior art unit by wearing at least two friction surfaces.

This object is achieved in that the friction lining carrier connected to one another in a rotationally locking manner by a storage unit are, with a friction lining carrier relative to the bearing is axially resiliently positioned and a Reibbelagträ ger is firmly connected to the storage unit.

Normally when the brake is 100% of its nominal torque four friction surfaces are effective. These are in the Individual the friction surfaces between the armature plate and the first friction lining carrier, the first friction lining carrier and the Friction disk, the friction disk and the second friction lining carrier and between the second friction lining carrier and the stationary held brake disc. By the solution according to the invention is also in the event of a malfunction, for example a jamming Friction lining carrier, always ensures that the brake min reached at least 50% of their nominal torque. So it's always effective at least two friction surfaces that apply a braking torque bring and thus brake the brake hub. The fiction moderate electromagnetic brake corresponds to the previous writings of elevator technology that when braking with  Rated load of the loaded car at least 50% of the nominal torque tes of the brake must be available.

The coils used in the electromagnetic brake order can consist of one or more coils. Before preferably two coaxially arranged coils used with separate circuits. This ensures does that in the event of a coil failure through the whose coil can be braked. As a friction lining carrier in the sense the registration will all include a friction or Understand suitable brake pad body. Preferably have the friction lining carrier a disc shape, but can also others re geometries. They are in particular axial to one Center axis of the brake hub arranged in parallel one behind the other net. In contrast to the armature disk, which has one or more parts can be formed, the friction lining carriers are preferred one-piece. It is possible that the axially flexible Reibbe support by means of a flexible membrane arrangement on the La is held. The membrane arrangement can in one piece with the friction lining carrier or as a separate construction be partially connected to it. It is preferably axial compliant friction lining carrier, however, axially floating on the Storage unit stored. This is a particularly functional one safe and easy to manufacture design.

In a development of the invention, the storage will be unit formed by a toothing carrier, the axial Length at least over the axial thickness of both friction lining carriers and the friction disc extends. So it can two friction lining carriers on a common one, with the inner ver toothed toothing carrier arranged in a rotationally locking manner his. The friction adjacent to the armature disk is preferably lining carrier on the bearing unit axially resilient positi oniert. To tilt the friction lining carrier and the order to prevent toothed carriers, extends the Internal teeth at least over three quarters of the length of the External toothing of the hub to be braked. If there is one  Incident occurs, for example when the gearing between the gear carrier and the hub are stuck, the axi all axially move the flexible friction lining carrier. There by the axially acted upon by the armature plate compliant friction lining carrier act on the friction disc, the again due to their axial mobility on the neighboring beard friction surface of the subsequent friction lining carrier acts, so that carry a total of three friction surfaces. With a jam of the friction lining carrier adjacent to the armature disk becomes a Axial movement of the entire toothed carrier achieved where with this friction lying opposite the first friction lining carrier lining carrier on the back through the stationary brake disc is hit, so that a total of two friction surfaces wear. If the friction disc jams, the brake is applied by the located between the friction disc and the armature disc Friction lining carrier, so that even in this case two friction surfaces be available. This is compared to the state of the Technology guaranteed in each of the named jamming cases Tet that at least two friction surfaces are always effective. The Friction lining carrier can be in with the help of a bolt arrangement Direction of rotation held positively on the toothing carrier his. The bolt arrangement is also used for axially floating Storage of the friction lining carrier by the friction lining carrier too bores corresponding to the bolts of the bolt arrangement having.

In a further embodiment of the invention, the storage unit formed by linear guide means on one Friction lining carrier are arranged. Preferably the two are Friction lining carrier by several as linear guide means end, evenly ver over the circumference of the friction lining carrier divides arranged friction lining carrier bolts together the. There is a friction lining carrier with the friction lining carrier bolt firmly connected, for example via a snug fit. The other friction lining carrier, preferably that of the armature disk neighboring, however, is ver on the friction lining carrier bolt slidably guided, for example by means of a floating  Storage. The two friction lining carriers are therefore over the friction Cover carrier bolt telescopically displaceable against each other stored. This storage preferably takes place outside of Coil housing coaxial with this. This makes the friction lining carrier and the friction lining carrier bolts easily accessible and can be easily maintained, for example the Brake lining of the friction lining carrier checked and given in case they are replaced quickly. To initiate the rotation movement of the brake hub are preferably used as drive bolts trained driver who with the brake hub, for example se via a flange. Preferably, the the friction lining carrier, the one with the friction lining carrier bolts is firmly connected, slidably mounted on the drive pin.

In a further embodiment of the invention, the friction disc on a guide device that is fixed to the armature disk connected, positioned axially movable. The leadership direction can be a friction disc bolt on which the friction disc is floating. The friction disc can or be in several parts. It preferably has the same division like the armature plate on. The armature disk in turn slides preferably on an anchor guide bolt that connects to the spu steering housing is firmly connected.

Further advantages and features of the invention result from the claims and from the following description two he preferred embodiments of the invention based on of the drawings are shown.

Fig. 1 shows a sectional view of a first exporting approximate shape of a brake according to the invention with two Reibbelagträgern and a ten between this friction plate is arrange,

Fig. 2 shows a section of the brake according to Fig. 1 for Erläute a first hazardous incident the first execution tion form with a clamping teeth,

Fig 3 be. The section of FIG. 2 in a further incident to the first embodiment with a clamping Reibschei,

Fig. 4 shows the segment of FIGS. 2 and 3, in a third incident of the first embodiment klemmendem, adjacent to the armature disc friction lining

Fig. 5 shows a sectional view of a second exporting approximate shape of a brake according to the invention with two Reibbelagträgern and a ten therebetween is arrange friction disc,

Fig. 6 is a sectional view of the brake according to Fig. 5 for explaining a first hazardous incident from the second guide die with a clamping armature guide between a half and the armature guide bolts,

Fig. 7 shows the segment of FIG. 5 lower half, in a further incident, the second embodiment, in case of failure of the friction disc

Fig. 8 shows the section of FIG. 5 upper half in a third accident of the second embodiment in case of the first friction lining and

Fig. 9 shows the section of FIG. 5 upper half in a fourth malfunction of the second embodiment in case of the second friction lining carrier.

In FIGS. 1 to 4 show a first embodiment of the electromagnetic brake OF INVENTION to the invention is shown. It has a stationary coil housing 2 , by an elec tromagnetic coil arrangement 3 is housed. The brake se 1 has a brake hub 5 which is rotatable about an axis of rotation D and can be connected to a drive shaft of a drive unit to be braked, in particular an electric motor. The coil arrangement 3 acts on an armature disk 4 , which is mounted in a linearly movable manner coaxially to the axis of rotation D with the aid of unspecified screw bolt arrangements. In the release direction, the armature plate 4 is struck by the electromagnetic table coil arrangement 3 with appropriate energization. In the braking direction it is acted upon by a Druckfederan arrangement 12 . When the electromagnetic coil arrangement 3 is energized, this overcomes the restoring force of the compression spring arrangement 12 and holds the armature disk 4 against these compression spring forces in the released position.

Two friction lining carriers 6 , 8 , which are rotatably carried along by the brake hub 5 , are each provided with a friction lining on their opposite end faces. The two friction lining carriers 6 , 8 are arranged on a common toothing carrier 10 , which is hen with an internal toothing 14 verses. The internal toothing 14 corresponds to an external toothing 13 of the brake hub 5 , so that the toothing carrier 10 is rotatably carried by the brake hub 5 in the direction of rotation. In contrast, an axial displacement of the toothing carrier 10 on the brake hub 5 is ensured in the axial direction to the axis of rotation D. The toothings 13 , 14 are aligned and designed accordingly, on the one hand to ensure the rotationally entrained entrainment and on the other hand to enable axial displacement relative to one another.

Both friction lining carriers 6 , 8 are held on the toothing carrier in a rotationally locking manner on the toothing carrier 10 by means of a plurality of bolts 11 which are aligned axially parallel to the axis of rotation D and which together form a bolt arrangement. The friction lining carrier 6 adjacent to the armature disk 4 is mounted in an axially floating manner on the bolt 11 of the bolt arrangement, so that the friction lining carrier 6 is mounted such that it can move axially relative to the toothing carrier 10 . The second friction lining carrier 8, however, is axially fixed on the toothing carrier 10 by being screwed, glued or fixed in some other way with the toothing carrier 10 in addition to the rotational locking fixation by means of the bolt arrangement 11 .

Between the two friction lining carriers 6 , 8 , a ring-shaped friction disc 7 is positioned, which is axially linearly movable in a linear manner relative to the axis of rotation D by means of corresponding bearing sleeves in the region of the external screw bolt arrangements. The second friction lining carrier 8 is supported on the back, ie on its side opposite the armature disk 7 , by a stationary brake disk 9 which is part of the brake housing.

In the current-charged state, the armature disk 4 is therefore retracted in the direction of the coil housing and thus towards the coil arrangement 3 , as a result of which the friction lining carriers 6 , 8 can be freely rotated together with the brake hub 5 . In the de-energized state, the compression springs 12 press the armature disk 4 against the first friction lining carrier 6 , which is pressed against the friction disk 7 , which in turn is pressed against the second friction lining carrier 8 due to its axial mobility. Braking of the brake hub 5 is achieved by the counter support by means of the stationary brake disk 9 . With normal, perfect functioning, four friction surfaces, namely both friction surfaces of both friction linings of both friction lining carriers 6 , 8 are therefore effective.

The fact that both friction lining carriers 6 , 8 are arranged on a common toothing carrier 10 , the axial length of which otherwise corresponds almost to the axial extent of the brake hub 5 , is always ensured, even in the case of individual, possibly occurring jamming cases, that we have at least two friction surfaces in one wear appropriate brake gear and are therefore in function. The axial length of the internal toothing 14 corresponds to the rest of the axial length of the toothing carrier 10 . The axial extent of the external toothing 13 corresponds to the axial extent of the brake hub 5 , so that the axial length ratio between the internal toothing 14 and the external toothing 13 corresponds to the length ratio between the toothing carrier 10 and the brake hub 5 .

In Figs. 2 to 4 are different for the first exporting approximate shape of the electromagnetic brake possible Verklem mung cases shown, which are explained below:

In FIG. 2, the fault is shown that the toothing between the toothed member 10 and the brake hub 5, ie external toothing 13 and internal toothing 14, is stuck and no axial movement of the gear carrier 10 is possible relative to the brake hub 5. Because be to the armature disc 4 neighboring friction lining 6, however, to the serrations of carrier 10 is axially slidable on the bolt assembly 11, can in a corresponding pressure load on the on kerscheibe the friction lining 6 are pressed against the friction disk 7 4, the axial, due to its movability relative the friction lining of the second friction lining carrier 8 is pressed. A total of three friction surfaces are therefore effective.

In the second case according to FIG. 3, in which the friction disk 7 is clamped and is consequently not axially movable, two friction surfaces are effective when the armature disk 4 is pressurized accordingly, namely both friction surfaces of the friction lining carrier adjacent to the armature disk 4 .

In the latter case, in which the friction lining carrier 6 adjacent to the armature disk 4 is clamped on the toothing carrier 10 and is consequently not axially movable relative to the toothing carrier 10 , a total of two friction surfaces are effective with a corresponding pressurization of the armature disk 4 , since the armature disk 4 on the one hand counteracts presses the adjacent friction surface of the first friction lining carrier 6 . Since the friction lining 6 on the other hand acts due to its clamping like a star ren arrangement of the toothed supports 10, a corresponding pressure force is transmitted to the second friction lining 8 on the toothing carrier 10, so that this thing in common with the axial movement of the entire Verzahnungsträ gers 10 against the rear brake disc 9 is pressed. The friction surface of the friction bearing support 8 facing the brake disc 9 also contributes such that a total of two friction surfaces are effective.

In Figs. 5 to 9 a second embodiment of he inventive electromagnetic brake 1 a is illustrated. It has a stationary coil housing 2 a, which is connected to a stationary coil axis 15 by means of a screw connection 16 . The coil axis 15 is connected via a bearing 17 to the brake hub 5 a. The brake hub 5 a of the brake 1 a is rotatable about an axis of rotation D and can be connected to a drive shaft of a drive unit to be braked, in particular an electric motor. In the coil housing 2 a, an electromagnetic coil arrangement 3 a is housed. The Spu lenanordnung 3 a has two coaxial to the axis of rotation D angeord designated coils with separate circuits. Each coil thus has its own power connection 18 . The coil arrangement 3 a acts on an armature disk, which consists of two armature halves 4 a, 4 b. The armature halves 4 a, 4 b are each approximately 19 , by linear guidance guide bolts 19 coaxially to the axis of rotation D gela gelert. In the release direction, the armature halves 9 a, 4 b are acted upon by the electromagnetic coil arrangement 3 a with appropriate current supply. In the braking direction, they are acted upon by a compression spring arrangement 12 a. When energizing the electromagnetic coil assembly 3 a, this overcomes the restoring force of the compression spring assembly 12 and holds the armature halves 4 a, 4 b against these compression spring forces in the released position.

At the outer end of a flange-like projection of the brake hub 5 a, a plurality of drive bolts 20 are arranged, one of which is shown as an example. It serves to initiate the rotational movement on the two friction lining carriers 6 a, 8 a. The two friction lining carrier 6 a, 8 a are thus rotatably entrained by the driving bolt 20 , the first friction lining carrier 6 a being mounted on the driving bolt 20 in a linearly movable manner. The disc-shaped friction lining carrier 6 a, 8 a have holes distributed over their circumference, which are suitable for receiving linear guide means 21 in the form of friction lining carriers. The holes are formed in a against the rest of the friction lining carrier 6 a, 8 a wider Randbe rich. The sliding on the drive pin 20 first friction lining carrier 6 a gerbolzen is firmly connected to the Reibbelagträ, while the second friction lining carrier 8 a is linearly guided on the Reibbelagträgerbolzen. The Reibbelagträgerbolzen have in the middle of an enlarged diameter section 22 , which serves to center the first Reibbelagträgers 6 a and as a stop for the two th, axially movable Reibbelagträger 8 a. Between the two friction lining carriers 6 a, 8 a, an annular friction disc 7 a is positioned, which is mounted axially linearly movable relative to the axis of rotation D by means of a guide device 23 . The guide device are friction disc bolts, which are firmly connected to the respective anchor halves 4 a, 4 b. The first friction lining carrier 6 a is supported on the back, ie on its side opposite the friction disc 7 a, by a stationary brake disc 9 a. The brake disc 9 a is screwed onto the brake housing and is secured against rotation by means of fixing screws.

The electromagnetic brake 1 a also has a wear indicator 24 , which consists of a contactor on the anchor halves 4 a, 4 b and a switch on the coil housing 2 a. If the two anchor halves 4 a, 4 b reach the friction surface of the second friction lining carrier in the currentless, that is to say pressure spring-loaded, state in order to trigger braking, this is given via the contactor to the switch and wear is indicated.

In normal, i.e. trouble-free operation, the compression springs 12 a press the two armature halves 4 a, 4 b against the second friction lining carrier 8 a, which is pressed against the friction disk 7 a, which in turn is pressed against the second due to its axial mobility in the current-free state Friction lining carrier 8 a is pressed. By the counter support by means of the stationary brake disc 9 a braking of the brake hub 5 a is achieved. With normal, flawless function, four friction surfaces are effective, namely both friction surfaces of both friction lining carriers in the friction lining carrier 6 a, 8 a. 100% of the nominal torque of the brake 1 a is reached.

In Figs. 6 to 9 are various possible cases deadlock shown the second embodiment, which are explained nachfol quietly.

In Fig. 6 the accident is shown that the anchor guide bolt 19 an anchor surface 4 b is jammed and no axial movement of this anchor half 4 b relative to the brake hub 5 a is possible. An air gap 26 is formed between the second armature half 4 b and the second friction lining carrier 8 a, so that no braking torque acts here. Despite the jamming 25 , braking of the brake hub 5 a is possible, since the other half of ker 4 a is freely movable and is pressed by the Druckfederan arrangement 12 onto the second friction lining carrier 8 a. The spring assembly of the other anchor half 4 a acts on all four friction surfaces. The brake 1 a thus reaches 50% of its nominal torque.

The second jamming case of this embodiment of the brake 1 according to FIG. 7 shows the failure of the friction disk 7 a. In this example, the failure is caused by blocking 27 of the guide between the second friction lining carrier 8 a and the Reibbe lagträgerbolzen. There are air gaps 28 , 29 between the friction lining carriers 6 a, 8 a and the friction disk 7 a, so that no braking torque acts here. Nevertheless, the brake hub 5 a is braked because the armature halves 4 a, 4 b press against the second friction lining carrier 8 a. About the friction lining bolt, the first friction lining 6 a is pressed against the brake flanges 9 a. There are two friction surfaces in use. The brake thus reaches 50% of the nominal torque.

Another case of jamming can be seen in FIG. 8. There the first friction lining carrier 6 a has failed. In this case, the failure is caused by clamping 30 of the guide between the first friction lining carrier 6 a and the drive bolt 20 . So there is an air gap 31 between the friction lining carrier 6 a and the brake flanges 9 a, there is no braking torque. However, the other three friction surfaces of the brake 1 a are in use. The brake thus reaches 75% of the nominal torque.

In the latter case, which can be seen in Fig. 9, the second friction lining carrier 8 a has failed. In this example, the failure is caused by clamping 32 of the guide between the friction disc 7 a and the friction disc bolt, ie an axial movement of the friction disc 7 a is no longer possible and between the armature halves 4 a, 4 b and the second friction lining carrier 8 a , and between the second friction lining carrier 8 a and the friction disc 7 a there are air gaps 33 , 34 , so that no braking torque acts here. Nevertheless, braking of the brake hub 5 a takes place, since the compression spring arrangement 12 presses the friction disk bolts against the friction disk 7 a via the armature halves 4 a, 4 b. The friction disc 7 a is in turn pressed against the first friction lining carrier 6 a and this against the brake flange 9 a. So there are two friction surfaces in use. The brake thus reaches 50% of the nominal torque.

Claims (8)

1. Electromagnetic brake with a coil arrangement, with an armature disk and with two friction lining carriers and with an axially movable friction disk arranged between the friction lining carriers, the friction lining carriers being axially movably supported, characterized in that the friction lining carriers ( 6 , 8 ; 6 a , 8 a) are rotationally connected to one another by a storage unit, a Reibbelagträ ger ( 6 , 8 a) is axially resiliently po sitioned relative to the storage unit and a Reibbelagträger ( 8 , 6 a) is firmly connected to the storage unit. 2. Brake according to claim 1, characterized in that the bearing unit is formed by a toothing carrier ( 10 ) ge, the axial length of which extends at least over the axial thickness of both friction lining carriers ( 6 , 8 ) and the friction disc ( 7 ). 3. Brake according to claim 2, characterized in that the toothing carrier ( 10 ) has an internal toothing ( 14 ) which is axially movable relative to an external toothing ( 13 ) of a brake hub ( 5 ) to be braked. 4. Brake according to claim 3, characterized in that the axially flexible friction lining carrier ( 6 ) is axially floating on the toothing carrier ( 1 a). 5. Brake according to claim 3, characterized in that the axially flexible friction lining carrier by means of a flexible Membrane arrangement is held on the gear rack. 6. Brake according to claim 1, characterized in that the bearing unit is formed by linear guide means ( 21 ) which are arranged on the one friction lining carrier ( 6 a). 7. Brake according to claim 6, characterized in that a friction lining carrier is rotatably and axially movably mounted on at least one drive pin ( 20 ), which serves to initiate the rotary movement of the brake hub ( 5 a). 8. Brake according to claim 6 or 7, characterized in that the friction disc ( 7 a) on a guide device ( 23 ) which is fixedly connected to the armature disc ( 4 a, 4 b) is positioned so as to be axially movable.