DE4109740A1 - ELECTROMAGNETIC SPRING BRAKE OR CLUTCH - Google Patents

Abstract

The invention concerns an electromagnetically operated spring-pressure brake or coupling (1) which operates on the closed-circuit current principle. In the no-current state of a coil (8), a closing force is exerted on a disc armature (15). In order to ensure that the spring-pressure brake (1) can still be used as a retention brake even when the disc armature (15) is prevented from moving longitudinally, the armature (15) is made up of at least two discs (21, 22). The closing force acts proportionately on the discs. The design proposed meets safety requirements which require redundancy of parts essential to the operation of the brake (1). The brake (1) proposed is particularly suitable for use in drive systems for lifts.

Description

The invention relates to an electromagnetic Spring pressure brake or clutch with a set of plates, the in the de-energized state of a coil of a magnetic body Springs that exert a closing force on an armature disk, closed is.

For synchronizing or braking rotating Machine parts become frictional clutches and brakes used. In many cases, these are clutches and Brakes for safety reasons as quiescent current actuated electromagnetic spring pressure brakes or clutches educated.

It is known to be a quiescent current, electromagnetic spring pressure brake as a safety brake to be used for lifts and lifts. Most of the time Winch drive here by an adjustable speed Electric motor. Braking is also possible with this electric motor performed. For emergencies, e.g. B. in the event of a power failure, an additional safety brake is required. These Safety brake is automatically applied to the with the Safe braking of the rated load of the elevator car. This brake can also be used to control the cabin to hold on during the stops at the stations.

The relevant safety rules also write before that with such a safety brake Actuation necessary parts must be available twice and are to be carried out in such a way that if one fails Actuator the second actuator - regardless of the first - adequate braking must guarantee.

An object of the present invention  consists of an electromagnetic spring pressure brake create that meet the requirements mentioned above becomes.

The object underlying the invention will solved in that the armature plate from at least two Discs is formed, and that the closing force is proportional the discs works. This solution has the following in particular Advantages: With a conventional spring pressure brake or clutch with a one-piece armature disk would block, e.g. B. by jamming, tilting or gluing the armature disk inevitably lead to brake failure because the Compression springs would no longer be able to hold the armature plate to press against the plate pack and the frictional connection bring about. In the solution according to the invention takes place a distribution of the closing force on the disks, which in together form the armature disk. Will the Armature disk is formed, for example, from two disks it is advantageous to halve the closing force on each Distribute slices. Usually the Spring pressure brake actuated with the entire closing force. For the case that the disc facing the coil in its Leadership or storage in the magnetic body is blocked in currentless state of the coil facing the plate set Disc of the armature disc in the closing direction acts and causes a frictional engagement of the plate set. If the closing force is divided in half, this will occur Braking torque of 50% of the normal braking torque. In this Context should be mentioned that the slat set facing disc of the armature disc opposite the other Washer or the magnetic body is not guided precisely. A Blocking this disc is practically impossible. If this disc were still stuck, it would be from the disc in front of it, as is usually the case, against the Slat set are moved, so that in this - hypothetical - case of braking with full  Closing force would occur. The distribution of the closing force has further the advantage that if individual compression springs fail, e.g. B. due to material defects, nevertheless a safe closing the spring pressure brake or clutch is effected.

It is advantageous to have the disk facing the coil the armature disk as a guide disk with at least one to form a magnetically insulating ring zone. With this Measure can affect the magnetic flux effectively will.

With an electromagnetic spring pressure brake or -Clutch, in which the closing force by compression springs and - bolts are transferred to the armature plate are included an advantageous embodiment of the invention Push pin partially on the disc, that of the coil is adjacent and partially on the disc that the Slat set is adjacent to. The division of the Closing force on the washers of the armature disk is thereby easily possible. To the proportional closing force transferred to the disk assigned to the disk set , it is advantageous to use the one adjacent to the coil Disc with recesses, for example holes Mistake. The part of the Push the bolt through to the plate set adjacent pane acts.

Since the disc facing the disc set is not specially designed is guided, it is advantageous to center provide the relative location of the washers is determined to each other. Here is on big enough Play to ensure that the panes tilt under no circumstances can occur.  

In the axially movable storage of the disks in It is advantageous for the magnetic body to be adjacent to the coil Disc over a sleeve in one turn of the Lead magnetic body. About the one in the turn The sleeve becomes one of the two plates of the armature plate led directly.

To prevent the disk adjacent to the coil from rotating secure, it is advantageous that this disc has an axial groove has, in which a pin of the magnetic body with play intervenes.

Other features essential to the invention and the resulting advantages are the following Description of an embodiment of the invention based on the drawings. Show it:

Fig. 1 is a spring pressure brake in longitudinal section and

Fig. 2 shows the upper part of the spring pressure brake according to Fig. 1 along the section line II-II.

In Fig. 1, a spring pressure brake 1 is shown schematically in longitudinal section. On a shaft 2 , which is to be braked, a carrier 3 for a plurality of inner plates 4 is arranged in a rotationally fixed manner. The non-rotatable connection is established by a washer 5 and a fastening screw 6 .

A coil 8 is accommodated in a magnetic body 7 . At the end facing away from the coil 8 , the magnetic body 7 has a connecting flange 9 . With the help of the connecting flange 9 , the magnetic body 7 can be fixed in a manner not shown, for. B. attached to a machine frame.

Between the connecting flange 9 and the area of the coil 8 , the magnetic body 7 is pot-shaped. A plurality of axially extending longitudinal slots 11 are incorporated in an annular wall 10 . External slats 12 engage in these longitudinal slots 11 . The inner plates 4 and outer plates 12 form a plate set 13 .

The plate set 13 can be supported against a pressure ring 14 . This pressure ring 14 is in the opening of the connecting flange 9 or the annular wall 10 of the magnetic body 7 z. B. screwed.

The inner and outer plates 4 and 12 of the plate set 13 can be designed, for example, as sintered plates, so that the spring-loaded brake 1 can be used for dry and wet running. The pressure ring 14 takes over the function of an adjusting device, so that lamella output can be compensated for if necessary.

An armature disk 15 is located between the coil 8 and the disk set 13 .

The frictional engagement of the disk set 13 is generated by compression springs 16 , which exert a closing force on the armature disk 15 via pressure bolts 17 and 18 , provided the coil 8 is in the de-energized state. The pressure bolts 17 and 18 are partially and the compression springs 16 are housed completely in the longitudinal bores 19 of the magnetic body 7 . The longitudinal bores 19 are closed by grub screws 20 , against which one end of the compression springs 16 rests. The use of grub screws has the advantage that the preload force of the compression springs can be adjusted. The compression springs can also be arranged in blind holes, which leads to a cheaper solution. The armature disk 15 is formed from two disks 21 and 22 in the described embodiment of the invention. The disk 21 of the armature disk 15 facing the coil 8 is designed as a guide disk with a magnetically insulating ring zone 23 .

From the drawing it can be seen that the pressure bolts 17 (only one of a plurality of pressure bolts 17 is shown in FIG. 1) act on the disk 21 , while the pressure bolts 18 (here too FIG. 1 shows only one pressure bolt 18 of several) through recesses 24 , z. B. bores, the disc 21 protrude and act on the disc 22 . The diameters of the recesses 24 and the pressure pin 18 are chosen so that there is a relatively large clearance between these parts, so that tilting or jamming is excluded with certainty. In order to be able to use uniform pressure springs 16 , the axial length of the pressure pin 18 is chosen to be greater by approximately the thickness of the disk 21 than that of the pressure pin 18 .

It is apparent from the above explanation that the closing force which is exerted on the armature disk 15 acts proportionally on the disks 21 and 22 . If, for example, a number of twenty pressure pins 17 , 18 is selected, it is advantageous to have ten pressure pins 17 and 18 act on the disk 21 and the disk 22 , respectively. The result is a halving of the closing force.

The disk 22 is centered relative to the disk 21 in such a way that a screw head 25 of a screw 26 which is screwed into the disk 22 projects into a bore 27 in the disk 21 . There is a relatively large amount of play between the screw head 25 and the bore 27 , so that canting or jamming is excluded with certainty. At least two such screws 26 are provided.

Otherwise, the disc 22 is not guided. The outer diameter of the disk 22 is selected such that here, too, no tilting or jamming of the disk 22 can occur in the interior of the pot-shaped magnetic body 7 .

The disk 21 has an axial groove 28 , in which a pin 29 of the magnetic body 7 engages. The groove 28 and the pin 29 form an anti-rotation device for the disk 21 . In addition, the disk 21 is centered by a sleeve 30 in a recess 31 of the magnetic body 7 and guided axially.

The coil 8 is supplied with current via a cable connection 32 .

In the case of coil 8 through which current flows, the armature disk 15 is tightened while overcoming the closing force of the compression springs 16 . The slat set 13 is open. In the de-energized state ( FIG. 1), the disk set 13 is closed by the spring-loaded armature disk 15 .

In the event that the disk 21 is jammed, canted or glued and consequently cannot exert a closing force on the disk set 13 , the compression springs 16 , which act on the disk 22 via the pressure bolts 18 , nevertheless ensure that the disk set 13 closes. The proportional braking torque is 50% of the nominal braking torque and is so large that it is sufficient for safety braking of shaft 2 in any case.

The operational safety of the spring-applied brake is also ensured in that the disc 22 , since it is not particularly guided inside the magnetic body 7 , cannot jam, tilt or otherwise be prevented from moving axially. Should a handicap nevertheless occur, it should be noted that in this case the disks 21 and 22 behave like a - conventional - one-piece armature disk. The full closing force then also acts on the armature disk.

Reference numerals

1 spring pressure brake
2 wave
3 carriers
4 inner slats
5 disc
6 fastening screw
7 magnetic body
8 spool
9 connecting flange
10 wall
11 longitudinal slots
12 outer slats
13 slat set
14 pressure ring
15 armature disk
16 compression spring
17 pressure bolts
18 push pins
19 longitudinal bore
20 grub screw
21 disc
22 disc
23 ring zone
24 recesses
25 screw head
26 screw
27 hole
28 groove
29 pen
30 sleeve
31 turn
32 Cable connection

Claims (10)

1. Electromagnetic spring pressure brake ( 1 ) or clutch with a disc set ( 13 ), which is closed in the de-energized state of a coil ( 8 ) of a magnetic body ( 7 ) by compression springs ( 16 ) which exert a closing force on an armature disk ( 15 ) , characterized in that the armature disk ( 15 ) is formed from at least two disks ( 21 , 22 ) and that the closing force acts proportionately on the disks ( 21 , 22 ). 2. Electromagnetic spring pressure brake ( 1 ) or coupling according to claim 1, characterized in that the coil ( 8 ) facing disc ( 21 ) of the armature disc ( 15 ) is designed as a guide disc with at least one magnetically insulating ring zone ( 23 ). 3. Electromagnetic spring pressure brake ( 1 ) or clutch, in which the closing force by compression springs ( 16 ) and pressure bolts ( 17 , 18 ) is transmitted to the armature disk ( 15 ), according to claim 1, characterized in that the pressure bolts ( 17 , 18th ) partially in the disc ( 21 ), which is adjacent to the coil ( 18 ) and partially on the disc ( 22 ), which is adjacent to the plate set ( 13 ). 4. Electromagnetic spring pressure brake ( 1 ) or clutch according to claim 3, characterized in that the coil ( 18 ) adjacent disc ( 21 ) has recesses ( 24 ) through which a part of the pressure bolt ( 18 ) protrudes. 5. Electromagnetic spring pressure brake ( 1 ) or clutch according to claims 1 and 3, characterized by means ( 25 , 26 , 27 ) for centering the disks ( 21 , 22 ). 6. Electromagnetic spring pressure brake ( 1 ) or clutch according to claim 5, characterized in that the means are formed from screw heads ( 25 ) which are guided with play in bores ( 27 ) of one of the disks ( 21 , 22 ). 7. Electromagnetic spring pressure brake ( 1 ) or clutch according to claims 1 and 3, characterized in that the disks ( 21 , 22 ) are axially movably mounted in the magnetic body ( 7 ), the disc ( 8 ) adjacent disk ( 21 ) is guided in a recess ( 31 ) of the magnetic body ( 7 ) via a sleeve ( 30 ). 8. Electromagnetic spring pressure brake ( 1 ) or clutch according to claims 1 to 4, characterized in that at least the coil ( 8 ) adjacent disc ( 21 ) is secured against rotation. 9. Electromagnetic spring pressure brake ( 1 ) or clutch according to claim 8, characterized in that the disc ( 21 ) has a groove ( 28 ) into which a pin ( 29 ) of the magnetic body ( 7 ) engages with play. 10. Electromagnetic spring pressure brake ( 1 ) or clutch, characterized in that the disk set ( 13 ) inner and outer disks ( 4 , 12 ) that the inner disks ( 4 ) rotatably on a support ( 3 ) to be braked or coupled Shaft ( 2 ) are mounted and that the outer plates ( 12 ) are supported on the magnetic body ( 7 ).