DE10103736C2 - Electromagnetically ventilated spring-applied brake with a brake rotor that can be pressed against an abutment flange - Google Patents

Description

The invention relates to a spring brake according to the preamble of claim 1.

In known spring-applied brakes of this type, the Widerla gerflansch using sleeve screws in the area of the outer pole attached to the magnet housing, as is known from the patent DE 196 05 234 A1 evident. About these sleeve screws at the same time the torque support of the armature plate performed. As a rule, they also have such spring force brake a brake rotor, its neck to accommodate the with of the hub to be braked in the direction to the magnet housing through the central opening of the armature protrudes through the disc.

Furthermore, designs of spring-applied brakes are known where at the outer pole of the magnet housing a radial Direction on the outside coaxially via the armature disk and the Brake rotor protruding collar is arranged on  to which the abutment flange is screwed, as the Of Application GB 2 302 574 A shows. Here are the Screw connections on the outside of the collar at the outer pole of the magnet housing arranged what the brake diameter enlarged without any benefits for performance to be able to pull the brake.

Overall, the known types of spring force brake the dimension in relation to the respective size tion of the pole cross sections of the magnet housing limits what especially applies to the inner pole. This will make the magnetic flux and accordingly the magnetic force, which acts on the armature disk for ventilation, limits what again has the consequence that the mechanical force of the Brake springs, i.e. the compression springs, cannot enlarge.

Spring-applied brakes can therefore be used for many applications described type are not used because their so-called named power density is too low. It is understood as the braking torque in relation to the volume of the brake, whereby in any case the overcoming or abolition of the Braking torque safe through electromagnetic ventilation must be posed.

Spring-applied brakes are special as emergency stop brakes suitable because they occur in the event of a power failure. Because in the event of de-excitation, the magnetic force is lost by the loss of magnetic force The armature disk is released, and the braking force effective in the preloaded mechanical compression springs is saved.

A special area of application for emergency stop brakes are Ser  vomotore, which are speed controllable or regulable. Such Motors are used in robots, machine tools, and racking systems devices etc. used as prime movers. Here poses the installation of an emergency stop brake provides special safety feature. B. a robot power failure one, is about the brake in the servo motor that drives the robot arm drives, the robot arm held. So far you have for such emergency stop brakes used permanent magnet brakes, which have a higher power density than the spring-applied brakes of the type mentioned above. The invention of the half of the thought for such applications now also to use spring-applied brakes.

Techniques are used that are based on other material offer are known for other purposes. So describes the Laid-open specification DE 43 38 163 A1 a liquid series Exercise coupling, which has a base body and a cover points, which are connected to each other by a flange connection that are. Furthermore, that from the patent specification DE 2832 723 C2 known electromagnetic brake cone-shaped Fasteners on that by means of a press fit are laid.

The invention has for its object a spring force brake with the features of the preamble of the patent Proverb 1 to create the due to structural modification nen has a higher power density.

This task is the pre with a spring-applied brake named type according to the invention by the characterizing Features of claim 1 solved.  

It is essential for the invention that by the axi al protruding collar on the outer pole of the magnet housing pressed abutment and firmly connected by flanging flange for a given outside diameter inside the brake Friction zones on the brake rotor continue in the radial direction can be relocated to the outside, which is already the case with Chen braking forces because of the extended lever arm to Wel lenachse increases the braking torque. In addition, the Diameter of the armature disk and the brake rotor enlarged with which a more favorable design of the magnetic Circle is possible. A particularly advantageous configuration tion of the invention is the rotor neck of the Bremsro tors on the of the armature plate or the magnet housing remote side of the brake rotor axially projecting NEN. This enables smaller central through holes in the armature disk and in the magnet housing, whereby the pole area on the inner pole of the magnet housing can. All in all stand for the magnetic flux of the magnetic circuit ver  Larger cross-sections are available, which increase the height allow their magnetic forces. This in turn makes it possible Lich to increase the force of the mechanical brake springs.

Further advantageous design features of the invention result from the subclaims.

The invention is based on the drawing to egg NEM embodiment explained in more detail. Show:

Fig. 1 shows a longitudinal section in the axial direction by a spring brake and

Fig. 2 shows a longitudinal section corresponding to FIG. 1 through the spring-applied brake in the installation position and finally a section through the installation area of a servo motor.

In particular, FIG. 1 shows a magnet housing 1, which is substantially annular. The magnet housing 1 receives between an inner pole 3 and an outer pole 4, an excitation winding 2 , which is also ring-shaped. The magnetic circuit closes from the poles 3 , 4 of the magnet housing 1 via an armature disk 5 , which is applied to the pole faces of the inner pole 3 and the outer pole 4 of the magnet housing 1 when the excitation coil 2 is flooded in accordance with the magnetic force exerted on it. In the area of these pole faces, the end face of the magnetic housing 1 which is open here is closed by the armature disk 5 .

In the area of the inner pole 3 of the magnet housing 1 , mechanical compression springs 6 are arranged axially parallel, which constantly act on the armature disk 5 in the axial direction. It is understood that when excited via the excitation coil 2, the magnetic forces are sufficient to attract the armature disk 5 against the force surfaces of the mechanical springs 6 against the pole faces of the two poles 3 and 4 of the magnet housing 1 and to bring them into contact there.

When de-energized, the armature disk 5 falls from the pole faces of the magnet housing 1 and acts on the force of the mechanical compression springs 6 in a brake rotor 7 , which is also disk-shaped in its radially outer region. The brake rotor 7 is pressed by driving the armature disk 5 in the axial direction against an abutment gerflansch 9 , which is fixed and which is firmly connected to the magnet housing 1 . As a result of the frictional forces occurring between the abutment flange 9 on the one hand and the armature disk 5 on the other hand, which are promoted by friction linings 8 on both sides of the brake rotor 7 , the brake rotor 7 is blocked. The brake rotor 7 , which is usually rotatably carried by a shaft, which will be discussed below, strives during braking to take the armature disk 5 with it in the direction of rotation. In order to prevent this from happening, axially parallel pins 19 are fixedly inserted in the outer pole 4 of the magnet housing 1, which project axially parallel over the pole face of the outer pole 4 and engage positively in bores 20 of the armature disk 5 which are adapted thereto.

The rotational driving of the abutment flange 9 by the brake rotor 7 is prevented by a fixed connection between the abutment flange 9 and the magnet housing 1 . For this purpose, the magnet housing 1 along the outer circumference of its outer pole 4 has a coaxially projecting collar 10 , in the inner wall of which the abutment flange 9 is frictionally and / or positively pressed. Between the abutment flange 9 and the collar 10 on the magnet housing 1 there is a so-called oversize fit. An additional backup of the abutment flange 9 is in a circumferential web 11 on the collar 10 of the magnet housing 1 , which is flanged and for a positive connection in the axial direction between the Wi derlagerflansch 9 and the magnet housing 1 .

The brake rotor 7 has a central through opening 12 , which continues in a neck 13 of the brake rotor 7 , which projects coaxially on the side remote from the magnet housing 1 on the brake rotor 7 . The rotor neck 13 receives a hub 14 , which on the one hand is connected in a rotationally fixed manner to the rotor neck 13 or the entire rotor 7 , but on the other hand the rotor neck 13 and the hub 14 are displaceable in the axial direction relative to one another. The axially loose connec tion between the brake rotor 7 and the hub 14 is neces sary to compensate for the axial play of the brake rotor 7 between the brake position and brake release, especially when the armature disk 5 is attracted to the magnetic part 1 . For this purpose, there is an axially parallel toothing 15 between the outer circumferential side of the hub 14 and the wall of the through opening 12 of the brake rotor 7 and the ro tor neck 13 .

The magnet housing 1 and the armature disk 5 have a ring shape and corresponding central or axial bores or through openings 16 and 17 , which have almost the same inner diameter. The inside diameter of these bores 16 and 17 is still slightly smaller than the inside diameter of the through hole 12 of the brake rotor 7 and the rotor neck 13 , which is possible because the neck 13 on the brake rotor 7 on the magnet housing 1 and the armature disk 5th protruding side. Depending on the diameter of the shaft sections of that, correspondingly stepped shaft, which passes through the magnet housing 1 , the armature disk 5 and the hub 14 in the rotor neck 13 , the inner diameter of the armature disk 5 and the magnetic housing 1 can be further reduced, especially to be able to enlarge the inner pole 3 of the magnet housing 1 . On the other hand, the armature disk 5 and in particular the brake rotor 7 have a maximum possible outer diameter, because both parts, seen in the radial direction, come close to the axially projecting collar 10 on the magnet housing 1 .

The magnet housing 1 has on the side away from the brake rotor 7 the side a flat end face or side 21 with threaded holes 22 , which are used primarily for mounting in the housing of a servo motor. The corresponding arrangement of the spring-applied brake of FIG. 1 in the installed position is shown in FIG. 2. The servomotor has a circumferential housing 23 , which is closed on the output side by means of a motor end shield 24 , which is usually referred to as a B end shield. This engine end plate 24 exits the drive end of the motor shaft 25 , which is mounted in the motor bearing plate 24 by means of a roller bearing 26 . The motor shaft 25 is the shaft to be braked.

The magnet housing 1 of the spring applied brake is page 21 to the inside of Motorla gerschildes 24 placed with its face or and is xed through from the outside into the motor bearing plate 24 inserted screws 18 fi, which in the threaded holes 22 on the end face 21 of the magnet housing 1 ( Fig. 1) intervene.

The servo motor is an electric motor and has corresponding windings with winding heads 27 , which because of their arrangement in the radially outward stator plate in the usual execution have a distance from the motor shaft 25 in the radial direction and project in the axial direction over the stator plate and the rotor of the motor. This offers the possibility of installing the spring-applied brake in such a way that the neck 13 of the brake rotor 7 , in which the hub 14 connected to the motor shaft 25 is received, protrudes in the axial direction into the free space 28 , which is seen in the radial direction between the axially projecting winding heads 27 and the motor shaft 25 .

For installation in an electric motor, especially in a Servomotor, offers the closed design of the spring power brake further advantages. This means less braking rubbed into the electric motor, which especially the lifespan of the Winding benefits. Elements of the electri cabling or wiring, both for the Ver supply of the spring-applied brake as well as the electric motor are required, not in contact with moving parts come on the brakes.

Claims (5)

1. Spring-applied brake with an annular, an excitation coil (2) receiving magnet housing (1) forming an inner pole (3) and an outer pole (4) on egg ner open end face at a radial distance from one another, white ter with the magnet housing ( 1 ) coaxial, ring-shaped armature plate ( 5 ), which is energized when the excitation coil ( 2 ) on the poles ( 3 , 4 ) of the magnet housing ( 1 ) and which is acted upon by compression springs ( 6 ), which in at least one of the Poles ( 3 , 4 ) of the magnet housing ( 1 ) are arranged axially parallel, and also with a coaxial brake rotor ( 7 ), which in the event of de-excitation taking with the armature disc ( 5 ) falling off from the magnet housing ( 1 ) against a fixed abutment flange ( 9 ) can be pressed in by friction, this brake rotor ( 7 ) having an axial passage opening ( 12 ) and an extension that extends axially beyond the brake rotor ( 7 ) and has the neck ( 13 ) and in this passage opening ( 12 ) e with a shaft to be braked, through the magnet housing ( 1 ), the armature disk ( 5 ) and the brake rotor ( 7 ) projecting through shaft to be firmly connected hub ( 14 ) is rotatably received relative to that of the brake rotor ( 7 ) including the rotor neck ( 13 ) is axially displaceable, characterized in that the collar ( 10 ) is arranged on the outer pole ( 4 ) of the magnet housing ( 1 ) in the radial direction outwardly and beyond the armature disk ( 5 ) and the brake rotor ( 7 ) projecting coaxially and in this collar ( 10 ) for frictional engagement with the brake rotor ( 7 ) before seen abutment flange ( 9 ) with an oversize firmly pressed and additionally secured by a flanged web ( 11 ) on the collar ( 10 ), the anchor plate be ( 5 ) and the brake rotor ( 7 ) radially towards the outside up to the collar ( 10 ) on the outer pole ( 4 ) of the magnet housing ( 1 ). 2. Spring-applied brake according to claim 1, characterized in that the rotor neck ( 13 ) on the armature disk ( 5 ) or the magnet housing ( 1 ) remote side of the brake rotor ( 7 ) projects axially and the armature disk ( 5 ) and the magnet housing ( 1 ) have coaxial bores ( 17 , 16 ) with an inner diameter which is the same size as or smaller than the inner diameter of the axial through opening ( 12 ) through the brake rotor ( 7 ) and the rotor neck ( 13 ). 3. Spring-applied brake according to one of claims 1 or 2, characterized in that the armature disk ( 5 ) by means of at least one pin ( 19 ) which is inserted into the outer pole ( 4 ) of the magnet housing ( 1 ) and through an opening ( 20 ) in the armature disc ( 5 ) passes through, is supported against rotation by the brake rotor ( 7 ). 4. Spring-applied brake in the installed position in an electric servo motor, whose shaft ( 25 ) is the shaft to be braked, according to one of claims 1-3, characterized in that the outwardly projecting rotor neck ( 13 ) of the brake rotor ( 7 ) in the axial direction is immersed in the exposed winding heads ( 27 ) of the motor winding. 5. Spring-applied brake according to claim 4, characterized in that the magnet housing ( 1 ) with its from the armature plate ( 5 ) and the brake rotor ( 7 ) remote end face ( 21 ) on the output side of the motor shaft ( 25 ) are the motor end shield ( 24th ) is attached.