JP4775551B2 - Motor with brake - Google Patents

Description

The present invention relates to a motor with a brake that drives a joint of a robot and the like.

2. Description of the Related Art Conventionally, a servo motor with a brake is configured as shown in FIG.
The stator core 1 is formed by laminating silicon steel plates, and a plurality of armature windings 2 are arranged at equal intervals in the circumferential direction via an insulating layer (not shown) on the inner periphery thereof to constitute a predetermined magnetomotive force distribution. After being connected in this manner, it is resin-molded and fixed to the stator core. The stator core 1 and the frame 3 are fixed by shrinkage or adhesion.
A permanent magnet 4 is opposed to the inner periphery of the armature winding 2 through a gap. The permanent magnet 4 is a ring-shaped magnet that is magnetized so as to have a predetermined number of poles, and is bonded and fixed to the outer periphery of an annular rotor yoke 15 ′ made of laminated steel plates.
The rotor yoke 15 is fixed concentrically with the shaft 14, and the shaft 14 is rotatably supported with respect to the L bracket 11 and the anti-L bracket 21 by bearings A12 and B13. The L bracket 11 and the anti-L bracket 21 are fixed to the frame 3 with screws to constitute a motor unit.
A brake is provided between the motor unit and the bearing B. The brake includes a brake disk 5, an armchair 6, a brake coil 7, and a brake field 8.
An encoder 18 is attached to the rear side of the anti-L bracket 21, and an encoder cover 20 is fixed to the frame 3 with screws to protect the encoder.
Thus, the motor, the brake, and the encoder are arranged in series with respect to the shaft 14. For low speed and large torque applications such as robots, a reduction gear is attached to the output shaft of the shaft 14 in series.
As another conventional example, as disclosed in Japanese Patent Application Laid-Open No. 2004-328898, the rotor yoke 15 is formed in a cylindrical shape, and a cylindrical solenoid and a disk-like shape are provided in the inner circumferential space of the cylindrical portion. There are some which arrange a brake having a brake disc.
JP 2004-328898 A

In this way, the conventional servo actuator with brake has a series of devices such as a motor, negative-actuated brake, rotation detector, etc., and a bearing, a partition wall, etc. are provided between these devices. Therefore, there is a problem that it is difficult to reduce the size.
Further, since the heat generated by the actuator is radiated to the device through the bracket, there is a problem that the cooling performance is lowered when the axial length is increased.
Further, in the motor configuration described in Japanese Patent Application Laid-Open No. 2004-328898 shown as another embodiment, there is a brake field on the inner periphery of the rotor yoke, so that the leakage magnetic flux of the rotor yoke and the magnetic flux of the brake can interfere with each other. There is also a problem that if the yoke thickness is increased to prevent interference, the inner and outer diameters cannot be reduced.
The present invention has been made in view of such problems, and an object of the present invention is to provide a motor with a brake that achieves miniaturization and in which the leakage magnetic flux of the rotor yoke and the magnetic flux of the brake do not interfere with each other.

In order to solve the above problem, the invention according to claim 1 relates to a motor with a brake, and is a motor with a brake including a stator, a rotor, and an electromagnetic brake,
The stator includes a frame, an inner periphery secured to a cylindrical toward the stator core of the frame, an armature winding disposed so as to constitute a predetermined magnetic pole on the inner periphery of the stator core,
The rotor has a substantially cup-like shape having a shaft rotatably disposed by a bearing on the inner peripheral side of the armature winding, and a substantially cylindrical space on the inner diameter side, and is fixed to the shaft. If, possess a predetermined field permanent magnets disposed with a gap from and the armature winding such that different poles alternately every pitch on the outer circumference of the rotor yoke,
Before SL electromagnetic brake includes a brake disk provided movably the shaft side in the axial direction of the shaft, urged in the direction of contact allows the setting vignetting prior Symbol brake disk moves in the axial direction of said shaft An armature, a brake coil disposed between the armature and the rotor for attracting the armature by excitation and separating from the brake disk, and a groove formed in a groove formed on the armature side in the axial direction. A brake field having a coil fixed thereto, and a bearing housing portion that is provided integrally with the brake field, is arranged concentrically with the rotor yoke via a predetermined gap, and holds the bearing; The shaft, the bearing, and the bearing housing are disposed in the space of It is characterized.
The invention of claim 2, in the motor with brake according to claim 1, grease of the bearing is characterized in that the oil seal to prevent entry to the electromagnetic brake provided in the bearing housing portion.

According to the motor with a brake according to claim 1, the housing portion of the bearing is provided integrally with the brake field, the housing portion is disposed on the inner diameter side of the rotor yoke of the motor via a predetermined gap, and leakage magnetic flux of the rotor yoke is transmitted to the housing. Since it is linked to the portion and also used as a part of the magnetic path of the rotor yoke, it is possible to achieve downsizing and to provide a motor with a brake in which the leakage magnetic flux of the rotor yoke and the magnetic flux of the brake do not interfere with each other.
Further, since the diameter of the bearing can be increased, the shaft can be easily a hollow shaft, and the space of the entire apparatus can be saved by passing a cable or a pipe through the hollow shaft.
According to the brake with motor according to claim 2, wherein, since it is possible to prevent the grease in the bearing from entering into an electromagnetic brake, the safety brake is ensured.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a cross-sectional view of a motor with a brake according to the present invention.
In the figure, 1 is a stator core, 2 is an armature winding, 3 is a frame, 4 is a permanent magnet, 5 is a brake disk, 6 is an armor chair, 7 is a brake coil, 8 is a brake field, 9 is a mold resin, and 10 is a connection. A substrate, 11 is an L bracket, 12 is a bearing A, 13 is a bearing B, 14 is a shaft, 15 is a rotor yoke, 16 is an anti-L bearing housing, 17 is a brake cover, 18 is an encoder, and 20 is an encoder cover.
The stator core 1 is formed by laminating silicon steel plates, and a plurality of armature windings 2 are arranged at equal intervals in the circumferential direction via an insulating layer (not shown) on the inner periphery thereof. After each armature winding is soldered to the connection board 10, the stator core 1, the armature winding 2, and the connection board 10 are integrally fixed by a resin mold 9. After molding, the stator core 1 and the frame 3 are fixed by shrinkage or adhesion.
Since the armature winding 2 generates heat when energized and the heat is transmitted to the frame 3 through the stator core 1, the material of the frame 3 is preferably a high heat transfer material such as aluminum. In this embodiment, the frame 3 is made of aluminum. A permanent magnet 4 is disposed opposite to the inner periphery of the armature winding 2 through a gap.
The permanent magnet 4 is composed of a ring magnet or a plurality of segment magnets, is magnetized so as to have a predetermined number of poles, and is bonded and fixed to the outer periphery of a rotor yoke 15 made of a soft magnetic material. According to the present invention, the rotor yoke 15 is formed in a substantially cup shape that is recessed toward the inner diameter side. That is, the conventional rotor yoke 15 ′ of FIG. 2 has a thick annular shape and is fixed to the entire surface of the shaft 14. However, the rotor yoke 15 according to the present invention is a shaft 14 of the thick annular shape of the conventional rotor yoke 15 ′. A portion fixed to the inner surface is formed into a cup shape with the inner diameter side recessed in the axial direction. The rotor yoke 15 is fixed concentrically with the shaft 14, and the shaft 14 is rotatably supported by a bearing A12 and a bearing B13. The L bracket 11 is formed integrally with the frame 3, and the outer ring of the bearing A 12 is fitted to the L bracket 11. According to the present invention, the brake field 8 and the anti-L bearing housing 16 are integrally formed. The outer ring of the bearing B13 is fitted into the anti-L bearing housing 16, and the outer periphery of the brake field 8 is fixed to the frame 3 by bolts (not shown) to constitute a motor part.
In general, the radial thickness of the rotor yoke 15 is determined by the magnetic flux and the saturation magnetic flux density of the yoke material. A minute gap is formed on the inner circumference of the rotor yoke, which is also made of a soft magnetic material according to the present invention. Since the L bearing housing 16 is arranged and the motor magnetic flux is linked to the anti-L bearing housing 16 and becomes a part of the magnetic circuit of the motor even if the radial thickness of the rotor yoke 15 is reduced, the induced electromotive force is reduced. It does not occur and does not affect the motor characteristics. For this reason, since the rotor yoke can be made thinner than in the prior art, the outer diameter of the motor can be reduced and the hollow diameter can be increased in the case of a hollow shaft.

Next, the brake unit will be described.
The brake field 8 has a cylindrical shape with concentric slots and is made of a soft magnetic material such as iron. The brake coil 7 is wound around a bobbin (not shown) in a cylindrical shape, inserted into a groove of the brake field 8, and then fixed by a resin mold or the like. A coil spring (not shown) is arranged on the outer periphery of the brake field 8 in order to press the brake disc 5 against the armor chair 6 and the side plate 22.
The brake disk 5 is disposed between the armor chair 6 and the side plate 22 and is attached to the shaft 14 via the hub 23.
The side plate is fixed to the brake field 8 via a collar (not shown).
Next, the operation of the brake will be described.
When the brake coil is not energized, the brake brake disc 5 is pressed and restrained against the armor chair 6 and the side plate 22 by the force of the coil spring. Since the brake disc 5 is attached to the shaft 14 via the hub 23, the shaft 14 also does not rotate.
When the coil 7 is energized, the armature 6 is attracted to the brake field 8 by the magnetic attractive force, so that the brake disk 5 is rotatable and the brake is released.
Rotor position information from a magnetic sensor is input to a servo amplifier (not shown), and a current with a predetermined current phase and amplitude is applied to the armature winding from a command from a servo controller (not shown) and rotor position information. The motor rotates.
In a state where the armor chair 6 and the brake field 8 are adsorbed, the current supplied to the brake coil can be reduced, and the power consumption and the heat generation from the brake can be reduced. The heat generated by the brake coil 7 is transmitted to the brake field 8, but since the brake field 8 is fixed to the frame 3, heat can be efficiently radiated through the frame. A brake cover 17 is attached to the opposite side of the brake for protection, and the stator side of the encoder 18 is attached to the opposite side of the brake cover 17.
The rotor side of the encoder is attached to the shaft 14 so as to face the stator side. An encoder cover is provided on the opposite side of the brake cover 17 to protect the encoder. In this example, an oil seal 24 is provided on the non-L side bearing housing to prevent the grease of the bearing B13 from entering the brake.
Needless to say, the present invention can be configured as a motor with a brake and a reduction gear by providing a reduction gear on the output shaft of the motor.

As described above, according to the smooth armature winding type motor of the first aspect, it is possible to reduce the size by arranging the housing portion of the brake on the inner diameter side of the rotor yoke of the motor via the predetermined gap.
According to the motor with a brake according to claim 2, the housing portion of the bearing is provided integrally with the brake field, the housing portion is disposed on the inner diameter side of the rotor yoke of the motor via a predetermined gap, and the leakage flux of the rotor yoke is reduced. Since it is linked to the housing portion and is also used as a part of the magnetic path of the rotor yoke, it is possible to achieve downsizing and to provide a motor with a brake in which the leakage magnetic flux of the rotor yoke and the magnetic flux of the brake do not interfere with each other.
Further, since the diameter of the bearing can be increased, the shaft can be easily a hollow shaft, and the space of the entire apparatus can be saved by passing a cable or a pipe through the hollow shaft.
According to the brake-equipped motor according to the third aspect, since the grease of the bearing can be prevented from entering the electromagnetic brake, a safe brake is ensured.

  By attaching a speed reducer to the output shaft of the motor according to the present invention, a small servo motor with a speed reducer can be constructed, so that a very small robot built in the arm of the robot can be manufactured. In addition, a robot arm with a built-in cable and piping can be easily realized by adopting a hollow shaft configuration.

It is a sectional side view of the motor with a brake which shows the example of the present invention. It is a sectional side view of the conventional motor with a brake.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 .... Stator core 2 .... Armature winding 3 .... Frame 4 .... Permanent magnet 5 .... Brake disc 6 .... Armor chair 7 .... Brake coil 8 .... ... Brake field 9 ... Mold resin 10 ... Connection board 11 ... L bracket 12 ... Bearing A
13 ... Bearing B
14 ... Shaft 15 ... Rotor yoke 16 ... Anti-L side bearing housing 17 ... Brake cover 18 ... Encoder 20 ... Encoder cover 21 ... Anti-L bracket 22... Side plate 23... Hub 24.

Claims (2)

A motor with a brake including a stator, a rotor, and an electromagnetic brake,
The stator includes a frame, an inner periphery secured to a cylindrical toward the stator core of the frame, an armature winding disposed so as to constitute a predetermined magnetic pole on the inner periphery of the stator core,
The rotor has a substantially cup-like shape having a shaft rotatably disposed by a bearing on the inner peripheral side of the armature winding, and a substantially cylindrical space on the inner diameter side, and is fixed to the shaft. If, possess a predetermined field permanent magnets disposed with a gap from and the armature winding such that different poles alternately every pitch on the outer circumference of the rotor yoke,
Before SL electromagnetic brake includes a brake disk provided movably the shaft side in the axial direction of the shaft, urged in the direction of contact allows the setting vignetting prior Symbol brake disk moves in the axial direction of said shaft An armature, a brake coil disposed between the armature and the rotor for attracting the armature by excitation and separating from the brake disk, and a groove formed in a groove formed on the armature side in the axial direction. A brake field having a coil fixed thereto, and a bearing housing portion that is provided integrally with the brake field, is arranged concentrically with the rotor yoke via a predetermined gap, and holds the bearing; The shaft, the bearing, and the bearing housing are disposed in the space of Motor with brake, characterized. 2. The motor with a brake according to claim 1, wherein an oil seal for preventing the grease of the bearing from entering the electromagnetic brake is provided in the bearing housing portion .

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