JP7034350B1 - Electromagnetic magnets, electromagnetic brakes, and elevator hoisting machines - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an electromagnetic magnet capable of suppressing a decrease in suction ability. SOLUTION: An opening 11d is provided in a part of an outer pole portion 11b. The opening 11d exposes the first outlet portion 14a and the second outlet portion 14b to the outside of the outer pole portion 11b. A first guide groove 12d and a second guide groove 12e are provided in a portion of the second flange portion 12c facing the opening 11d. A first outlet portion 14a is inserted and along the first guide groove 12d. A second outlet portion 14b is inserted and along the second guide groove 12e. [Selection diagram] Fig. 3

Description

The present disclosure relates to electromagnetic magnets, electromagnetic brakes, and elevator hoisting machines.

In the electromagnetic magnet of the conventional brake device, the fixed core has an inner pole core and an outer pole core. The outer pole core is provided around the inner pole core. A bobbin is provided on the inner pole iron core. The bobbin is provided with a brake coil.

The brake coil is composed of coil conductors. Both ends of the coil lead wire are drawn out from the brake coil as a pair of outlets. The outer pole core is provided with a notch for pulling out a pair of mouthpieces to the outside of the outer pole core (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-190531

In the conventional electromagnetic magnet as described above, the positions of the pair of outlets vary depending on the brake coil. Further, if at least one of the pair of outlets comes into contact with the outer pole core, dielectric breakdown may occur between the coil lead wire and the outer pole core. Therefore, it is necessary to increase the notch, and the area of the outer pole iron core is reduced, so that the suction capacity of the electromagnetic magnet is reduced.

The present disclosure has been made to solve the above-mentioned problems, and an object of the present invention is to obtain an electromagnetic magnet, an electromagnetic brake, and an elevator hoist capable of suppressing a decrease in suction capacity.

The electromagnetic magnet according to the present disclosure includes a bobbin having a tubular portion and a flange portion, an electromagnetic coil composed of an electric wire wound around the tubular portion, and an internal electrode inserted in the tubular portion. It has an iron core having a portion and an outer pole portion surrounding the bobbin, and the electric wire has a mouth-out portion drawn from an electromagnetic coil. An opening is provided to be exposed to the outside of the portion, and a guide groove along the mouth portion is provided in the portion of the flange portion facing the opening.

According to the present disclosure, it is possible to suppress a decrease in the suction ability of the electromagnetic magnet.

It is a front view which shows the elevator hoist according to Embodiment 1. FIG. It is a side view which shows the elevator hoist of FIG. It is a top view which shows the electromagnetic magnet of FIG. It is a front view which shows the electromagnetic magnet of FIG. It is a front view which shows the main part of FIG. 4 enlarged. It is a top view which shows the main part of the electromagnetic magnet by Embodiment 2. FIG.

Hereinafter, embodiments will be described with reference to the drawings.
Embodiment 1.
FIG. 1 is a front view showing an elevator hoist according to the first embodiment. FIG. 2 is a side view showing the elevator hoist of FIG. 1. In the figure, the elevator hoist has a housing 1, a spindle 2, a drive sheave 3, a hoist motor 4, a brake drum 5, and a pair of electromagnetic brakes 6.

The spindle 2 is horizontally fixed to the housing 1. The drive sheave 3 is supported by the spindle 2. Further, the drive sheave 3 rotates about the main shaft 2.

A suspension body (not shown) is wound around the drive sheave 3. As the suspension body, a plurality of ropes or a plurality of belts are used. A basket (not shown) and a counterweight (not shown) are suspended from the suspension body. The car and the balance weight move up and down in the hoistway by rotating the drive sheave 3.

The hoisting machine motor 4 is supported by the housing 1. Further, the hoisting machine motor 4 rotates the drive sheave 3. The brake drum 5 is fixed to the drive sheave 3. Further, the brake drum 5 rotates integrally with the drive sheave 3 about the main shaft 2.

The pair of electromagnetic brakes 6 are attached to the housing 1. Further, the pair of electromagnetic brakes 6 are arranged on the radial side of the brake drum 5. Further, the pair of electromagnetic brakes 6 keeps the drive sheave 3 and the brake drum 5 stationary. Further, the pair of electromagnetic brakes 6 brakes the rotation of the drive sheave 3 and the brake drum 5.

Each electromagnetic brake 6 has an electromagnetic magnet 7, an armature 8, a brake shoe 9, and a brake spring (not shown).

The brake shoe 9 is supported by the armature 8. The armature 8 and the brake shoe 9 are movable with respect to the electromagnetic magnet 7 in a direction in which they come into contact with or separate from the braking surface 5a. The braking surface 5a is an outer peripheral surface of the brake drum 5.

The braking spring generates a force that presses the brake shoe 9 against the braking surface 5a. When the braking force of each electromagnetic brake 6 is applied, the brake shoe 9 is pressed against the braking surface 5a by the braking spring. When the braking force of each electromagnetic brake 6 is released, the electromagnetic magnet 7 attracts the armature 8 against the braking spring. As a result, the brake shoe 9 is separated from the braking surface 5a.

FIG. 3 is a plan view showing the electromagnetic magnet 7 of FIG. FIG. 4 is a front view showing the electromagnetic magnet 7 of FIG. The suction surface for sucking the armature 8 is the upper surface in FIG.

The electromagnetic magnet 7 has an iron core 11, a bobbin 12, an electromagnetic coil 13, and an insulating tape 15.

The iron core 11 is made of, for example, iron. Further, the iron core 11 has an inner pole portion 11a, an outer pole portion 11b, and a flat plate-shaped bottom portion 11e.

The inner pole portion 11a protrudes from the center of the bottom portion 11e at a right angle to the bottom portion 11e. The outer pole portion 11b protrudes from the edge portion of the bottom portion 11e in the same direction as the inner pole portion 11a. Further, the outer pole portion 11b surrounds the inner pole portion 11a at a distance from the inner pole portion 11a. As a result, an annular bobbin insertion groove 11c is provided between the inner pole portion 11a and the outer pole portion 11b.

The bobbin 12 is arranged in the bobbin insertion groove 11c. Further, the bobbin 12 is fixed to the iron core 11 by an adhesive or a plurality of screws. The bobbin 12 is made of, for example, a resin.

Further, the bobbin 12 has a cylindrical portion 12a, a first flange portion 12b, and a second flange portion 12c. The first flange portion 12b is provided at the first end portion of the tubular portion 12a. The second flange portion 12c is provided at the second end portion of the tubular portion 12a.

An internal pole portion 11a is inserted into the tubular portion 12a. A gap is provided between the inner pole portion 11a and the tubular portion 12a.

The end surface of the first flange portion 12b opposite to the second flange portion 12c, the end surface of the inner pole portion 11a opposite to the bottom portion 11e, and the end surface of the outer pole portion 11b opposite to the bottom portion 11e are flush with each other. Located inside.

The end surface of the second flange portion 12c on the opposite side of the first flange portion 12b is in contact with the bottom portion 11e. A gap is provided between the first flange portion 12b and the second flange portion 12c and the outer pole portion 11b.

The electromagnetic coil 13 is composed of an electric wire 14 wound around a tubular portion 12a. The insulating tape 15 is wound around the outer circumference of the electromagnetic coil 13. As the insulating tape 15, for example, a glass tape is used.

The electric wire 14 has a first outlet portion 14a and a second outlet portion 14b. The first outlet portion 14a and the second outlet portion 14b are drawn out from the electromagnetic coil 13.

The first outlet portion 14a is connected to the winding start portion of the electromagnetic coil 13. The second outlet portion 14b is connected to the winding end portion of the electromagnetic coil 13.

An opening 11d is provided in a part of the outer pole portion 11b. The opening 11d exposes the first outlet portion 14a and the second outlet portion 14b to the outside of the outer pole portion 11b.

A first guide groove 12d and a second guide groove 12e are provided in a portion of the second flange portion 12c facing the opening 11d. The first guide groove 12d and the second guide groove 12e are provided on the surface of the second flange portion 12c facing the first flange portion 12b.

A first outlet portion 14a is inserted and along the first guide groove 12d. A second outlet portion 14b is inserted and along the second guide groove 12e.

As shown in FIG. 3, when the electromagnetic magnet 7 is viewed from a direction perpendicular to the suction surface, a part of the first guide groove 12d overlaps with the electromagnetic coil 13.

FIG. 5 is an enlarged front view showing a main part of FIG. 4. The first guide groove 12d has a deep groove portion 21 and an inclined portion 22. The inclined portion 22 is located between the electromagnetic coil 13 and the deep groove portion 21.

The depth of the inclined portion 22 is continuously deepened from the electromagnetic coil 13 toward the deep groove portion 21. The depth of the deep groove portion 21 is constant over the entire length. The second guide groove 12e also has a deep groove portion 21 and an inclined portion 22 like the first guide groove 12d.

In such an electromagnetic magnet 7, a first guide groove 12d and a second guide groove 12e are provided in a portion of the second flange portion 12c facing the opening 11d. Therefore, the positioning of the first outlet portion 14a and the second outlet portion 14b can be easily performed, and the variation in the positions of the first outlet portion 14a and the second outlet portion 14b is suppressed.

As a result, the width of the opening 11d can be reduced, the area reduction of the outer pole portion 11b can be suppressed, and the decrease in the suction capacity of the electromagnetic magnet 7 can be suppressed while preventing dielectric breakdown. Further, the size of the electromagnetic brake 6 and the size of the elevator hoist can be reduced.

Further, it is possible to suppress the movement of the first outlet portion 14a and the second outlet portion 14b with respect to the vibration of the elevator hoisting machine, and it is possible to suppress damage to the electric wire 14.

Further, when the insulating tape 15 is wound around the outer periphery of the electromagnetic coil 13, the insulating tape 15 is prevented from being turned over by the first outlet portion 14a and the second outlet portion 14b to expose the outer periphery of the electromagnetic coil 13. As a result, deterioration of the insulation performance of the electromagnetic magnet 7 can be suppressed.

Further, the first guide groove 12d and the second guide groove 12e are each provided with an inclined portion 22. Therefore, the first outlet portion 14a can be gently aligned with the first guide groove 12d, and the second outlet portion 14b can be gently aligned with the second guide groove 12e. Damage to the second outlet portion 14b can be suppressed.

Embodiment 2.
Next, FIG. 6 is a plan view showing a main part of the electromagnetic magnet 7 according to the second embodiment. The first guide groove 12d has a groove main portion 23 and an outlet portion 24. The outlet portion 24 is located at the end of the first guide groove 12d on the opening 11d side. The groove main portion 23 is located between the outlet portion 24 and the electromagnetic coil 13.

The width of the outlet portion 24 is larger than the width of the groove main portion 23. That is, the width of the groove main portion 23 is smaller than the width of the outlet portion 24. Although not shown in FIG. 6, the inclined portion 22 is provided in the groove main portion 23. Further, the outlet portion 24 is provided in the deep groove portion 21. The second guide groove 12e also has a groove main portion 23 and an outlet portion 24, similarly to the first guide groove 12d.

The electromagnetic magnet 7 of the second embodiment has a pair of insulating protective tubes 25 in addition to the same configuration as that of the first embodiment. A first outlet portion 14a is passed through one of the pair of insulating protective tubes 25. A second outlet portion 14b is passed through the other of the pair of insulating protective tubes 25.

The end portion of each insulation protection tube 25 on the electromagnetic coil 13 side is inserted into the outlet portion 24. The width of the groove main portion 23 is smaller than the outer diameter of each insulating protective tube 25. The width of the outlet portion 24 is larger than the outer diameter of each insulating protective tube 25.

Except for the configuration shown in FIG. 6, the configuration of the electromagnetic magnet 7, the electromagnetic brake 6, and the elevator hoist is the same as that of the first embodiment.

In such an electromagnetic magnet 7, the width of the groove main portion 23 is smaller than the width of the outlet portion 24. Therefore, when each insulation protection tube 25 is pushed into the outlet portion 24, the tip of each insulation protection tube 25 is caught at the boundary portion between the outlet portion 24 and the groove main portion 23, and the positioning of each insulation protection tube 25 is easily performed. It can be carried out. As a result, it is possible to prevent the insulating protective tube 25 from entering and exiting too much, and it is possible to improve the productivity and the insulating performance of the electromagnetic magnet 7.

The planar shapes of the iron core 11 and the electromagnetic coil 13 are not limited to rectangles, and may be circular or oval, for example.

Further, either one of the first guide groove 12d and the second guide groove 12e may be omitted.

Further, the inner pole portion 11a and the outer pole portion 11b may be formed of different members.

Further, the electromagnetic brake 6 may be arranged inside the brake drum 5.

Further, the electromagnetic brake 6 may be of a type that brakes the rotation of the brake disc.

Further, the electromagnetic brake 6 may be provided in a device other than the elevator hoisting machine.

Further, the electromagnetic magnet 7 may be provided in a device other than the electromagnetic brake 6.

6 Electromagnetic brake, 7 Electromagnetic magnet, 11 Iron core, 11a Inner pole, 11b Outer pole, 11d Opening, 12 Bobbin, 12a Cylindrical part, 12c 2nd flange part, 12d 1st guide groove, 12e 2nd guide groove, 13 Electromagnetic coil, 14 electric wire, 14a 1st outlet, 14b 2nd outlet, 21 deep groove, 22 inclined part, 23 groove main part, 24 outlet part, 25 insulation protection tube.

Claims (3)

A bobbin having a tubular part and a flange part,
An electromagnetic coil composed of an electric wire wound around the cylindrical portion, and an iron core having an inner pole portion inserted into the tubular portion and an outer pole portion surrounding the bobbin. Prepare,
The electric wire has a mouth-out portion drawn from the electromagnetic coil.
The outer pole portion is provided with an opening for exposing the outlet portion to the outside of the outer pole portion.
A guide groove along the outlet portion is provided in the portion of the flange portion facing the opening.
Further provided with an insulating protective tube through which the opening portion is passed,
The guide groove has a groove main portion and an outlet portion.
The outlet portion is located at the end portion of the guide groove on the opening side.
The groove main portion is located between the outlet portion and the electromagnetic coil.
The width of the groove main portion is smaller than the width of the outlet portion.
The end portion of the insulation protection tube on the electromagnetic coil side is an electromagnetic magnet inserted into the outlet portion. The guide groove has a deep groove portion and an inclined portion.
The inclined portion is located between the electromagnetic coil and the deep groove portion.
The electromagnetic magnet according to claim 1, wherein the depth of the inclined portion is continuously deepened from the electromagnetic coil toward the deep groove portion. Drive sheave,
A hoist motor that rotates the drive sheave,
It is equipped with a brake drum that rotates integrally with the drive sheave, and an electromagnetic brake that holds the drive sheave and the brake drum in a stationary state.
The electromagnetic brake is an elevator hoist equipped with the electromagnetic magnet according to claim 1 or 2 .

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