JPH08135684A - Armature assembly in electromagnetic connection device - Google Patents

Abstract

PURPOSE: To provide an armature assembly of lightweight and small size in which distorsion of an armature support member is prevented. CONSTITUTION: A reinforced plastic plate 12 provided with a damper rubber housing part 13 is integrated with an armature hub 10 formed with a flange 10b by insert-molding. A rivet 14 is fixed to a damper rubber 15 housed in the damper rubber housing part 13, while an armature 16 is fixed to a leading end of the rivet 14. The armature 16 which is attracted to the side of the plate by elastic force of the damper rubber 15 abuts against a side surface 10e which is not coated with the plate 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an armature assembly of a damper rubber type electromagnetic coupling device used in, for example, an electromagnetic clutch for a car air conditioner.

[0002]

2. Description of the Related Art As an armature assembly of this type of electromagnetic coupling device, there is one proposed by the present applicant in Japanese Patent Laid-Open No. 4-262127. In the armature assembly proposed in this publication, not only the armature support member is made of reinforced plastic, but also reinforcing ribs are integrally formed on the armature support member in order to increase rigidity and reliability of mechanical strength. It is a thing. Further, the inner side in the radial direction of the armature support member made of reinforced plastic is integrally fixed by covering the entire outer peripheral surface of the cylindrical metal-made armature hub by insert molding.

[0003]

However, even in an armature support member made of a reinforced plastic material having a reinforcing rib, the elastic force of the damper rubber for movably supporting the armature on the armature support member in the axial direction is strong. Therefore, in the electromagnetic clutch, the air gap between the armature and the rotor becomes narrower due to the strain generated radially outward. If this distortion is large, the armature vibrated by external vibration will come into contact with the rotor in a non-excited state in which the electromagnetic coil is not energized. In order to prevent such distortion, it is necessary to increase the wall thickness of the armature support member to increase the rigidity, but the device becomes large. The present invention has been made in view of the above problems, and an object thereof is to provide a lightweight and small-sized armature assembly in which distortion of the armature support member is prevented.

[0004]

To achieve this object, an armature assembly of an electromagnetic coupling device according to the present invention is, as a first invention, an outer diameter dimension of a flange portion of an armature hub rather than an inner diameter dimension of an armature. And the flange portion is formed with an escape portion for the fastening member, so that the flange portion is configured as an aggregate that enhances the rigidity of the armature support member made of a reinforced plastic material. As a second aspect of the invention, the outer diameter of the flange portion of the armature hub is made larger than the inner diameter of the armature, and the flange portion of the armature hub is provided with a clearance portion for the fastening member and an uncovered portion for the armature support member. By limiting the retreat of the armature pulled toward the armature support member side by the damper rubber with the uncovered part of the flange part, the flange part that is an aggregate to increase the rigidity of the armature support member made of reinforced plastic material, It is characterized by limiting retreat.

Furthermore, as a third aspect of the invention, the outer diameter of the flange portion of the armature hub is made larger than the inner diameter of the armature, and the flange portion of the armature hub is provided with a clearance for the fastening member and a non-contact of the armature support member. By providing a covered part and interposing a stopper rubber between this uncovered part and the armature, it is a flange part that is an aggregate for increasing the rigidity of the armature support member made of a reinforced plastic material, and via the stopper rubber Characterized by limiting the retreat of armatures.

[0006]

In the electromagnetic clutch for a car air conditioner having the armature assembly of the present invention, the magnetic attraction of the magnetic flux of the electromagnetic coil causes the armature to be magnetically attracted to the rotor against the elastic force of the damper rubber. Further, when the electromagnetic coil is de-energized, the magnetic flux disappears, so that the armature is pulled toward the armature support member side by the elastic force of the damper rubber and retracts from the rotor to be separated. By repeating such an operation, the elastic force of the damper rubber causes a tensile force to the rotor side on the outer side in the radial direction of the armature support member, but since the flange portion of the armature hub increases the rigidity, Tilt distortion is prevented.

[0007]

An embodiment of the present invention will be described below with reference to the drawings. 1 is a front view of an electromagnetic clutch provided with an armature assembly of an electromagnetic coupling device according to the present invention, and FIG. 2 is II of FIG.
2 is a sectional view taken along line II, FIG. 3 is a sectional view taken along line III-III in FIG. 2, and FIG. 4 is a front view illustrating the operation after the damper rubber has fallen off.
In these drawings, an electromagnetic clutch generally designated by 1 is attached to a car air-conditioner compressor 2 and is used as a power transmission device for transmitting or interrupting rotation of an automobile engine to the compressor 2. . Reference numeral 3 denotes a rotor rotatably supported by a cylindrical portion 2a of the compressor 2 via a bearing 2b. A poly V groove pulley 4 made of a plastic material is integrally fixed to the outer peripheral surface of the rotor 3. There is. 3a,
Denoted at 3b are slits for bypassing the magnetic flux, which are punched by press working and are provided at intervals on the same circumference. The rotor 3 and the pulley 4 are attached to the rotor 3 as an insert in a mold of an injection molding machine,
It is formed by insert molding by injecting a plastic material into the mold from the gate. This molding method is disclosed in Japanese Patent Laid-Open No. 4-290618. A field core 6 having an electromagnetic coil 5 therein is fitted in the annular groove of the rotor 3, and the field core 6 is fixed to the housing of the compressor 2 with a screw through a mounting plate 7.

An armature assembly 9 according to the present invention is mounted on the rotary shaft 8 of the compressor 2 so as to rotate integrally therewith.
The armature assembly 9 is formed of these members and a reinforced plastic, with an armature hub 10 made of a metal material fitted to the rotary shaft 8 by serration and a contact plate 11 with which the tip of the rotary shaft 8 abuts as an insert. It has a structure in which a disc-shaped plate 12 as an armature support member is integrally fixed by insert molding. The armature hub 10 has a boss portion 10a having an inner peripheral surface formed with a serration groove for fitting with the rotary shaft 8, and the boss portion 10a.
Disk-shaped flange portion 10 extending radially outward from the end face of the plate and serving as an aggregate for increasing the rigidity of the plate 12.
b. The flange portion 10b has a plurality of (six in this embodiment) engagement holes 10c formed at equal positions on the same circumference, and a rivet (described later) formed in a semicircular shape on the outer peripheral edge. A plurality of (three in the present embodiment) escape portions 10d for the fastening member 14 are formed.

On the outer side of the plate 12 in the radial direction, a plurality (three in this embodiment) of recessed damper rubber storage portions 13 are formed at equal positions on the same circumference, and extend in the axial direction. It is formed by being surrounded by a peripheral wall portion 12a having a circular shape, and the disc portion 12b on the inner side in the radial direction is integrally formed with a detent portion 12c that engages with the engaging hole 10c of the armature hub 10. ing. The peripheral wall portion 12a of the damper rubber storage portion 13 is provided with a protrusion 12h having a height higher than that of a rivet 14 described later. Further, a retaining portion 12d, which is formed in a flat shape on the rotor 3 side of the flange portion 10b of the armature hub 10, is integrally formed at the tip of the rotation preventing portion 12c, and the plate 12 includes the disc portion 12b and the retaining portion. The flange portion 10b is sandwiched between the armature hub 10 and 12d, and is integrally fixed to the armature hub 10. Further, the inner peripheral edge of the plate 12 has a cylindrical portion 12e that functions as a retainer for the contact plate 11.
However, cylindrical cover portions 12f are integrally formed on the outer peripheral edge.

Reference numeral 14 designates a rivet as a fastening member whose end on the opening side of the storage portion 13 is chamfered in an arc shape.
Is a damper rubber to which the rivet 14 is fixed at the center, and is press-fitted and fixed to the damper rubber storage portion 13 of the plate 12. The tip of the rivet 14 extends from the through hole 12g formed in the bottom surface of the damper rubber storage portion 13 to the rotor 3
It is projected to the side and is caulked and fixed to the armature 16. A caulking fixing structure of the rivet 14 and the armature 16 is disclosed in Japanese Utility Model Laid-Open No. 4-32327. Reference numeral 16a is a slit for bypassing the magnetic flux, which is provided at intervals on the same circumference.

The inner diameter of the armature 16 is smaller than the outermost diameter of the flange portion 10b of the armature hub 10, and the elastic force of the damper rubber 15 causes the armature 16 to plate out of the flange portion 10b of the armature hub 10. 12 is in contact with the uncoated side surface (uncoated portion) 10e. That is, armature 1
The side surface 10e of the flange portion 10b that abuts against the outer peripheral edge of the armature 16 is formed to be slightly higher than the facing surface on the outer side in the radial direction of the plate 12 that faces the outer peripheral edge of the armature 16.
The uncovered portion 10e of the armature hub 10 and the side surface of the plate 12 on the armature 16 side may be formed in the same plane. Also, armature hub 1
The zero flange portion 10b may be completely embedded in the plate 12. In addition, the plate 12 may be covered to the outside of the boss portion 10a of the armature hub 10.

Next, the operation of the electromagnetic clutch constructed as above will be described. The magnetic flux Φ generated by energizing the electromagnetic coil 5 is generated by the slits 3a, 3b, 16a from the rotor 3 via the air gap.
It flows in the double flux type magnetic flux path which is bypassed by 6 and returns to the rotor 3. Due to the magnetic attraction of this magnetic flux, the armature 16 is magnetically attracted to the rotor 3 against the elastic force of the damper rubber 15, and the rotation of the automobile engine is transmitted to the car air-conditioning compressor 2. Further, when the electromagnetic coil 5 is de-energized, the magnetic flux Φ disappears and the armature 16 is released, so that the elastic force of the damper rubber 15 causes the plate 12 to move.
Attracted to the side. The retraction of the armature 16 retracted from the rotor 3 and separated from the rotor 3 is restricted by the uncovered portion 10e of the flange portion 10b of the armature hub 10.

In this embodiment, the outermost diameter of the flange portion 10b of the armature hub 10 is larger than the inner diameter of the armature 16 and the armature 16 is larger than the inner diameter.
And make it smaller than the drilling position of the slit 16a of
The uncoated portion 1 is provided on the flange portion 10b of the armature hub 10.
However, when the flange portion 10b is made of a non-magnetic member or when the flange portion 10b is completely covered with the plate 12, the armature hub 1 is provided.
The outermost diameter of the flange portion 10b of 0 is set to the armature 16
The design can be changed to a structure in which the slit 16a is larger than the drilled position. When changing to such a structure,
The escape portion 10d of the rivet 14 formed on the flange portion 10b of the armature hub 10 is inserted into the damper rubber storage portion 1
The through hole may have the same diameter as the through hole 12g of No. 3 or a larger diameter.

Next, a safety measure when the damper rubber 15 falls off will be described with reference to FIG. The electromagnetic clutch for a car air conditioner may be required to be designed assuming an unexpected scandal that does not cause a design problem. In the unlikely event of a misconduct, the damper rubber 15 that is baked and fixed to the rivet 14 and press-fitted and fixed in the damper rubber storage portion 13 may fall off due to frictional heat generated by repeated operations and heat generated from the engine. is assumed. In such a case, the elastic return of the rivet 14 by the damper rubber 15 is not performed, the electromagnetic clutch 1 is locked, and when the power transmission state to the car air-conditioning compressor is continued in this state, as shown in FIG. Then, the rivet 14 melts the peripheral wall portion 12a housed therein, further melts the plate 12 as indicated by the chain double-dashed line 14a, and finally melts to the adjacent peripheral wall portion 12a. Therefore, in this embodiment, the protruding portion 1 protruding from the head portion of the rivet 14 is provided on the peripheral wall portion 12a.
2h is provided, and the protruding portion 12h remains as a non-dissolving portion, so that the plate 12 is not separated.

Next, another embodiment according to the present invention will be described. 5 is a sectional view of the armature assembly, and FIG. 6 is a left side view of FIG. The armature assembly 17 shown in these drawings corresponds to the armature assembly 9 of the first embodiment.
Only the structure in which the stopper rubber 18 is provided differs from that of the stopper rubber 18 described above. The armature assembly 17
The flange portion 10b of the armature hub 10 is integrally formed with a plurality (three in this embodiment) of extension portions 10f. In addition, a small diameter portion of the stopper rubber 18 is press-fitted and fixed in a through hole formed in the extension portion 10f. The armature 16 that is pulled toward the plate 12 by the elastic force of the damper rubber 15 is in contact with the stopper rubber 18 and its retracted position is limited. The electromagnetic clutch including the armature assembly 17 having such a structure operates in the same manner as the electromagnetic clutch 1 described above.

In the above embodiments, the example of the electromagnetic clutch is given as the electromagnetic coupling device, but it goes without saying that the invention can also be applied to an electromagnetic brake in which an armature is magnetically attracted to a field core. Further, the detailed structure such as the flange portion of the armature hub formed separately from the boss portion is not limited to this embodiment, and it is needless to say that various design changes can be made.

[0017]

As described above, according to the present invention, as the first invention, the outer diameter dimension of the flange portion of the armature hub is made larger than the inner diameter dimension of the armature, and the clearance portion of the fastening member is provided in the flange portion. Has formed
The outermost diameter of the flange part of the armature hub, which is an aggregate for increasing the rigidity of the armature support member made of reinforced plastic, can be increased, and the tensile force that acts on the armature support member by the elastic force of the damper rubber can be increased. Since it can be surely suppressed, the distortion can be prevented without increasing the wall thickness of the armature support member. Further, the fastening member can be brought closer to the center direction of the armature assembly, and the outer diameter dimension of the armature assembly can be reduced. Therefore, it is possible to provide a lightweight and small-sized armature assembly in which distortion of the armature support member is prevented.

According to a second aspect of the invention, the outer diameter of the flange portion of the armature hub is made larger than the inner diameter of the armature, and the flange portion of the armature hub has a relief portion for the fastening member and an uncovered portion for the armature support member. The armature hub flange, which is an aggregate for increasing the rigidity of the armature support member made of reinforced plastic material, is provided because the armature support member side, which is attracted to the armature support member side by the damper rubber, is restricted by the uncovered part of the flange part. Since the outermost diameter of the armature can be increased and the tensile force that acts on the armature support member due to the elastic force of the damper rubber can be reliably suppressed, its distortion can be prevented without increasing the wall thickness of the armature support member. It Further, the fastening member can be brought closer to the center direction of the armature assembly, and the outer diameter dimension of the armature assembly can be reduced. Therefore, it is possible to provide a lightweight and small-sized armature assembly in which distortion of the armature support member is prevented. Further, in the present invention, even if the flatness of the side surface of the armature support member by insert molding is poor, the flatness of the armature retracting due to the elastic force of the damper rubber does not deteriorate, so that the reliability in terms of quality is good. An armature assembly can be provided.

Furthermore, as a third aspect of the invention, the outer diameter dimension of the flange portion of the armature hub is made larger than the inner diameter dimension of the armature, and the flange portion of the armature hub is provided with a clearance portion for the fastening member and a non-contact of the armature support member. The outermost diameter of the flange part of the armature hub, which is the aggregate for increasing the rigidity of the armature support member made of reinforced plastic, is provided by providing the covered part and interposing the stopper rubber between this uncovered part and the armature. Since the tensile force acting on the armature support member can be reliably suppressed by the elastic force of the damper rubber, the strain can be prevented without increasing the wall thickness of the armature support member. Further, the fastening member can be brought closer to the center direction of the armature assembly, and the outer diameter dimension of the armature assembly can be reduced. Therefore, it is possible to provide a lightweight and small-sized armature assembly in which distortion of the armature support member is prevented. Further, in the present invention, the armature attracted to the armature support member side by the elastic force of the damper rubber is interposed between the uncovered portion of the flange portion of the armature hub and the armature, and has a sufficiently thick stopper rubber. The armature release sound is quiet, and the rivet (fastening member) axial direction compared to the armature assembly in which a stopper rubber is interposed between the armature hub flange and the armature. Since the size of the electromagnetic coupling device can be reduced, the size of the electromagnetic coupling device in the axial direction is also reduced.

[Brief description of drawings]

FIG. 1 is a front view of an electromagnetic clutch including an armature assembly according to the present invention.

FIG. 2 is a sectional view taken along line II-II in FIG.

3 is a sectional view taken along line III-III in FIG.

FIG. 4 is a front view for explaining the operation of the armature assembly according to the present invention after the damper rubber has fallen off.

FIG. 5 is a sectional view of an armature assembly according to another embodiment of the present invention.

6 is a side view of FIG. 7.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Electromagnetic clutch, 3 ... Rotor, 8 ... Rotating shaft, 9 ... Armature assembly, 10 ... Armature hub, 10b ... Flange part, 10e ... Uncoated part, 12 ... Plate, 12a
... peripheral wall part, 12h ... protruding part, 13 ... damper rubber storage part, 14 ... rivet (fastening member), 15 ... damper rubber, 16 ... armature, 18 ... stopper rubber.

Claims (3)

[Claims] 1. An armature hub having a boss attached to a rotary shaft and a flange extending outward in the radial direction, and a flange of the armature hub whose inner side in the radial direction is covered by insert molding to be integrally formed. A fixed armature support member made of a reinforced plastic material, a plurality of recessed damper rubber storage portions integrally formed on the outer side in the radial direction of the armature support member, and individually stored in these damper rubber storage portions. Along with the damper rubber, each of which has a fastening member whose tip protrudes from a through hole formed in the bottom of the damper rubber storage portion is individually fixed, and each tip of the fastening member is fixed to the armature support member by the damper rubber. An armature that is movably supported and that is disposed outside the boss portion of the armature hub. In the armature assembly of the magnetic coupling device, the outer diameter dimension of the flange portion of the armature hub is made larger than the inner diameter dimension of the armature, and an escape portion of the fastening member is formed in the flange portion. Armature assembly of coupling device. 2. An armature hub having a boss mounted on a rotary shaft and a flange extending outward in the radial direction, and a flange of the armature hub whose inner side in the radial direction is covered by insert molding to be integrally formed. A fixed armature support member made of a reinforced plastic material, a plurality of recessed damper rubber storage portions integrally formed on the outer side in the radial direction of the armature support member, and individually stored in these damper rubber storage portions. Along with the damper rubber, each of which has a fastening member whose tip protrudes from a through hole formed in the bottom of the damper rubber storage portion is individually fixed, and each tip of the fastening member is fixed to the armature support member by the damper rubber. An armature that is movably supported and that is disposed outside the boss portion of the armature hub. In the armature assembly of the magnetic coupling device, the outer diameter dimension of the flange portion of the armature hub is made larger than the inner diameter dimension of the armature, and the clearance portion of the fastening member and the armature support member are provided in the flange portion of the armature hub. An armature assembly for an electromagnetic coupling device, wherein an uncovered portion is provided, and the retraction of the armature pulled toward the armature support member side by the damper rubber is restricted by the uncovered portion of the flange portion of the armature hub. 3. An armature hub having a boss mounted on a rotary shaft and a flange extending radially outward, and a flange of the armature hub whose inner side in the radial direction is covered by insert molding to be integrally formed. A fixed armature support member made of a reinforced plastic material, a plurality of recessed damper rubber storage portions integrally formed on the outer side in the radial direction of the armature support member, and individually stored in these damper rubber storage portions. Along with the damper rubber, each of which has a fastening member whose tip protrudes from a through hole formed in the bottom of the damper rubber storage portion is individually fixed, and each tip of the fastening member is fixed to the armature support member by the damper rubber. An armature that is movably supported and that is disposed outside the boss portion of the armature hub. In the armature assembly of the magnetic coupling device, the outer diameter dimension of the flange portion of the armature hub is made larger than the inner diameter dimension of the armature, and the clearance portion of the fastening member and the armature support member are provided in the flange portion of the armature hub. An armature assembly for an electromagnetic coupling device, wherein an uncoated portion is provided, and a stopper rubber is interposed between the uncoated portion and the armature.