JPH0728236U - Electromagnetic spring clutch - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide an electromagnetic spring clutch with a simplified armature shape to reduce the unit cost in manufacturing and an improved operating characteristic. A coil spring 7 is fitted to the cylindrical portion 3a of the input hub 3 and the cylindrical portion 4a of the output hub 4. A field core 8 having an electromagnetic coil 11 therein is fitted on the outside of the coil spring 7. The field core 8 includes a cylindrical portion 4b of the output hub 4 and a cylindrical portion 3 of the input hub 3.
It is supported on the input hub 3 by a cover 9 fitted to c. The disk-shaped armature 6 is a field core 8
It is formed in the space formed by the cover 9 and one hook of the coil spring 7 is hooked.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an electromagnetic spring clutch that transmits power by winding a coil spring around a first hub and a second hub arranged on the same axis.

[0002]

[Prior art]

 A conventional electromagnetic spring clutch has a hollow shaft-shaped first hub mounted on a rotary shaft, and the outer peripheral surface of the first hub is formed in a stepped shape.

That is, like the electromagnetic spring clutch illustrated in FIG. 1 of Japanese Patent Application Laid-Open No. 57-65426, the first hub has a radial direction in which the second hub is rotatably fitted. The smaller diameter cylindrical part, the largest radial part where the armature, which is an annular member with an L-shaped cross section, is magnetically attracted to the side surface, and the smaller diameter part Is large, but has a large-diameter cylindrical portion with a dimension smaller than the radial dimension of the disc portion.

The electromagnetic spring clutch having such a first hub has one hook of the coil spring hooked on the second hub and the other hook hooked on the armature, and then the inner peripheral surface of the coil spring. Are fitted to the outer peripheral surface of the large diameter cylindrical portion of the first hub and the inner peripheral surface of the second hub to the outer peripheral surface of the small diameter cylindrical portion of the first hub.

Next, in the center hole of the field core, which is formed of an annular member having an L-shaped cross section and in which the electromagnetic coil is provided, the small diameter cylindrical portion is opposite to the large diameter cylindrical portion of the first hub. Assemble by inserting the side cylinder.

In the conventional electromagnetic spring clutch having such a structure, when the electromagnetic coil is energized, the magnetic flux thereof flows from the cylindrical portion of the field core to the disc portion of the armature, and from the cylindrical portion of the armature to the first hub portion. A magnetic circuit that flows through the disk portion to the disk portion of the field core is configured.

Therefore, when the electromagnetic coil is energized, the end surface of the cylindrical portion of the armature is magnetically attracted to the side surface of the disk portion of the first hub, and the hook on the armature side of the coil spring is connected to the first hub. As a result, the power is transmitted from the second hub to the first hub, for example.

On the other hand, an electromagnetic spring clutch for tightening the coil spring around the first hub and the second hub by magnetically attracting the armature to the disk portion of the first hub, which is a rotating member or a rotated member. On the other hand, there is an electromagnetic spring clutch illustrated in FIG. 2 of the publication, in which power is transmitted by magnetically attracting the armature to the fixed member side.

That is, the inner peripheral surface of the metal bearing, which is press-fitted and fixed in the center hole of the field core, is rotatably fitted to the outer peripheral surface of the cylindrical portion of the first hub, which is axially opposite to the small-diameter cylindrical portion. However, an electromagnetic spring clutch having a structure in which the disc portion of the first hub is omitted is also known.

In the electromagnetic spring clutch having such a structure, when the electromagnetic coil is energized, the armature is magnetically attracted to the field core side, and in FIG. 2 of the same publication, the side surface of the disk portion of the armature causes the electromagnetic coil to move. The side surface of the wound coil bobbin makes frictional sliding contact, and the braking force by the frictional sliding contact brakes the hook on the armature side of the coil spring, so that power is transferred from the second hub to the first hub, for example. Transmitted.

[0011]

[Problems to be solved by the device]

 In conventional electromagnetic spring clutches, the armature has an L-shaped cross-section regardless of whether the armature with the coil spring hook is connected to the rotating member or the rotated member or frictionally slidably contacting the fixed member. The mainstream structure is that the field core has a yoke portion made of an annular member having an L-shaped cross section as well as the annular member.

However, if a cylindrical movable iron core portion such as a general solenoid type electromagnet is formed on the armature, not only the unit price of the parts for manufacturing the armature becomes expensive but also the weight increases. It takes time to wind the spring around the first and second hubs, and improvement in operating characteristics has been desired.

It is an object of the present invention to provide an electromagnetic spring clutch having a simplified armature shape, a reduced unit cost for manufacturing, and an improved operating characteristic.

[0014]

[Means for Solving the Problems]

 In order to achieve such an object, according to the present invention, a large-diameter first cylindrical portion formed substantially at the center in the axial direction and a small-diameter second cylindrical portion formed on one side of the first cylindrical portion, or this A hollow shaft-shaped first hub having small-diameter second and third cylindrical portions formed on both sides of the first cylindrical portion, and rotatably fitted to the second cylindrical portion of the first hub. A second hub having a cylindrical portion whose radial dimension is substantially the same as that of the first cylindrical portion is rotatably fitted to the first cylindrical portion or the third cylindrical portion of the first hub. Disc-shaped armature, the first cylindrical portion of the first hub and the outer peripheral surface of the cylindrical portion of the second hub are fitted to each other, and one hook is hooked on the second hub. It consists of a coil spring with the other hook hooked on the armature and an annular member with a generally U-shaped cross section. The bottom portion is fitted to the large-diameter cylindrical portion of the second hub by being fitted to the outside of the coil spring, and the inner magnetic pole surface and the outer circumference of the armature are opposed to the side surface of the armature with an axial gap. Field core in which an electromagnetic coil having an outer magnetic pole surface facing the surface with a radial gap is provided, an end portion of the field core on the outer magnetic pole surface side, and the first cylindrical portion or the first hub portion of the first hub. And a means for limiting the movement amount of the armature attracted to the field core by the magnetic attraction force of the electromagnetic coil. .

[0015]

[Action]

 In the electromagnetic spring clutch, when the electromagnetic coil is energized, the magnetic flux flows from the outer magnetic pole surface of the field core to the armature through a radial gap, and from this armature to the inner magnetic pole surface of the field core through an axial gap. Since the circuit is formed, the armature is magnetically attracted to the field core in a state where the movement of the armature is restricted by the side surface of the first cylindrical portion of the first hub, which is the rotating member or the rotated member.

Therefore, the coil spring is wound around the cylindrical portions of the first hub and the second hub, and power is transmitted from the first hub to the second hub, for example. If the electromagnetic coil is de-energized, the restraint of the armature on the field core is released, so that the transmission of power from the first hub to the second hub is cut off.

[0017]

【Example】

 1 and 2 show an embodiment of an electromagnetic spring clutch according to the present invention. FIG. 1 is a side view with an upper half section thereof, and FIG. 2 is an enlarged sectional view of an essential part of FIG. is there. Hereinafter, a detailed description of an embodiment will be given based on these drawings.

The electromagnetic spring clutch 1 is attached to a rotary shaft 2 of a paper feeding mechanism of a copying machine or a printer, and comprises a hollow shaft-shaped first hub 3 (hereinafter referred to as an input hub) and a gear. It is configured as a joint for transmitting power to the second hub 4 (hereinafter referred to as an output hub).

The input hub 3 has a large-diameter first cylindrical portion 3a around which a coil spring 7, which will be described later, is wound, is formed in a substantially central portion in the axial direction, and a small-diameter first cylindrical portion 3a is formed on both sides of the first cylindrical portion 3a. Two cylindrical portions 3b and a third cylindrical portion 3c are formed. An output hub 4 having a cylindrical portion 4a having substantially the same size (slightly larger size in the embodiment) as the radial direction of the first cylindrical portion 3a is rotatably fitted to the second cylindrical portion 3b. The snap ring 5 prevents it from coming off.

On the other hand, a disk-shaped armature 6 is rotatably fitted to the third cylindrical portion 3c of the input hub 3 such that the inner side surface abuts the side surface 3d of the first cylindrical portion 3a. . A coil spring 7 is fitted over the outer peripheral surface of the first cylindrical portion 3a of the input hub 3 and the outer peripheral surface of the cylindrical portion 4a of the output hub 4, and extends inward in the radial direction of the coil spring 7. One hook 7a is hooked on the output hub 4, and the other hook 7b extending in the axial direction is hooked on the armature 6.

A field core 8 made of an annular member drawn into a substantially U-shaped cross section is fitted to the outside of the coil spring 7 in the radial direction, and the inner peripheral surface of the bottom portion is a large-diameter cylinder of the output hub 4. It is fitted to the portion 4b. A cover 9 is fitted between the end on the side of the outer magnetic pole surface 8a and the third cylindrical portion 3c of the input hub 3, and the field core 8 is supported by the input hub 3 and is supported by the snap ring 10. It is locked out.

The cover 9 has a flange (not shown) serving as a rotation stop plate extending outward in the radial direction, and the flange is engaged with a pin (not shown) planted in the fixing frame. As a result, the field core 8 is prevented from rotating.

A coil bobbin 12 around which an electromagnetic coil 11 is wound is inserted and fixed in the annular groove of the field core 8 configured as described above. When the electromagnetic coil 11 is energized, the magnetic flux flows from the outer magnetic pole surface 8a of the field core 8 to the armature 6 via the air gap S ₁ and from the armature 6 to the inner magnetic pole surface 8b of the field core 8 via the air gap S _2. Form a flowing magnetic circuit.

In the electromagnetic spring clutch 1 configured as described above, the side surface on the inner peripheral surface side of the armature 6 that is attracted to the inner magnetic pole surface 8b side of the field core 8 by the magnetic attraction force of the electromagnetic coil 11 Since the side surface 3d of the first cylindrical portion 3a of the hub 3 is pressed, the side surface of the armature 6 and the side surface 3d of the input hub 3 are in frictional sliding contact.

Therefore, the armature 6 rotates together with the input hub 3 to reduce the diameter of the coil spring 7, so that the coil spring 7 is wound around the first cylindrical portion 3a of the input hub 3 and the cylindrical portion 4a of the output hub 4 and Power is transmitted from the hub 3 to the output hub 4.

When the electromagnetic coil 11 is de-energized, the restraint of the armature 6 on the field core 8 is released, and the coil spring 7 elastically returns. Then, the transmission of power from the input hub 3 to the output hub 4 is cut off.

In the electromagnetic spring clutch 1 having the above-described configuration and operation, the input hub 3 is made of a resin material except for the outer peripheral surface of the first cylindrical portion around which the coil spring 7 is wound and tightened, and the output hub By forming the hub 4 and the cover 9 entirely from a resin material, it is possible to prevent the leakage magnetic circuit of the electromagnetic coil 11 from being formed, and it is possible to provide a lightweight and quiet electromagnetic spring clutch.

Further, in the electromagnetic spring clutch 1 of the embodiment, by pressing the armature 6 against the side surface 3d of the input hub 3 which is a rotating member or a rotated member, the side surface 3d limits the movement amount of the armature 6. However, like the conventional electromagnetic spring clutch, the coil bobbin 12 has an end surface projecting from the inner magnetic pole surface 8b of the field core 8, and the end surface of the coil bobbin 12 limits the amount of movement of the armature 6. It may be used as a means.

Further, when such a means is adopted, the armature 6 is fitted on the first cylindrical portion 3a side of the input hub 3, and the hook (7b) of the coil spring 7 extending outward in the radial direction is attached. Design changes such as hanging can be made.

[0030]

[Effect of device]

 As described above, in the electromagnetic spring clutch of the present invention, the armature has a disk-like shape and the field core is an annular member having a substantially U-shaped cross section, so that the weight of the armature can be reduced and the electromagnetic coil of the electromagnetic coil can be achieved. The magnetic circuit has been simplified.

Therefore, the connection time from the start of winding the coil spring to the end of winding is shortened, and the operating characteristics of the electromagnetic spring clutch are improved.

By supporting the field core on the first hub with the second hub and the cover, the first and second hubs serving as the winding tightening surfaces of the armature and the coil spring are provided in the space formed by these members. It was possible to construct a cylindrical part of the, and it was possible to provide a quiet electromagnetic spring clutch as this type of joint.

[Brief description of drawings]

FIG. 1 is a side view showing a cross section of an upper half of an electromagnetic spring clutch according to an embodiment of the present invention.

FIG. 2 is an enlarged sectional view of a main part of FIG.

[Explanation of symbols]

 3 1st hub 4 2nd hub 6 Armature 7 Coil spring 8 Field core 9 Cover 11 Electromagnetic coil

Claims (1)

[Scope of utility model registration request] 1. A large-diameter first member formed substantially at the center in the axial direction.
A cylindrical portion and a second small diameter formed on one side of the first cylindrical portion.
A hollow shaft-shaped first hub having a cylindrical portion or second and third small-diameter cylindrical portions formed on both sides of the first cylindrical portion, and rotatable to the second cylindrical portion of the first hub. A second hub having a cylindrical portion that is fitted to the first cylindrical portion and has substantially the same radial dimension as the first cylindrical portion, and is rotatably fitted to the first cylindrical portion or the third cylindrical portion of the first hub. The combined disc-shaped armature is fitted over the outer peripheral surfaces of the first cylindrical portion of the first hub and the cylindrical portion of the second hub, and one hook is attached to the second hub. It consists of a coil spring having the other hook hooked on the armature and an annular member having a substantially U-shaped cross section. The coil spring is fitted on the outside of the coil spring and has a bottom portion on the large-diameter cylindrical portion of the second hub. And the side surface of the armature and the axial gap. A field core in which an electromagnetic coil having an outer magnetic pole surface that faces the inner magnetic pole surface that faces the outer peripheral surface of the armature with a radial gap is provided, and an end portion of the field core on the outer magnetic pole surface side and the first core. A disk-shaped cover fitted between the first cylindrical portion or the third cylindrical portion of the first hub and the movement amount of the armature attracted to the field core by the magnetic attraction force of the electromagnetic coil. And an electromagnetic spring clutch.