JPS6238021Y2 - - Google Patents

Description

[Detailed Description of the Invention] This invention relates to an electromagnetic spring clutch that is used by being attached to a cultivation machine or other machinery.

An electromagnetic spring clutch is a clutch that uses a coil spring to tighten the boss part of the input rotor and the output hub to transmit torque between the two.The coil spring is usually magnetically attracted to the end surface of the input rotor. One end is hooked to the ring-shaped armature, and the other end is hooked to the output hub.
Furthermore, the outer circumferential surface is surrounded by a spring cover fixed to the output hub side.

By the way, since the armature is unstable if only one end of the coil spring is hooked, the armature is housed movably in the axial direction within a stepped portion formed at the end of the spring cover.

In such a structure, the outer diameter of the spring cover becomes large, which is disadvantageous in terms of miniaturization.

Based on the above-mentioned points of view, this invention allows the outer diameter of the spring cover to be minimized, while stably supporting the armature, and furthermore, makes it possible to reduce the weight by making the material for the spring cover thinner. An electromagnetic spring clutch is provided, which comprises: an input rotor and an output hub arranged on the same axis; an annular armature arranged on the same axis that can freely magnetically attract an end face of the input rotor; The inner circumferential surface of the coil faces the outer circumferential surface of the boss portion of the input rotor and the outer circumferential surface of the output hub, and the bent portion of one end is hooked to the armature, and the bent portion of the other end is hooked to the output hub. a coil spring for tightening; a notch surrounding the coil spring and facing the armature-side bent portion of the coil spring at the end on the input rotor side; and an armature stopper for preventing excessive movement of the armature. and a spring cover in which the armature is disposed between the end face of the input rotor and the armature stopper, and the outer peripheral surface of the end of the spring cover is configured as a guide part of the armature. The points are distinctive.

Next, the electromagnetic spring clutch of this invention will be explained by way of examples with reference to the drawings.

FIG. 1 shows an embodiment of the electromagnetic spring clutch of this invention in a longitudinal sectional side view of the upper half thereof. As shown in the drawing, the input rotor 1 supports the output hub 3 via bearings 2, 2 in a coaxial arrangement, while the boss portion 1A on the side opposite to the output hub support side is connected to the annular field core 4. It is supported through a bearing 6 in the center hole 5 of.

The field core 4 is fixed to the mounting plate 7,
It has a built-in electromagnetic coil 8.

The input rotor 1 has a boss portion 1A and a flange portion 1B fixed to the boss portion with a plurality of screws 9, and the flange portion 1B faces the field core 4 through a slight gap.

The outer circumferential surface 1a of the boss portion 1A and the outer circumferential surface 3a of the output hub 3 have the same diameter, or the outer circumferential surface 3a of the output hub 3 is formed to have a slightly smaller diameter. The inner circumferential surface 10a of the coil of the tightening coil spring 10 is exposed.

The coil spring 10 has one end formed into a bent part 10A bent outward, and the other end formed into a bent part 10B bent inward.

The bent portion 10A is hooked onto a notch 12 of an annular armature 11 that can be magnetically attracted to the flange portion 1B of the input rotor 1.
is hooked to a notch 13 formed in the output hub 3.

On the other hand, the cylindrical spring cover 14 surrounding the coil spring 10 has an outer circumferential surface 14 a formed at the guide portion of the armature 11 , and the outer circumferential surface 14 a of the end portion
A shows the bent portion 10A of the coil spring 10.
A notch 15 is formed that faces the.

FIG. 2 shows a front view of the spring cover 14.
Further, FIG. 3 shows each in a longitudinal sectional side view.

The spring cover 14 is provided with a required number of protrusions 16 as armature stoppers for regulating the range of movement of the armature 11 in the axial direction, at a portion continuing from the outer circumferential surface 14a of the end portion that serves as a guide portion of the armature.
It is stretch-molded by press working.

In the electromagnetic spring clutch of this invention constructed as described above, when a voltage is applied to the electromagnetic coil 8, the armature 11 is excited and magnetically attracted to the flange portion 1B of the input rotor 1.

When the armature 11 is magnetically attracted to the input rotor 1, the armature 11 rotates together with the input rotor 1, the coil spring 10 is tightened, and torque is transmitted from the input rotor 1 to the output hub 3.

Next, when the voltage application to the electromagnetic coil 8 is finally stopped, the armature 11 becomes demagnetized, separates from the flange portion 1B of the input rotor 1, and enters the clutch open state.

In this way, the electromagnetic spring clutch of this invention can operate in the same manner as the conventional electromagnetic spring clutch, but since the armature 11 is supported by the outer circumferential surface 14a of the end of the spring cover 14 as a guide, the electromagnetic spring clutch is made of thin plate material. Even when the spring cover is used, the armature 11 can be stably supported, and the protrusion 16 can prevent the armature 11 from moving excessively in the axial direction.

Therefore, in the electromagnetic spring clutch of this invention, the spring cover, which was conventionally a cast product, a turned product, or other thick-walled member, can be made into a press-formed product of extremely thin steel plate. In addition to being a lightweight product, the coil spring can be securely stored inside the spring cover, so the armature-side bent part of the coil spring will not protrude outside the spring cover, and the armature will always be in the spring cover's guide area. It has the excellent advantage of being able to move stably.

[Brief explanation of the drawing]

Fig. 1 is a side view showing an embodiment of the electromagnetic spring clutch of this invention, with the upper half sectioned vertically, Fig. 2 is a front view of the spring cover, and Fig. 3 is a sectional view taken along the line of Fig. 2. . In the drawings, 1...Input rotor, 1A...Boss part, 1B...Flange part, 1a...Outer peripheral surface, 3
... Output hub, 3a ... Outer circumferential surface, 4 ... Field core, 8 ... Electromagnetic coil, 10 ... Coil spring, 10a ... Coil inner circumferential surface, 11 ... Armature, 12, 13 ... Notch, 14 ... Spring cover, 14A ... End, 14a ... End outer peripheral surface, 15 ... Notch, 16 ... Protrusion.

Claims (1)

[Claims for Utility Model Registration] An input rotor 1 and an output hub 3 arranged on the same axis, and an annular armature 11 arranged on the same axis that can be magnetically attracted to the end face of the input rotor 1.
and boss portions 1A of the input rotor 1 that are adjacent to each other.
The inner circumferential surface 10a of the coil faces the outer circumferential surface 1a of the output hub 3, and the inner circumferential surface 10a of the coil faces the outer circumferential surface 1a of the output hub 3.
A tightening coil spring 10 with 0A hooked on the armature 11 and the other end bent portion 10B hooked on the output hub 3; A spring cover 14 is provided with a notch 15 facing the armature-side bent portion 10A of the coil spring 10 and an armature stopper 16 for preventing excessive movement of the armature 11, The outer peripheral surface 14 of the spring cover 14 is disposed between the end surface of the input rotor 1 and the armature stopper 16.
An electromagnetic spring clutch characterized in that a is configured as a guide portion of the armature 11.