JP3833987B2 - Clutch mechanism - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention includes a first rotating member that is supported to be rotated by a rotational driving force obtained from a driving source, a second rotating member that is rotatably supported coaxially with the first rotating member, An actuating spring extending along a circumferential surface of the second rotating member from a first end connected to the first rotating member, and a second end of the actuating spring accompanying the forward rotation of the first rotating member The clutch mechanism is provided with a switching operation means for reducing the diameter of the operating spring by restraining it and winding it around the peripheral surface of the second rotating member, thereby rotating the second rotating member integrally with the first rotating member. About.
[0002]
[Prior art]
As this type of clutch mechanism, there is Patent Document 1 shown below as prior art document information related to the present invention.
In the clutch mechanism described in Patent Document 1, an input gear that is rotationally driven by a drive motor (drive source) is provided, and a clutch spring (operating spring) engaging portion (second spring) is provided as a switching operation means. And an electromagnet that adsorbs the clutch disk to the rotor integrated with the input gear (the first end of the clutch spring is engaged) by the electromagnetic attraction generated based on the energization operation. And a coil. When electromagnetic attracting force is generated in the coil, the bushing starts to rotate integrally with the rotor, the clutch spring wraps around the output hub (second rotating member), and the output hub (second rotating member) is integrated with the rotor. Connected to the (first rotating member).
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 2001-37155 (paragraph numbers 0066 to 0067, FIGS. 2 and 9)
[0004]
[Problems to be solved by the invention]
In the clutch mechanism described in Patent Document 1, the rotor (first rotating member) and the bushing are rotated in the direction opposite to the normal direction due to a wiring error of the driving motor (driving source) during installation. Then, the engaging portion (second end) of the clutch spring (actuating spring) is relative to the first end of the clutch spring in the direction of rewinding the clutch spring (that is, the direction in which the inner diameter of the clutch spring increases). As a result, the clutch spring (particularly near the second end) may be damaged.
[0005]
Accordingly, an object of the present invention is to provide a clutch in which the operating spring is unlikely to be damaged even if a situation in which the first rotating member rotates reversely due to an unexpected cause occurs in view of the above-described drawbacks of the conventional clutch mechanism exemplified above. To provide a mechanism.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, a clutch mechanism according to the present invention has the characteristic structure described in any one of claims 1 to 6.
That is, the clutch mechanism according to claim 1 of the present invention is:
A first rotating member supported so as to be rotated by a rotational driving force obtained from a driving source; a second rotating member supported so as to be rotatable coaxially with the first rotating member; and the first rotating member. An operation spring extending along the peripheral surface of the second rotating member from the first end connected to the first rotation member, and the second end of the operating spring accompanying the forward rotation of the first rotating member is suppressed. A clutch mechanism comprising switching operation means for reducing the diameter of the actuating spring and winding it around the circumferential surface of the second rotating member, thereby rotating the second rotating member integrally with the first rotating member,
A restricting member is provided for restricting relative movement between the first end and the second end of the operating spring that accompanies the rotation of the first rotating member in the direction opposite to the normal rotation. It is configured.
[0007]
In order to provide such a characteristic configuration, in the clutch mechanism according to claim 1 of the present invention,
Even if the first rotating member rotates reversely due to a wiring mistake of the drive motor and the second end of the actuating spring tries to move relative to the first end (in the direction to rewind the clutch spring), the restricting member Since the relative movement is held down, it is possible to obtain an effect that the operating spring is hardly damaged.
[0008]
Further, holding the operating spring before a rotational driving force is applied to the first rotating member from a driving source in a shape and a position along a common axis of the first rotating member and the second rotating member. It can be set as the structure provided with the member.
With this configuration, the gap between the actuating spring and the second rotating member is kept constant with high accuracy by the action of the holding member, so that the first rotating member is rotated forward by the drive source. Response of the clutch mechanism, such as the length of time from the start until the actuating spring contracts and wraps around the circumferential surface of the second rotating member, and the second rotating member starts to rotate integrally with the first rotating member. Can be kept constant, or when the rotational driving force is not applied to the first rotating member from the driving source, it is possible to suppress the phenomenon that the operating spring prevents free rotation of the second rotating member due to friction, etc. An effect is obtained. Also, with this configuration, when assembling the clutch mechanism or the actuator equipped with the clutch mechanism, the holding member functions as a means for guiding the mounting direction and mounting position of the operating spring. Smoothly proceed.
[0009]
Alternatively, the second end of the operating spring is provided with an engaged portion extending radially outward, and the cylindrical guide member that houses the cylindrical body of the operating spring in the first rotating member And the restricting member includes a protrusion provided on the cylindrical guide member so as to come into contact with the engaged portion of the actuating spring as the first rotating member rotates backward. can do.
With this configuration, when assembling the clutch mechanism or the actuator equipped with the clutch mechanism, the cylindrical guide member functions as a means for guiding the mounting direction and the mounting position of the operating spring, so that the assembling work can be performed more smoothly. In addition, since this cylindrical guide member can be used as a base for providing the restriction member, the restriction member can be arranged at an ideal position very close to the operating spring in the radial direction, and the number of parts can be reduced. be able to. Also, with this configuration, the gap between the actuating spring and the second rotating member is kept constant with high accuracy by the action of the cylindrical guide member, so that the first rotating member is driven by the drive source. After starting the forward rotation operation, the operating spring contracts and winds around the peripheral surface of the second rotating member, and the time length until the second rotating member starts to rotate integrally with the first rotating member, etc. Suppresses the phenomenon that the response of the clutch mechanism is easy to keep constant or that the actuating spring hinders the free rotation of the second rotating member due to friction when the driving force is not applied to the first rotating member from the drive source And the like.
[0010]
In addition to the above-described configuration, a fixing portion for fixing the first end of the operating spring to the first rotating member is provided, and the first end of the operating spring is connected to the cylindrical guide member with the fixing portion. It can be set as the structure in which the guide groove which guides to was formed. According to this structure, when the operating spring is attached when the clutch mechanism is assembled, first, the first end of the operating spring is inserted into the guide groove of the cylindrical guide member, and the cylindrical body of the operating spring is directly cylindrical. By simply feeding the guide spring into the guide member, the first end of the operating spring is automatically guided to the fixed portion of the first rotating member by the guide groove, so that an easy and reliable assembly operation can be performed.
[0011]
In particular, the guide groove may be formed of a groove provided in a tapered shape with a gap that gradually decreases toward the fixed portion.
If comprised in this way, as the first operation of assembling the operating spring to the clutch mechanism, the first end of the operating spring enters the end of a sufficiently wide guide groove formed at the inlet of the cylindrical guide member. After that, if the cylindrical body of the operating spring is fed into the cylindrical guide member as it is, the first end of the operating spring is naturally fixed to the first rotating member accurately by the guide groove with a gradually narrowing gap. As a result, the operation of assembling the operating spring becomes easier.
[0012]
Further, the guide groove is formed of a tapered slit that gradually narrows toward the fixed portion, and is narrower than the outer diameter of the first end of the operating spring between the terminal portion of the slit and the fixed portion. A portion is formed, and the first end of the actuating spring can be engaged with the fixed portion by a press fit over the narrow portion.
With this configuration, as an operation for assembling the operating spring to the clutch mechanism, first, the first end of the operating spring is made to enter a sufficiently wide slit portion formed at the inlet portion of the cylindrical guide member. In addition, if the cylindrical body of the operating spring is fed into the cylindrical guide member, the first end of the operating spring is guided to the narrow portion by a slit that gradually narrows, and further pushes the operating spring into the cylindrical guide member. For example, since the first end of the operating spring passes over the narrow portion and is engaged with the fixed portion of the first rotating member, the assembling operation of the operating spring becomes easier.
[0013]
The switching operation means is rotatable with a collar member fixedly installed near the second end of the operating spring and a biasing force including a radial component with respect to a circumferential sliding contact surface of the collar member. The brake member is provided with an engaging portion that engages with the engaged portion of the operating spring in accordance with the forward rotation operation of the first rotating member. It can be.
If comprised in this way, if the 1st rotation member rotates in the normal rotation direction with the 1st end of an operation spring based on rotation of a drive source, the 2nd end of an operation spring will be first held by a braking member, When the spring part main body of the operating spring starts to deform in the direction of diameter reduction, finally, the spring part main body of the operating spring binds the peripheral surface of the second rotating body, and the braking member starts to rotate relative to the collar member. At the same time, the second rotating body starts to rotate integrally with the first rotating member. That is, according to this configuration, the switching operation means, as seen in the prior art, generates a clutch disk connected to the second end of the operating spring and an electromagnetic suction force that attracts the clutch disk with a constant suction force. It is simpler and lighter than a coil member, etc., and the first rotating member rotates reversely due to a wiring error of the driving motor, and the second end of the operating spring is relative to the first end. Even if the relative movement is attempted, a clutch mechanism is obtained in which the relative movement is held down by the restricting member and the operating spring is not easily damaged.
[0014]
Other features and advantages of the present invention will become apparent from the following description of embodiments using the drawings.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
An example of an embodiment of the present invention will be described based on the drawings.
(Schematic configuration of the latch release actuator)
FIG. 1 shows an actuator 100 for unlatching an automobile door using one embodiment of a clutch mechanism according to the present invention. However, the clutch mechanism according to the present invention is not limited to the following examples, but can be used for various purposes including latching and locking an automobile door or an actuator for operating a locking lever of a door lock device to a locking side or a releasing side. It goes without saying that it can be used for the above.
The actuator 100 has a casing-like case member 2 that can be attached to the inside of an automobile door. The case member 2 includes a DC motor M as a drive source and a cable 60 (operating the latch of the automobile door to the release side). An operating lever 30 connected to the operating lever 30 is supported, and a transmission mechanism for transmitting the rotational driving force of the DC motor M to the operating lever 30 is also provided.
[0016]
As shown in FIGS. 2 and 3, the transmission mechanism includes a worm gear 4 fixed to the drive shaft of the DC motor M, and an input wheel 6 having a ratchet gear portion 6b meshed with the worm gear 4 (an example of a first rotating member). , A driven rotating body 18 coaxial with the input wheel 6 (an example of a second rotating member), an intermediate gear 20 meshed with a gear portion 18b formed at one end of the driven rotating body 18, and a sector gear gear meshed with the intermediate gear 20 And an output rotator 22 having 22a. An operation lever 30 is supported at one end of the output rotating body 22 so as not to be relatively rotatable. The intermediate gear 20 integrally includes a large-diameter gear portion 20a and a small-diameter gear portion 20b. The gear portion 18b of the driven rotor 18 is a large-diameter gear portion 20a, and the sector gear portion 22a is a small-diameter gear portion 20b. The reduction gear mechanism is configured.
The input wheel 6, the driven rotor 18, the intermediate gear 20, and the output rotor 22 have rotation axes that are parallel to each other, and these rotation axes intersect with the rotation axis of the worm gear 4 at a substantially right angle. Yes.
The input wheel 6 and the driven rotor 18 are supported in series on the outer periphery of a single clutch shaft 5 fixed to the case member 2 so as to be relatively rotatable. A clutch mechanism 50 that transmits only the rotation of the input wheel 6 in the forward rotation direction to the driven rotating body 18 is provided therebetween.
[0017]
As understood from FIGS. 2, 4, and 5, the clutch mechanism 50 includes a fixed portion 10 b (an example of a first end) fixed to the input wheel 6 in addition to the input wheel 6 and the driven rotor 18. The clutch spring 10 (an example of an actuation spring) extending along the pressure-receiving peripheral surface 18a of the driven rotor 18 from and the engaged portion 10c (an example of the second end) of the clutch spring 10 accompanying the forward rotation of the input wheel 6 ) To reduce the diameter of the clutch spring 10 so as to be wound around the pressure-receiving peripheral surface 18a of the driven rotor 18. The inner diameter of the spring body 10a of the clutch spring 10 is set to be slightly large so that it does not touch the pressure receiving peripheral surface 18a of the driven rotor 18. Therefore, when the switching operation means 12 is not operating, the driven rotation is performed. The body 18 can rotate smoothly without any frictional resistance with the clutch spring 10.
In FIG. 2, the switching operation means 12 is arranged radially outside the collar member 14 fixedly installed at the height of the engaged portion 10c of the clutch spring 10 and the circumferential inner peripheral surface 14H of the collar member 14. Two C-shaped springs 16a and 16b that are forcibly fitted to exert a biasing force in the direction are provided. The C-shaped springs 16a and 16b can be said to be an example of a braking member that is rotatably locked with a biasing force including a radial component with respect to the circumferential sliding contact surface of the collar member. That is, the two C-shaped springs 16a and 16b are rotatable with respect to the collar member 14 while exhibiting a resistance due to a constant friction based on the biasing force. Each of the C-shaped springs 16a and 16b is provided with an engaging portion that engages with the engaged portion 10c of the operating spring.
[0018]
Therefore, from the state of FIG. 6 in which the DC motor M does not output the driving force, the input wheel 6 rotates forward together with the fixed portion 10b of the clutch spring 10 based on the driving force of the DC motor M (indicated by the arrow in FIG. 7). Since the engaged portion 10c of the actuating spring is initially retained by the C-shaped springs 16a and 16b (not yet rotatable relative to the collar member 14), as shown in FIG. Only the fixed portion 10b of the clutch spring 10 rotates together with the input wheel 6, and the spring portion main body 10a of the clutch spring 10 starts to deform in the diameter reducing direction. Finally, as shown in FIG. The driven rotor 18 starts to rotate integrally with the clutch spring 10 and the input wheel 6 by a strong frictional force by constraining the surface 18a (at this time, substantially simultaneously C-shaped springs 16a, 16b also starts to rotate relative to the collar member 14). If the forward rotation of the input wheel 6 is continued for a certain period of time, the vehicle door latch (such as a torsion spring provided in the latch mechanism) is pulled by the operation lever 30 supported on one end of the output rotating body 22. Operated on the release side (against forces).
[0019]
When the release operation of the latch is completed, the DC motor M is stopped based on a signal generated from a sensor that detects the completion, and the power supply to the DC motor M is also stopped. The power supply to the DC motor M may be stopped using a timer with a lapse of a predetermined time after starting energization. When the power supply to the DC motor M is stopped, the fixed portion 10b of the clutch spring 10 as shown in FIG. 9 based on the restoring force that the clutch spring 10 tries to return to the original state where no external force is applied. However, the input wheel 6 and the worm gear 4 meshed with the input wheel 6 are rotated in the reverse direction together with the DC motor M, and the clutch mechanism 50 is in an initial state where it waits for the input wheel 6 to be driven forward again. Returned. Thus, the ratchet gear portion 6b of the input wheel 6 has a lead angle exceeding a predetermined value so that the worm gear 4 can be rotationally driven based on the driving force from the input wheel 6 (see FIG. 4).
[0020]
(Detailed structure of clutch mechanism 50)
Here, each element which comprises the clutch mechanism 50 is demonstrated in detail.
As shown in FIGS. 4 and 5, the clutch spring 10 includes a spring body portion 10 a that extends in a cylindrical shape, and a fixed portion 10 b that extends radially outward from the lower end of the spring body portion 10 a (an example of a first end). And a semicircular engaged portion 10c (an example of a second end) extending radially outward from the upper end of the spring body portion 10a.
The input wheel 6 includes a disc-shaped wheel main body 6a, a ratchet gear portion 6b formed integrally extending radially outward from the outer edge of the wheel main body 6a, and the wheel main body 6a so that the clutch shaft 5 is inserted therethrough. A boss portion 6e formed extending in the axial direction from the center, and a spring holding portion provided between the outer edge of the wheel body 6a and the boss portion 6e are provided. The spring holding portion includes a main sleeve portion 6c (an example of a cylindrical guide member) having a length substantially equal to the main body portion 10a of the clutch spring 10, and an auxiliary member that is shorter than the main sleeve portion 6c and located on the inner diameter side. It consists of a sleeve portion 6d. The wheel body 6a, the ratchet gear portion 6b, the main sleeve portion 6c, and the auxiliary sleeve portion 6d constituting the input wheel 6 are integrally formed by injection molding of a synthetic resin into the mold.
[0021]
As shown in FIGS. 10, 4, and 5, the engaged portion 10 c of the clutch spring 10 (rewinding of the spring) is caused at the tip of the main sleeve portion 6 c due to inadvertent reverse rotation of the input wheel 6 due to some cause. Protruding regulating wall 6R (an example of a regulating member) is provided that regulates movement (synonymous with preventing the clutch spring 10 from deforming in the diameter-expanding direction and impairing its original function). ing.
When the input wheel 6 is reversed as indicated by an arrow for some reason from the state of FIG. 11A in which the DC motor M is not rotating in any direction, the engaged portion 10c of the clutch spring 10 is 11 (b), the clutch spring 10 may be pressed against the engaging portions 16Ea and 16Eb of the two C-shaped springs 16a and 16b from the opposite side. The semi-circular engaged portion 10c is backed up by the restriction wall portion 6R, and thereafter, when the two C-shaped springs 16a and 16b are rotated backward while dragging, the clutch spring 10 Since the engaged portion 10c and the fixed portion 10b rotate integrally with the restriction wall portion 6R and the relative positional relationship between them does not change, the engaged portion 10 of the clutch spring 10 does not change. There the engaging portion 16Ea, hardly become a situation that is deformed in the rewinding direction by the contact of the 16Eb.
[0022]
Further, a through hole 6H (an example of a fixing portion) for fixing the fixed portion 10b of the clutch spring 10 is provided at the lower end of the main sleeve portion 6c. Furthermore, a slit 6S (an example of a guide groove) that guides the fixed portion 10b of the clutch spring 10 to the through hole 6H is formed in the main sleeve portion 6c. The slit 6S is provided in a tapered shape in which the gap gradually decreases from the radial center of the regulating wall 6R toward the through hole 6H. The narrowest narrow portion at the lowest part of the taper is set to a dimension that is smaller than the outer diameter of the wire rod of the clutch spring 10. Therefore, at the time of assembly, first, as shown in FIG. 10 (a), the fixed portion 10b of the clutch spring 10 is entered into a wide portion above the slit 6S, and then the main body portion 10a of the clutch spring 10 is directly moved. If it is pushed along the inner surface of the main sleeve portion 6c, the fixed portion 10b of the clutch spring 10 gets over the narrow portion of the slit 6S (the input wheel 6 is made of resin having a deformability that enables such press-fitting. And fitted into the through-hole 6H having a cross-sectional dimension substantially larger than the outer diameter of the wire rod of the clutch spring 10, and fixed thereto as shown in FIG.
[0023]
In this fixed state, the main body portion 10a of the clutch spring 10 is housed in a cylindrical space formed between the main sleeve portion 6c and the auxiliary sleeve portion 6d, and the main sleeve portion 6c and the auxiliary sleeve portion 6d. In cooperation with each other, when the driving force in the forward rotation direction is not applied to the input wheel 6 and the clutch mechanism 50 is in the disengaged state, the main body portion 10a of the clutch spring 10 touches the pressure receiving circumferential surface 18a of the driven rotor 18. The clutch spring 10 is held in a correct posture so as not to be present.
As shown in FIG. 11 (a), when the driving force in the normal rotation direction is not applied to the input wheel 6 and the clutch mechanism 50 is in the disengaged state, the restricting wall portion 6R of the main sleeve portion 6c is Is slightly in contact with the engaged portion 10c, or is slightly pushed toward the spring-drawing diaphragm side.
[0024]
As shown in FIGS. 4 and 5, the collar member 14 includes a color main body 14P integrally formed of a synthetic resin, and a lid 14Q fixed to the upper end of the color main body 14P.
As shown in FIG. 5, the collar body 14P extends radially outward from the upper end of the first sleeve portion 14a and the first sleeve portion 14a, which are arranged to be fitted to the main sleeve portion 6c of the input wheel 6. A disc-shaped first disk portion 14b, a second sleeve portion 14c extending upward from the outer edge of the first disk portion 14a (a portion forming a circumferential sliding contact surface 14H), a second sleeve portion And a second disk portion 14d having a generally disc shape extending radially outward from the upper end of 14c. A plurality of botches 14e are erected on the upper end of the second disk portion 14d, and three mounting flanges 14f extend radially outward from the outer periphery of the second disk portion 14d.
[0025]
The lid body 14Q is a disk-like member that is also formed of synthetic resin or the like, and has through holes corresponding to the plurality of botches 14e of the color main body 14P. When the bottom 14e is inserted into the through-hole of the lid 14Q, the lid 14Q is pressed against the upper surface of the second disk portion 14d of the collar body 14P, and the bottom 14e is melted and crimped with an iron or the like, the collar body 14P and The lid 14Q is integrated. In this state, as shown in FIG. 2, the edge on the inner diameter side of the lid body 14Q slightly protrudes inward from the inner peripheral surface 14H of the second sleeve portion 14c. Thus, the protruding portion of the lid body 14Q cooperates with the first disk portion 14b and the second sleeve portion 14c of the collar body 14P to form a storage space 14S in which C-shaped springs 16a and 16b described later can be engaged. Form. The color member 14 may be provided to the assembly site as a single component in which the color main body 14P and the lid body 14Q are integrated in advance. Alternatively, the collar main body 14P and the lid body 14Q may be further integrated and provided with the C-shaped springs 16a and 16b already engaged in the storage space 14S.
[0026]
The driven rotator 18 has a main body having a pressure receiving peripheral surface 18a having substantially the same outer diameter as the auxiliary sleeve portion 6d of the input wheel 6, and a gear portion 18b formed further upward from the upper end of the main body. A flange portion 18c for holding the spring main body portion 10a of the clutch spring 10 at the height of the pressure receiving circumferential surface 18a protrudes between the pressure receiving circumferential surface 18a and the gear portion 18b with a small size. At the time of assembling, the clutch shaft 5 is set on the half of the case member 2 of the actuator 100, the input wheel 6 into which the clutch spring 10 is previously fitted is inserted into the clutch shaft 5, and then the driven rotor 18 is attached to the clutch shaft. If the E-ring 5R is attached to the tip of the clutch shaft 5 while being inserted into the clutch spring 10 while being inserted into the clutch spring 10, the input wheel 6 and the driven rotating body 18 are retained in the clutch shaft 5. Set. Next, the collar member 14 in which the two C-shaped springs 16a and 16b are fitted in advance is set so as to cover the upper surface of the input wheel 6, and the color member is inserted with a screw or the like inserted through the through hole of the mounting flange 14f. What is necessary is just to fix 14 to the case member 2.
[0027]
As shown in FIG. 4, the two C-shaped springs 16 a and 16 b have a shape that forms a part of an oval when no external force is applied. Then, when the collar member 14 is forcibly fitted into the storage space 14 </ b> S after being deformed into a reduced diameter state by an external force from the outside in the radial direction, a radially outward biasing force is applied to the inner peripheral surface 14 </ b> H of the collar member 14. That is, while generating a repulsive force (an example of an urging force including a radial component), it is held in a shape that forms a part of a circle along the inner peripheral surface 14H as shown in FIGS. The inner peripheral surface 14 </ b> H has a linear cross section extending substantially parallel to the clutch shaft 5, and has a length that allows the two C-shaped springs 16 a and 16 b to be juxtaposed in parallel with the axis of the clutch shaft 5. Have. The first C-shaped spring 16a engaged with the collar member 14 on the side close to the first disk portion 14b in the storage space 14S has a circumferential length of about 330 °. The second C-shaped spring 16b engaged on the side away from 14b is shorter than the former and has only a circumferential length of about 210 °. The two C-shaped springs 16a and 16b have engaging portions 16Ea and 16Eb extending in a direction parallel to the axial center of the clutch shaft 5 by bending the ends on the same side in the circumferential direction by about 90 °. Is forming.
[0028]
As shown in FIG. 6, the engaging portions 16Ea and 16Eb of the two C-shaped springs 16a and 16b are captured in the circumferential direction in the semicircular engaged portion of the engaged portion 10c of the clutch spring 10. It is provided at the position to obtain. When the assembly is completed, only the engaging portions 16Ea and 16Eb of the two C-shaped springs 16a and 16b enter the locus of the engaged portion 10c of the clutch spring 10 as the input wheel 6 rotates. can get. Accordingly, the two C-shaped springs 16a and 16b can be connected to the collar member 14 even when the engaging portions 16Ea and 16Eb are engaged in the storage space 14S of the collar member 14 at different angular positions when assembly is completed. If the input wheel 6 is rotated by an appropriate angle in the forward rotation direction after being set and fixed so as to cover the upper surface of the input wheel 6 as described above, the engagement of the clutch spring 10 that rotates and moves accordingly. The joining portion 10c is displaced from the engaging portions 16Ea and 16Eb existing at arbitrary angular positions, and becomes a normal initial state (state shown in FIG. 6) assembled at substantially the same location. Since the two C-shaped springs 16a and 16b have different lengths, in this standby state where the engaging portions 16Ea and 16Eb are aligned in one place, the inner peripheral surface 14H (C-shaped The maximum urging force is exerted at different locations on the sliding surfaces of the springs 16a and 16b). As a result, the load direction applied to the inner peripheral surface 14H of the collar member 14 is dispersed with respect to the circumferential direction, and is more uniform as a whole. The C-shaped springs 16a and 16b themselves are always held in a stable state. Thus, the C-shaped springs 16a and 16b are referred to as braking members that are rotatably locked with a biasing force including a radial component with respect to the circumferential sliding contact surface of the collar member 14. Can do.
[0029]
Each of the engaging portions 16Ea and 16Eb of the two C-shaped springs 16a and 16b is provided at an end portion located on the right side of the C-shaped springs 16a and 16b in FIG. When the engaging portion is provided at the left end in this manner, as predicted from FIG. 7, the C-shaped springs 16 a and 16 b are moved from the engaged portion 10 c of the clutch spring 10 during the forward rotation operation of the input wheel 6. As a result, a pulling force that separates from the inner peripheral surface 14H of the collar member 14 is received. This is because the C-shaped springs 16a and 16b do not rotate during the forward rotation of the input wheel 6 and prevent the engaged portion 10c of the clutch spring 10 from moving (before the clutch is engaged). ) Or, finally, the C-shaped springs 16a and 16b start rotating relative to the second sleeve portion 14c of the collar member 14 by the engaged portion 10c of the clutch spring 10 that rotates together with the input wheel 6. More stable braking force is created when the clutch is engaged (after clutch engagement starts to occur).
[0030]
(Operation of latch release actuator)
The actuator 100 described above operates as follows when it is used for latch release of an automobile door.
When the DC motor M is rotated forward based on radio waves emitted from, for example, a keyless switch or the like while the automobile door is latched, the input wheel 6 is connected to the clutch spring 10 via the worm gear 4. Together with the fixed portion 10b, the rotation is performed in the forward rotation direction. At this time, the engaged portion 10c of the clutch spring 10 tries to rotate in the forward direction by the input wheel 6, but immediately, the engaging portions 16Ea and 16Eb of the two C-shaped springs 16a and 16b Engage and the switching operation means 12 functions. That is, first, since the braking force acting between the two C-shaped springs 16a and 16b and the collar member 14 exceeds the shape retention force of the clutch spring 10 (force that holds the position of the engaged portion 10c), The two C-shaped springs 16a and 16b remain stationary. As a result, the fixed portion 10b of the clutch spring 10 moves in the direction indicated by the arrow in FIG. 7, and gradually the engaged portion 10c of the clutch spring 10. Go away from. As the first end 10 of the clutch spring 10 is separated from the engaged portion 10c, the spring body 10a of the clutch spring 10 is reduced in diameter, and the pressure receiving peripheral surface 18a of the driven rotor 18 is constrained. When this restraint is almost complete, the clutch spring 10 is integrated with the driven rotor 18 by a strong frictional force, and at the same time, the clutch spring 10 itself cannot be further reduced in diameter and deformed. The springs 16 a and 16 b start sliding rotation against the frictional resistance with the collar member 14 by the traction force from the engaged portion 10 c of the clutch spring 10. At this time, since the clutch spring 10 is integrated with the driven rotator 18, the three rotators engaged with the gear teeth, that is, the driven rotator 18, the intermediate gear 20, and the output rotator 22 are rotationally driven. The operation lever 30 supported on one end of the output rotating body 22 is swung in the direction of the arrow in FIG. 1, and the latch of the automobile door is latched via the cable 60 (or rod) connected to the operation lever 30. It is operated to the release side (the state of the operation lever 30 indicated by a one-dot chain line in FIG. 1).
[0031]
As can be understood from FIG. 8, the engaged portion 10c of the clutch spring 10 is sufficiently less than 360 ° as the angle around the clutch shaft 5 based on the forward rotation of the input wheel 6 (this embodiment). 2), the inner diameter of the spring body 10a of the clutch spring 10 and the inner diameter of the driven rotor 18 so that the spring body 10a of the clutch spring 10 can bind the pressure receiving peripheral surface 18a of the driven rotor 18. Since the dimensional difference between the outer diameters of the pressure receiving peripheral surface 18a and the length of the spring portion main body 10a are set, the restriction wall portion 6R formed on the main sleeve portion 6c of the input wheel 6 serves as the clutch spring 10. The movement of the engaged portion 10c is not hindered. Next, when the release operation of the latch is completed, as described above, the DC motor M is stopped based on the signal issued from the sensor that detects the completion, and the power supply to the DC motor M is also stopped. As soon as the power supply to the DC motor M is stopped, the fixed portion 10b of the clutch spring 10 is input based on the restoring force that attempts to return the clutch spring 10 to the original state where no external force is applied. The wheel 6 and the worm gear 4 meshed with the input wheel 6 are rotated together with the DC motor M in the reverse direction. As a result, the clutch spring 10 returns to its original shape that is not reduced in diameter due to an external force applied, and is separated from the pressure receiving peripheral surface 18a of the driven rotor 18, and the clutch mechanism 50 causes the input wheel 6 to be driven forward again. At the same time, the driven rotator 18, the intermediate gear 20, and the output rotator 22 can freely rotate with respect to the input wheel 6, and the torsion provided in the latch mechanism of the door Due to the urging force of the spring, the operation lever 30 supported on one end of the output rotating body 22 is returned to the initial position (the state of the operation lever 30 indicated by a solid line in FIG. 1).
[0032]
[Another embodiment]
<1> Contrary to the above-described embodiment, the C-shaped springs 16a and 16b are used in such a way that the force to press the inner peripheral surface 14H of the collar member 14 is received from the engaged portion 10c of the clutch spring 10. Each engagement portion of the C-shaped spring of the book (or only the engagement portion of one C-shaped spring) may be provided at the left end of the C-shaped spring in FIG. In this case, there is an advantage that a sufficient braking force can be obtained by using a C-shaped spring having a lower repulsive force. Further, even if only one C-shaped spring is used, it functions as a braking member required in the present invention, and three or more C-shaped springs may be used as a braking member.
[0033]
<2> Or, unlike the above embodiments, the outer peripheral surface may be formed on a collar member fixed to the body of the actuator. In this case, a shape forming a part of an ellipse is exhibited in a state where no external force is exerted. It can be used as a braking member that can prevent the rotation of the portion 10c.
[0034]
<3> The switching operation means constituting the clutch mechanism includes a collar member that is fixedly installed and a biasing force that includes a radial component with respect to the sliding surface of the collar member, as in the above-described embodiment. And a C-shaped spring (braking member) locked in a rotatable manner, and an engaging portion that engages with the second end of the clutch spring is not provided on the braking member. A coil and a friction plate that is attracted to the electromagnetic coil side based on the on / off operation of the energization of the electromagnetic coil, and an engagement portion that engages with the second end of the clutch spring may be provided on the friction plate. good.
[Brief description of the drawings]
FIG. 1 is a schematic view of the appearance of an actuator using a clutch mechanism according to the present invention.
FIG. 2 is a cutaway side view of the actuator of FIG.
FIG. 3 is a cutaway plan view of the actuator of FIG.
4 is an exploded perspective view of main components of a clutch mechanism used in the actuator of FIG.
5 is a cross-sectional view of each component shown in FIG.
FIG. 6 is a plan view showing one state of a main part of the clutch mechanism.
FIG. 7 is a plan view showing another state of the main part of the clutch mechanism.
FIG. 8 is a plan view showing still another state of the main part of the clutch mechanism.
FIG. 9 is a plan view showing another state of the clutch mechanism.
FIG. 10 is a side view showing a slit and a first end of a clutch spring included in the input wheel.
FIG. 11 is a plan view showing a restriction wall portion of the input wheel and a second end of the clutch spring.
[Explanation of symbols]
M DC motor (drive source)
2 Case members
6 Input wheel (first rotating member)
6c Main sleeve (tubular guide member)
6R regulating wall (regulating member)
6H Through hole (fixed part)
6S slit (guide groove)
10 Clutch spring (actuating spring)
14 Color members
16 C-shaped spring (braking member)
18 driven rotating body (second rotating member)
30 Control lever
50 Clutch mechanism
60 cables

Claims (7)

A first rotating member supported so as to be rotated by a rotational driving force obtained from a driving source; a second rotating member supported so as to be rotatable coaxially with the first rotating member; and the first rotating member. An operation spring extending along the peripheral surface of the second rotating member from the first end connected to the first rotation member, and the second end of the operating spring accompanying the forward rotation of the first rotating member is suppressed. A clutch mechanism comprising switching operation means for reducing the diameter of the actuating spring and winding it around the circumferential surface of the second rotating member, thereby rotating the second rotating member integrally with the first rotating member,
A clutch mechanism provided with a restricting member for restricting relative movement between the first end and the second end of the actuating spring in association with a rotating operation in a direction opposite to the forward rotation of the first rotating member. A holding member that holds the operating spring before a rotational driving force is applied to the first rotating member from a driving source in a shape and a position along a common axis of the first rotating member and the second rotating member. The clutch mechanism according to claim 1 provided. An engaged portion extending radially outward is provided at the second end of the actuating spring, and a cylindrical guide member is formed on the first rotating member to accommodate the cylindrical body of the actuating spring. 2. The clutch according to claim 1, wherein the restricting member includes a protrusion provided on the cylindrical guide member so as to come into contact with the engaged portion of the actuating spring as the first rotating member rotates backward. mechanism. A fixing portion for fixing the first end of the operating spring is provided in the first rotating member, and a guide groove for guiding the first end of the operating spring to the fixing portion is formed in the cylindrical guide member. The clutch mechanism according to claim 3. The clutch mechanism according to claim 4, wherein the guide groove is a groove provided in a tapered shape in which a gap gradually decreases toward the fixed portion. The guide groove is formed of a tapered slit that gradually narrows toward the fixed portion, and a narrow portion having a dimension smaller than the outer diameter of the first end of the operating spring is provided between the terminal portion of the slit and the fixed portion. The clutch mechanism according to claim 5, wherein the first end of the actuating spring is engaged with the fixed portion by a press fit over the narrow portion. The switching operation means is rotatable with a collar member fixedly installed near the second end of the operating spring and a biasing force including a radial component with respect to a circumferential sliding contact surface of the collar member. And an engaging portion that engages with the engaged portion of the operating spring as the first rotating member rotates forward. The clutch mechanism according to claim 3.

Images