JP6672558B2 - Door opening and closing device - Google Patents

Description

  The present invention relates to a door opening and closing device for opening and closing a side door supported on a side surface of a vehicle body via a hinge.

  Vehicles are already provided with a drive unit configured to assist in opening and closing the door. A drive unit mounted on this kind of vehicle is generally configured to rotate an output arm by driving a motor. The drive unit has a unit body attached to the vehicle body and an output arm connected to the door. When the motor of the drive unit is driven, the output arm rotates, so that the door can be moved in the opening direction or the closing direction with respect to the vehicle body. For example, if the drive unit operates in a state in which the engagement between the striker and the latch has been released, the opening of the partially opened door is assisted, and the door can be opened with a small operating force. In addition, if the drive unit operates in the direction opposite to the direction in which the door is opened, the door can be closed without touching the hand (for example, see Patent Document 1).

JP 2005-320784 A

  Here, as in Patent Literature 1, it is easy to secure a space for attaching a drive unit to a vehicle body in a vehicle back door. However, the side door of the vehicle is provided at an opening through which a person enters and exits the vehicle. Therefore, it is difficult to secure a space for mounting the drive unit on the ceiling portion or the floor portion of the vehicle in consideration of the ease of getting on and off and the comfort of the person. Moreover, in the drive unit described in Patent Document 1, the shaft member of the output arm (final output shaft of the drive unit) is disposed along a direction perpendicular to the output shaft of the motor, so that the installation is performed. Requires a relatively large occupied space, and it is also difficult to house it inside the side door.

  The present invention has been made in view of the above circumstances, and has as its object to provide a door opening / closing device capable of assisting opening / closing of a side door without impairing getting on / off and comfort.

  In order to achieve the above object, a door opening and closing device according to the present invention is a door opening and closing device for opening and closing a side door supported on a side surface of a vehicle body via a hinge, wherein a window glass is provided inside the side door. A drive unit is disposed in a space between the lifting guide and the end surface of the side door to which the hinge is attached.

  The present invention also provides the door opening and closing device described above, wherein the drive unit includes a speed reducer and a final output shaft on an extension of the output shaft of the drive source, and the final output shaft is provided on a rotation axis of the hinge. An output arm is provided along the radial direction on the final output shaft of the drive unit, housed inside the side door along the side, and the output arm is connected to the vehicle body.

  Further, according to the present invention, in the door opening / closing device described above, the hinge is provided between the side door and the vehicle main body at an interval vertically, and the output arm is provided at a portion between the hinges. It is characterized by being connected to the main body.

  According to the present invention, in the door opening / closing device described above, a check mechanism for controlling an opening angle of the side door is provided at the hinge.

  According to the present invention, in the door opening and closing device described above, a check link mechanism for controlling an opening angle of the side door is provided between the side door and the vehicle body.

  According to the present invention, in the door opening and closing device described above, the output arm is connected to the vehicle body via a link arm, and the check link mechanism is provided on the output arm or the link arm. And

  According to the present invention, the drive unit is disposed in the space between the elevating guide of the window glass and the end surface of the side door to which the hinge is attached inside the side door, so that the getting on / off and comfort are not impaired at all. Without opening and closing the side door.

FIG. 1 is a diagram conceptually showing a left side surface of a vehicle to which a door opening / closing device according to an embodiment of the present invention is applied. FIG. 2 conceptually shows a connecting portion between a side door of the vehicle shown in FIG. 1 and a vehicle body, and is an enlarged plan view in a state where the side door is closed. FIG. 3 conceptually shows a connection portion between the side door of the vehicle shown in FIG. 1 and the vehicle body, and is an enlarged plan view in a state where the side door is opened. FIG. 4 is a sectional view of a hinge applied between the side door and the vehicle body shown in FIG. 1 as viewed from the side. 5A and 5B show the hinge shown in FIGS. 4A and 4B. FIG. 5A is an enlarged cross-sectional view showing a state in which the needle bearing is housed in a groove of the hinge shaft, and FIG. FIG. 4 is an enlarged cross-sectional view in a state where it is performed. FIG. 6 is a perspective view showing the appearance of a drive unit applied to the vehicle shown in FIG. FIG. 7 is a perspective view showing a state where the speed reducer of the drive unit shown in FIG. 6 is exposed. FIG. 8 is a perspective view of the disassembled state of the clutch mechanism of the drive unit shown in FIG. FIG. 9 is a perspective view showing a main part of a clutch mechanism applied to the drive unit shown in FIG. FIG. 10 is a perspective view showing a main part of a clutch mechanism applied to the drive unit shown in FIG. FIG. 11 is a view showing the operation of the clutch mechanism applied to the drive unit shown in FIG. 6, and is a view showing a state where the cam member is separated from the two clutch plates. FIG. 12 is a diagram illustrating a state in which the electric motor serving as a driving source is driven from the state illustrated in FIG. 11, the control unit of the cam member contacts one clutch plate, and the roller contacts the engagement surface of the driven shaft. It is. FIG. 13 is a diagram illustrating a state where the driven shaft is manually operated at a speed exceeding the cam member from the state illustrated in FIG. 12. FIG. 14 is a view showing a state in which the driven shaft is further rotated from the state shown in FIG. 13 and the torque from the driven shaft to the electric motor is cut off.

  Hereinafter, preferred embodiments of a door opening and closing device according to the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 shows a vehicle to which a door opening / closing device according to an embodiment of the present invention is applied. The vehicle exemplified here is a four-door type four-wheeled vehicle having a front side door D and a rear side door D on both sides of a vehicle body B, respectively. As shown in FIG. 1 to FIG. 3, the front side door D and the rear side door D include a door body DM configured in a box shape by an outer panel OP and an inner panel IP, and a sash provided in a frame shape on an upper part of the door body DM. DS. Each side door D is connected to the vehicle main body B by an upper hinge 10 and a lower hinge 10 provided on the front surface (end surface of the side door) DMF of the door main body DM, and around a hinge shaft 11 along the vertical direction. It is possible to open and close the opening / closing opening BO of the vehicle body B by rotating.

  As the upper hinge 10 and the lower hinge 10, as shown in FIGS. 4 and 5, those having a built-in check mechanism between the outer hinge plate 12 and the inner hinge plate 13 are applied. That is, the hinge shaft 11 is attached to the outer hinge plate 12 in a state where the relative rotation is restricted. A needle bearing 14 and a coil spring 15 are sequentially provided around the hinge shaft 11. The needle bearings 14 are arranged at equal intervals in the circumferential direction by a retainer 16, and are respectively housed in grooves 11 a provided on the peripheral surface of the hinge shaft 11. The retainer 16 of the needle bearing 14 is engaged with the inner hinge plate 13. For example, when the side door D is closed, the needle bearing 14 is housed in the groove 11a of the hinge shaft 11, and the state is maintained by the coil spring 15, as shown in FIG. When the side door D is opened from this state, the inner hinge plate 13 rotates with respect to the outer hinge plate 12, and as a result, the needle bearing 14 held by the retainer 16 becomes a coil as shown in FIG. The spring 15 deviates from the groove 11a while being expanded. When the rotation of the inner hinge plate 13 with respect to the outer hinge plate 12 progresses, the needle bearing 14 is housed in the groove 11a of the hinge shaft 11 again as shown in FIG. Since it is maintained, the rotation of the inner hinge plate 13 is checked. Reference numeral 17 in the drawing denotes a cover that covers the outer periphery of the coil spring 15.

  A window glass G is provided on the sash DS of the side door D as shown in FIG. The window glass G is disposed so as to be vertically movable along an elevating guide WG by an elevating mechanism (not shown) disposed inside the door body DM, and closes the opening of the sash DS when moved upward. It is possible. When the window glass G moves downward, the window glass G is sequentially housed inside the door body DM, and the opening of the sash DS can be opened.

  In addition, each side door D is provided with a drive unit 20 inside the door body DM. The drive unit 20 assists the opening and closing of the side door D with respect to the vehicle body B. As shown in FIGS. 6 to 8, the drive unit 20 includes an electric motor 21 serving as a drive source, a first reduction gear 22, a rotation sensor 23, It comprises a second speed reducer 24 and a clutch mechanism 25.

  The first reduction gear 22, as shown in FIG. 7, is a planetary gear mechanism in which a gear (not shown) fixed to the output shaft 21a of the electric motor 21 is configured as a sun gear. In this planetary gear mechanism, the carrier 22b of the planetary carrier 22a is fixed to the gear case 22c, and the rotation of the sun gear is reduced and output from the ring gear 22d. The rotation sensor 23 magnetically detects a rotation angle and a rotation direction of the ring gear 22d, which are outputs of the first reduction gear 22. The second reduction gear 24 is configured by connecting two sets of planetary gear mechanisms. The two sets of planetary gear mechanisms are provided with a common fixed ring gear 24a. The rotation of the preceding sun gear 24b connected to the ring gear 22d of the first reduction gear 22 is reduced and transmitted to the subsequent planetary carrier 24c. Is output from a second deceleration output shaft 24d connected to the planetary carrier 24c. Although not explicitly shown in the figure, both the first reduction gear 22 and the second reduction gear 24 are arranged such that the rotation axis of the sun gear and the second reduction output shaft 24 d are extended from the output shaft 21 a of the electric motor 21. It is configured so that

  As shown in FIG. 8, the clutch mechanism 25 is interposed between the second deceleration output shaft 24d and the driven shaft 26 that is the final output shaft, and applies torque to the driven shaft 26 when the second deceleration output shaft 24d rotates. While the driven shaft 26 rotates, the torque to the second deceleration output shaft 24d is cut off. In the present embodiment, a clutch case 251 including a plate-shaped upper case 251a and a cylindrical lower case 251b is provided, and a clutch drum 252, a cam member 253, and a driven shaft 26 housed inside the clutch case 251 are provided. Thus, a clutch mechanism 25 is configured.

  The clutch drum 252 has a cylindrical base 252a and a flange 252b having a large outer diameter provided at one end of the base 252a. The clutch drum 252 can rotate inside the clutch case 251 around the axis of the base 252a as a rotation center. Housed in As is apparent from the drawing, a coil spring 254 is provided between the flange 252b of the clutch drum 252 and the bottom wall of the lower case 251b. The coil spring 254 regulates the movement of the clutch drum 252 in the axial direction by urging the clutch drum 252 to the upper case 251a via the flange 252b.

  As shown in FIGS. 9 and 10, the clutch drum 252 has recesses 252c at two locations on the peripheral surface of the base 252a. The concave portion 252c has an opening at a position shifted by 180 ° from each other along the circumferential direction, and has two clutch plates 271 and 272 and a roller 28 inside each.

  The clutch plates 271 and 272 are rotatably connected to each other between base end portions via a support shaft 273. The two clutch plates 271 and 272 are connected to the support shaft 273 in a state where the support shaft 273 is along the axis of the base 252a and the respective distal edges gradually increase in the interval toward the outer periphery of the base 252a. It is disposed in the recess 252c of the clutch drum 252 through the intermediary of the clutch drum 252. Each of the clutch plates 271 and 272 has a contact piece 271a and 272a at each of the distal end edges, and a clutch spring 274 between them. The contact pieces 271a and 272a are disc-shaped portions provided so as to bend from a part of the distal end edges of the clutch plates 271 and 272 in a direction away from each other. These contact pieces 271a and 272a contact the inner peripheral surface of the base 252a when the clutch plates 271 and 272 rotate in a direction approaching each other around the support shaft 273, and the two clutch plates 271a , 272 to define the minimum included angle. The clutch spring 274 is a torsion spring provided to urge the clutch plates 271 and 272 in a direction to close each other, and to press the respective contact pieces 271a and 272a against the inner peripheral surface of the base 252a. In this clutch spring 274, the support shaft 273 of the clutch plates 271 and 272 penetrates a portion wound in a cylindrical shape, and each spring end abuts on the back surface of the clutch plates 271 and 272 facing the inner peripheral side of the base 252a. It is arranged to be in contact.

  As shown in FIGS. 8 and 10, the roller 28 has a columnar shape having a substantially constant outer diameter over the entire length, and is configured to contact the surface of the clutch plates 271 and 272 facing the outer peripheral side of the base 252 a. It is arranged. As shown in FIG. 11, when the contact pieces 271a and 272a of the clutch plates 271 and 272 are in contact with the inner peripheral surface of the base 252a, a part of the roller 28 is closer to the outer peripheral surface than the outer peripheral surface of the base 252a. Each dimension is set so as to protrude. When the peripheral surface of the roller 28 is pressed toward the center of the base 252a against the urging force of the clutch spring 274 from this state, the clutch plates 271 and 272 move around the support shaft 273 as shown by the solid line in FIG. As a result, the rotation of the roller 28 from the outer peripheral surface of the base 252a can be reduced.

  As shown in FIG. 8, the cam member 253 is connected to the second deceleration output shaft 24d, and has two control units 253a. The control section 253a protrudes radially from a position deviated from the second deceleration output shaft 24d by 180 ° with respect to the second deceleration output shaft 24d, and through an insertion hole (not shown) provided in the flange 252b of the clutch drum 252. It is inserted into the inside of the base 252a and is disposed so as to face the rear surfaces of the clutch plates 271 and 272. As shown in FIG. 11, when the contact pieces 271a and 272a of the clutch plates 271 and 272 are in contact with the inner peripheral surface of the base 252a, the control unit 253a of the cam member 253 controls all the clutch plates 271. , 272 are set to be separated from the back surface. When the cam member 253 is rotated in one direction with respect to the clutch drum 252 from this state, as shown in FIG. 12, the respective control units 253a move to the back of one clutch plate 272 provided in the individual recesses 252c. While being in contact with each other, the separated state is maintained from the back surface of the other clutch plate 271 provided in each of the concave portions 252c. Similarly, when the cam member 253 is rotated toward the other side with respect to the clutch drum 252, each control unit 253a abuts on the back surface of the other clutch plate 271 provided in each of the concave portions 252c, 252c is maintained in a state separated from the back surface of one clutch plate 272.

  The driven shaft 26 is formed by integrally forming a cylindrical engagement portion 261 having a cylindrical shape, one end of which is a closed end, and a quadrangular prism-shaped output portion 262 provided at the closed end of the engagement cylindrical portion 261. The base portion 252a of the clutch drum 252 is housed inside the cylindrical portion 261 while the output portion 262 is housed inside the clutch case 251 in a state of being exposed to the outside through a hole of the lower case 251b. As shown in FIG. 11, arcuate surfaces 261a and engagement surfaces 261b are provided alternately along the circumferential direction on the inner peripheral surface of the engagement cylindrical portion 261. The arcuate surface 261a is a surface having an arc shape having an inner diameter larger than the maximum protrusion amount of the roller 28 abutting on the clutch plates 271 and 272. On the other hand, the meshing surface 261b is a flat surface that linearly continues between the arcuate surfaces 261a, and the distance from the shaft center of the meshing cylindrical portion 261 is the maximum protrusion of the roller 28 in contact with the clutch plates 271 and 272. It is formed so as to have a size smaller than the amount. However, the protruding dimension d of the meshing surface 261b is set to be smaller than the movable distance of the roller 28 to the inner circumference when the clutch plates 271 and 272 rotate toward the inner circumference of the base 252a about the support shaft 273. It is.

  In the drive unit 20 configured as described above, for example, when the electric motor 21 is driven forward, the rotation of the output shaft 21a is reduced through the first reduction gear 22 and the second reduction gear 24 so that the second reduction output shaft 24d Rotate toward. When the second deceleration output shaft 24d rotates toward one side, in the clutch mechanism 25, as shown in FIG. 12, the control unit 253a of the cam member 253 has the back surface of the one clutch plate 272 disposed in each recess 252c. , The clutch drum 252 rotates toward one via one clutch plate 272, and the respective rollers 28 rotate toward one. When the roller 28 rotates in one direction, the peripheral surface of the roller 28 comes into contact with the meshing surface 261b of the meshing cylindrical portion 261 located in the traveling direction.

  Here, the clutch plate 272 rotating the roller 28 is in a state in which the control unit 253a of the cam member 253 is in contact with the back surface. Therefore, the clutch plate 272 does not rotate inward with respect to the base 252 a of the clutch drum 252, and the peripheral surface of the roller 28 is maintained in a state of being in contact with the engagement surface 261 b of the engagement cylinder portion 261. As a result, when the second deceleration output shaft 24d rotates, torque is transmitted to the driven shaft 26 via the cam member 253, the clutch plate 272, the roller 28, and the meshing cylinder 261.

  On the other hand, when the driven shaft 26 is rotated by the electric motor 21 in the same direction at a speed exceeding the clutch drum 252 when the driven shaft 26 is rotated, as illustrated in FIG. Abuts on the peripheral surface of the roller 28, and the roller 28 rotates with the driven shaft 26 with respect to the clutch drum 252. Here, the controller 253a of the cam member 253 does not abut on the back surface of the clutch plate 271 located in the traveling direction of the roller 28. Therefore, at the time when the roller 28 comes into contact, as shown in FIG. 14, the clutch plate 271 rotates inwardly so as to separate the contacting piece 271a from the inner peripheral surface of the base 252a, and the roller 28 is moved to the base 252a. To the inner circumference toward the center of. As a result, the amount of protrusion of the roller 28 from the outer peripheral surface of the clutch drum 252 decreases, so that the meshing surface 261b of the meshing cylindrical portion 261 passes through the roller 28, and the torque is transmitted to the clutch drum 252. There is no. Even when the electric motor 21 is driven to rotate in the reverse direction, the torque is transmitted to the driven shaft 26 by the rotation of the second deceleration output shaft 24d as described above. Even if the driven shaft 26 is rotated at a speed exceeding the clutch drum 252 from this state, torque is not transmitted from the driven shaft 26 to the clutch drum 252 in the same manner as described above.

  For the above-described vehicles, as shown in FIG. 1, the clutch mechanism 25 is located below, and the output shaft 21 a of the electric motor 21 is placed inside each side door D in a state along the extending direction of the hinge shaft 11. The drive unit 20 is attached. The position where the drive unit 20 is mounted is a space A between the front DMF to which the hinge 10 is mounted and the elevation guide WG inside the door body DM. The driven shaft 26 of the drive unit 20 is connected to the pillar P of the vehicle body B via an output arm 30 fixed to the output section 262 and an opening / closing link arm (link) 31, as shown in FIG. The opening / closing link arm 31 is connected to the vehicle body B at a portion between the upper hinge 10 and the lower hinge 10.

  As described above, when the electric motor 21 of the drive unit 20 is driven, torque is transmitted to the driven shaft 26. Therefore, for example, if the drive unit 20 is operated in a state where the engagement between the striker and the latch is released, the opening of the side door D partially opened as shown in FIG. It is possible to open the side door D with an operating force. In addition, if the drive unit 20 is operated in a direction opposite to the direction in which the side door D is opened, the side door D can be closed without touching as shown in FIG.

  During these operations, according to the drive unit 20, when the side door D is manually operated in the same direction at a speed exceeding the opening / closing speed of the side door D by the electric motor 21, as described above, the driven shaft Since the transmission of torque from the motor 26 to the electric motor 21 is interrupted, the drive unit 20 does not become a load, and the operation of opening and closing the side door D does not feel heavy. In addition, since the opening / closing link arm 31 is connected to the vehicle body B at a position between the upper hinge 10 and the lower hinge 10, there is no possibility that the opening / closing link arm 31 is twisted during operation. . Further, the drive unit 20 accommodated in the side door D only exposes the opening / closing link arm 31 to the outside from the front DMF of the side door D, and does not affect the living space of the vehicle at all. There is no loss of sex.

  As described above, according to the drive unit 20, the roller 28 is brought into contact with the arcuate surface 261a of the meshing tubular portion 261 via the clutch plates 271 and 272 by the urging force of the clutch spring 274, and the second deceleration output shaft 24d Is rotated, the control portion 253a of the cam member 253 is brought into contact with one of the clutch plates 271 and 272, and the roller 28 is brought into contact with the meshing surface 261ab of the meshing cylindrical portion 261. The torque is transmitted to the shaft 26. On the other hand, when the driven shaft 26 rotates at a speed exceeding this relative to the rotation of the second deceleration output shaft 24d, the urging force of the clutch spring 274 is caused by the engagement of the engagement surface 261b of the engagement cylinder portion 261 with the roller 28. The clutch plates 271 and 272 move in opposition to this, and the roller 28 moves to the inner peripheral side, so that torque from the driven shaft 26 to the second deceleration output shaft 24d is cut off. Therefore, unlike the related art, a configuration for guiding the movement route is not required, so that the device can be easily manufactured and operability can be improved without impairing productivity.

  Further, in a vehicle to which the above-described drive unit 20 is applied, the drive unit 20 can be housed in the door body DM in advance in the process of assembling and manufacturing the side door D. Therefore, in the main vehicle assembly and production line, only the work of attaching the side door D to the vehicle main body B and then performing the wiring connection with the vehicle main body B side is required, and the production efficiency can be improved. Will be possible.

  After the side door D is closed or the side door D is opened, the electric motor 21 is rotated in the reverse direction for a preset time, and the control unit 253a of the cam member 253 causes any of the clutch plates 271 and 272 to rotate. Is controlled so as to return to the state shown in FIG. For example, when the clutch mechanism 25 is stopped in the state shown in FIG. 12, when the side door is manually operated in a direction in which the meshing cylinder 261 rotates counterclockwise, the clutch plate 272 controls the cam member 253. Since the roller 253a is in contact, the roller 28 cannot move inward. As a result, the transmission of torque from the driven shaft 26 to the electric motor 21 is not interrupted, and the electric motor 21 may become a load when performing a manual operation. Therefore, in the drive unit 20, the electric motor 21 is rotated in the reverse direction to stop the clutch mechanism 25 in the state shown in FIG.

  In the above-described embodiment, a vehicle having four side doors D is illustrated, but the number of side doors D does not need to be four. The position of the hinge 10 does not need to be at the front DMF of the side door D, and may be provided between the rear surface of the side door and the vehicle body. The number of hinges 10 is not limited to two.

  Further, in the above-described embodiment, the hinge 10 having the built-in check mechanism is applied, but the hinge 10 does not need to have the check mechanism. For example, a check link may be provided between the side door and the vehicle body, or the opening / closing link arm 31 may be configured to function as a check link. Also, the mechanical friction of the drive unit 20 can be used as a check mechanism.

  Further, in the above-described embodiment, since the drive unit 20 including the clutch mechanism 25 is applied, there is no possibility that the operability when performing the manual operation is impaired, but the drive unit necessarily includes the clutch mechanism. No need.

  Further, in the above-described embodiment, the drive unit 20 including two sets of the two clutch plates 271 and 272 and the roller 28 is illustrated, but the combination of the two clutch plates 271 and 272 and the roller 28 There may be three or more.

Reference Signs List 10 hinge 11 hinge shaft 11a groove 14 needle bearing 15 coil spring 16 retainer 20 drive unit 21 electric motor 21a output shaft 22 first reducer 24 second reducer 26 driven shaft 30 output arm 31 opening / closing link arm A space B vehicle body D Side door DM Door body DMF Front G Window glass P Pillar WG Lifting guide

Claims (6)

A door opening and closing device for opening and closing a side door supported on a side surface of a vehicle body via a hinge,
A drive unit is disposed in a space between an elevation guide of a window glass and an end surface of the side door to which the hinge is attached inside the side door,
The drive unit reduces the rotation of the drive source through a first reduction gear and a second reduction gear each including a planetary gear mechanism, and the first reduction gear and the second reduction gear both rotate a sun gear. its Rutotomoni second deceleration output shaft of the axis and the second reduction gear is configured so that its extension to the output shaft of the driving source, the final output shaft to the output shaft of the driving source Disposed on an extension, further between the second deceleration output shaft and the final output shaft, while transmitting the torque to the final output shaft when the second deceleration output shaft rotates, while the final output shaft is A clutch mechanism configured to cut off torque to the second deceleration output shaft when rotated,
The clutch mechanism,
A meshing cylinder portion provided on the final output shaft so as to surround the periphery of the second deceleration output shaft,
The second deceleration output shaft and the final output shaft are disposed between the second deceleration output shaft and the meshing cylinder in a state where the second deceleration output shaft and the final output shaft can rotate relative to each other. A clutch drum having a concave portion that opens toward, and a clutch plate movably supported by a clutch plate at portions that are both ends along the circumferential direction of the concave portion,
A roller disposed in the recess in a state of contacting each of the two clutch plates;
A separate clutch spring for urging the roller to abut on the inner peripheral surface of the meshing cylinder portion via the clutch plate;
An arcuate surface and a meshing surface are provided alternately on the inner peripheral surface of the meshing tube portion, and the meshing surface is configured such that a distance from an axis of the meshing tube portion is smaller than the arcuate surface,
When the two clutch plates move in a direction away from the inner peripheral surface of the meshing cylindrical portion against the biasing force of the clutch spring, the rollers move toward the inner peripheral side at least by the amount of protrusion of the meshing surface. To allow them to move,
The second deceleration output shaft is provided with a cam member that protrudes from an outer peripheral surface toward an inner peripheral surface of the final output shaft and has two control units facing the two clutch plates,
When the second deceleration output shaft rotates in the first direction, one control unit is separated from one clutch plate, while the other control unit contacts the roller via the other clutch plate. The clutch drum and the roller rotate in a first direction and the roller comes into contact with a meshing surface of the meshing cylindrical portion,
When the second deceleration output shaft rotates in the second direction, the other control unit is separated from the other clutch plate, while the one control unit is connected to the roller via the one clutch plate. The door opening / closing device, wherein the clutch drum and the roller rotate in the second direction when the roller comes into contact, and the roller comes into contact with a meshing surface of the meshing tubular portion . The drive unit, together with the final output shaft is accommodated inside the side door in the state along the rotational axis of the hinge, providing an output arm along the radial direction to the final output shaft of the drive unit, wherein The door opening / closing device according to claim 1, wherein an output arm is connected to the vehicle body.   3. The vehicle according to claim 2, wherein the hinge is provided at an interval between the side door and the vehicle body, and the output arm is connected to the vehicle body at a portion between the hinges. A door opening / closing device according to claim 1.   The door opening / closing device according to any one of claims 1 to 3, wherein a check mechanism for controlling an opening angle of the side door is provided on the hinge.   The door opening / closing device according to claim 2 or 3, wherein a check link mechanism for controlling an opening angle of the side door is provided between the side door and the vehicle body.   The door opening / closing device according to claim 5, wherein the output arm is connected to the vehicle body via a link arm, and the check link mechanism is provided on the output arm or the link arm.

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