JP4045085B2 - Electronic equipment and drive mechanism - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic device and a drive mechanism.
[0002]
[Prior art]
Conventionally, display panels (liquid crystal monitors and the like) are used in in-vehicle electronic devices such as in-vehicle televisions and navigation devices. As a vehicle-mounted electronic device using such a display panel, a model of a type that can store the display panel in a main body is also known. This type of vehicle-mounted electronic device stores the display panel in a storage unit in the main body when not in use, and moves the display panel (slide movement, tilt movement, etc.) to the use position on the front surface of the main body when in use.
[0003]
An example of such an in-vehicle electronic device is shown in FIG. FIG. 5 is an external perspective view showing a state in which the display panel 91 has been moved to the use position on the front surface of the main body 92. In general, the in-vehicle electronic device includes a display panel 91, a main body 92, and an arm 93.
[0004]
The display panel 91 is rotatably supported by the main body 92 via the arm 93. The display panel 91 is provided with a tilt gear or the like on the back surface, and this tilt gear meshes with a transmission gear (a part of a mechanical assembly described later) disposed in the main body 92. As the transmission gear rotates, the tilt gear rotates, and the display panel 91 rotates about the support shaft of the arm 93.
[0005]
The main body 92 includes a storage unit that stores the display panel 91 and the like, a control circuit that controls display of the display panel 91, and the like, and slidably holds a mechanical assembly including the arm 93.
In addition to the arm 93, this mechanical assembly includes a slide movement mechanism and a tilt movement mechanism. The slide moving mechanism includes a slide motor, a coaxial gear, and the like for sliding the mechanical assembly in the main body 92. The tilt movement mechanism is composed of a tilt motor, a transmission gear, etc. for tilting the display panel 91.
[0006]
The arm 93 moves while holding the display panel 91 when the mechanical assembly slides, and appropriately holds the display panel 91 that rotates about the support shaft when tilting.
[0007]
Hereinafter, the operation of such a conventional vehicle-mounted electronic device will be described with reference to FIG. FIGS. 6A to 6D are schematic diagrams for explaining how the display panel 91 moves from the storage position in the main body 92 to the use position on the front surface of the main body 92.
In addition, the vehicle-mounted electronic device shall be attached to the storage location in a vehicle (for example, opening part of an instrument panel).
[0008]
First, when the slide movement mechanism of the mechanical assembly starts driving in a state where the display panel 91 is housed in the main body 92, the display panel 91 is moved to the front surface of the main body 92 (arrow method) as shown in FIG. Move towards the slide.
Then, as shown in FIG. 6B, when the display panel 91 is completely discharged from the main body 92, the slide moving mechanism stops its driving. This time, the tilt moving mechanism of the mechanical assembly starts to drive.
As the tilt movement mechanism is driven, the rotational driving force is transmitted to the tilt gear of the display panel 91, and the display panel 91 rotates to rise in the direction of the arrow as shown in FIG. Up).
[0009]
The display panel 91 continues the tilting operation as the tilt moving mechanism is driven, and tilts up to a use position orthogonal to the arm 93, for example, as shown in FIG. When the display panel 91 is rotated to this use position, the tilt moving mechanism stops its driving.
Thus, the conventional in-vehicle electronic device can move the display panel 91 housed in the main body 92 to the use position on the front surface of the main body 92 when the user uses it.
[0010]
[Problems to be solved by the invention]
However, in the above-described in-vehicle electronic device, the use position of the display panel 91 may not be an appropriate position.
For example, as shown in FIG. 6D, in the case where an air outlet 94 of an air conditioner is arranged on the upper part of a main body 92 stored in the vehicle, the display panel 91 stopped at the use position causes the air outlet 94 to be opened. It will block and prevent discharge of cold air or the like from the air outlet 94.
In addition, the display panel 91 stopped at the use position may interfere with the user's button operation of the main body 92 and the insertion / ejection of media.
[0011]
The present invention has been made in view of the above circumstances, and an object thereof is to provide an electronic device and a driving mechanism capable of appropriately adjusting a use position of a display panel.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, an electronic device according to the first aspect of the present invention provides:
A display panel in which a rack gear having a guide groove formed on a side surface is fixed to the back surface of the display surface;
A panel holding portion in which the display panel is slidably held via a roller fitted into a guide groove of the display panel, and a hinge is formed at an end portion,
A holding drive unit that rotatably holds the panel holding unit via a hinge of the panel holding unit and transmits a predetermined driving force by a transmission gear and a coaxial gear that are pivotally supported, and
A slide rack gear that meshes with a coaxial gear of the holding drive unit is fixed, and a main body that slidably holds the holding drive unit by a driving force transmitted by the coaxial gear of the holding drive unit. There,
The holding drive unit rotates a coaxial gear with a predetermined motor, slides the panel holding unit together with the display panel in a horizontal direction with respect to the main body,
The panel holding portion includes a lock member that engages with the display panel and locks the slide movement of the display panel, and the display member is rotated by the lock member via a hinge. Stop sliding the panel,
When the panel holding member is rotated to a position substantially orthogonal to the main body, the lock member comes into contact with the holding drive unit to disengage the display panel,
When the panel holding portion rotates to a position substantially orthogonal to the main body, the rack gear of the display panel is engaged with the transmission gear of the holding driving portion, and the engagement with the display panel by the lock member is released. In this state, the display panel is slid according to the driving force transmitted from the transmission gear of the holding drive unit.
It is characterized by that.
[0013]
In order to achieve the above object, the drive mechanism according to the second aspect of the present invention provides:
A display panel in which a rack gear having a guide groove formed on a side surface is fixed to the back surface of the display surface;
A panel holding portion in which the display panel is slidably held via a roller fitted into a guide groove of the display panel, and a hinge is formed at an end portion,
A holding drive unit that rotatably holds the panel holding unit via a hinge of the panel holding unit and transmits a predetermined driving force by a transmission gear and a coaxial gear that are pivotally supported, and
A main body that slidably holds the holding drive unit by a driving force transmitted by the coaxial gear of the holding drive unit, and a slide rack gear that meshes with the coaxial gear of the holding drive unit. A drive mechanism,
The holding drive unit rotates a coaxial gear with a predetermined motor, slides the panel holding unit together with the display panel in a horizontal direction with respect to the main body,
The panel holding portion includes a lock member that engages with the display panel and locks the slide movement of the display panel, and the display member is rotated by the lock member via a hinge. Stop sliding the panel,
When the panel holding member is rotated to a position substantially orthogonal to the main body, the lock member comes into contact with the holding drive unit to disengage the display panel,
When the panel holding portion rotates to a position substantially orthogonal to the main body, the rack gear of the display panel is engaged with the transmission gear of the holding driving portion, and the engagement with the display panel by the lock member is released. In this state, the display panel is slid according to the driving force transmitted from the transmission gear of the holding drive unit.
It is characterized by that.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
An in-vehicle electronic device provided with a movable display panel (display monitor) according to an embodiment of the present invention will be described below with reference to the drawings.
[0018]
FIG. 1A is a plan view for explaining the configuration (internal structure) of an in-vehicle electronic device. FIG. 1B is a side view of the display panel 1. FIG. 1 is a diagram showing a state where the display panel 1 is not tilted up. When the display panel 1 is manually tilted up as will be described later, the surface (display surface) faces the front as in the conventional vehicle-mounted electronic device shown in FIG.
[0019]
Returning to FIG. 1, the on-vehicle electronic device is schematically configured to include a display panel 1, a panel holding assembly 2, a mechanical assembly 3, and a main body 4 as shown in the figure.
[0020]
The display panel 1 is, for example, a panel (monitor) in which an LCD (Liquid Crystal Display) unit or the like is disposed on the front surface (the bottom surface in FIG. 1), and is controlled by a control circuit (not shown) in the main body 4. Predetermined characters and graphic information are displayed.
Further, two upper and lower slide rack gears 11 are fixedly disposed on the rear surface of the display panel 1 as shown in FIG.
[0021]
When the display panel 1 is tilted up, the upper and lower slide rack gears 11 mesh with transmission gears (transmission gears 36a and 36b of the panel holding assembly 2) described later, and slide along with the display panel 1 as the transmission gears rotate. To do.
Moreover, as shown in FIG.1 (b), the up-and-down slide rack gear 11 has the guide groove 12 carved in the side surface. A guide roller (guide roller 22 of the panel holding assembly 2), which will be described later, is fitted in the guide groove 12, and the display panel 1 is slidably held by the panel holding assembly 2.
Further, a notch (not shown) for engaging with a panel lock member (a panel lock member 21 of the panel holding assembly 2) to be described later is formed on the back surface of the display panel 1.
[0022]
As shown in FIG. 2A, the panel holding assembly 2 includes an upper surface plate 2a, two side surface plates 2b, and a slope plate 2c inclined at a predetermined angle with respect to the upper surface plate 2a. Is supported by the mechanical assembly 3 so as to be rotatable.
Specifically, the panel holding assembly 2 holds the panel lock member 21 in a freely rotatable manner in a hole 2d engraved across the upper surface plate 2a and the slope plate 2c. In addition, two (four in total) guide rollers 22 are pivotally supported inside each side plate 2b. Furthermore, the hinge 23 is provided in the edge part of the slope board 2c.
[0023]
As shown in FIG. 2B, the panel lock member 21 is a member in which a claw portion 21a, a protruding portion 21b, a shaft hole 21c, and a pin 21d are formed in a substantially rectangular parallelepiped shape.
The panel lock member 21 is rotatable by the panel holding assembly 2 by fitting a predetermined support shaft provided in the hole 2d of the panel holding assembly 2 into the shaft hole 21c with the spring 21e interposed therebetween. Retained. At that time, since the spring 21e is hooked and fixed on the pin 21d, the panel lock member 21 is urged toward the tip of the claw portion 21a by the restoring force of the spring 21e. The panel lock member 21 rotates about the shaft hole 21c, and the claw portion 21a engages with a notch formed on the back surface of the display panel 1.
When the projection 21b is pressed, the projection 21b rotates in the reverse direction around the shaft hole 21c, and the engagement between the notch and the claw 21a is released.
[0024]
The guide roller 22 is rotatably supported on the inner side of the side plate 2b, and is fitted into the guide groove 12 of the vertical slide rack gear 11 as shown in FIG. The panel holding assembly 2 holds the display panel 1 slidably along the guide groove 12.
In the state where the claw portion 21a of the panel lock member 21 is engaged with the notched portion engraved on the back surface of the display panel 1, the display panel 1 cannot be slid, and the projection 21b is pressed. Thus, the display panel 1 can be slid in a state in which the engagement between the notch portion and the claw portion 21a is released.
[0025]
The hinge 23 is joined to the end of the mechanical assembly 3. The panel holding assembly 2 is rotatably held by the mechanical assembly 3 via the hinge 23.
[0026]
Returning to FIG. 1, the mechanical assembly 3 slides the display panel 1 in the horizontal direction with respect to the main body 4, and the tilted-up display panel 1 is moved in the vertical direction (perpendicular to the main body 4). Drive mechanism for sliding in the direction). Specifically, the mechanical assembly 3 includes, on a predetermined mechanical chassis, two side arms 31, a horizontal slide motor 32, coaxial gears 33a and 33b, a connecting shaft 34, a vertical slide motor 35, a transmission gear 36a, 36b is arranged.
Since the end of the mechanical assembly 3 is coupled to the panel holding assembly 2 by the hinge 23 described above, the mechanical assembly 3 rotatably holds the display panel 1 via the panel holding assembly 2. .
[0027]
The two side arms 31 pivotally support coaxial gears 33a and 33b and transmission gears 36a and 36b.
The horizontal slide motor 32 is disposed in the vicinity of the coaxial gear 33a and meshes with the coaxial gear 33a via, for example, a helical gear fitted to the rotation shaft. The horizontal slide motor 32 transmits the driving force generated by the rotational drive to the coaxial gear 33a and the like.
[0028]
The coaxial gears 33 a and 33 b are pivotally supported by the connecting shaft 34. The connecting shaft 34 is sandwiched between the two side arms 31.
The coaxial gear 33a meshes with the helical gear or the like of the horizontal slide motor 32 described above. The coaxial gears 33a and 33b mesh with slide rack gears (two slide rack gears 41 of the main body 4) described later. When the horizontal slide motor 32 is rotationally driven, a driving force is transmitted to the coaxial gear 33 a and the coaxial gears 33 a and 33 b are rotated together by the connecting shaft 34. As the coaxial gears 33a and 33b rotate, the mechanical assembly 3 slides in the horizontal direction on the sliding rack gears that mesh with each other.
At that time, the display panel 1 slides in the horizontal direction together with the panel holding assembly 2 coupled to the mechanical assembly 3 by the hinge 23. That is, according to the rotation direction of the horizontal slide motor 32, the display panel 1 horizontally moves in either the discharge direction (L direction in the figure) or the storage direction (R direction in the figure).
[0029]
The vertical slide motor 35 is disposed in the vicinity of the transmission gear 36a and meshes with the transmission gear 36a via, for example, a helical gear fitted to the rotation shaft. The vertical slide motor 35 transmits the driving force generated by the rotational drive to the transmission gear 36a.
[0030]
The transmission gears 36a and 36b are pivotally supported by the side arm 31 described above. Further, the transmission gear 36a meshes with the helical gear or the like of the above-described vertical slide motor 35.
Further, as shown in FIG. 3, the transmission gear 36a (transmission gear 36b) meshes with the above-described vertical slide rack gear 11 in a state where the display panel 1 is tilted up. As the vertical slide motor 35 is driven to rotate, the transmission gear 36a rotates, so that the display panel 1 slides in the vertical direction together with the meshed vertical slide rack gear 11.
[0031]
Returning to FIG. 1, although not shown, the main body 4 is provided with a storage section for storing the display panel 1 and the like, a control circuit for controlling display of the display panel 1 (LCD unit and the like), and the like. Similarly, a drive circuit for driving the horizontal slide motor 32 and the vertical slide motor 35 is also arranged.
In addition, two slide rack gears 41 are fixedly disposed on the main body 4.
[0032]
The slide rack gear 41 meshes with the coaxial gears 33a and 33b. That is, the main body 4 slidably holds the mechanical assembly 3 via the sliding rack gear 41 and the like.
[0033]
The specific operation of the in-vehicle electronic device according to this embodiment will be described below with reference to FIG. 4A to 4E are schematic diagrams for explaining the operation until the display panel 1 stored in the main body 4 is arranged at the use position on the front surface of the main body 4. FIG. In addition, the vehicle-mounted electronic device shall be attached to the storage location in a vehicle (for example, opening part of an instrument panel).
[0034]
First, in a state where the display panel 1 is housed inside the main body 4, the horizontal slide motor 32 is driven to rotate, and the mechanical assembly 3 slides. That is, the rotational driving force of the horizontal slide motor 32 is transmitted to the coaxial gear 33a, and the coaxial gears 33a and 33b rotate together. Then, the mechanical assembly 3 slides on the sliding rack gear 41 by the rotation of the coaxial gears 33a and 33b.
As the mechanical assembly 3 moves, the display panel 1 slides toward the front surface (arrow direction) of the main body 4 as shown in FIG.
[0035]
When the display panel 1 (mechanical assembly 3) moves to a predetermined position, the horizontal slide motor 32 stops rotating. That is, as shown in FIG. 4B, when the display panel 1 reaches a predetermined position where the display panel 1 is completely discharged to the front surface of the main body 4, the rotation of the horizontal slide motor 32 is caused by, for example, pressing a micro switch. Stops.
[0036]
In this state, the user manually tilts up the display panel 1. That is, since the panel holding assembly 2 is rotatably held with the mechanical assembly 3 by the hinge 23, the display panel 1 pushed by the user is brought together with the panel holding assembly 2 as shown in FIG. Rotate.
At this time, even if the display panel 1 is rotated and inclined, the claw portion 21a of the panel lock member 21 is engaged with a notch formed on the back surface of the display panel 1 (protrusion portion). In a state where 21b is not pressed), the display panel 1 does not slide.
[0037]
The display panel 1 continues to tilt while being pushed by the user, and rotates to a position orthogonal to the main body 4, for example, as shown in FIG. When the display panel 1 rotates to this position, the upper and lower slide rack gears 11 mesh with the transmission gears 36a and 36b.
At this time, the protrusion 21 b of the panel lock member 21 is pressed by the end of the mechanical assembly 3. For this reason, the panel lock member 21 rotates to disengage the claw portion 21a from the notch portion of the display panel 1, the panel holding assembly 2 can be moved, and the tilt operation of the display panel 1 is completed ( No further rotation is possible).
[0038]
When the tilting operation of the display panel 1 is completed, the vertical slide motor 35 is rotationally driven by, for example, pressing the panel up / down button by the user, and the display panel 1 has a main body as shown in FIG. 4 slidably move in the direction of the arrow while being orthogonal to 4. That is, as the vertical slide motor 35 is driven, the transmission gear 36 a rotates while meshing with the vertical slide rack gear 11, whereby the display panel 1 moves up and down.
[0039]
By this vertical slide movement, the display panel 1 moves to a use position arbitrarily designated by the user (for example, a position that does not cover the air outlet or the like of the air conditioner). As a result, the use position of the display panel can be adjusted appropriately.
[0040]
In the above embodiment, since the display panel 1 is slid by the panel lift button or the like, the user needs to operate the panel lift button or the like every time. However, since the user generally uses the display panel 1 at the same use position, once the user has stored an arbitrary use position, the user may automatically move to the use position from the next time.
For example, when the tilt operation of the display panel 1 is completed, the vertical slide motor 35 starts to be driven by pressing a micro switch or the like. When the display panel is automatically moved to the stored use position, the vertical slide motor 35 automatically stops driving.
In this case, the operation burden on the user can be reduced.
[0041]
In addition, the display panel 1 stopped at the use position may interfere with the user's button operation of the main body 4 and media insertion / ejection. In such a case, for example, the user presses the panel up / down button to raise the display panel 1 to the tilted up position (tilt up end position), and performs the button operation of the main body 4 and the insertion / ejection of the media. Do. Then, the panel lift button is pressed again to return the display panel 1 to the use position.
In order to omit such a button operation again, the display panel 1 moved to the tilt up end position may be automatically returned to the use position.
For example, when moving to the tilt-up end position, time measurement is started with a predetermined timer, and when a predetermined time (which can be arbitrarily set) has elapsed, the vertical slide motor 35 starts driving and displays the stored use position. Move panel 1 automatically.
[0042]
Furthermore, the display panel 1 may be automatically slid up and down without operating the panel up / down button when inserting media or the like.
For example, when a media detection sensor or the like is installed on the display panel 1 and the user brings the media close to the insertion slot, the media detection sensor detects the approach of the media. In response to this, the vertical slide motor 35 starts to drive, and the display panel 1 is automatically raised to the tilt up end position.
In this case as well, when the predetermined time has elapsed after moving to the tilt up end position, the display panel 1 is automatically returned to the stored use position.
[0043]
Thus, since the above-described in-vehicle electronic device holds the display panel 1 with the panel holding assembly 2 (guide roller 22), it is possible to suppress the backlash of the display panel 1 and to improve the mechanical strength. it can.
In addition, since the drive system is gathered in one place, space saving can be realized and wiring can be easily routed.
Further, since the tilting operation of the display panel 1 can be performed manually, the mechanical strength is improved and the space can be saved and the cost can be reduced as compared with the conventional in-vehicle electronic device. .
[0044]
Further, the panel lock member 21 allows the display panel 1 to move only during the up / down sliding operation, and the display panel 1 is fixed to the panel holding assembly 2 during other operations. For this reason, the backlash of the display panel 1 can be suppressed during the tilt operation or the horizontal slide operation.
When the display panel 1 is rotated to the tilt up end position (tilt up), the panel lock member 21 automatically disengages the display panel 1 from the panel holding assembly 2. On the other hand, when the display panel 1 is tilted down, the display panel 1 and the panel holding assembly 2 are automatically engaged. For this reason, the user does not need to operate the engagement (lock) of the display panel 1 and the panel holding assembly 2 separately.
[0045]
In addition, by storing the use position of the display panel 1, the user can automatically move the display panel 1 to the stored use position only by manually tilting the display panel 1 up.
In addition, when the display panel 1 moves from the use position to the tilt-up end position after a predetermined time (can be arbitrarily set) has elapsed, the display panel 1 is automatically returned to the use position so that the user's The operation burden can be reduced.
[0046]
Thus, according to the above-described in-vehicle electronic device, the use position of the display panel can be appropriately adjusted.
[0047]
In the above embodiment, the case where all the drive systems are arranged in the mechanical assembly 3 has been described. However, a part of the drive system, for example, the transmission gears 36 a and 36 b and the like, together with the upper and lower slide rack gears 11, May be arranged. In this case, the transmission gears 36a and 36b and the upper and lower slide rack gears 11 are always meshed so that the driving force of the upper and lower slide motor 35 is transmitted to the transmission gear 36a and the like when the display panel 1 is tilted up.
[0048]
【The invention's effect】
As described above, according to the present invention, the use position of the display panel can be adjusted appropriately.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of the configuration (internal structure) of an in-vehicle electronic device according to an embodiment of the present invention, where (a) is a plan view and (b) is a side view.
2A is a perspective view of a panel holding assembly, and FIG. 2B is a perspective view of a panel lock member.
FIG. 3 is a schematic diagram showing how the transmission gear meshes with the vertical slide rack gear when the display panel is tilted up.
FIGS. 4A to 4E are schematic views for explaining a specific operation of the in-vehicle electronic device.
FIG. 5 is an external perspective view showing an example of a conventional in-vehicle electronic device.
FIGS. 6A to 6D are schematic views for explaining the operation of a conventional in-vehicle electronic device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Display panel 2 Panel holding assembly 3 Mechanical assembly 4 Main body 11 Vertical slide rack gear 12 Guide groove 21 Panel lock member 22 Guide roller 31 Side arm 32 Horizontal slide motor 33a, 33b Coaxial gear 34 Connecting shaft 35 Vertical slide motor 36a, 36b Transmission gear 41 Rack gear for slide

Claims (2)

A display panel in which a rack gear having a guide groove formed on a side surface is fixed to the back surface of the display surface;
A panel holding portion in which the display panel is slidably held via a roller fitted into a guide groove of the display panel, and a hinge is formed at an end portion,
A holding drive unit that rotatably holds the panel holding unit via a hinge of the panel holding unit and transmits a predetermined driving force by a transmission gear and a coaxial gear that are pivotally supported, and
A slide rack gear that meshes with the coaxial gear of the holding drive unit, and a main body that slidably holds the holding drive unit by a driving force transmitted by the coaxial gear of the holding drive unit. There,
The holding drive unit rotates a coaxial gear with a predetermined motor, slides the panel holding unit together with the display panel in a horizontal direction with respect to the main body,
The panel holding portion includes a lock member that engages with the display panel and locks the slide movement of the display panel, and the display member is rotated by the lock member via a hinge. Stop sliding the panel,
When the panel holding member is rotated to a position substantially orthogonal to the main body, the lock member comes into contact with the holding drive unit to disengage the display panel,
When the panel holding portion is rotated to a position substantially orthogonal to the main body, the rack gear of the display panel is engaged with the transmission gear of the holding driving portion, and the engagement with the display panel by the lock member is released. In this state, the display panel is slid according to the driving force transmitted from the transmission gear of the holding drive unit.
An electronic device characterized by that. A display panel in which a rack gear having a guide groove formed on a side surface is fixed to the back surface of the display surface;
A panel holding portion in which the display panel is slidably held via a roller fitted into a guide groove of the display panel, and a hinge is formed at an end portion,
A holding drive unit that rotatably holds the panel holding unit via a hinge of the panel holding unit and transmits a predetermined driving force by a transmission gear and a coaxial gear that are pivotally supported, and
A main body that slidably holds the holding drive unit by a driving force transmitted by the coaxial gear of the holding drive unit, and a slide rack gear that meshes with the coaxial gear of the holding drive unit. A drive mechanism,
The holding drive unit rotates a coaxial gear with a predetermined motor, slides the panel holding unit together with the display panel in a horizontal direction with respect to the main body,
The panel holding portion includes a lock member that engages with the display panel and locks the slide movement of the display panel, and the display member is rotated by the lock member via a hinge. Stop sliding the panel,
When the panel holding member is rotated to a position substantially orthogonal to the main body, the lock member comes into contact with the holding drive unit to disengage the display panel,
When the panel holding portion rotates to a position substantially orthogonal to the main body, the rack gear of the display panel is engaged with the transmission gear of the holding driving portion, and the engagement with the display panel by the lock member is released. In this state, the display panel is slid according to the driving force transmitted from the transmission gear of the holding drive unit.
A drive mechanism characterized by that.

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