JP2015191678A - disk device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disk device capable of preventing a shutter member from rattling at the time when the shutter member is moved to a retracted position.SOLUTION: The disk device is configured in such a manner that: when a shutter switching member 61 moves in a direction Y1, a restriction concavity 61b goes away from a holding pin 57 and a shutter member 55 is pivoted in a direction φ2 by an elastic arm 56c of a shutter spring 56 so as to be in a retracted position; and when the shutter switching member 61 moves to the direction Y1, the tip part of the elastic arm 56c is applied with pressure in the direction Y1 by a spring pressurization part 61e and force to energize the shutter member 55 to a direction φ1 is increased. With such a configuration, it becomes possible to suppress a rattling sound of the shutter member 55 from generating due to vibration of a vehicle body and the like.

Description

  The present invention relates to a disk device in which a shutter member for preventing supply of a disk is provided at a front portion of a housing.

  A disk device used for in-vehicle use or the like is a so-called slot-in system in which a disk is inserted in a direction along the disk surface from an insertion port at the front of a housing.

  In the disk device disclosed in Patent Document 1, a disk supplied from an insertion port in front of the casing is transferred by the rotational force of the transport roller and is carried into the casing.

  A side slider is provided inside the housing, and the side slider starts to move when the center of the disk moves on the turntable. As the side slider moves, the clamper is lowered, the center of the disk is clamped by the turntable and the clamper, and the roller bracket supporting the transport roller is rotated by the moving force of the side slider. The transport roller is lowered and separated from the disk.

  A shutter member is rotatably supported at the front portion of the housing. When the disk is carried in or out, the shutter member is moved to the open state away from the insertion port by the spring member. When the disk is clamped to the rotation drive unit, the shutter member is rotated halfway toward the insertion port against the biasing force of the spring member by the rotational force of the roller bracket rotated by the side slider. Be made. Thereafter, the shutter member is directly pressed by the shutter pressing portion of the side slider, and the shutter member is moved to a position where the insertion port can be closed.

JP 2009-301687 A

  In the disk device described in Patent Document 1, when the disk is loaded or unloaded, the shutter member is moved to an open state away from the insertion port by the biasing force of the spring member. The elastic force of the spring member at this time becomes weaker than when the shutter member is rotated in the closed state.

  Therefore, when the vehicle body vibration acts, there is a problem that the shutter member in the open state vibrates and generates rattling noise.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described conventional problems, and an object of the present invention is to provide a disk device that can suppress rattling of the shutter member when the shutter member is in a retracted position that does not hinder the supply of the disk.

The present invention relates to a rotation drive unit disposed inside a housing, a transport mechanism for carrying a disk supplied from the front part of the housing into the rotation drive unit, and a disk from the front part of the housing. In a disk device provided with a shutter member for blocking supply,
The shutter member is movably supported between a blocking position for blocking the disk supply path and a retracted position for retracting from the supply path to enable disk supply, and an elastic arm is hung on the shutter member. The shutter member is biased to the retracted position by the elastic arm,
A shutter switching member is provided that moves in a first direction for restraining the shutter member to the blocking position and in a second direction for releasing the restraint. When the shutter member moves to the retracted position, the shutter switching member moves in the second direction. The elastic arm is pushed by the moving shutter switching member, and the shutter member is pushed to the retracted position by the elastic force of the elastic arm.

  In the disk device of the present invention, when the shutter member is in the retracted position, the moving force of the shutter switching member in the second direction acts on the shutter member via the elastic arm, and biases the shutter member to the retracted position. Since the elastic force is enhanced, the shutter member is less likely to be rattled by vehicle body vibration.

In the present invention, the elastic arm is a part of a torsion spring.
However, the elastic arm may be a wire spring or a leaf spring.

  In the present invention, the shutter member is rotatably supported and is urged in the rotational direction toward the retracted position by the elastic arm.

  According to the present invention, the shutter switching member is provided with a constraining concave portion that constrains a part of the shutter member when the shutter switching member moves in the first direction, and the shutter member moves in the second direction. In addition, it is preferable that the constraining recess is separated from the shutter member.

  In the above configuration, even when the moving distance of the shutter switching member is short, the shutter member can be moved to the blocking position and the retracted position.

  In the present invention, the shutter switching member is moved in the first direction by the biasing force of the shutter spring, and the shutter spring is more elastic than the elastic force by which the elastic arm rotates the shutter member to the retracted position. It can be configured that the elastic force for moving the switching member in the first direction is set stronger.

  In the disk device of the present invention, when the shutter member is moved to the retracted position by the elastic force of the elastic arm, the elastic force of the elastic arm is increased, so that the shutter member is less likely to vibrate. Therefore, it becomes easy to suppress the rattling noise from being generated by the shutter member due to body vibration.

The top view which shows the disc apparatus of embodiment of this invention, FIG. 2 is a left side view including a partial cross section of the disk device shown in FIG. 1 as viewed from the left side, showing a disk clamp state; FIG. 2 is a partial left side view of the disk device shown in FIG. FIG. 2 is a partial left side view of the disk device shown in FIG. 1 as viewed from the left side, showing a clamped state of the disk; It is the partial left view which shows operation | movement of a shutter switching mechanism, (A) shows the clamp release state of a disc, (B) shows the clamp state of a disc, It is a partial enlarged perspective view showing a shutter member and a shutter switching mechanism, and shows a disc clamp release state, It is a partial enlarged perspective view showing a shutter member and a shutter switching mechanism, and shows a clamped state of a disk.

  In the disk device 1 according to the embodiment of the present invention, the Y1 direction is the loading direction (rear), the Y2 direction is the unloading direction (front), the X1 direction is the left side, and the X2 direction is the right side. Further, the Z1 direction is upward and the Z2 direction is downward.

  The disk device 1 has a housing 2. The housing | casing 2 is formed with the metal plate. As shown in FIG. 2, the housing 2 faces the ceiling plate 3 and the bottom plate 4, the front plate 5 located in the front part facing in the carry-out direction (front: Y2 direction), and the carry-in direction (rear: Y1 direction). And a rear plate 6. As shown in FIG. 1, the housing 2 includes a left side plate 7 a that constitutes a side portion on the X1 side and a right side plate 7 b that constitutes a side portion on the X2 side. The housing 2 has a so-called 1 DIN volume, and when used for in-vehicle use, the housing 2 is installed inside the instrument panel of the automobile, and the front plate 5 is directed to the vehicle interior.

  As shown in FIG. 2, an opening 5 a is formed in the front plate 5 of the housing 2. As shown in FIGS. 1 and 2, a panel 8 is installed in front of the front plate 5. The panel 8 is a decorative panel, on which a display screen and various operation buttons are arranged. The panel 8 has an insertion / discharge port 8a.

  The disk D is carried into the housing 2 from the insertion / discharge port 8a through the opening 5a. Further, the disk D in the housing 2 is unloaded from the opening 5a through the insertion / discharge port 8a.

  As shown in FIGS. 1 and 2, a drive base 10 formed of a metal plate is housed inside the housing 2. The drive base 10 includes a drive plate portion 10a that is substantially parallel to the XY plane and drive side plates 10b and 10b that are bent on both sides in the left-right direction (X1-X2 direction). As shown in FIG. 2, the drive plate portion 10 a is supported by a compression coil spring 26 a installed on the bottom plate 4 in the rear (Y1 direction) inside the housing 2. As shown in FIG. 1, a plurality of damper members 26 b are provided inside the housing 2. The damper member 26b is a rubber flexible case in which a fluid such as oil is sealed. A support shaft fixed to the drive side plates 10b and 10b of the drive base 10 is supported by the damper member 26b. ing.

  The drive base 10 is elastically supported inside the housing 2 by an elastic support member including the compression coil spring 26a and the damper member 26b.

  A rotation drive unit 20 is mounted on the drive base 10. In the rotation drive unit 20, a spindle motor is fixed to the drive plate unit 10a of the drive base 10, and a turntable 21 is fixed to a rotation shaft 21a of the spindle motor.

  As shown in FIGS. 1 and 2, a left side support piece 11 is integrally formed on the left side (X1 side) of the rear side (Y1 direction) by bending the metal plate forming the drive base 10 upward. Yes. A support shaft 12 extending in the right direction (X2 direction) is integrally formed on the left support piece 11 by a mechanical forming method such as drawing. As shown in FIG. 1, a right support piece 13 is integrally formed on the right side (X2 side) of the rear side (Y1 direction), in which a metal plate that similarly forms the drive base 10 is bent upward. A shaft support hole is formed in the right support piece 13.

  A clamp arm 22 is disposed on the drive plate portion 10 a of the drive base 10. The clamp arm 22 is formed of a metal plate. As shown in FIGS. 1 and 2, the clamp arm 22 is integrally formed with a left arm side plate 23 bent downward on the left side (X1 side) in the rear (Y1 direction). A shaft support hole is formed in the left arm side plate 23, and this shaft support hole is rotatably supported by the support shaft 12 of the left support piece 11.

  As shown in FIG. 1, the clamp arm 22 is integrally formed with a right arm side plate 24 bent downward on the right side (X2 side) in the rear (Y1 direction). A support shaft 25 extending in the left direction (X1 direction) is integrally formed on the right arm side plate 24 by a mechanical forming method such as drawing. The support shaft 25 is rotatably supported in a shaft support hole formed in the right support piece 13.

  As shown in FIG. 1, the support shaft 12 formed integrally with the left support piece 11 and the support shaft 25 formed on the right arm side plate 24 are coaxially positioned in the X-axis direction. The clamp arm 22 is rotatable about the support shaft 12 and the support shaft 25 in the clamp release direction (α2 direction) shown in FIG. 3 and the clamp direction (α1 direction) shown in FIG. 4 on the drive base 10. It is supported.

  As shown in FIGS. 3 and 4, a support plate spring is fixed to the front end (Y2 direction) of the clamp arm 22, and the clamper 27 is rotatably supported by the support plate spring. The clamper 27 faces the upper side of the turntable 21.

  As shown in FIGS. 1 and 2, the drive base 10 is provided with a clamp spring 28 on the left side (X1 side). The clamp spring 28 is a torsion spring, and the winding center is supported by a spring support piece 18 formed on the drive base 10 as shown in FIG. One arm portion 28a of the clamp spring is hung on the clamp arm 22, and the other arm portion 28b is hung on the drive plate portion 10a of the drive base 10, so that the clamp arm 22 is always attached in the clamping direction (α1 direction). It is energized.

  In FIG. 4, the center hole Da of the disk D is installed on the turntable 21, the clamp arm 22 receives a biasing force in the α1 direction from the clamp spring 28, and the clamper 27 is pressed against the disk D. 21 and the clamper 27 hold the peripheral edge of the center hole Da of the disk D.

  As shown in all the drawings, a mode switching slider 30 is mounted on the drive base 10 on the left side (X1 side). The mode switching slider 30 is supported inside the drive side plate 10b of the drive base 10 so as to be linearly movable in the front-rear direction (Y1-Y2 direction). The mode switching slider 30 is provided so as not to hit the disk D at a position away from the disk D held by the rotary drive unit 20 in the left-right direction (X1-X2 direction). A switching motor is mounted on the drive base 10, and the mode switching slider 30 is moved in the Y1-Y2 direction by the driving force of the switching motor.

  As shown in FIGS. 2 to 5, the mode switching slider 30 is integrally formed with a clamp release member 31 protruding upward. A clamp control unit 29 that is bent downward is provided on the left side (X1 side) of the clamp arm 22. When the mode switching slider 30 moves in the Y1 direction and reaches the position shown in FIG. 3, the clamp control unit 29 is lifted upward by the clamp release member 31, and the clamp arm 22 rotates in the clamp release direction (α2 direction). As a result, the clamper 27 moves away from the disk D, and the holding of the disk D is released.

  A transport mechanism 40 is provided inside the front plate 5 of the housing 2. As shown in FIGS. 2 and 3, the transport mechanism 40 is provided with a roller bracket 41. The roller bracket 41 includes a guide plate portion 42 that extends in the left-right direction and a support side plate 43 that is bent downward at both left and right side portions thereof. As shown in FIG. 2, support shafts 17 are fixed to the front portions of the drive side plates 10 b on the left and right sides of the drive base 10. The support side plates 43 on both the left and right sides of the roller bracket 41 are supported by the support shaft 17, respectively, and the roller bracket 41 is rotatably supported in the β2 direction shown in FIG. 3 and the β1 direction shown in FIG. .

  As shown in FIGS. 2 and 3, a roller shaft 44 is rotatably supported on the Y1 side end portion of the support side plate 43 bent to the left and right sides of the roller bracket 41, and is combined with the outer periphery of the roller shaft 44. A conveyance roller 45 made of a rubber material is attached.

  As shown in FIGS. 2 and 3, in the transport mechanism 40, a facing member 46 is fixed to the lower side of the ceiling plate 3 of the housing 2. The facing member 46 is made of a synthetic resin material having a small friction coefficient. The lower surface of the facing member 46 is a sliding surface 46 a, and a shaft recess 46 b is formed in the sliding surface 46 a along the axial direction of the transport roller 45.

  The roller bracket 41 is biased in the β2 direction by a roller biasing spring (not shown). When no external force is applied to the roller bracket 41, the conveying roller 45 is pressed against the opposing member 46 by the urging force of the roller urging spring, as shown in FIG. D can be clamped.

  As shown in FIGS. 2 and 3, the transmission member 47 is disposed inside the drive side plate 10 b of the drive base 10. A support shaft 48 protruding inward is fixed to the drive side plate 10b, and a transmission member 47 is rotatably supported by the support shaft 48. A connecting recess 47a is formed at the end of the transmission member 47 on the Y2 side. A connecting shaft 49 is fixed to the support side plate 43 of the roller bracket 41, and the connecting recess 47a and the connecting shaft 49 are connected.

  As shown in FIGS. 3 and 4, the transmission member 47 is integrally formed with a protruding portion 47 b at the end on the Y1 side. A lifting cam portion 33 is formed integrally with an end portion of the mode switching slider 30 on the Y2 side. As shown in FIG. 4, when the mode switching slider 30 is moved forward (Y2 direction), the protruding portion 47b is lifted by the lifting cam portion 33, and the transmission member 47 is rotated in the γ1 direction. 47, the roller bracket 41 is rotated in the β1 direction against the biasing force of the roller biasing spring. As shown in FIG. 3, when the mode switching slider 30 moves in the Y1 direction, the lifting cam portion 33 moves away from the protruding portion 47b. Since the transmission member 47 and the roller bracket 41 have no restraining force, the roller bracket 41 is rotated in the β2 direction by the biasing force of the roller biasing spring.

  As shown in FIGS. 3 and 4, an upper restraint portion 51 is formed on the support side plate 43 of the roller bracket 41, and a latching protrusion 52 projects from a part of the upper restraint portion 51. A lower restraining portion 53 is formed on the support side plate 43 at a position facing the upper restraining portion 51. The roller bracket 41 functions as a restraining member. In addition, the restraining mechanism 50 is configured by the transmission member 47 and the roller bracket 41.

  As shown in FIGS. 2 and 4, a shutter member 55 is provided in front of the inside of the housing 2. As shown in FIG. 6, the shutter member 55 is formed of a metal plate, and includes a blocking plate portion 55a extending in the left-right direction (X direction) and a support plate portion 55b bent from the left and right sides of the blocking plate portion 55a. It is integrally formed.

  As shown in FIGS. 6 and 7, support protrusions 46 c are integrally formed on both sides of the facing member 46 in the left-right direction (X direction). A rotation hole 55c is formed at the end of each support plate 55b on the Y1 side. Each of the pair of rotation holes 55c is supported by the support protrusion 46c, and the shutter member 55 is supported so as to be rotatable in the φ1-φ2 direction with the support protrusion 46c as a fulcrum. As shown in FIG. 5A, the shutter member 55 is in the retracted position when it is rotated in the φ2 direction, and is in the blocking position when it is rotated in the φ1 direction as shown in FIG. 5B. As shown in FIGS. 2 and 4, when the shutter member 55 is moved to the blocking position, the blocking plate 55a faces the opening 5a and the insertion / discharge port 8 to block the disc insertion path.

  As shown in FIGS. 6 and 7, a shutter spring 56 is supported by the support protrusion 46 c extending from the facing member 46. The shutter spring 56 is a torsion spring, and includes a winding center portion 56a around which a spring wire is wound, and a pair of wire end portions 56b and 56d formed by extending both ends of the spring wire from the winding center portion 56a. Have. The tip portion of one line end portion 56b is bent at a substantially right angle to form an elastic arm 56c extending in the X1 direction.

  A winding center portion 56a of the shutter spring 56 is mounted on the outer periphery of the support protrusion 46c. A spring hook portion 55d is formed on the support plate portion 55b of the shutter member 55, and a base portion on the X2 side of the elastic arm 56c is hooked on the spring hook portion 55d. A spring support portion 46d is formed integrally with the opposing member 46, and the other line end portion 56d is hung on the spring support portion 46d.

  The torsion spring exerts an elastic force to expand the opposing angle between the line end portion 56b and the line end portion 56d by torsional elasticity. The shutter member 55 is always urged in the φ2 direction by this elastic force. The shutter spring 56 is provided only on the left side (X1 side) of the facing member 46 and is not provided on the right side (X2 side).

  As shown in FIGS. 5 to 7, a shutter switching mechanism 60 is provided inside the left side plate 7 a of the housing 2. The shutter switching mechanism 60 has a shutter switching member 61. As shown in FIG. 1, the shutter switching member 61 is supported so as to be linearly movable in the Y1-Y2 direction along the inner surface of the left side plate 7a of the housing 2. Regarding the moving direction of the shutter switching member 61, the Y2 direction is the first direction and the Y1 direction is the second direction. The shutter switching member 61 is disposed so as to overlap with members such as the drive side plate 10b and the transmission member 47 of the drive base 10 shown in FIG. 2, but in order to avoid the members from being overlapped and illustrated. In addition, the shutter switching member 61 is not shown in FIG. 2, but is shown separately in FIG.

  As shown in FIG. 5, a switching spring 62 is provided in the shutter switching mechanism 60. One end of the switching spring 62 is hooked on a spring hook 61 a formed on the Y1 side end of the shutter switching member 61, and the other end is a spring support formed on the ceiling plate 3 of the housing 2. It is hung on 3a. Due to the elastic force of the switching spring 62, the shutter switching member 61 is always urged in the Y2 direction. In FIG. 5, the switching spring 62 is a tension coil spring, but a torsion spring or the like may be used instead.

  As shown in FIG. 6, a constraining recess 61b is formed as a constraining portion at the end of the shutter switching member 61 on the Y2 side, and the end of the Y2 side is continuously inclined downward from the constraining recess 61b. An extending guide portion 61d is formed. A spring pressurizing portion 61e is formed in a concave shape on the Y1 side of the guide portion 61d. A holding pin 57 protrudes in the X1 direction and is fixed to the support plate portion 55b on the left side (X1 side) of the shutter member 55. As shown in FIGS. 5B and 7, when the shutter switching member 61 moves in the first direction (Y2 direction), the holding pin 57 is lifted by the guide portion 61 d and is held by the restraining recess 61 b and restrained. Is done.

  As shown in FIG. 5, a connecting portion 63 is provided at the end of the shutter switching member 61 on the Y1 side. The mode switching slider 30 is formed with a pressing portion 34. As shown in FIG. 1, the connecting portion 63 is formed by being bent in the X2 direction toward the inside of the housing 2, so that the connecting portion 63 can face the pressing portion 34.

Next, the operation of the disk device 1 will be described.
The disk device 1 can insert the disk D in the standby mode shown in FIGS. 3 and 5A and FIG. As shown in FIG. 3, in this standby mode, the mode switching slider 30 is moved in the Y1 direction, the clamp controller 29 is lifted by the clamp release member 31, and the clamp arm 22 is rotated in the α2 direction. The clamp release posture is set, and the clamper 27 is separated upward from the turntable 21.

  Further, the lifting cam portion 33 of the mode switching slider 30 is separated from the protruding portion 47b of the transmission member 47, and the roller bracket 41 is rotated in the β2 direction by the biasing force of the roller biasing spring. The transport roller 45 is pressed against the shaft recess 46 b of the facing member 46.

  The roller bracket 41 functions as a restraining member constituting the restraining mechanism 50, receives the biasing force of the roller biasing spring, causes the upper restraining portion 51 to abut against the inner surface of the ceiling plate 3 of the housing 2, and A hooking protrusion 52 is hooked on the ceiling board 3. Further, the lower restraining portion 53 is pressed against the inner surface of the bottom plate 4 of the housing 2. As a result, at least the front portion (Y2 side portion) of the drive base 10 is restrained inside the housing 2.

  As shown in FIG. 5A, in the standby mode, the pressing portion 34 of the mode switching slider 30 contacts the connecting portion 63, and the shutter switching member 61 together with the mode switching slider 30 moves in the second direction (Y1 direction). It has been moved. Since the restraining recess 61b of the shutter switching member 61 is separated from the holding pin 57 fixed to the support plate portion 55b of the shutter member 55, the shutter member 55 is rotated in the φ2 direction by the elastic force of the shutter spring 56 and retracted. Position. As shown in FIG. 6, the shutter member 55 rotated to the retracted position hits the stopper portion 58 and stops.

  At this time, since the blocking plate portion 55a moves away from the front opening 5a of the housing 2 and retreats downward, the disk D can be supplied into the housing 2 from the insertion / discharge port 8a and the opening 5a. become.

  The shutter spring 56, which is a torsion spring, has a torsional elastic force that weakens when the opening angle between the line end portion 56d and the elastic arm 56c is widened. Therefore, in the state of FIG. 6, the shutter member 55 is pressed against the stopper portion 58. The power is decreasing.

  Therefore, in the state of FIG. 6, the shutter switching member 61 is moved in the Y1 direction to a position where the tip of the elastic arm 56c of the shutter spring 56 can be further pressed in the Y1 direction by the spring pressurizing portion 61e. The elastic arm 56c has a base portion that is hooked on the spring hooking portion 55d of the shutter member 55 and a tip portion that is pushed in the Y1 direction by the spring pressing portion 61e, so that the elastic arm 56c that is a wire spring is bent and deformed. The shutter member 55 is further pressurized in the φ2 direction. With this applied pressure, the shutter member 55 is strongly pressed against the stopper portion 58, so that the shutter member 55 is unlikely to generate rattling noise even when vehicle body vibration or the like acts.

  In the standby mode, when the disk D is inserted into the housing 2 from the insertion / discharge port 8a and the opening 5a and is detected by a detection member provided in the housing 2, the transport motor is started. The rotational force of the transport motor is transmitted to the roller shaft 44 through a gear mechanism (not shown), and the roller shaft 44 is rotationally driven in the carry-in direction. The disk D is sandwiched between the transport roller 45 and the facing member 46 and is sent into the housing 2 by the rotational force of the transport roller 45.

  When the central portion of the loaded disk D moves onto the turntable 21 and is detected by the loading detection member, the switching motor is started and the power is transmitted to the mode switching slider 30, and the mode switching slider 30. Moves in the Y2 direction. In the moving process, as shown in FIG. 4, the clamp release member 31 of the mode switching slider 30 is separated from the clamp control unit 29, and the clamp arm 22 is rotated in the α1 direction by the urging force of the clamp spring 28, thereby clamping posture. Thus, the periphery of the center hole Da of the disk D is pressed against the turntable 21 by the clamper 27, and the disk D is clamped to the rotation drive unit 20.

  When the mode switching slider 30 moves forward to the position shown in FIG. 4, the projecting portion 47b is lifted by the lifting cam portion 33, and the transmission member 47 is rotated in the γ1 direction. With this rotational force, the roller bracket 41 is rotated in the β1 direction, and the conveying roller 45 is separated from the disk D. The conveyance roller 45 is separated from the disk D while rotating in the carry-in direction, and the conveyance motor stops and the conveyance roller 45 stops when the state shown in FIG. 4 is reached.

  Further, the upper restraining portion 51 and the lower restraining portion 53 of the roller bracket 41 are separated from the ceiling plate 3 and the bottom plate 4 of the housing 2, and the restraint by the restraining mechanism 50 is released, so that the drive base 10 is connected to the compression coil spring 26a and the damper member 26b. It will be in the state elastically supported by the elastic support member.

  In a state where the drive base 10 is elastically supported, the spindle motor of the rotation drive unit 20 rotates and the disk D is driven to rotate. Then, reproduction of information recorded on the disk D and information recording operation are performed by the head supported by the drive base 10.

  As shown in FIG. 5B, when the mode switching slider 30 moves in the Y2 direction, the shutter switching member 61 to which the urging force of the switching spring 62 is applied moves in the Y2 direction together with the mode switching slider 30. When the mode switching slider 30 reaches the end of movement in the Y2 direction, the pressing portion 34 formed on the mode switching slider 30 separates from the connecting portion 63 of the shutter switching member 61. In the state shown in FIG. However, it is moved in the Y2 direction only by the elastic force of the switching spring 62.

  In the process of moving the shutter switching member 61 in the Y2 direction, the guide portion 61d formed at the end of the shutter switching member 61 on the Y2 side hits the holding pin 57 provided on the shutter member 55, and the holding pin 57 becomes the guide portion 61d. Thus, the shutter member 55 is rotated in the φ1 direction. Then, as shown in FIGS. 5B and 7, when the holding pin 57 is guided and restrained inside the restraining recess 61b, the shutter member 55 is held at the blocking position rotated in the φ1 direction.

  As shown in FIGS. 2 and 4, when the shutter member 55 is held at the blocking position, the blocking plate 55 a is positioned at the opening 5 a of the housing 2, and the disk D is rotationally driven inside the housing 2. When this is done, another disk or foreign object is prevented from entering the inside of the housing 2.

  As shown in FIG. 7, when the shutter member 55 is in the blocking position, the opening angle between the line end portion 56d of the shutter spring 56, which is a torsion spring, and the elastic arm 56c becomes narrow, and the winding center portion 56a of the shutter spring 56 And the elastic force of the shutter spring 56 is increased. Since the elastic arm 56c has a strong force to rotate the shutter member 55 in the φ2 direction, the holding pin 57 provided on the shutter member 55 is strongly pressed against the inner peripheral surface of the restraining recess 61b of the shutter switching member 61. Even when vehicle body vibration or the like is applied, rattling of the shutter member 55 at the blocking position is unlikely to occur.

  The facing member 46 shown in FIG. 6 is fixed to the ceiling plate 3 of the housing 2, and the shutter member 55 is supported by the facing member 46. That is, the shutter member 55 is not mounted on the drive base 10 side, but is attached to the housing 2 side. Therefore, as shown in FIG. 2 and FIG. 3, the disk D is clamped to the rotary drive unit 20, the restraint by the restraining mechanism 50 of the drive base 10 is released, and the drive base 10 is connected to the compression coil spring 26a and the damper member 26b. The relative position between the shutter member 55 and the opening 5a does not change even if the elastic support state is achieved.

  On the other hand, the mode switching slider 30 is supported on the drive base 10 so as to be movable in the Y1-Y2 direction. However, as shown in FIG. 5B, when the shutter member 55 is held at the blocking position, the pressing portion 34 of the mode switching slider 30 is separated from the connecting portion 63 of the shutter switching member 61, so that the elastic support is provided. Even if the drive base 10 is moved, the movement is not transmitted to the shutter switching member 61.

  As shown in FIG. 5B, when the mode switching slider 30 and the shutter switching member 61 are separated, the shutter switching member 61 is moved in the Y2 direction by the force of the switching spring 62, and the elasticity of the switching spring 62 is increased. By the shutter switching member 61 moved by force, the shutter member 55 is rotated in the φ1 direction against the force of the shutter spring 56.

  Therefore, it is necessary to set the elastic force of the shutter spring 56 sufficiently smaller than the elastic force of the switching spring 62. Therefore, as shown in FIG. 6, when the shutter member 55 is in the retracted position, the elastic arm 56c is pressed by the spring pressing portion 61e to increase the elastic force, thereby using the relatively weak shutter spring 56. In addition, rattling of the shutter member 55 at the retracted position can be prevented.

  When an instruction for taking out the disk D from the housing 2 is input by operating an operation button provided on the panel 8 or a remote control, the switching motor on the drive base 10 is started and the mode switching slider 30 is started. Moves in the Y1 direction from the position shown in FIG. At substantially the same time, the transport motor starts and the transport roller 45 starts to rotate in the carry-out direction (clockwise). Then, the clamp is released as shown in FIG. 3, and the disk D is sandwiched between the transport roller 45 and the opposing member 46, and is carried out from the opening 5a and the insertion / discharge port 8a.

  In the above-described embodiment, the elastic arm 56c is configured by a line end portion of a torsion spring, but the elastic arm 56c may be configured by a leaf spring or a wire spring.

DESCRIPTION OF SYMBOLS 1 Disk apparatus 2 Case 3 Ceiling board 4 Bottom board 5a Opening part 8a Insertion / discharge port 10 Drive base 20 Rotation drive part 21 Turntable 22 Clamp arm 27 Clamper 29 Clamp control part 30 Mode switching slider 31 Clamp press part 33 Lifting cam part 34 Pressing portion 41 Roller bracket 44 Roller shaft 45 Conveying roller 46 Opposing member 47 Transmission member 50 Restraining mechanism 55 Shutter member 55d Spring hooking portion 56 Shutter spring 56c Elastic arm 57 Holding pin 60 Shutter switching mechanism 61 Shutter switching member 61b Holding recess 61d Guide Part 61e spring pressure part 62 switching spring 63 connecting part

Claims (5)

A rotation drive unit disposed inside the housing, a transport mechanism for carrying a disk supplied from the front part of the housing into the rotation drive unit, and a supply of the disk from the front part of the housing are blocked. In the disk device provided with the shutter member,
The shutter member is movably supported between a blocking position for blocking the disk supply path and a retracted position for retracting from the supply path to enable disk supply, and an elastic arm is hung on the shutter member. The shutter member is biased to the retracted position by the elastic arm,
A shutter switching member is provided that moves in a first direction for restraining the shutter member to the blocking position and in a second direction for releasing the restraint. When the shutter member moves to the retracted position, the shutter switching member moves in the second direction. The disk device according to claim 1, wherein the elastic arm is pushed by the moving shutter switching member, and the shutter member is pushed to a retracted position by an elastic force of the elastic arm.   The disk device according to claim 1, wherein the elastic arm is a part of a torsion spring.   3. The disk device according to claim 1, wherein the shutter member is rotatably supported, and is urged in the rotational direction toward the retracted position by the elastic arm.   The shutter switching member is provided with a constraining recess for constraining a part of the shutter member when moved in the first direction, and the constraining recess when the shutter member is moved in the second direction. 4. The disk device according to claim 1, wherein the concave portion is separated from the shutter member.   The shutter switching member is moved in the first direction by the biasing force of the shutter spring, and the shutter spring causes the shutter switching member to move more than the elastic force by which the elastic arm rotates the shutter member to the retracted position. 5. The disk device according to claim 1, wherein the elastic force to be moved in the direction of 1 is set stronger.

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