JP3591020B2 - Disc loading mechanism - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to a disc loading mechanism for mounting an optical disc on a disc player device.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been proposed an optical disk in which an information signal is recorded and the information signal is read by an optical pickup device. This optical disk is configured to have a disk substrate formed of a disc made of a synthetic resin material such as polycarbonate, and a signal recording surface formed on one main surface of the disk substrate. On the signal recording surface, a thin film made of a metal material such as aluminum is formed as a reflective layer.
[0003]
Such an optical disk is mounted on a disk player device provided with the optical pickup device, so that an information signal is read out by the optical pickup device.
[0004]
The disk player device has a rotation operation mechanism that rotates the optical disk while holding the optical disk facing the optical pickup device. That is, the rotation operation mechanism and the optical pickup device constitute a disk mounting unit on which the optical disk is mounted.
[0005]
The disk player device has a disk loading mechanism for mounting the optical disk on the disk mounting section. The disc loading mechanism conveys an optical disc inserted from an outer side of the disc player apparatus into an outer casing of the disc player apparatus and mounts the optical disc on the disc mounting unit.
[0006]
As the disk loading mechanism, a so-called slot-in type has been proposed. The slot-in type disk loading mechanism transports an optical disk inserted from a slot formed in the outer housing to the disk mounting portion in a direction along a main surface portion of the optical disk, and transfers the optical disk to the disk mounting portion. It is configured to be attached.
[0007]
This disk loading mechanism has a pair of rotating rollers for holding the optical disk inserted from the slot from both sides of the optical disk. These rotating rollers are rotated by a driving force from a driving force source such as a motor in a state where the optical disk is sandwiched, and convey the optical disk. Then, the optical disk transported to a position facing the disk mounting portion is moved in a direction perpendicular to the main surface of the optical disk, mounted on the disk mounting portion and chucked.
[0008]
Also, when the optical disk mounted on the disk mounting portion is ejected from the disk player device, the optical disk is moved in a direction perpendicular to the main surface portion of the optical disk and detached from the disk mounting portion, and each of the rotating rollers It is pinched by. Then, the optical disc is carried out to the outside of the outer casing via the slot by rotating each of the rotating rollers.
[0009]
[Problems to be solved by the invention]
By the way, in a disk player device having the above-described disk loading mechanism, it is necessary to incorporate an ejecting motor serving as a driving force source for discharging the optical disk and a power supply of the ejecting motor. Therefore, an increase in the size and weight of the device configuration and an increase in power consumption have been caused.
[0010]
Further, in this disc player device, if the power for the ejection motor is supplied from an external power source, the disc player device cannot be used where there is no external power source, for example, outdoors.
[0011]
Therefore, this disc loading mechanism is unsuitable as a mechanism applied to so-called portable and outdoor disc player devices.
[0012]
Further, in this disc player device, a brake mechanism for stopping the optical disc at an appropriate position is required to prevent the optical disc ejected by the disc loading mechanism from being thrown into the air. This brake mechanism complicates the device configuration of the disc player device.
[0013]
Then, the present invention is proposed in view of the above-mentioned situation, and simplification of a device configuration, miniaturization, and weight reduction are possible, increase in power consumption is suppressed, and especially, portable, outdoor It is an object of the present invention to provide a disc loading mechanism suitable for being applied to a disc player device configured for use.
[0014]
[Means for Solving the Problems]
In order to solve the above-mentioned problems and achieve the above object, a disk loading mechanism according to the present invention includes a support top plate disposed on a rear side of a disk mounting unit for reading an information signal recorded by rotating an optical disk. A front end side of which has a disk contact member pressed by an optical disk moved toward the disk mounting portion from the front, and is rotatably supported in the front-rear direction by the support top plate; An optical disk moved toward the mounting portion, a disk ejection member that is rotated in a direction in which the disk contact member moves backward, and a disk ejection member that is attached to the support top plate so as to be movable in the left-right direction, and is mounted on a rack gear. A discharge slider with which the gear portion of the disk discharge member meshes, and a discharge bias for urging the disk discharge member in a direction in which the disk contact member moves forward. Material, and a retracting urging member that generates an urging force that urges the disk ejection member in a direction in which the disk contact member moves rearward and that is stronger than the urging force of the ejection urging member. An urging means, an urging direction switching mechanism for switching an urging direction of the disc ejecting member by the urging means in accordance with a moving direction and a position of the disc contact member, and discharge slider Ru and a lock lever for locking it points to the direction in which the disc contact member moves toward the front.
[0015]
The biasing direction switching mechanism includes a first switching lever rotatably attached to the support top plate, a first switching lever rotatably attached to the support top plate, a front end side being an operation end, and a rear end side being an operated end. , The base end side of which is rotatably attached to the discharge slider, and the distal end side of which is urged to rotate in a direction facing the operated end of the first switching lever, and the cam of the support top plate. A second switching lever that is controlled to rotate by a unit, and a forward end of the first switching lever, a base end of which is rotatably attached to the ejection slider, and an operating end of the first switching lever. And a third switching lever opposed to the third switching lever .
[0016]
The discharge urging member has one end locked to a support top plate and the other end locked to a discharge slider, and applies a disk discharge member in a direction in which the disk contact member goes forward via the discharge slider. Energize . The retraction urging member has one end locked to a support top plate and the other end locked to a first switching bar, and the disk is moved through the first switching lever and the third switching lever. The contact member biases the disc ejection member in a direction toward the rear .
[0017]
Said disk discharging member, the disc contact member, located on the front side than the first reversing position the optical disc corresponding to the rear side of the edge portion of the optical disc when in the position opposed to the disc instrumentation adhering part when that is, Ru is rotationally urged forward through the discharge slider by urging member for the discharge.
[0018]
When the disc contact member is moved backward by the movement of the optical disc, the disc contact member is rotated against the urging member for ejection, and the second switching lever is moved to the operated end of the first switching lever. When the tip of the lever comes into contact and the retracting urging member starts to extend and reaches the first reversing position, the operating end of the first switching lever is brought into contact with the tip of the third switching lever. In opposition, the ejecting slider is urged by the retracting urging member in a direction in which the disc contact member moves rearward .
[0019]
When the disc contact member reaches the second reversing position on the rear side of the first reversing position, the operation end of the first switching lever is moved from the tip of the third switching lever by the movement of the ejection slider. The ejection urging member returns to the initial state, and is locked by the lock lever in a state where the urging member is urged by the ejection urging member .
[Action]
In the disk loading mechanism according to the present invention, when the optical disk is rotated, the discharge urging member rotates the disk discharge member via the discharge slider so that the disk contact member is located rearward, and the discharge slider is locked. Since the disk is locked by the lever, the optical disk can be rotated while the disk contact member is separated from the optical disk. The optical disk is, by releasing the lock, the disk ejection member via the ejection slider by urging member for discharge is turned to disc contact member is positioned behind, it is discharged.
[0020]
Further, in each of the disk loading mechanisms described above, the locking of the lock lever with respect to the disk discharge member is released, and the disk discharge member holds the optical disk by the urging force of the discharge urging means via the disk contact member. In the case where a brake member is provided which slides on the peripheral portion of the optical disc to suppress the moving speed of the optical disc when ejected to the front side, the moving speed of the optical disc is adjusted to an appropriate level when ejected by the disc ejecting member. And will not be thrown into the air.
【Example】
Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.
[0021]
This example is an example in which the disk loading mechanism according to the present invention is applied to a disk player device that reproduces an information signal recorded on an optical disk 201 as shown in FIG. The description will be made in the following order.
[1] Configuration of optical disk (FIGS. 1 and 4)
[2] Configuration of disc player device (2-1) Disc mounting section (FIGS. 1 and 4)
(2-2) Configuration of Disk pull arm (1, 2, 4 to 16)
(2-3) Configuration of the chucking member (1, 2, 4 to 16)
(2-4) Configuration of disk ejection arms (1, 3, 4 through 16)
[3] Operation of the disc player apparatus (FIGS. 4 through 16)
(3-1) Initial state (FIG. 4)
(3-2) an optical disk insertion operation (FIGS. 4 to 10)
(3-3) Chucking of optical disk (FIGS. 9 and 10)
(3-4) optical disk ejecting operation (FIGS. 11 to 16)
[0022]
[1] Configuration of optical disk (FIGS. 1 and 4)
The optical disk 201 has a disk substrate formed of a synthetic resin material such as polycarbonate and having a diameter of, for example, about 120 mm. A chucking hole 202 having a diameter of, for example, about 15 mm is formed in the center of the disk substrate.
[0023]
One main surface portion of the disk substrate serves as a signal recording surface, and when this disk substrate is formed by injection molding means, fine irregularities, that is, pits are formed. The pits correspond to information signals converted into digital signals recorded on the optical disk.
[0024]
A reflection layer made of a metal material such as aluminum is formed on the signal recording surface.
[0025]
This optical disk irradiates a light beam focused on the signal recording surface through the disk substrate from the signal reading surface side, which is the other main surface portion, using an optical pickup device. An information signal can be read by detecting a reflected light beam from the signal recording surface.
[0026]
[2] Configuration of disc player device (2-1) Disc mounting section (FIGS. 1 and 4)
As shown in FIG. 1, the disc player device has a housing body 1 whose upper side is open. The housing main body 1 is closed at its open upper side by a lid 8, and constitutes an outer housing together with the lid 8.
[0027]
The outer housing has a bottom portion, a side length of length and substantially corresponding to the diameter of the optical disc 201, i.e., are made with a rectangular shape, for example 13cm to 14cm approximately. The thickness of the vertical direction of the outer casing is made, for example, 2cm to 3cm about.
[0028]
A slot 7 is provided on the front surface of the outer housing so that the optical disk 201 can be inserted horizontally from the front side.
[0029]
A chassis 6 is provided on the bottom side in the outer housing. The mounting section 2 is provided on the chassis 6. The disk mounting section 2 includes a disk table 4, an optical pickup device 5, and a frame portion that supports the disk table 4 and the optical pickup device 5.
[0030]
The frame portion of the disc mounting portion 2 is supported by the chassis 6 via a plurality of damper members 3, and is supported in a so-called floating state.
[0031]
The disk table 4 is formed in a substantially disk shape, and is attached to a tip end side of a drive shaft of a spindle motor (not shown) supported by the frame. The spindle motor is supported with the drive shaft facing upward. The disk table 4 has a truncated-cone-shaped projection at the center of the upper surface. The disk table 4 is located on the center of the chassis 6.
[0032]
When the central portion of the optical disk 201 is placed, the disk table 4 fits the truncated-cone-shaped projection into the chucking hole 202 to position the optical disk 201 in a direction along the main surface of the optical disk 201, so-called positioning. Performs centering. The optical disk 201 placed on the disk table 4 is pressed and held on the disk table 4 by a chucking member described later.
[0033]
The optical pickup device 5 includes a semiconductor laser serving as a light source, various optical devices for guiding a light beam emitted from the semiconductor laser, an objective lens 107 for condensing and emitting the light beam, and detecting a light beam returning via the objective lens 107. A photodetector or the like is built in the optical block unit.
[0034]
The optical pickup device 5 is supported by the frame so as to be movable in the direction of contacting and separating from the disk table 4. The optical pickup device 5 has the optical axis of the objective lens 107 parallel to the drive shaft of the spindle motor, and emits a light beam upward through the objective lens 107. In the disc mounting section 2, the optical disc 201 is placed and held on the disc table 4, so that the objective lens 107 of the optical pickup device 5 faces the signal reading surface of the optical disc 201. When the spindle motor is driven to rotate, the disk table 4 and the optical disk 201 are rotated, and when the optical pickup device 5 is moved toward and away from the disk table 4, this optical disk is moved. The pickup device 5 can read information signals from the entire surface of the signal recording area of the optical disc 201.
[0035]
(2-2) Disc pulling arms (1, 2, 4 to 16)
As shown in FIG. 1, a pair of left and right disk retraction arms 54 and 56 are provided in the outer housing. As shown in FIG. 2, these disk retraction arms 54 and 56 have a substantially bilaterally symmetrical shape and are disposed in a symmetrical position on the front side of the disk mounting portion 2.
[0036]
The disk pull-in arms 54 and 56 allow the rotation shafts implanted on the lower surface of the lid 8 to pass through the support holes 59 and 61 formed on the base end side, respectively, and through the rotation shafts. It is rotatably supported. In the initial state, the disk pull-in arms 54 and 56 have their distal ends extended forward.
[0037]
Further, the disk pull-in arms 54 and 56 have disk pull-in pins 55 and 57 serving as disk contact members on the distal end side. The disc pull-in pins 55 and 57 are cylindrical pins, and project in a direction perpendicular to the main surface of the optical disc 201 to be inserted from the slot 7, that is, downward. The diameter of the lower end of the disk pull-in pins 55 and 57 is reduced, so that the side of the side surface of the optical disk 201 that is inserted from the slot 7 and in contact with the peripheral portion of the optical disk 201 on the side of the disk mounting portion 2 becomes the defective portion 108. ing.
[0038]
The disk retraction arms 54 and 56 are linked to each other via a retraction slider 51 serving as a transmission member. That is, the pull-in slider 51 is supported in the outer housing so as to be slidable in the lateral direction along the lower surface of the lid 8. The pull slider 51, retraction spring 113 becomes stretched been equipped for attracting biasing member between the locking pawl (not shown) provided in the locking pawl 94 and the outer housing provided in the retraction slider 51 Thus, it is urged in one direction (rightward toward the disc player device) indicated by an arrow G in FIG.
[0039]
The disk pull-in arm 56 on one side (right side toward the disk player device) has a link pin 60 behind the support hole 61, and the link pin 60 is inserted into the link groove 53 of the pull-in slider 51. The fitting engagement is performed. Further, the disk retraction arm 54 on the other side (the left side when facing the disc player device) has a link pin 58 in front of the support hole 59, and the link pin 58 is connected to the link hole of the pull-in slider 51. 52.
[0040]
Therefore, when the pull-in slider 51 is slid to one side shown by an arrow G in FIG. 2, the one-side disk pull-in arm 56 is moved to the tip end side as shown by an arrow H in FIG. It is rotated in the direction toward the center between 54 and 56. When the pull-in slider 51 is slid to one side shown by an arrow G in FIG. 2, the disk pull-in arm 54 on the other side moves the leading end side to each of the disk pull-in arms as shown by an arrow J in FIG. It is rotated in the direction toward the center between 54 and 56.
[0041]
That is, the retracting spring 113 biases the respective disk retracting arms 54 and 56 in a direction in which the distal end side of each of the disk retracting arms 54 and 56 is directed toward the center between the disk retracting arms 54 and 56. It becomes.
[0042]
When the optical disc 201 is inserted between the disc pull-in arms 54 and 56 from the front side, as shown by the arrow S in FIGS. The disk pull-in pins 55 and 57 are brought into contact with each other, and as shown by arrows T and U in FIG. The disc is rotated in a direction against the force, that is, in a direction to separate the disc drawing pins 55 and 57 from each other.
[0043]
In this manner, before the optical disk 201 is inserted, the disk retraction arms 54 and 56 are held at the initial position by the disk detection lever 62 described later. In this initial position, the respective disc retraction arms 54, 56 are arranged such that the distance between the respective disc retraction pins 55, 57 is such that the optical disc 201 is inserted between the disc retraction pins 55, 57, as shown in FIG. It is a position to be separated as far as possible.
[0044]
Then, as shown in FIGS. 6 and 7, after the distance between the disk pull-in pins 55 and 57 becomes a distance corresponding to the diameter of the optical disk 201, the disk pull-in arms 54 and 56 further move. When the optical disk 201 is moved rearward, as shown by arrows H and J in FIG. 8, the disk pull-in pins 55 and 57 are rotated in a direction in which the disk pull-in pins 55 and 57 approach each other by the urging force of the pull-in spring 113. As shown in FIGS. 9 and 10, the optical disk 201 is moved toward the disk mounting portion 2 via the disk draw-in pins 55 and 57.
[0045]
The disc pull-in pins 55 and 57 are located at positions where the disc pull-in arms 54 and 56 face the optical disc 201 to the disc mounting portion 2, that is, the chucking holes 202 face the center of the disc table 4. When the optical disk 201 is moved to a position where the optical disk 201 is moved, the optical disk 201 is positioned.
[0046]
As described above, when each of the disk pull-in arms 54 and 56 pulls the optical disk 201 to a position facing the disk mounting portion 2, the disk pull-in arms 54 and 56 are moved by the disk detection lever 62 described later. Is turned to the loading position. In this loading position, the respective disk pull-in arms 54 and 56 are located at positions where the respective disk pull-in pins 55 and 57 approach each other as shown in FIG.
[0047]
Also, disk ejection pins 13 and 15 serving as positioning members, which will be described later, are located on the rear side of the disk mounting section 2, and the respective disk pull-in arms 54 and 56 allow the optical disk 201 to face the disk mounting section 2. When the optical disc 201 is moved, the optical disc 201 is positioned in cooperation with the disc pull-in pins 55 and 57.
[0048]
(2-3) Configuration of the chucking member (1, 2, 4 to 16)
A chucking member is provided in the outer housing. The chucking member includes a chucking frame 84, a disc lifter plate 90, a chucking arm 92, and a chucking plate 91.
[0049]
The chucking frame 84 includes a rear beam portion disposed along a rear edge portion in the outer housing, and a front beam extending from both ends of the rear beam portion to the front and left and right sides in the outer housing. It has a pair of left and right side beams 86, 86 along the edge, and is formed in a U-shape. The chucking frame 84 has a pair of left and right support holes 85 on the rear side of the side beams 86. The chucking frame 84 is rotatably supported by inserting a pair of left and right support shafts disposed in the outer casing into the support holes 85, 85, and is supported rotatably. At the front end side can be moved up and down.
[0050]
A disc lifter plate 90 is attached between the front beams of the both side beams 86, 86 of the chucking frame 84. The disc lifter plate 90 has a cutout portion corresponding to the size of the disc mounting portion 2 in the center portion, and when the chucking frame 84 is rotated and moved to the chassis 6 side, That is, when the chucking frame 84 is at the chucking position, the disc mounting portion 2 is fitted into the cutout portion, and the chucking frame 84 is moved toward the chassis 6 with respect to the disc table 4.
[0051]
When the chucking frame 84 is rotated and moved in a direction away from the chassis 6, that is, when the chucking frame 84 is set to the release position, the disc lifter plate 90 4 is moved to a position further away from the chassis 6.
[0052]
The chucking arm 92 is formed so as to project forward from a substantially central portion of a rear beam of the chucking frame 84. The tip side of the chucking arm 92 is located above the disk table 4.
[0053]
The chucking plate 91 is formed in a disk shape having a diameter slightly larger than the diameter of the chucking hole 202 of the optical disc 201. The chucking plate 91 is rotatably attached to the lower surface of the tip side of the chucking arm 92.
[0054]
The chucking plate 91 is in contact with the upper surface of the disc table 4 when the chucking frame 84 is at the chucking position. At this time, when the optical disk 201 is placed on the disk table 4, the chucking plate 91 cooperates with the disk table 4 to hold the optical disk 201. When the disk table 4 is rotated by the spindle motor, the chucking plate 91 holding the optical disk 201 in cooperation with the disk table 4 rotates together with the disk table 4 and the optical disk 201. Is done.
[0055]
The chucking plate 91 is separated from the upper surface of the disc table 4 when the chucking frame 84 is at the release position.
[0056]
When the chucking frame 84 is at the release position and the optical disc 201 is inserted from the slot 7, the optical disc 201 is inserted between the chucking plate 91 and the disc lifter plate 90. You.
[0057]
Then, the chucking frame 84, a spring engaging portion provided on the spring locking portion 87 and the outer housing provided on one of the side beam portions 86 (the side beams of the other side end in this example) 1 and 2, a direction in which the chucking position is moved to the disk table 4 side, as indicated by an arrow L in FIGS. 1 and 2. Is urged to rotate. In the vicinity of one side beam portion 86 (in this example, the side beam portion on the other side), a stopper member 73 and an eject slider 77 are provided.
[0058]
The stopper member 73 is rotatably supported at the lower edge thereof via a support shaft 75 with respect to a support side plate 67 disposed on the other side in the outer housing. In an initial state in which the upper edge is directed upward, the stopper member 73 abuts and supports the lower edge of the one side beam 86 by an abutting support 106 provided on the upper edge. The chucking frame 84 is held at the release position.
[0059]
The stopper member 73 is rotated around the support shaft 75 to move the upper edge portion inward of the outer housing, so that the one side beam portion by the contact support portion 106 is formed. The support for the chuck 86 is released, and the chucking frame 84 can rotate toward the chucking position.
[0060]
The stopper member 73 is rotationally urged by a torsion coil spring 76 fitted around the support shaft 75 in a direction in which the chucking frame 84 is initially supported.
[0061]
The stopper member 73 has an engaging pin 74 serving as an engaged portion on the upper end side, and a hook-like member 93 serving as an engaging portion attached to the retraction slider 51 via the engaging pin 74. As a result, the turning operation is performed against the urging force of the torsion coil spring 76. The hook-shaped member 93 is rotatably supported at the other end of the retractable slider 51 via a support shaft 96 implanted on the retractable slider 51. The hook-shaped member 93 has a hook on the tip end side, and ranges from an initial position where the hook can be engaged with the engagement pin 74 and a position where the hook is separated from the engagement pin 74. Thus, it can be rotated. The hook-shaped member 93 is rotationally urged by a torsion coil spring 95 in the direction of the initial position as indicated by an arrow R in FIGS.
[0062]
When the respective retracting arms 54 and 56 are at the initial position, the retracting slider 51 engages the hook portion of the hook-shaped member 93 with the engaging pin 74 of the stopper member 73 as shown in FIG. Let me.
[0063]
When the optical disk 201 is inserted and the retracting slider 51 sets the respective disk retracting arms 54 and 56 to the loading position, as shown in FIG. As a result, the engagement pin 74 is moved inward of the outer housing, and the stopper member 73 is rotated.
[0064]
That is, when the optical disk 201 is pulled up to a position facing the disk mounting section 2, the pull-in slider 51 rotates the stopper member 73 via the hook-shaped member 93 to move the chucking frame 84. The above chucking position is set.
[0065]
The eject slider 77 has a pair of front and rear support slits 78 and 79, and a pair of front and rear support pins 69 and 68 provided on the support side plate 67 are inserted and engaged with the support slits 78 and 79, respectively. , So as to be slidable in the front-rear direction.
[0066]
The eject slider 77 has an eject button 82 attached to the front end. The eject button 82 protrudes forward from the front surface of the outer housing via a through hole provided in the front surface of the outer housing. The eject slider 77 is urged to move forward as indicated by an arrow M in FIG. 1 by a tension coil spring 83 stretched between the eject slider 77 and the outer housing.
[0067]
The eject slider 77 has a release operation pin 80 at a rear end side portion. The release operation pin 80 is located below one side beam portion 86 of the chucking frame 8. A tapered cam portion 88 is formed at the lower edge of this one side beam portion 86.
[0068]
When the eject button 82 is pressed and slid rearward, the eject slider 77 slides the release operation pin 80 against the tapered cam portion 88 to move the chucking frame 84 to the release position. Rotate until
[0069]
When the eject slider 77 is slid forward by the urging force of the tension coil spring 83, the chucking frame 84 is moved by moving the release operation pin 80 to a position not in contact with the tapered cam portion 88. It is possible to rotate to the chucking position.
[0070]
The eject slider 77 has an engagement piece 81 extending above the other end of the retracting slider 51. The rear edge of the engaging piece 81 is a tapered portion inclined with respect to the sliding direction of the eject slider 77, that is, the front-back direction. It faces the front side of the pin 65.
[0071]
As shown by an arrow X in FIG. 11, when the eject button 82 is pressed and slid rearward, the eject slider 77 moves the rear edge of the engaging piece 81 to the return operation pin 65. By making sliding contact, the retracting slider 51 is returned to the position where the respective disk retracting arms 54 and 56 are in the initial position as shown by the arrow Y in FIG.
[0072]
The disk detection lever 62 is rotatably supported on the base end side via the support shaft 102 in the outer housing. A disk detection pin 63 is implanted on the tip side of the disk detection lever 62.
[0073]
The disk detection lever 62 has an initial position shown in FIG. 4 in which the disk detection pin 63 is located between the support shaft 102 and one end of the pull-in slider 51, and the disk detection pin 63 is moved rearward from the initial position. It is rotatable over a disk detection position shown in FIG. 8, which is a position moved to the side.
[0074]
The disk detecting lever 62 is rotationally biased by the torsion coil spring 64 in a direction to move the disk detecting pin 63 forward in the initial position as shown by an arrow K in FIGS. Positioned in position.
[0075]
When the disk detection lever 62 is at the initial position, as shown in FIG. 4, the disk detection pin 63 causes the respective retracting sliders 51 to move from the position where the respective disk retracting arms 54 and 56 are in the initial position. This prevents the slider 51 from moving toward the one end side, that is, the pulling slider 51 from setting the respective disk pulling arms 54 and 56 to the loading position.
[0076]
That is, when the disc detection lever 62 is at the initial position, the retraction slider 51 rotates the chucking frame 84 in a direction approaching the disc mounting unit 2, that is, in a direction toward the chucking position. Is preventing that.
[0077]
When the optical disk 201 is located at a position facing the disk mounting portion 2, the disk detection lever 62 is operated to move the disk detection pin 63 backward by the optical disk 201, as shown in FIG. Is rotated to the disk detection position.
[0078]
At this time, the disk detecting lever 62 releases the movement of the disk detecting pin 63 from moving to the retracting slider 51, and the retracting slider 51 is moved to one end from a position where the disk retracting arms 54 and 56 are at the initial position. Moving in the lateral direction, that is, the retraction slider 51 allows the respective disc retraction arms 54, 56 to be in the loading position.
[0079]
That is, when the optical disk 201 is located at a position facing the disk mounting portion 2, the disk detection lever 62 causes the retraction slider 51 to rotate the chucking frame 84 in the direction toward the chucking position. Is possible.
[0080]
Then, the disk detection lever 62 is operated when the retracting slider 51 sets the disk retracting arms 54 and 56 to the loading position, that is, when the disk retracting arms 54 and 56 face the optical disk 201 to the disk mounting unit 2. 9, the one end of the pull-in slider 51 holds the disc detection pin 63 at a position where the disc detection pin 63 is separated from the optical disc 201, as shown in FIG.
[0081]
That is, at this time, the pull-in slider 51 holds the disk detection pin 63 at a position separated from the optical disk 201 by bringing one end of the slider 51 into contact with the disk detection pin 63.
[0082]
Therefore, the chucking frame 84 moves the optical disk 201 to a position facing the disk mounting portion 2 with the disk retraction arms 54 and 56 at the loading position, and the disk detection lever 62 When the optical disk 201 is rotated to the disk detection position, the disk is moved in a direction approaching the disk mounting portion 2 in conjunction with the rotation of the disk retraction arms 54 and 56, and the chucking position is changed. Then, the optical disk 201 is mounted on the disk mounting section 2.
[0083]
When the optical disk 201 is mounted on the disk mounting section 2, that is, when the optical disk 201 is mounted on the disk table 4 and is sandwiched between the disk table 4 and the chucking plate 91, the optical disk 201 The peripheral edge of 201 is opposed to the defective portion 108 of each of the disk pull-in pins 55 and 57. That is, the periphery of the optical disk 201 mounted on the disk mounting portion 2 does not slide on the disk pull-in pins 55 and 57.
[0084]
When the optical disk 201 is mounted on the disk mounting section 2, the optical disk 201 is mounted on the disk table 90 when the chucking frame 84 is at the chucking position as described above. Since the chassis 6 is closer to the chassis 6 than the chassis 4, there is no sliding contact with the disc lifter plate 90.
[0085]
When the chucking frame 84 is rotated to the release position, the optical disk 201 mounted on the disk mounting unit 2 is mounted on the disk lifter plate 90 and moved upward, It is separated from the disk table 4.
[0086]
(2-4) Configuration of disk ejection arms (1, 3, 4 through 16)
A pair of left and right disk discharge arms 12 and 14 serving as a disk discharge member are disposed in the outer housing. The disk ejection arms 12 and 14 are disposed symmetrically on the rear side of the disk mounting section 2.
[0087]
The disc discharge arms 12 and 14 are supported at their base ends in correspondence with a pair of left and right support shafts 10 and 11 implanted on a support top plate 9 attached to the lower surface of the lid 8. In the initial state, as shown in FIG. 4, the front ends are set to the initial positions with the front ends facing obliquely forward in the middle between the disk ejection arms 12 and 14.
[0088]
Each of the disk discharge arms 12 and 14 has a disk discharge pin 13 or 15 on the distal end side which serves as a disk contact member and also serves as the positioning member. When the disc ejection arms 12 and 14 are at the initial positions, the disc ejection pins 13 and 15 are also at the initial positions of the disc ejection pins 13 and 15.
[0089]
That is, each of the disk discharge arms 12, 14 is supported such that the disk discharge pins 13, 15 can be moved in the front-rear direction. And these disk ejection arms 12 and 14, the optical disk 201 is moved toward the disk mounting portion 2 from the front side, as indicated by arrows W and arrow V in FIG. 7 to FIG. 9, the disk ejection pin 13 , 15 are pressed, and the disc ejecting pins 13, 15 are rotated in a direction to move them backward.
[0090]
Each of the disk ejection arms 12 and 14 has gear portions 16 and 17 centered on the support shafts 10 and 11 on the base end side. A rear portion of the lower surface of the lid 8 has a pair of rack gears 34 and 36 that mesh with the gears 16 and 17 of the respective disc discharge arms 12 and 14 so as to switch the biasing force. A discharge slider 31 serving as a slider is supported via a support top plate 9 so as to be slidable in the lateral direction.
[0091]
The discharge slider 31 has a pair of support slits 32 and 33, and a pair of support pins implanted in the support top plate 9 are inserted through the support slits 32 and 33 to be slidably supported. I have.
[0092]
A rack gear portion 34 at one end of the ejection slider 31 that meshes with the gear portion 16 of the ejection arm 12 on one side (the right side as viewed from the disc player device) is formed toward the front side, and the rear side of the gear portion 16. It is engaged with the part. Further, a rack gear portion 36 at the other end of the discharge slider 31 that meshes with the gear portion 17 of the discharge arm 14 on the other side (left side as viewed from the disc player device) is formed toward the rear side. Is engaged with the front side of the vehicle.
[0093]
Therefore, when the ejection slider 31 is slid in the other side direction indicated by the arrow B in FIG. 1, the respective disc ejection arms 12 and 14 move as shown by the arrows C and D in FIG. The disc ejecting pins 13 and 15 are turned in a direction to move forward through an intermediate position between the disc ejecting arms 12 and 14.
[0094]
The disc player device has an urging means for urging the disc ejection arms 12 and 14 to rotate.
[0095]
The rotation means includes a discharge spring 29 serving as a discharge urging member for urging the disk discharge arms 12 and 14 to rotate in a direction in which the disk discharge pins 13 and 15 move forward, and the disk discharge pins 13 and 15. A retracting spring 23 serving as a retracting biasing member for generating a biasing force for biasing the disk discharge arms 12 and 14 in the direction toward the rear, which is stronger than the biasing force of the discharge spring 29, and Consists of
[0096]
The ejection spring 29 is a tension coil spring, and is stretched between a spring engagement piece 27 on the other side on the support top plate 9 and a spring engagement portion 25 on the ejection slider 31. The ejection slider 31 is urged in the other side direction indicated by the arrow B in FIG.
[0097]
The retracting spring 23 is a tension coil spring, and is rotatably attached to the spring locking piece 30 on one side on the support top plate 9 and the other side on the support top plate 9. The first switching lever 19 is stretched between the first switching lever 19 and the spring locking portion 24.
[0098]
The first switching lever 19 constitutes a biasing direction switching mechanism for switching the biasing direction of the biasing means with respect to the disk ejection arms 12, 14. The first switching lever 19 has a central portion rotatably supported by the support top plate 9 via a support shaft 111.
[0099]
The first switching lever 19 has an operation end 22 on the front end side and an operated end 21 on the rear end side. The first switching lever 19 has the spring engaging part 24 between the support shaft 111 and the operating end 22, by the retraction spring 23 which is locked to the spring locking portion 24, The operation end 22 is rotationally urged in a direction for moving the operation end 22 in one side direction indicated by an arrow A in FIG.
[0100]
The first switching lever 19 is positioned at an initial position where the operation end 22 is directed forward and the operated end 21 is directed rearward. From this initial position, a predetermined direction is set in a direction in which the retracting spring 23 is extended. Is rotatable within the range of.
[0101]
The biasing direction switching mechanism includes the first switching lever 19 and second and third switching levers 43 and 40 rotatably attached to the ejection slider 31.
[0102]
The second switching lever 43 is disposed on the rear side of the first switching lever 19, and has a base end facing the other end of the discharge slider 31 via the support shaft 109. The slider 31 is rotatably supported. The second switching lever 43 has a distal end toward one end of the ejection slider 31 facing the operated end 21 of the first switching lever 19.
[0103]
The second switching lever 43 is rotationally biased by the torsion coil spring 44 in a direction to move the front end side to the front side, as indicated by an arrow F in FIG. 1, and a copying pin provided on the front end side. 45 is brought into contact with a cam portion 26 formed at the rear edge of the support top plate 9 and is positioned at an initial position as shown in FIG. When the ejection slider 31 is moved toward the one end, the cam portion 26 moves the tip end side of the second switching lever 43 through the copying pin 45 to the rear side as shown in FIG. It has a shape to be moved.
[0104]
The third switching lever 40 is disposed in front of the first switching lever 19, and has a base end facing one end of the discharge slider 31 via a support shaft 112. 31 rotatably supported. The third switching lever 40 has the tip 41 directed toward the other end of the ejection slider 31.
[0105]
The third switching lever 40 is positioned at the initial position by the torsion coil spring 42 in a state where the third switching lever 40 is rotationally biased in a direction for moving the distal end portion 41 backward as shown by an arrow E in FIG. I have.
[0106]
When the ejection slider 31 is slid toward the one end, the third switching lever 40 is temporarily moved to the distal end 41 by the operation end 22 of the first switching lever 19 being brought into contact with the distal end. Is returned to the initial position by the urging force of the torsion coil spring 42, and at this time, as shown in FIG. 8 and FIG. Of the switching lever 19 of FIG.
[0107]
Note that the operation end 22 of the first switching lever 19 is configured such that if the first switching lever 19 is at the initial position, even if the ejection slider 31 is slid toward one end, the third switching lever Do not abut against the tip side of 40. However, when the ejection slider 31 is slid toward the one end side, the first switching lever 19 causes the operation end 22 to move forward from the initial position by the second switching lever 43 as described later. Therefore, the operating end 22 is brought into contact with the distal end of the third switching lever 40 and is opposed to the distal end 41 of the third switching lever 40.
[0108]
The urging direction switching mechanism switches the urging direction of the urging means with respect to the disk ejection arms 12 and 14 in accordance with the moving direction and the position of the disk ejection pins 13 and 15.
[0109]
That is, the disc ejection arms 12 and 14 move the disc ejection pins 13 and 15 between the initial position and the first reversal position, that is, when the disc ejection pins 13 and 15 are positioned forward of the first reversal position. as shown in FIGS. 4-8, it is rotationally biased in a direction to move the disk ejection pins 13 and 15 forward. At this time, the rotation of the disk discharge arms 12, 14 in the direction of moving the disk discharge pins 13, 15 forward is performed by the discharge spring 23 via the discharge slider 31.
[0110]
The first reversal position is a position corresponding to the rear edge of the optical disk 201 when the optical disk 201 is positioned to face the disk mounting section 2.
[0111]
Further, when the respective disc eject pins 13 and 15 has reached the first reversal position described above, the second switching lever 43, as shown in FIGS. 8 to 9, is moved to the distal end side to the rear side As a result, the distal end is displaced rearward from the operated end 21 of the first switching lever 19.
[0112]
Then, when the ejection slider 31 is moved to one end side and the disc ejection pins 13 and 15 approach the first reversing position, as shown in FIGS. 7 and 8, the second switching lever 43 is used. The first switching lever 19 is rotated, and the retracting spring 29 is extended. Therefore, at this time, the retraction spring 29 also urges the discharge slider 31 toward the other end side via the first and second switching levers 19 and 43, like the discharge spring 23. Then, each of the disk discharge arms 12, 14 is rotationally biased in a direction for moving the disk discharge pins 13, 15 forward.
[0113]
Further, the urging direction switching mechanism is configured such that when the disc ejection pins 13 and 15 are moving rearward, the positions of the disc ejection pins 13 and 15 are the first reversing position and the first reversing position. As shown in FIG. 9, when the position is between the second reversing position, which is on the rear side of the reversing position, the urging force of the retracting spring 29 is applied to the operation end 22 of the first switching lever 19 and the The light is transmitted to the disk ejection arms 12 and 14 via the tip 41 of the third switching lever 40.
[0114]
At this time, the urging force of the retracting spring 29 urges the discharge slider 31 toward one end, and moves the disk discharge pins 13 and 15 rearward as shown by arrows W and V in FIG. The respective disc ejection arms 12, 14 are urged to rotate in the direction in which they are caused to rotate. Here, since the urging force of the retracting spring 29 is larger than the urging force of the discharging spring 23, the respective disk discharging arms 12, 14 move the respective disk discharging pins 13, 15 backward. Is rotated. Therefore, at this time, the respective disc ejection pins 13 and 15 are separated from the peripheral edge of the optical disc 201 and reach the second reversal position.
[0115]
The urging direction switching mechanism is arranged such that when each of the disk discharge arms 12, 14 positions the respective disk discharge pins 13, 15 behind the second reversing position, the respective disk discharge arms 12, 14 are displaced. 12 and 14 are urged to rotate in the direction in which the disc ejection pins 13 and 15 are moved forward.
[0116]
That is, when the respective disc ejection pins 13 and 15 are located behind the second reversing position after the second reversing position, the first switching lever 19 is initially set as shown in FIG. The ejection slider 31 is urged toward the other end only by the ejection spring 23 in order to return to the position and remove the operation end 22 behind the tip end 41 of the third switching lever 40. The Rukoto.
[0117]
After each disc eject pins 13 and 15 reaches the rear side of the second reversal position, the discharge slider 31 is engaging with the lock lever 46 serving as a locking mechanism.
[0118]
The lock lever 46 is rotatably supported at a central portion thereof via a support shaft 110 implanted on a lower surface portion of the support top plate 9. It is arranged.
[0119]
The lock lever 46 is biased by a torsion coil spring 47 in a direction in which one end side is pressed against the front edge of the discharge slider 31 as shown by an arrow Q in FIGS. A lock pin 49 is attached to one end of the lock lever 46.
[0120]
A pressed surface portion 48 is formed on the other end of the lock lever 46 toward the front side. The pressed surface portion 48 faces the rear end of the eject slider 77.
[0121]
A lock recess 50 is formed at the front edge of the discharge slider 31 on the other end side so that the lock pin 49 can be fitted and engaged.
[0122]
When the discharge slider 31 is the respective disc eject pins 13 and 15 is positioned until the first reversing position from the initial position, the lock lever 46, as shown in FIGS. 4 to 8, The lock pin 49 is brought into contact with a front edge of the discharge slider 31, which is one end side of the discharge slider 31 with respect to the lock recess 50.
[0123]
When the ejection slider 31 positions the disc ejection pins 13 and 15 behind the first reversing position, the lock lever 46 locks the lock lever 46 as shown in FIGS. 9 and 10. The pin 49 is fitted into the lock recess 50. At this time, the lock lever 46 prevents the discharge slider 31 from returning to the other end side.
[0124]
When the eject slider 77 is slid rearward, the lock lever 46 presses the pressed surface portion 48 by the rear end of the eject slider 77 as shown in FIG. The lock pin 49 is rotated against the force, and the lock pin 49 is pulled out forward from the lock recess 50. Therefore, at this time, the discharge slider 31 can return to the other end side direction by the urging force of the discharge spring 23.
[0125]
In other words, the lock lever 46 allows the disc ejection arms 12 and 14 to be released by the eject slider 77 via the ejection slider 31 and causes the disc ejection pins 13 and 15 to move to the first reversing position. It is behind the, i.e., to lock in position a position spaced from the optical disc 201.
[0126]
When the eject slider 77 is the discharge slider 31 is slid to the rear side is returned to the other end direction by the urging force of the ejection spring 23, as shown in FIGS. 11 to 14, the discharge slider 31, each disk ejection pins 13 and 15 until the return to the initial position, as indicated by arrow C and an arrow D in FIGS. 11 to 14, operated to rotate the respective disk ejection arms 12.
[0127]
When the eject slider 77 is slid rearward, the chucking frame 84 is set to the release position, as described above, so that the optical disk 201 placed on the disk table 4 is moved to the disk lifter. It is raised by the plate 90 and is separated from the disk table 4.
[0128]
The optical disk 201 lifted by the disk lifter plate 90 is moved forward by the disk discharge pins 13 and 15 of the disk discharge arms 12 and 14 that move forward.
[0129]
A pair of left and right brake members 97, 97 are provided on both sides of the front side portion in the outer housing. Each of the brake members 97 is rotatably supported on the rear end side by a support shaft 99 provided in the outer housing, and is provided between the spring locking pin 100 on the front end side and the inner wall of the outer housing. In a state in which the front end side is turned and biased in a direction to turn the front end side toward the inside of the outer housing as shown by arrows O and P in FIG. 1 by a tension coil spring 98 stretched over Positioned in position.
[0130]
Each brake member 97, 97 is engaging against the discharge slider 31 by the lock lever 46, i.e., the locking is released for the disk ejection arms 12, as shown in Figure 15 in an arrow Z, the disk ejection When the arms 12 and 14 eject the optical disc 201 to the front side by the urging force of the ejection spring 23 via the disc ejection pins 13 and 15, as shown in FIG. Make sliding contact.
[0131]
At this time, the brake members 97, 97 are rotated by the optical disc 201 in the outward direction of the outer housing against the urging force of the tension coil springs 98, 98, and the tension coil springs 98, 98 are rotated. The moving speed of the optical disk 201 is suppressed by the force of returning the optical disk 201 to the initial state. At this time, as shown in FIG. 14, the optical disk 201 stops in a state where substantially half of the front side portion is projected forward through the slot 7 toward the front side of the outer housing.
[0132]
Then, as shown by an arrow Z in FIGS. 15 and 16, the ejection operation is completed when the optical disk 201 is pulled out from the outer housing through the slot 7 to the front side.
[0133]
[3] Operation of the disc player apparatus (FIGS. 4 through 16)
(3-1) Initial state (FIG. 4)
In this disk player device, in the initial state, as shown in FIG. 4, the disk pull-in arms 54 and 56 and the disk detection lever 62 are at the initial position.
[0134]
The disc ejection arms 12 and 14 have the disc ejection pins 13 and 15 as initial positions.
[0135]
The chucking frame 84 is held at the release position by the contact support 106 of the stopper member 73.
[0136]
(3-2) an optical disk insertion operation (FIGS. 4 to 10)
In this disc player apparatus, in order to insert the optical disc 201, as shown by an arrow S in FIG. 4, the optical disc 201 is inserted between the disc pull-in arms 54 and 56 through the slot 7 from the front side. insert. Then, the respective disc retraction arms 54 and 56 are pressed by the respective disc retraction pins 55 and 57 by the peripheral edge of the optical disc 201, and are opposed to the urging force of the retraction spring 113 by arrows T and arrow in FIG. As shown by U, the disc pulling pins 55 and 57 are rotated in a direction to separate them.
[0137]
When the optical disk 201 is further inserted to the rear side, the distance between the disk pull-in pins 55 and 57 becomes a distance equal to the diameter of the optical disk 201 as shown in FIG. At this time, the trailing edge portion of the optical disc 201 comes into contact with the disc ejection pins 13 and 15 at the initial position.
[0138]
At this time, the disk detection lever 62 is brought into contact with the disk detection pin 63 at the periphery of the optical disk 201, and starts rotating in a direction in which the disk detection pin 63 is on the rear side.
[0139]
When the optical disk 201 is further inserted to the rear side, as shown in FIG. 7, the trailing edge portion of the optical disk 201 presses the respective disk ejection pins 13 and 15, and as shown by arrows W and V in FIG. Then, the disc ejection arms 12 and 14 are rotated against the urging force of the ejection spring 29.
[0140]
The disk detection lever 62 is brought into contact with the disk detection pin 63 at the periphery of the optical disk 201, and is rotated in a direction in which the disk detection pin 63 is on the rear side.
[0141]
At this time, the distal end of the second switching lever 43 comes into contact with the operated end 21 of the first switching lever 19, and the retracting spring 23 starts to be extended. When the rotation of the disk ejection arms 12 and 14 to move the disk ejection pins 13 and 15 to the rear side starts, as shown in FIG. By the urging force, the disc pull-in pins 55 and 57 are rotated in a direction to approach each other. At this time, the respective disk retraction arms 54 and 56 retract the optical disk 201 rearward via the respective disk retraction pins 55 and 57 by the urging force of the retraction spring 113.
[0142]
The disk detection lever 62 is brought into contact with the disk detection pin 63 at the periphery of the optical disk 201, and is rotated in a direction in which the disk detection pin 63 is on the rear side. The retracting spring 23 is further extended.
[0143]
When the optical disk 201 is pulled to a position facing the disk mounting portion, as shown in FIG. 9, each of the disk pull-in arms 54 and 56 is at the loading position. At this time, the disc pull-in pins 55 and 57 position the leading edge side of the optical disc 201. At this time, the disc ejection pins 13 and 15 position the trailing edge of the optical disc 201.
[0144]
In other words, the optical disk 201 is positioned at the position facing the disk mounting portion, that is, the chucking hole 202 is positioned at the center of the disk table 4 by the disk pull-in pins 55 and 57 and the disk discharge pins 13 and 15. Is positioned at a position to face.
[0145]
The disc detection lever 62, one end of the pull slider 51 to the respective disc pull arms 54 have no the said loading position is brought into contact with the disc detection pin 63. The disk detection lever 62 is pushed by the pull-in slider 51, and is rotated to a position where the disk detection pin 63 is separated from the optical disk 201, and this state is maintained.
[0146]
At this time, the respective disc ejection pins 13 and 15 have reached the first reversing position, and the operation end 22 of the first switching lever 19 faces and abuts on the distal end portion 41 of the third switching lever 40. ing. Accordingly, the urging force of the retracting spring 23 is transmitted to the ejection slider 31 via the first switching lever 19 and the third switching lever 40, and as shown by arrows W and V in FIG. The respective disk discharge arms 12, 14 are rotated in a direction to bring the respective disk discharge pins 13, 15 to the second reversal position.
[0147]
When the distal end of the second switching lever 43 is disengaged from the operated end 21 of the first switching lever 19, and the respective disc ejection pins 12, 14 reach the second reversing position, FIG. As shown, the operating end 22 of the first switching lever 19 is disengaged from the distal end 41 of the third switching lever 40, and the retracting spring 23 returns to the initial state. The discharge slider 31, while being biased in the other end direction by the discharge spring 29, is a locking by the lock lever 46. At this time, the disc ejection pins 12 and 14 are separated from the optical disc 201.
[0148]
(3-3) Chucking of optical disk (FIGS. 9 and 10)
When each of the disk retraction arms 54 and 56 reaches the loading position, the retraction slider 51 rotates the stopper member 73 via the hook-like member 93 as shown in FIG. Therefore, at this time, the holding of the chucking frame 84 by the contact support portion 106 of the stopper member 73 is released , and the chucking frame 84 is rotated to the chucking position by the urging force of the tension coil spring 89.
[0149]
When the chucking frame 84 is at the chucking position, the optical disc 201 is held between the chucking plate 91 and the disc table 4. At this time, in the optical disk 201, the peripheral portion facing the base end of each of the disk pull-in pins 55 and 57 faces the defective portions 108 and 198 by the chucking plate 91 being lowered to the chucking position. Then, they are separated from the disk draw-in pins 55 and 57.
[0150]
In this state, the optical disc 201 can be rotated by the spindle motor, and the information signal can be read from the optical disc 201 by the optical pickup device 5.
[0151]
(3-4) optical disk ejecting operation (FIGS. 11 to 16)
In this disc player device, as shown by an arrow X in FIG. 11, when the eject button 82 is pressed to slide the eject slider 77 backward, the eject slider 77 is moved by an arrow Y in FIG. As shown in the drawing, the engagement piece 81 returns the retracting slider 51 to the position where the disk retracting arms 54 and 56 are at the initial position via the return operation pin 65.
[0152]
At this time, the hook-shaped member 93 comes into contact with the engaging pin 74 of the stopper member 73 and is temporarily rotated rearward to engage the hook on the tip end with the engaging pin 74. When it reaches the position, it is rotated forward and returns to the initial state.
[0153]
When the eject slider 77 slides rearward, the chucking frame 84 is rotated upward by the release operation pin 80 via the tapered cam portion 88 to the release position, and the stopper member 73 is moved. At the release position.
[0154]
When the chucking frame 84 is at the release position, the optical disk 201 is placed on the disk lifter plate 90 and separated from the disk table 4 above.
[0155]
When the eject slider 77 slides rearward, the lock lever 46 is rotated, and the lock lever 46 releases the engagement with the discharge slider 31.
[0156]
Discharge slider 31 is released the locking by the lock lever 46 by the urging force of the ejection spring 29, as shown by an arrow C and an arrow D in FIG. 12, the respective disk ejection pins 13 and 15 are front side The disc ejecting arms 12 and 14 are operated to rotate in the direction of moving the discs.
[0157]
Each disk ejection arms 12 and 14, as shown in FIGS. 11 to 14, the respective disk ejection pins 13 and 15 until the above initial position, FIG. 11 through as shown in Figure 13 in an arrow C and an arrow D Is rotated.
[0158]
At this time, the rear edge of the optical disk 201 is pressed by the disk ejection pins 13 and 15, and as shown by an arrow Z in FIG. 12 and FIG. Is ejected to the front side.
[0159]
When the respective disc ejection arms 12 and 14 are rotated until the respective disc ejection pins 13 and 15 are set to the initial position, the second switching lever 43 moves the leading end of the second switching lever 43 toward the first switching lever 19. Contacted with the operated end 21, but once turned toward the rear, and when the leading end reaches a position where it does not contact the operated end 21, it is turned forward and returned to the initial state. . Therefore, at this time, the first switching lever 19 is not rotated.
[0160]
Further, when the respective disc ejection arms 12 and 14 are rotated until the respective disc ejection pins 13 and 15 are set to the initial position, the third switching lever 40 is moved to the first switching lever 19. There is no contact.
[0161]
When the disc ejection pins 13 and 15 are at the initial position, the optical disc 201 is clamped on both sides by the brake members 97 and 97, as shown in FIG. The operation is stopped in a state where approximately half of the outer case projects forward of the outer casing through the slot 7.
[0162]
Then, as shown by an arrow Z in FIGS. 15 and 16, when the optical disk 201 is pulled out from the outer housing through the slot 7, the disk retraction arms 54 and 56 are moved by arrows H in FIG. As indicated by an arrow J, the disc pull-in pins 55 and 57 are rotated in a direction of approaching each other by the urging force of the pull-in spring 113, and push the optical disc 201 forward.
[0163]
When the optical disk 201 is pulled out from the outer casing to the front side, the disk detection lever 62 returns to the initial position as shown in FIG. As shown in FIG. 16, when the optical disk 201 is pulled out from the outer casing to the front side, the disk detection lever 62 causes the disk detection pin 63 to move the pull-in slider 51 to the disk pull-in arms 54 and 54. 56 is held at the initial position. In this manner, the eject operation is completed when the respective disk retraction arms 54 and 56 return to the initial positions.
[0164]
【The invention's effect】
As described above, in the disc loading mechanism according to the present invention, the disc ejection member is prevented from coming into contact with the optical disc mounted on the disc mounting portion, and the lock by the lock mechanism is released, whereby the disc ejection member is released. Thus, the optical disk can be ejected to the front side.
When the locking of the disk discharge member is released and the disk discharge member discharges the optical disk to the front side by the urging force of the discharge urging means via the disk contact member, the disk slide member comes into sliding contact with the peripheral edge of the optical disk. In the case where a brake member for suppressing the moving speed of the optical disc is provided, the moving speed of the optical disc ejected by the disc ejecting member is appropriately suppressed, so that the optical disc can be prevented from being thrown into the air.
[0165]
In other words, the present invention enables simplification, miniaturization, and weight reduction of the device configuration, suppresses an increase in power consumption, and is particularly suitable for being applied to a portable or outdoor disk player device. A disk loading mechanism can be provided.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view showing a configuration of a disc player device having a disc loading mechanism according to the present invention.
FIG. 2 is a perspective view showing a configuration of a disk retraction arm of the disk loading mechanism.
FIG. 3 is a perspective view showing a configuration of a disc ejection arm of the disc loading mechanism.
FIG. 4 is a plan view showing an initial state of the disc loading mechanism.
FIG. 5 is a plan view showing a state in which an operation of inserting an optical disk is started in the disk loading mechanism.
FIG. 6 is a plan view showing a state during the operation of inserting an optical disk in the disk loading mechanism.
FIG. 7 is a plan view showing a state where an optical disc is inserted in the disc loading mechanism and an operation on a disc ejection arm is started.
FIG. 8 is a plan view showing a state in which the optical disc is pulled in and the disc ejection arm is operated in the disc loading mechanism.
FIG. 9 is a plan view showing a state where the optical disk is pulled in the disk loading mechanism and the urging direction of the disk discharge arm is reversed.
10 is a plan view showing a state in which the urging direction of disk ejection arms are inverted locking again in the disk loading mechanism.
FIG. 11 is a plan view showing a state where a disc ejection operation is started in the disc loading mechanism.
FIG. 12 is a plan view showing a state in which a disk discharge arm has started discharging the optical disk in the disk loading mechanism.
FIG. 13 is a plan view showing a state where the disc ejection arm is ejecting the optical disc in the disc loading mechanism.
FIG. 14 is a plan view showing a state in which the disc ejection arm has completed ejection of the optical disc in the disc loading mechanism.
FIG. 15 is a plan view showing a state in which the optical disc ejected by the disc ejection arm is taken out of the outer casing in the disc loading mechanism.
FIG. 16 is a plan view showing an initial state in which the optical disc is returned after the optical disc is taken out by the disc loading mechanism.
[Explanation of symbols]
4 disk table, 5 optical pickup device, 51 pull-in slider, 54, 56 disk pull-in arm, 55, 57 disk pull-in pin, 59, 61 support hole, 62 disk detection lever, 84 chucking frame, 91 chucking plate, 92 chuck King arm, 113 Retraction spring, 201 Optical disk

Claims (2)

A support top plate arranged on the rear side of the disc mounting portion for reading out an information signal recorded by rotating the optical disc;
A disk contact member pressed by an optical disk moved from the front toward the disk mounting portion is provided at the distal end side, and is supported by the support top plate so as to be rotatable in the front-rear direction. A disc ejecting member that is rotated in a direction in which the disc contact member moves backward by an optical disc that is moved toward
A discharge slider attached to the support top plate so as to be movable in the left-right direction, and a gear portion of the disk discharge member meshes with a rack gear;
An ejection urging member for urging the disc ejection member in a direction in which the disc contact member moves forward, and an urging force for urging the disc ejection member in a direction in which the disc contact member moves rearward. An urging means comprising a retracting urging member that generates an urging force stronger than the urging force of the discharge urging member;
An urging direction switching mechanism that switches an urging direction of the urging means with respect to the disk ejection member in accordance with a moving direction and a position of the disk contact member;
A lock lever that is locked to the discharge slider and locks the discharge slider so that the disk contact member moves forward.
The biasing direction switching mechanism includes a first switching lever rotatably attached to the support top plate, a first switching lever rotatably attached to the support top plate, a front end side being an operation end, and a rear end side being an operated end. , The base end side of which is rotatably attached to the discharge slider, and the distal end side of which is urged to rotate in a direction facing the operated end of the first switching lever, and the cam of the support top plate. A second switching lever that is controlled to rotate by a unit, and a forward end of the first switching lever, a base end of which is rotatably attached to the ejection slider, and an operating end of the first switching lever. And a third switching lever opposed to
The discharge urging member has one end locked to a support top plate and the other end locked to a discharge slider, and applies a disk discharge member in a direction in which the disk contact member goes forward via the discharge slider. The retracting urging member has one end locked to the support top plate and the other end locked to the first switching bar, and is moved through the first switching lever and the third switching lever. The disc contact member biases the disc ejection member in a direction toward the rear,
The disc ejection member positions the disc contact member at a position forward of a first reversing position corresponding to a rear edge of the optical disc when the optical disc is at a position facing the disc mounting portion. When the discharge urging member, the discharge urging member is rotationally urged forward through the discharge slider,
When the disc contact member is moved backward by the movement of the optical disc, the disc contact member is rotated against the urging member for ejection, and the second switching lever is moved to the operated end of the first switching lever. When the distal end of the lever comes into contact and the retracting urging member starts to extend and reaches the first reversal position, the operating end of the first switching lever is brought into contact with the distal end of the third switching lever. In opposition, the ejection slider is urged by the retraction urging member in the direction in which the disk contact member goes rearward,
When the disc contact member reaches the second reversing position on the rear side of the first reversing position, the operation end of the first switching lever is moved from the tip of the third switching lever by the movement of the ejection slider. A disc loading mechanism , wherein the retracting urging member returns to an initial state, and is locked by the lock lever in a state of being urged by the discharging urging member . Further, when the locking of the lock lever to the disc ejection member is released, and the disc ejection member ejects the optical disc to the front side by the urging force of the ejection urging member via the disc abutting member, 2. The disk loading mechanism according to claim 1, further comprising a brake member that slides on a peripheral portion of the optical disk to suppress a moving speed of the optical disk.

Images