JPH08106774A - Disc driver - Google Patents

Abstract

PURPOSE: To enable a producing of a temperature detection means of a disc cassette at a lower cost while eliminating the need to consider the laying of cables. CONSTITUTION: A cassette holder 2 and a spindle lifting/lowering plate body 3 move upward or downward independently and an elastic deformation part 121a is made up of a flexible substrate 121 arranged on the spindle lifting/ lowering plate body 3. A temperature sensor S5 is fixed in such a manner that it does not contact a disc cassette DK in a cassette waiting state by on the elastic deformation part 121a and presses onto the disc cassette DK in a cassette loaded stated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disc drive device in which a disc cassette is replaceable, and more particularly to a technique for detecting the temperature of the disc cassette.

[0002]

2. Description of the Related Art In a disk of a recording medium in which information signals can be written or read, or both written and read by magnetic, optical or magneto-optical means, a disk for writing or reading It is important because the temperature of the recording medium has a great influence on recording and reproduction.

For example, in a magneto-optical disk, a high laser power is required because it is necessary to raise the temperature of the magnetic thin film above the Curie point during recording and erasing, and the recorded information is not demagnetized during reproduction. Relatively low laser power is required. Then, these laser powers are determined by the temperature of the disc, that is, it is necessary to set the size so that optimum recording / reproducing is performed. For example, even if the laser power during recording is set to an optimum condition at a certain temperature of the disk, the laser power during recording may be too low or too high due to the temperature change of the disk, and good magnetization reversal may not be possible. is there. Similarly, if the laser power during reproduction and erasure is too large or too small, the recorded information signal may be demagnetized or unerased may occur.

Therefore, conventionally, various means for detecting the temperature of the disk have been proposed, an example of which is shown in FIG. In FIG. 40, the disc cassette DK has a disc 201 rotatably housed in a case 201. The disc cassette DK is configured to be inserted into and removed from a cassette holder (not shown), and the cassette holder is provided to be movable up and down with respect to the chassis 210. When the cassette holder is in the upper position, it is in the cassette standby state, and when the cassette holder is in the lower position, the cassette is in the mounted state (state in FIG. 40).
Becomes A lower end of a spring 211 is fixed on the chassis 210, and a temperature sensor S is fixed on an upper end of the spring 211. The temperature sensor S does not come into contact with the disc cassette DK in the cassette stand-by state, and the spring 2 is displaced below the disc cassette DK in the cassette mounted state.
The spring force of 11 presses the disk cassette DK.

The detection output of the temperature sensor S is supplied to the central processing unit 212 via a cable (not shown), and the central processing unit 212 controls the laser power of the semiconductor laser 213 according to the detected temperature. Reference numeral 214 is a magnetic head.

[0006]

However, according to the above-mentioned conventional configuration, in addition to the temperature sensor S, the spring 210 is necessary to detect the temperature of the disc cassette DK, and the detection output of the temperature sensor S is used. Since a cable (not shown) for guiding is also required, the cost is high and it is necessary to consider the routing of the cable.

Therefore, an object of the present invention is to provide a disk drive device which is inexpensive in detecting the temperature of a disk cassette and which does not require consideration of cable routing.

[0008]

DISCLOSURE OF THE INVENTION A disk drive device according to the present invention for achieving the above-mentioned object has a cassette holder in which a disk cassette accommodating a disk can be inserted and removed, and the disk is in a cassette standby state. In a disc drive device that allows the cassette to be inserted / removed and enables recording / playback to / from the disc in the cassette mounted state, in the cassette mounted state rather than in the cassette standby state, relatively close to the cassette holder. A flexible substrate is provided on the member, and an elastically deforming portion utilizing its own elasticity is formed on the flexible substrate. The elastically deforming portion does not contact the disc cassette in the cassette standby state, and does not contact the disc cassette in the cassette mounted state. A temperature sensor is provided in pressure contact with the disc cassette. This temperature sensor is arranged so as to come into pressure contact with the cassette insertion rear surface of the disc cassette in the cassette mounted state.

Since a part of the flexible substrate arranged in a member relatively close to the cassette holder is configured as an elastically deformable portion and the temperature sensor is mounted on this elastically deformable portion, the flexible substrate is usually arranged for another purpose. In consideration of this, the components to be used are substantially only the temperature sensor, and the detection output of the temperature sensor may be wired so as to be guided using the flexible substrate.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. 1 to 37 show an embodiment of the present invention.

(Disc Cassette) FIGS. 36 and 37 show a disc cassette which can be attached to and detached from the disc drive device. In FIGS. 36 and 37, the disc cassette DK is for magneto-optical recording, and a disc-shaped magneto-optical disc (disc) 202 is rotatably accommodated in an eccentric case 201. A metallic hub 203 is fixed to the center of the magneto-optical disk 202,
The hub 203 is attached to the turntable of the disk drive device with the cassette mounted.

The case 201 comprises an upper half member 201a and a lower half member 201b.
1a and the lower half member 201b are joined together in a butted state. Openings 204a are formed at the positions where the upper half member 201a and the lower half member 201b face each other, and a hub hole 204b is further formed in the lower half member 201b. A part of the magneto-optical disk 202 is exposed from each opening 204a of the upper half member 201a and the lower half member 201b, and a hub 203 is exposed from a hub hole 204b of the lower half member 201b.

A shutter 205 is provided on the case 201 so as to be slidable in the directions of the arrows in FIGS. 36 and 37, and both openings 204a are formed by the shutter 205.
Also, the hub hole 204b is opened and closed. This shutter 20
5, one end of a torsion coil spring (not shown) is hooked,
Due to the spring force of this torsion coil spring, the shutter 205
Is biased toward the closed position. Incidentally, FIGS. 36 and 37 show a state in which the shutter 205 is located at the open position. Further, a bridge portion 205a is provided to project from the shutter 205, and the bridge portion 205a is arranged along the insertion front end face 201c of the case 201.

Positioning grooves 206 are formed at symmetrical positions on the rear end side of the lower half member 201b on the rear side of the cassette insertion, and the positioning pins of the disk drive device are inserted into the pair of positioning grooves 206 so that the disk is driven. The cassette DK is positioned in the plane direction. Further, since this disk cassette DK is for RAM, an erroneous erasure prevention member 207 is slidably provided at the cassette insertion rear end side of the case 201, and whether or not writing is possible is selected depending on the position of the erroneous erasure prevention member 207. It The erasure prevention member 7 is not provided for the ROM. Further, a drawing groove 208 is formed on one side end of the case 201 on the front side of the cassette insertion side.

(Disk Drive Device) FIG. 1 is a perspective view of the disk drive device, FIG. 2 is an exploded perspective view of the disk drive device, and FIG. 3 is an exploded perspective view of the cassette holder 2 and the slide plate 4 and the like. 4 is an exploded perspective view of the slide plate 4 and the spindle lifting plate body 3 and the like,
5 is a perspective view of the cassette holder 2, FIG. 6 is a perspective view of the cassette auto eject mechanism G, FIG. 7 is a perspective view of the head mechanism H, FIG. 8 is a perspective view of the head lifting mechanism I, and FIG.
Is a perspective view of the linear / rotary motion exchange section I ₁ , and FIG. 10 is an exploded perspective view thereof.

The following description will be given in the following order.

1. Overall outline 2. Chassis etc. 3. Holder / spindle lifting mechanism (slide plate,
Spindle lifting plate body, cassette holder) 4. Slide plate lock mechanism 5. Cassette auto-injection mechanism 6. Shutter opening / closing mechanism 7. Disk rotation mechanism 8. Cassette positioning means 9. Cassette auto eject mechanism 10. Measures against runaway of loading motor 11. Head mechanism 12. Magnetic head lifting mechanism 13. Sensor group 14. Explanation of motor control, etc. 15. State of each part when waiting for cassette insertion 16. Shutter opening operation 17. Cassette auto-injection operation 18. Operation when the cassette is installed 19. 20. Operation of spider motor drive and lock release of head carriage, operation of temperature sensor 20. Operation of descending magnetic head 21. Operation in sleep mode 22. Operation at power failure 23. Operation during cassette eject (1. Overall outline) In FIGS. 1 and 2, the disk drive device has a cassette holder 2 and a spindle lifting plate body 3 on a chassis 1, and these members are mounted by sliding a slide plate 4. Holder / spindle elevating mechanism A for elevating and lowering, and slide plate lock mechanism B for locking the slide plate at the unloading position.
A cassette auto-injection mechanism C that automatically pulls the disc cassette DK to the insertion completion position when the disc cassette DK is inserted into the cassette holder 2, and a disc cassette DK when the disc cassette DK is inserted into the cassette holder 2. Shutter opening / closing mechanism D for opening the shutter 205, a disk rotating mechanism E provided on the chassis 1 so as to be able to move up and down and rotationally driving the magneto-optical disk 202 of the disk cassette DK, and positioning of the disk cassette DK at the mounting position. Cassette positioning means F
And a cassette auto eject mechanism G for ejecting the disc cassette DK at the mounting position, and a disc cassette D
A head mechanism H that is displaced in the radial direction of the K magneto-optical disk 202 and performs magneto-optical recording / reproduction with the magnetic head 80 and the optical head 78 (optical pickup), and a magnetic head elevating mechanism I that elevates the magnetic head 80. , And a sensor group for detecting each state of the cassette side and the drive side.

(2. Chassis, etc.) In FIGS. 1 and 2, the chassis 1 is formed of a member having a high rigidity (for example, an Alky die cast), and is erected on the bottom surface and both left and right sides and the rear side of the bottom surface. It is composed of a standing wall portion. A front panel (not shown) is arranged on the front side of the chassis 1, and the disc cassette DK is inserted and ejected through the cassette insertion hole of the front panel. The upper surface of the chassis 1 is covered with a cover (not shown), and the above-described mechanisms and the like are housed in a substantially rectangular parallelepiped space surrounded by the covers.

(3. Holder / Spindle Lifting Mechanism) The holder / spindle lifting mechanism A has a slide plate 4 arranged so as to be in contact with the chassis 1 as shown in detail in FIGS. 2 to 4. 4, elongated holes 5 in the same direction are formed at four locations. This long hole 5
Fixed guide pins 6 are inserted into the chassis 1, respectively, and the slide plate 4 is guided by the guide pins 6 and slidable in the directions of arrows A and A'in FIG. The slide plate 4 has an unloading position (the position shown in FIG. 11) and a loading position (the position shown in FIG. 12).
Position). A tension coil spring 8 is hung between the slide plate 4 and the spring retaining pin 7 of the chassis 1, and the spring force urges the slide plate 4 in the direction of arrow A (on the loading position side).

At appropriate positions on both sides of the slide plate 4, a holder raising / lowering guide surface 9 and a spindle raising / lowering guide groove 10 are provided.
And a holder raising / lowering guide surface 9 are provided.
The vertical difference in height is set to be sufficiently smaller than that of the guide groove 10 for raising and lowering the spindle. A pair of left and right holder elevating / lowering support members 11 are attached to the chassis 1, and the restriction vertical grooves 12 of each holder elevating / lowering support member 11 are arranged along the holder elevating / lowering guide surface 9.

The cassette holder 2, which will be described in detail later, is arranged above the chassis 1, and guide pins 13 are provided at appropriate positions at the lower left and right ends of the cassette holder 2. Each of the guide pins 13 is inserted into each of the regulation vertical grooves 12, and each of the guide pins 13 is guided by the holder elevating / lowering guide surface 9 and moves only in the vertical direction. That is, the cassette holder 2 moves up and down by the slide of the slide plate 4, and the slide plate 4 moves to the unloading position (see FIG.
1 position), the slide plate 4 is at the upper position (the cassette standby position shown in FIG. 11) and the loading position (FIG. 1).
2 position), it is located at the lower position (cassette mounting position shown in FIG. 12). Further, spring holding pins 14 are provided at the left and right lower ends of the cassette holder 2, and a coil portion of a torsion coil spring 15 is held by each spring holding pin 14. Both ends of each torsion coil spring 15 are hooked on spring retaining portions 16 of each holder elevating / lowering support member 11, and the spring force of the torsion coil spring 15 urges the cassette holder 2 to the lower position (cassette mounting position) side. .

The spindle elevating plate body 3 is guided by a guide block body 17 fixed to the chassis 1 so as to be vertically movable. Guide pins 18 are provided at appropriate places on the spindle elevating plate body 3, and the guide pins 18 are arranged so as to be guided by the holder elevating guide grooves 10 and move vertically. That is, the spindle elevating plate body 3 is moved up and down by the slide of the slide plate 4, and the slide plate 4 is in the lower position (see FIG.
1 to the cassette standby position), and the slide plate 4 in the loading position (position in FIG. 12) is in the upper position (FIG. 12).
Cassette mounting position) shown in.

The cassette holder 2 is shown in FIGS. 5 (a) and 5 (b).
As shown in detail in FIG. 1, one metal plate is bent and formed, and the upper surface portion 2a, a pair of side surface portions 2b hanging from both sides of the upper surface portion 2a, and the lower end portions of the pair of side surface portions are inserted inward. It has a pair of lower surface edge portions 2c and is surrounded by these to form a cassette insertion space 19. Recesses 20 projecting to the cassette insertion space side are formed at four locations on the upper surface by press molding, and as shown in FIG. 5B, the height H ₁ from the upper surface of the lower edge 2c to the recess 20.
Is set to be slightly higher than the height (thickness) H ₂ of the disc cassette DK. Therefore, the disc cassette DK is smoothly inserted into the cassette insertion space 19 of the cassette holder 2 and is smoothly ejected from the cassette insertion space 19. The recess 20 constitutes a part of the cassette positioning means F described below.

A magnetic head 8 described below is provided on the upper surface 2a.
A notch portion 21 for inserting 0 is formed and a cassette stopper portion 22 is provided, and the cassette stopper portion 22 has a front end face 2 for inserting the disc cassette DK.
The position where 01c abuts is the cassette insertion completion position.

(4. Slide Plate Lock Mechanism) The slide plate lock mechanism B is as shown in detail in FIG.
There is a lock member 24 supported by a support shaft 23 of the chassis 1, and the lock member 24 rotates in the directions of arrows B and B '. One end side of the torsion coil spring 25 is locked to the lock member 24, and the lock member 24 is urged in the arrow B direction (lock direction) by this spring force. The lock member 24 is provided with a locking claw portion 24a and a release lever portion 24b, and the locking claw portion 24a is engaged with and disengaged from the lock pin 26 of the slide plate 4. That is, the locking claw portion 24a is locked to the lock pin 26 of the slide plate 4 so that the slide plate 4 is locked at the unloading position. The release lever portion 24b is located in the cassette insertion space 19 with the locking claw portion 24a locked, and is pushed by the inserted disk cassette DK to be in the arrow B'direction (release direction).
To be rotated.

(5. Cassette auto-injection mechanism)
The cassette auto-injection mechanism C is shown in FIGS.
As shown in detail in (a), it has a first injector plate 30 arranged on the lower surface side of the lower surface edge portion 2c of the cassette holder 2, and the first injector plate 30 is a guide for the lower surface edge portion 2c. Guided by the pin 31, FIG.
It is provided so as to be slidable in the directions of arrows C and C'in FIG. A rotation support shaft 32 is fixed to one end side of the first injection plate 30, and a second injection plate 33 is rotatably provided on the rotation support shaft 32. The cam groove 3 is formed in the second injector plate 33.
4 is formed, and the guide pin 31 is provided in the cam groove 34.
Has been inserted. In addition, the second injector plate 3
3, a cassette pull-in pin 35 is provided upright, and the cassette pull-in pin 35 is rotated in the direction of arrows D and D'in FIG. 5 by the rotation of the second injector plate 33.

The third injector plate 36 is supported by a support shaft 37 provided at an extension of the lower surface edge 2c,
It is rotated in the E and E'arrow directions in FIG. A locking pin 38 is provided at one end of the third injector plate 36,
The locking pin 38 is locked in the locking groove 39 of the first injector plate 30. A hold pin 40 is provided on the other end of the third injector plate 36, and the hold pin 40 is engaged with and disengaged from the injector holding piece portion 41 of the slide plate 4. Ends of a tension coil spring 42 are hooked on the locking pin 38 and the guide pin 31, respectively, and the spring force urges the third injector plate 36 in the direction of arrow E.

When the slide plate 4 is displaced from the loading position to the unloading position, the injector holding piece portion 41 presses the hold pin 40,
Inject plate 36 pulls coil spring 42
By rotating in the direction of the arrow E ′ against the spring force of the cassette pull-in pin 35, the cassette pull-in pin 35 is positioned at the standby position outside the cassette insertion space 19. Then, when the slide plate 4 is displaced from the unloading position to the loading position, the injector holding piece 41 is separated from the hold pin 40, and the third injector plate 36 is rotated in the E arrow direction by the spring force of the tension coil spring 42. As a result, the cassette pull-in pin 35 is located at the locking position in the cassette insertion space 19, and slides together with the first injector plate 30 to cause the disc cassette DK.
Automatically retracts to the cassette insertion complete position.

(6. Shutter Opening / Closing Mechanism) The shutter opening / closing mechanism D has a cam hole 43 formed in the upper surface 2a of the cassette holder 2 as shown in detail in FIGS. It is composed of an inclined area inclined with respect to the cassette insertion direction and a linear area in the same direction as the cassette insertion direction. A shutter opening pin 44 protruding into the cassette insertion space 19 is engaged with the cam hole 43, and the shutter opening pin 44 is fixed to one end of the moving plate 45. A long hole 45a for adjusting the distance is formed at the other end of the moving plate 45, and a moving guide pin 46 is engaged with the long hole 45a. The movement guide pin 46 is arranged in the cassette insertion space 19, and both ends of the movement guide pin 46 are guide holes 47 in the upper surface portion 2a and the lower surface edge portion 2c of the cassette holder 2.
Has been inserted. A spring retaining portion 48 is provided at the center of the moving plate 45, and a tension coil spring 50 is engaged between the spring retaining portion 48 and the spring retaining portion 49 of the cassette holder 2. The spring force of the tension coil spring 50 causes the shutter release pin 44 to move to the position shown in FIG.
It is biased toward the starting end position side shown in FIG.

(7. Disc Rotation Mechanism) As shown in detail in FIG. 4, the disc rotation mechanism E has a flat spindle motor M ₁ fixed to the lower surface side of the spindle lifting plate body 3. Rotating shaft 51 of M ₁
Protrudes upward from the hole 3a of the spindle lifting plate body 3. A turntable 52 is fixed to the rotary shaft 51, and a ring-shaped reference surface 52a is formed on the upper surface of the turntable 52. A magnet member 53 is provided inside the ring-shaped reference surface 52 a, and the hub 203 of the magneto-optical disk 202 is attracted to the turntable 52 by the attraction force of the magnet member 53.

(8. Cassette Positioning Means) The cassette positioning means F, as shown in detail in FIGS. 4, 5 (a) and 5 (b), has height determining members 55 provided upright at four locations on the chassis 1. The height determining member 55 is provided integrally with the chassis 1. The height determining member 55 may be a member separate from the chassis 1. Each height determining member 55
The above-mentioned recesses 20 of the cassette holder 2 are arranged directly above the disk holders 2. The disk cassette DK at the mounting position is placed on each height determining member 55 while being pressed downward by each recess 20 of the cassette holder 2. By doing so, positioning in the height direction is performed.

Here, the dimensional standards (thickness, flatness, etc.) of the disc cassette DK are the upper and lower half members 201a, 20a.
Since the peripheral portion of 1b is used as the reference surface, the four height determining members 55 are arranged to support the four corners in the reference surface of the rectangular disc cassette DK.

Further, the cassette positioning means F has a pair of left and right positioning pins 56 erected on the spindle lifting plate body 3, and the pair of positioning pins 56 is located at the raised position of the spindle lifting plate body 3 and is a disc cassette D.
It is inserted into each of the pair of K positioning grooves 206.
The disk cassette DK at the mounting position is horizontally positioned by the pair of positioning pins 56.

(9. Cassette Auto Eject Mechanism) The cassette auto eject mechanism G has a loading block body 57 fixed on the chassis 1, as shown in FIGS. the intermediate gear mechanism 58 outputting from deceleration to the end gear 58a and rotation of the loading motor M ₂ and the loading motor M ₂ is a direct current motor is housed. An output gear 59 arranged outside the loading block body 57 meshes with the end gear 58a, and an output pin 60 is provided so as to project from the outer peripheral side surface of the output gear 59. Further, a reference position detection switch S for detecting the rotational position of the output pin 60 is provided in the loading block body 57.
W _A, the reverse rotation position detection switch SW _B (FIG. 4, not shown in FIG.) Are provided, the respective detection switches S
W _A and SW _B output the output signals shown in FIG. 18 when the rotational position of the output pin 60 is defined as shown in FIG. That is, the loading motor M ₂ is controlled based on the outputs of the reference position and the reverse rotation position detection switches SW _A and SW _B , and the reference position is determined from the output of the reference point detection switch SW _A.
The position of point a and the position of point b are respectively recognized from the output of the reverse rotation point detection switch SW _B.

Returning to FIG. 6, a retracting bent piece 61 of the slide plate 4 is arranged at the rotation locking position of the output pin 60. The retracting bent piece 61 bends one end of the slide plate 4. It is composed of songs. When the output pin 60 at the reference position rotates in the direction of the arrow R1, the output pin 60 pulls in the retracting bent piece 61, pulls the slide plate 4 and displaces it from the loading position to the unloading position against the spring force of the coil spring 8. .

A pressed portion 85a of the main slider 85 and a pressed portion 87a of the sub-slider 87 of the magnetic head lifting mechanism H, which will be described below, are also disposed at the rotation locking position of the output pin 60. When the output pin 60 at the reference position rotates in the R2 arrow direction or the R1 arrow direction, the output pin 60 presses the pressed portion 85a or the pressed portion 87a via the pull-in bent piece 61 to thereby cause the magnetic head 80 to move. The loading block body 5 is also configured to move up and down.
Reference numeral 7 also serves as a part of the magnetic head lifting mechanism I.

(10. Means for Preventing Runaway of Loading Motor) On the other hand, a gear portion 62 is provided on a part of the outer periphery of the output gear 59.
A notched portion 63 in which the end gear 58a is not formed is provided, and the rotation of the end gear 58a is not transmitted at the position of the notched portion 63. That is, with respect to the rotational position of the output pin 60, the dead area shown in FIG.
8a is the range in which the rotation is not transmitted, and the output pin 60 rotating in the direction of the arrow R1 exceeds the position of point a, and even if the loading motor M ₂ is driven (runaway), the output pin 60
Does not continue to rotate in the direction of the arrow R1 and does not collide with the pressed portion 85a of the main slider 85. Also, R
2 Even if the output pin 60 which is rotating in the direction of the arrow exceeds the position of point b and the loading motor M ₂ is driven (runaway), the output pin 60 does not continue to rotate in the direction of the arrow R 2 and is for retracting the slide plate 4. It does not collide with the bent piece 61.

Further, as shown in FIG. 19, the first cam plate 64 and the second cam plate 65 are fixed to the shaft 59a of the output gear 59, and the projections 64a and 6 of the cam plates 64 and 65 are fixed.
The tip ends of the leaf springs 66 and 67 supported by the loading block body 57 are arranged so as to abut on 5a, respectively. In one leaf spring 66, the output gear 59 is R
By the rotation in the direction indicated by the arrow 1 abuts the protruding portion 64a of the first cam plate 64 at a position where it is disengaged from the end gear 58a, and the spring force urges the output gear 59 in the direction indicated by the arrow R2. The other leaf spring 67 has a second cam plate 65 at a position where the output gear 59 is disengaged from the end gear 58a by the rotation in the direction of the arrow R2.
Abutting against the projecting portion 65a, and the spring force biases the output gear 59 in the R1 arrow direction. That is, since it is urged to the end gear 58a side deviates from the end gear 58a is an output gear 59 by the presence of the notch 63 immediately mates with the end gear 58a and the output gear 59 by the reverse rotation of the loading motor M ₂ Return to the state.

In this embodiment, the means for preventing runaway of the loading motor M ₂ is constituted by the cam plate and the leaf spring, but it may be constituted by utilizing the magnetic force of the permanent magnet. Further, it is also possible to configure each with one cam plate and each leaf spring without configuring with each two cam plates and each leaf spring.
In this case, it is necessary to provide protrusions at two locations on the cam plate.

(11. Head Mechanism) The head mechanism H has a pair of left and right guide rail shafts 70 supported on the chassis 1, as shown in detail in FIGS. Extend in the radial direction of the mounted magneto-optical disk 202. A head carriage 71 is arranged between the pair of guide rail shafts 70, and rollers 72 are rotatably supported at a total of three positions on the left and right sides of the head carriage 71. The left and right rollers 72 are in contact with the pair of guide rail shafts 70 from the inclined direction of about 45 degrees with respect to the horizontal direction, and the head carriage 71 causes the rollers 72 to roll on the pair of guide rail shafts 70 so that the photomagnetism is generated. It is configured to be movable in the radial direction of the disk 202.

The linear motor M ₃ has a pair of left and right outer yokes 74, magnets 75 and inner yokes 76 fixed to the chassis 1 at a position further outside the pair of guide rail shafts 70, and these members are respectively arranged. It is a long flat plate and is arranged in the same direction as the guide rail shaft 70. Although the outer yoke 74 and the magnet 75 are arranged in close contact with each other, the magnet 75 and the inner yoke 76 are arranged with a constant gap. A coil portion 77 is slidably arranged so as to surround the outer circumference of the pair of left and right inner yokes 76, and the pair of coil portions 77 is fixed to the head carriage 71. Depending on the direction of the current supplied to the pair of coil portions 77, the head carriage 71 moves in the G arrow direction or G '.
Moved in the direction of the arrow.

The optical head 78 has a head carriage 71 via two flexible plates 79 having parallel spring properties.
It is configured to be capable of being finely displaced in the vertical direction against the spring force of the two flexible plates 79. A small linear motor (not shown) is formed between the optical head 78 side and the head carriage 71 side, and the driving force of the linear motor moves the optical head 78 up and down.
The optical head 78 is provided with an objective lens 78a,
Laser light emitted from an optical block (not shown) is focused on the magneto-optical disc 202 by the objective lens 78a, and laser light reflected from the magneto-optical disc 202 is returned to the optical block via the objective lens 78a. At this time, the focus of the laser light is controlled by displacing the position of the objective lens 78a.

The magnetic head 80 for magnetic field modulation is a flying type supported at the other end of a head arm 81 of a leaf spring whose one end is fixed to a head carriage 71, and is located directly above the optical head 78. There is. The head arm 80 is inclined downward toward the other end side (head side), and the magnetic head 80 is set to a height that contacts the magneto-optical disk 202 at the mounting position in the free state.
Then, when the magneto-optical disk 202 is rotated, a lift force is generated in the magnetic head 80 by the air flow, and the lift force causes the head arm 81 to bend in the anti-disk direction, so that the magnetic head 80 floats above the magneto-optical disk 202. The magnetic head 80 running on the magneto-optical disk 202 in this loading state selectively generates a magnetic field perpendicular to the surface of the magneto-optical disk 202 in both directions.

(12. Magnetic Head Elevating Mechanism) The magnetic head elevating mechanism I, as shown in detail in FIGS. 4, 6 and 8 to 10, has a loading block 57 and an output pin 60 of the loading block 57. The linear / rotary motion converting section I _{1 in} which the first lifter control member 101 and the second lifter control member 96 are rotated by the movement of the slide plate 4 and the first lifter control member 101 of the linear / rotary motion converting section I ₁ . And a lifter mechanism I ₂ which is moved up and down by the rotation of the second lifter control member 96.

The linear / rotary motion converting section I ₁ is shown in FIGS.
As shown in 0, the support member 8 fixed on the chassis 1
2, a main slider 85 is slidable on the support member 82 in the directions of arrows H and H'by a guide pin 83 and an elongated hole 84. The main slider 85 is urged in the direction of the arrow H (initial position direction) by the spring force of the tension coil spring 86, and the main slider 85 at the initial position has its pressed portion 85a separated from the output pin 60 at the reference position. Is located in.

The sub-slider 87 is slidable in the directions of arrows H and H'with respect to the main slider 85 by the guide pin 88 and the elongated hole 89. This sub-slider 87 is also biased in the direction of the arrow H (initial position direction) by the spring force of the other tension coil spring 90, and the pressed portion 87a of the sub-slider 87 at the initial position is a folding fold for retracting the slide plate 4 at the loading position. It is located at a position separated from the bending piece 61. The sub-slider 87 is provided with a second pressing pin 91 at the end opposite to the pressed portion 87a.

The swing plate 92 is supported by the main slider 85 by a support pin 93 so as to be rotatable in the directions of arrows I and I '. The swing plate 92 is biased in the direction of the arrow I by the spring force of the torsion coil spring 94, and the upper surface 92a of the swing plate 92 is located at a position where it abuts on the stopper portion 85b of the main slider 85. Further, the swing plate 92 is provided with a first pressing pin 95.

The second lifter control member 96 is rotatably supported in the support member 82 by the long shaft 97 so as to be rotatable in the directions of arrows J and J '. The second lifter control member 96 is biased in the direction of the arrow J by the spring force of the torsion coil spring 98, and the lower position where the lifter pressing portion 96a of the second lifter control member 96 contacts the stopper portion 82a of the support member 82 ( Rotation is restricted at the standby position). The second lifter control member 96 rotates between the standby position and the upper position (head-down position) which rotates in the J'arrow direction against the spring force and pushes the lever portion 113b of the lifter 113 described below upward. Displace with. Further, the second lifter control member 96 is provided with an inclined portion 99 that inclines upward as it goes in the direction of the arrow H ', and this inclined portion 99 is positioned at substantially the same height as the first pressing pin 95 of the swing plate 92. are doing. Further, the second lifter control member 96 is provided with the rotation transmission unit 100.

Similarly to the second lifter control member 96, the first lifter control member 101 is also supported by the support member 82 by the long shaft 102 so as to be rotatable in the K and K'arrow directions. The first lifter control member 101 is biased in the direction of the arrow K by the spring force of the tension coil spring 103, and the pin portion 104 of the first lifter control member 101 is the second
The rotation is restricted at a position (lower position) where the lifter control member 96 comes into contact with the rotation transmission portion 100. And the first
The lifter control member 101 rotates in the K'arrow direction against the lower position (head-up position) that pushes the lever portion 113b of the lifter 113 below, and separates from the lever portion 113b of the lifter 113 described below, against the spring force. It is displaced between the upper position (standby position).

Further, the lifter pressing portion 101a of the first lifter control member 101 extends in the moving direction of the head carriage 71 and is set to a length which covers the entire range of movement of the lifter described below. This lifter pressing part 101
A comb tooth portion 105 is provided in the lower part of a. further,
An extension arm portion 106 is integrally provided on the first lifter control member 101, and a magnetic member 107 such as iron is axially supported at the tip of the extension arm portion 106.

The electromagnetic attachment / detachment portion 108 is composed of a pair of upper and lower permanent magnets 110 provided at the tip of the extension arm portion 109 of the support member 82 and a coil portion 111 wound around the outer periphery of each permanent magnet 110. It is arranged at a position above the first lifter control member 101 (standby position) where the end faces of the pair of permanent magnets 110 come into contact with the magnetic member 107. Then, the first lifter control member 1
When 01 is displaced to the upper position against the spring force of the tension coil spring 103, the magnetic member 107 is attracted by the magnetic force of the pair of permanent magnets 110 to hold this state, and the coil portion 111 is energized. The hold is released by generating a magnetic field that cancels the magnetic force of the pair of permanent magnets 110.

The lifter mechanism I ₂ is shown in FIG. 7, FIG. 8, and FIG.
As shown in FIGS. 5 and 16, a lifter 113 axially supported by a side surface of the head carriage 71 via a support pin 112 is provided. The lifter 113 has a lifting portion 113a arranged below the head arm 81. The lever portion 113b protruding into the space between the first lifter control member 101 and the second lifter control member 96, and the permanent magnet 1 at the tip.
The magnet holding arm portion 113c to which 14 is fixed is integrally provided. The lever portion 113b is located right above the second lifter control member 96 when the magnetic head 80 reaches the outermost peripheral position outside the disk recording area. The permanent magnet 114 has a pair of left and right magnetic parts 11.
The pair of left and right magnetic parts 11 arranged between
5, 116 are attached to the head carriage 71. That is, the lifter 113 is at the lower position where the permanent magnet 114 is attracted to the one magnetic portion 115 (state of FIG. 16).
15 and the permanent magnet 114 is attracted to the other magnetic portion 116 and is rotated to an upper position (state of FIG. 15), and in the lower position, the lifting portion 113a is positioned below the head arm 81 so as not to contact with the magnetic field. When the head 80 is in the loading state, and the lifting portion 113a is at the upper position,
By pressing 1 upward, the magnetic head 80 enters the unloading state.

When the first lifter control member 101 is in the lower position, the lifter 113 is in the upper position, and the magnetic head 80 is in the unloading state, in order to unlock the head carriage 71, the loading motor M _{2 is set} to R2.
Drive in a pattern. That is, when the loading motor M ₂ drives the output pin 60 to rotate in the direction of arrow R2, the output pin 60 pushes the main slider 85 against the spring force of the tension coil spring 86 to move in the direction of arrow H '. During this movement process, the first pressing pin 95 of the swing plate 92 causes the second lifter control member 9 to move, as shown in FIG.
The second lifter control member 96 rotates in the direction of the arrow J ′ against the spring force of the torsion coil spring 98 by pressing the inclined portion 99 of 6 downward. Then, with this rotation, the rotation transmitting unit 100
Presses the second pressing pin 91 of the first lifter control member 101, and the first lifter control member 101 is also rotated in the K'arrow direction against the spring force of the tension coil spring 103. Then, when the first lifter control member 101 rotates to the upper position (standby position), the magnetic member 107 is attracted to the pair of permanent magnets 110. The rotation of the first lifter control member 101 unlocks the lifter 113, so that the head carriage 71 can move freely. On the other hand, when the first lifter control member 101 is rotated to the upper position, immediately after that, the first pressing pin 95 causes the inclined portion 9 to move.
It deviates from 9. Then, the first lifter control member 101 is held at the upper position against the spring force of the tension coil spring 103 by the attraction force of the pair of permanent magnets 110, but the second lifter control member 96 is held by the torsion coil spring 98.
Is rotated in the direction of the arrow J and returned to the lower position. When the first pressing pin 95 comes off the inclined portion 99, the loading motor M ₂ is rotated in the reverse direction. Then
As the output pin 60 returns, the main slider 85 also slides in the direction of arrow H by the spring force of the tension coil spring 86. During this return movement, the first pressing pin 95 of the swing plate 92 abuts the inclined portion 99 of the second lifter control member 96, but the swing plate 92 resists the spring force of the torsion coil spring 94 in the direction of the arrow I '. When the first pressing pin 95 rotates and slides along the inclined portion 99, and when the first pressing pin 95 is disengaged from the inclined portion 99, the oscillating plate 92 is rotated by the spring force of the torsion coil spring 94 in the direction indicated by the arrow I. Turn to and return to the original position. Therefore, the main slider 85 returns to the original position along with the rotational displacement of the output pin 60.

When the first lifter control member 101 is in the upper position (standby position) and the lifter 113 is in the upper position, the magnetic head 8 is
When 0 is in the unloading state, in order to bring the magnetic head 80 into the loading state, the head carriage 71 is displaced to the outermost periphery, and then the low dig motor M ₂ is moved to R.
Drive in two patterns. Then, the first
The operation without rotating the lifter control member 101 is performed. When the second lifter control member 96 is rotated from the lower position to the upper position, the lifter pressing portion 96a pushes the lever portion 113b of the lifter 113 upward.
Then, the lifter 113 is displaced from the lower position to the upper position and the lifting portion 113 a is displaced downward so as not to contact the head arm 81, and the magnetic head 80 enters the loading state.

In order to bring the magnetic head 80 into the unloading state when the first lifter control member 101 is at the upper position (standby position), the coil portion 111 of the electromagnetic detaching portion 108 is required.
Energize for a short time. Then, the magnetic force of the permanent magnet 110 is temporarily canceled, so that the first lifter control member 101 rotates in the direction of the arrow K by the spring force of the tension coil spring 103. First lifter control member 101
The lifter 11 as it moves from the upper position to the lower position.
The lever portion 113b of No. 3 is also displaced from the upper position to the lower position, the lifting portion 113a pushes the head arm 81 upward, and the magnetic head 80 enters the unloading state.

When the first lifter control member 101 is located at the upper position (standby position) and the cassette eject mode is selected, the loading motor M ₂ is driven in the eject pattern. That is, the driving of the loading motor M ₂ moves the slide plate 4 from the loading position to the unloading position. During this movement process, the pull-in bent piece 61 of the slide plate 4 is moved to the sub slider 8
The pressed portion 87a of No. 7 is pressed. Then, the sub-slider 87 is displaced in the direction of the arrow H ′ against the spring force of the tension coil spring 90, but when the pressed portion 87a is displaced to the position of the fixed sub-pressed portion 117, the spring force of the tension coil spring 86 is thereafter. The main slider 85 and the main slider 85 are displaced in the direction of the arrow H '. Immediately after the first pressing pin 95 is disengaged from the inclined portion 99, as shown in FIG. 21, the second pressing pin 91 of the sub-slider 87 contacts the pin portion 104 of the first lifter control member 101, and this pin Part 104
Is pushed upward and the first lifter control member 101 is slightly rotated in the direction of arrow K. Then, the magnetic member 107 of the first lifter control member 101 causes the pair of permanent magnets 110 to move.
With the further separation, the suction force almost disappears, and the first
The lifter control member 101 rotates in the direction of the arrow K by the spring force of the tension coil spring 103 and is displaced to the lower position. As a result, the lever portion 113 of the lifter 113 is
b is pushed downward, the lifter 113 is displaced from the lower position to the upper position, and the magnetic head 80 is in the unloading state.

(13. Sensor group) The pair of cassette state detection sensors S ₁ and S ₂ are mechanical type which detect by the presence or absence of the pressing of the detection rod 118, and as shown in FIG. It is arranged above and below each detection area of the erroneous erasure prevention member 207 of the RAM disk cassette DK. When the spindle lifting plate 3 is at the lowered position as shown in FIG. 14A, the outputs of the pair of cassette state detection sensors S ₁ and S ₂ are both at the L level regardless of whether the disc cassette DK is inserted or not. is there. The spindle lifting plate body 3 is shown in FIG.
At the raised position as shown in FIG. 4 (b), the outputs of the pair of cassette state detection sensors S ₁ and S ₂ are both at the H level when the ROM disk cassette DK is mounted, and when the RAM disk cassette DK is mounted, One is at H level and the other is at L level. This is an erasure prevention member 20.
It changes depending on the position of 7, that is, the presence or absence of write protection.

That is, the pair of cassette state detection sensors S ₁ and S ₂ determines whether or not the disc cassette DK is mounted (cassette in / out), and whether the mounted disc cassette DK is for RAM or ROM ( The type of cassette) and whether or not the mounted RAM disk cassette DK is in the erroneous erasure prevention state (whether or not there is write protection).

The loading state detection sensor S ₃ is a light-blocking type that performs detection depending on whether or not the detected part blocks the detection light. As shown in FIG.
7 is fixed. Loading state detection sensor S ₃
Means that the detected piece 119 of the slide plate 4 is the detected portion, the detected piece 119 blocks the detection light at the unloading position of the slide plate 4, and the detected level is detected at the loading position of the slide plate 4. The piece 119 outputs the H level without blocking the detection light. That is, the loading state detection switch S ₃ detects from the position of the slide plate 4 on the drive device side whether the disc cassette DK is in the loaded state (cassette in / out).

The head-up detection sensor S ₄ is a light-blocking type that performs detection depending on whether or not the detected portion blocks detection light, like the loading state detection sensor S _3, and as shown in FIG. It is fixed to the body 57. The head-up detection sensor S ₄ uses the detected piece 120 provided on the extension arm portion 106 of the first lifter control member 101 as a detected portion, and uses the detected first lifter control member 101.
At the head-up position (lower position), the detected piece portion 120 blocks the detection light, and the detected piece portion 12 is at the standby position (upper position) of the first lifter control member 101.
0 outputs the H level without blocking the detection light.

On the other hand, as shown in FIGS. 2, 4, 14 (a), 14 (b) and 22 (a), the temperature sensor S ₅ has a spindle motor M ₁ and cassette state detection sensors S ₁ , S. It is supported by a flexible substrate 121 on a spindle elevating plate 3 that electrically connects ₂ and the chassis 1 side.
Specifically, as shown in detail in FIG. 22 (a), a part of the flexible substrate 121 is circumferentially bent once to form an elastic deformation portion 121a on the spindle elevating plate 3 using its own elasticity. The temperature sensor S ₅ is fixed to the elastically deformable portion 121a. More specifically, the lead wires of both ends of the temperature sensor S ₅ are fixed to the wiring of the flexible substrate 121 by soldering. When the temperature sensor S ₅ is in the lowered position of the spindle lifting plate 3,
As shown in FIG. 4 (a), the cassette holder 2 is located at a height that does not come into contact with the disc cassette DK inserted in the cassette holder 2, and when the spindle lifting plate 3 is in the raised position, as shown in FIG. It is located at a height at which it comes into pressure contact with the disc cassette DK inserted in the cassette holder 2 in combination with the downward movement. That is, the temperature sensor S ₅ is pressed against the lower surface of the disk cassette DK by the elastic deformation of the elastic deformation portion 121a of the flexible substrate 121. Then, the laser power is controlled according to the temperature detected by the temperature sensor S ₅ , and recording / reproduction is performed with the optimum laser power.

Further, as shown in FIG. 22 (b), a part of the flexible substrate 121 is bent into an Ω shape to elastically deform the portion 121a.
May be configured.

(14. Description of Motor Control, etc.) In FIG. 23, the outputs of the reference position, reverse rotation position detection switches SW _A and SW _B, and the sensors S _{1 to} S ₅ are supplied to the CPU 130, and the CPU 130 outputs commands and the like. In order to execute each program accordingly, for example, command signals such as start and stop are output to each motor controller 131, and each motor controller 131 outputs a control signal to each motor drive circuit 132 based on these command signals. And
The loading motor M ₂ , the spindle motor M ₁ , and the linear motor M ₃ are driven by the drive signal of each motor drive circuit 132. Further, the CPU 130 controls the laser power based on the detection output of the temperature sensor S ₅ .

Further, the CPU 130 is constantly supplied with power, and when power-on is selected, the main power supply section 133 outputs a control signal to supply power to each section. Only the power supply line to the head-up detection sensor S ₄ has the first
The switch SW ₁ is interposed, and the opening / closing of the first switch SW ₁ is controlled by the CPU 130. The CPU 130 executes the program shown in FIG. 29, and controls so that the first switch SW ₁ is turned on in the normal mode and the first switch SW ₂ is turned off in the sleep mode.

The voltage level detecting section 134 is the main power source section 133.
Output voltage is detected and a voltage drop signal is output to the CPU 130 when this output voltage is below a certain level. Then, the CPU 130 causes the second and third switches S
A control signal is output to switch on W ₂ and SW ₃ . In addition, the CPU 130 may use the electromagnetic detaching unit 108 as needed.
The magnetic head 80 is brought into an unloading state by outputting an open pulse to the head carriage 7 and
1 is configured to be locked.

FIG. 24 shows a circuit diagram of the motor drive circuit 132 of the loading motor M ₂ . FIG.
In the above, the motor drive circuit 132 is configured by arranging _four transistors TR _{1 to} TR ₄ in a bridge shape, and the loading motor M ₂ which is a DC motor is connected between the output terminals of this bridge circuit. Although the loading motor M ₂ is not energized even if the voltage of the same level is supplied to the pair of input terminals T ₁ and T ₂ , if the H level voltage is applied to the input terminal T ₁ and the L level voltage is applied to the input terminal T _2. I ₁ current flows, on the contrary, L level at input terminal T ₁ , input terminal T ₂
When a voltage of H level is applied to, the I ₂ current flows in the direction opposite to the I ₁ current, and the rotation direction of the loading motor M ₂ is controlled. Further, the rotation speed is controlled by changing the duty ratio of the voltage applied to the input terminals T ₁ and T ₂ (PWM control). Then, the CPU 130 executes the program shown in FIG. 27 at the time of cassette ejection,
The motor controller 131 outputs the drive waveform signal shown in FIG. Further, the CPU 130 executes the program shown in FIG. 26 when the magnetic head descends, and the motor controller 131 outputs the drive waveform signal shown in FIG.

FIG. 28 shows a circuit diagram of a portion of the spindle motor M ₁ utilizing the counter electromotive force. In FIG. 28,
The input side of each phase of the spindle motor M ₁ and the electromagnetic detaching part 10
8 is connected to one end side of the coil portion 111 through a series circuit of the second switch SW ₂ and the diode D. or,
The other end of the coil unit 111 of the electromagnetic detaching unit 108 is grounded via the third switch SW ₃ . Then, when the spindle motor M ₁ rotates, the second and third switches SW ₂ , SW
_{When 3} is turned on by the control signal of the CPU 130, the counter electromotive force by the spindle motor M ₁ is supplied to the coil unit 111.

(15. State of each part when waiting for cassette insertion) The first lifter control member 101 of the head elevating mechanism I is located at the head-up position (lower position), and the lifter 113
As shown in FIG.
The magnetic head 80 is located at the unloading position and the head carriage 71 is also fixed.
The lock pin 26 of the slide plate 4 is locked by the lock member 24 and is positioned at the unloading position.
1, FIG. 13 (a) and FIG. 14 (a), the cassette holder 2 is located in the raised position and the spindle lifting plate 3 is located in the lowered position. Further, at the unloading position of the slide plate 4, the injector holding piece portion 41 of the slide plate 4 is locked to the hold pin 40 of the third injector plate 36, and the cassette pull-in pin 35 is located at the standby position.

(16. Shutter opening operation) When the disk cassette DK is inserted into the cassette holder 2 in this state, first, the insertion front end face 201c of the disk cassette DK contacts the shutter opening pin 44 as shown in FIG.
When the disc cassette DK is further inserted, the shutter opening pin 44 moves along the cam hole 43 against the spring force of the tension coil spring 50, and the shutter 205 moves in the direction of the arrow L to gradually open. When the shutter opening pin 44 enters the straight portion from the inclined portion of the cam hole 43 as shown in FIG. 31, the shutter 205 is fully opened and the insertion front end face 201c of the disc cassette DK contacts the movement guide pin 46. When the disc cassette DK is inserted further into this state from this state, the shutter opening pin 44 moves along the cam hole 43, and the movement guide pin 46 moves along the guide hole 47. That is, the movable plate 45 moves in parallel in the cassette insertion direction against the spring force of the tension coil spring 50, and the disc cassette DK reaches the insertion completion position as shown in FIG.

(17. Cassette Auto-Injection Operation) In the process of inserting the disc cassette DK, as shown in FIG. 32, the insertion front end of the disc cassette DK pushes the release lever portion 24b of the lock member 24, and the lock member 24 twists. The disc cassette DK is allowed to be inserted by rotating in the direction of the arrow B ′ against the spring force of the coil spring 25. Then, just before the lock pin 26 is unlocked, the cassette pull-in pin 35 is located at the entrance of the pull-in groove 208 of the disc cassette DK. As shown in FIG. 33, when the lock pin 26 is unlocked, the slide plate 4 slides in the direction of arrow A (direction of the loading position), and this slide releases the restriction on the hold pin 40, and the third injector plate is released. 36 rotates in the E arrow direction.

The rotation of the third injector plate 36 causes the first injector plate 30 to slide in the direction of the arrow C, and the second injector plate 33 to move to D.
As shown in FIG. 34, the cassette pull-in pin 35 is rotated in the direction of the arrow so that the pull-in groove 20 of the disc cassette DK is pulled.
Go into 8. In this state, the first injector plate 30 is further slid in the direction of arrow C by the spring force of the tension coil spring 42, whereby the disc cassette DK
Is automatically pulled into the back of the cassette holder 2, and
As shown in FIG. 5, the front end face 20 of the disc cassette DK is inserted.
1c reaches the insertion completion position where it abuts on the cassette stopper portion 22.

At the time of inserting the disc cassette DK, as shown in FIG. 5B, the height of the cassette insertion space 19 in the cassette holder 2 is larger than the thickness of the disc cassette DK, and the leaf spring-like shape is formed. Since there is no cassette pressing member, the disk cassette DK can be smoothly inserted to the insertion completion position. In addition, the following discharge is performed smoothly for the same reason.

(18. Operation during cassette loading (cassette positioning, disk loading)) On the other hand, the slide plate 4 continues to slide even after the disk cassette DK is pulled in to the insertion completion position, and the spindle raising / lowering guide groove 10
Along with the spindle elevating plate body 3 is displaced to the upper position, the cassette holder 2 is displaced to the lower position along the holder elevating guide surface 9 by the spring force of the torsion coil spring 15, and FIGS. Then, the state shown in FIG.

The turntable 52 approaches the hub 203 of the magneto-optical disk 202 by the ascent of the spindle lifting plate 3 and the lowering of the cassette holder 2, and the magnet 203 attracts the turntable 52 to the hub 203 of the turntable 52.
Is mounted, and the magneto-optical disk 202 is made rotatable by driving the spindle motor M ₁ .

As the spindle lifting plate 3 is raised and the cassette holder 2 is lowered, the pair of positioning pins 56 on the spindle lifting plate 3 are inserted into the positioning grooves 208 of the disc cassette DK. Further, when the cassette holder 2 is lowered, the height determining members 55 at four locations on the chassis 1 are inserted into the cassette insertion space 19 and abut on the lower surface of the disc cassette DK. That is, as shown in FIG. 12, FIG. 13B, and FIG. 14B, in the disc cassette DK, the pair of positioning pins 56 has the positioning groove 2.
08, the positioning in the horizontal direction is performed and the recess 20 of the upper surface 2a of the cassette holder 2 is inserted.
The upper surface is supported by and the lower surface is supported by the height determining members 55 at four positions, thereby positioning in the height direction. The height determining member 55 is provided near the four corners of the rectangular disc cassette DK and on the reference plane area.
Since it is supported by, reliable and accurate positioning in the height direction is performed. Further, since the recess 20 presses only directly above the disc cassette DK supported by each height determining member 55, even if the upper half member 201a of the disc cassette DK is deformed to the central convex shape, the height direction is accurately adjusted. Positioning is done.

(19. Operation of Spindle Motor Drive and Head Carriage Lock Release, Function of Temperature Sensor) The pair of cassette state detection sensors S ₁ and S ₂ ascend with the spindle elevating plate body 3 to a detectable position. If the disc cassette DK is for RAM, only one of the outputs changes from the L level to the H level depending on the presence or absence of write protection, and the disc cassette DK outputs RO.
If it is for M, both are switched from L level to H level.

The loading state detection sensor S ₃ switches from the L level to the H level when the slide plate 4 is displaced from the unloading position to the loading position.

The CPU 130 determines that the disc cassette DK has a condition that at least one of the outputs of the pair of cassette state detection sensors S ₁ and S ₂ is at the H level and the output of the loading state detection sensor S ₃ is at the H level. When it is recognized that the head carriage 71 is mounted, the spindle motor M ₁ is driven and the lock of the head carriage 71 is released as follows. That is, the loading motor M ₂ is driven to rotate the output pin 60 in the R2 arrow direction to displace it from the reference position to the b point position, and reversely rotate from the b point position in the R1 arrow direction to return to the reference position again. Then, as described above, the first lifter control member 101 is displaced from the lower position to the upper position, and the lock of the head carriage 71 is released. Whether or not the first lifter control member 101 is displaced to the upper position is checked by whether or not the output of the head-up detection sensor S ₄ is switched to the H level, and if it is at the L level, the lock release operation is performed. Start over.

Further, the temperature sensor S ₅ also rises together with the spindle elevating plate body 3 and comes into pressure contact with the disc cassette DK by the elastic force of the elastically deforming portion 121a. Then, the detection output of the temperature sensor S ₅ is supplied to the CPU 130, and in the recording / reproducing mode, recording / reproducing is performed by the optimum laser power according to the temperature of the disc cassette DK.

(20. Operation of descending magnetic head) CPU1
30 recognizes the type of the mounted disk cassette DK from the output states of the pair of cassette state detection sensors S ₁ and S ₂ , and reads the disc type data recorded on the magneto-optical disc 202 with the optical head 78, The type of the disc cassette DK is recognized. If the results are both for ROM, the next command is waited in the unloading state without lowering the magnetic head 80.

On the other hand, the result of coincidence of both information is the RAM.
For use, the magnetic head 80 is lowered by the following procedure.
That is, the linear motor 73 is driven to drive the head carriage 7.
Move 1 to the outermost position. Next, the loading motor M ₂ is driven to rotate the output pin 60 in the direction of the arrow R2 to displace it from the reference position to the point b position, and reversely rotate in the direction of the point b or the arrow R1 direction to return to the reference position again. Then, as described above, the second lifter control member 96 is displaced from the lower position to the upper position, and the second lifter control member 96 is moved to the lifter 113.
The lever portion 113b of is pushed up. This pressing force displaces the lifter 113 to the lower position, and the magnetic head 80 descends due to the flexure return force of the head arm 81, as shown in FIG. Then, the magnetic head 80 receives the lift force due to the rotation of the magneto-optical disk 202, and enters a loading state in which the magnetic head 80 floats and runs on the magneto-optical disk 202. In this loading state, it waits for the next command such as recording / playback.

Here, the control of the loading motor M ₂ when the magnetic head is lowered is performed based on the flow shown in FIG. That is, FIG. 2 to the loading motor M ₂
By outputting a driving waveform signal as shown in FIG.
The high speed drive is performed in the direction of the arrow 2 for a certain period of time, and the low speed drive is performed after a certain period of time. Then, the displacement speed of the second lifter control member 96 from the lower position to the upper position is fast in the first half but extremely slow in the second half, so that the lifting portion 1 of the lifter 113 is moved.
The magnetic head 80 descending while being regulated by 13a softly lands on the magneto-optical disk 202. Therefore, the magnetic head 80 does not collide with the magneto-optical disk 202 to damage the disk surface, and the situation of defocusing due to contact between the magnetic head 80 and the disk surface does not occur, and the magnetic head 80 descends at a high speed in the first half. Therefore, the head descent time does not take too long.

(21. Operation in Sleep Mode) When the mounted disk cassette DK is in the recordable / reproducible state as described above, the CPU 130 counts the internal counter when waiting for the next command as shown in the flowchart of FIG. Set up. Then, when this count value exceeds a certain value, that is, when a certain time has elapsed without any command, the sleep mode is entered. CPU1
When the sleep mode 30 enters the sleep mode, the first switch SW ₁ is turned off to cut off the power supply to the head-up detection sensor S ₄ . Since the head-up detection sensor S ₄ is usually necessary only when the power is turned on or when the cassette is inserted, the sensor S
The power consumption is reduced by cutting off the power supply in the time zone (sleep mode) where ₄ is completely unnecessary.

If the next command comes before the count value of the counter exceeds a certain value, the counter is cleared and the command is executed.

(22. Operation at the time of power failure) When the power supply to the main power supply section 133 is cut off due to a power failure or the like, the voltage level detection section 134 detects this when the voltage drops by a certain level and outputs it to the CPU 130. . The CPU 130 immediately outputs a control signal to turn on the second and third switches SW ₂ and SW ₃ . Then, the electromotive force of the spindle motor M ₁ is supplied to the electromagnetic attachment / detachment portion 108 to generate a canceling magnetic field. This canceling magnetic field causes the first lifter control member 101 to pull K by the spring force of the coil spring 103.
It rotates in the direction of the arrow and is displaced from the upper position to the lower position.
Due to the displacement of the first lifter control member 101, the lever portion 113b of the lifter 113 is pushed down and displaced to the upper position, and the magnetic head 80 is brought into the unloading state.
Further, the lever portion 113b of the lifter 113 is locked to the comb tooth portion 105 of the first lifter control member 101, and the head carriage 71 is locked.

When the power failure or the like is released, the lock releasing operation of the head carriage 71 is performed.

(23. Operation during cassette eject) When the cassette eject mode is selected, the CPU 130
_First , the spindle motor M ₁ is stopped, and it is confirmed that the rotation of the spindle motor M ₁ is stopped. Then C
The PU 130 drives the loading motor M ₂ to rotate the output pin 60 in the direction indicated by the arrow R1 to displace it from the reference position to the position a, and reverse the direction from the position a to the arrow R2 to return it to the reference position again. Then, when the output pin 60 rotates in the direction of the arrow R1, the pulling bent piece 61 of the slide plate 4 is pressed, and the slide plate 4 slides toward the unloading position side against the tension coil spring 8.
By the first half slide of the slide plate 4, the spindle lifting plate body 3 moves the spindle lifting guide groove 1
0 and the cassette holder 2 is twisted along the holder elevating / lowering guide surface 9 while being displaced to the lower position.
It is displaced to the upper position while resisting the spring force of.

The turntable 52 is moved by the displacement of the spindle lifting plate 3 to the lower position.
The pair of positioning pins 5 are separated from the second hub 203.
6 is a pair of positioning grooves 206 of the disc cassette DK
Get out of. Further, the four height determining members 55 relatively withdraw from the cassette insertion space 19 due to the displacement of the cassette holder 2 to the upper position.

Also, by the latter half sliding of the slide plate 4, the injector holding piece portion 41 of the slide plate 4 presses the hold pin 40, and the third injector plate 36 pulls against the spring force of the tension coil spring 42 and E ′ Rotate in the direction of the arrow. The rotation of the third injector plate 36 causes the first injector plate 30 to slide in the C'arrow direction, and the second injector plate 33 rotates in the D'arrow direction in accordance with this slide. The cassette pull-in pin 35 moves in the cassette ejecting direction by the sliding operation of the first inject plate 30 and the rotating operation of the second inject plate 33, and rotates in the C'arrow direction to rotate the disk cassette DK.
Exit from the drawing-in groove 208. Then, the force restricting the disc cassette DK is released, and the restoring force of the tension coil spring 50 causes the shutter opening pin 44 to move to the starting end position side along the cam hole 43, and is pushed by the shutter opening pin 44 to be pushed to the disc cassette DK. Are moved in the discharge direction. As a result, the disc cassette DK is forcibly ejected from the cassette holder 2.

Here, the control of the loading motor M ₂ at the time of the cassette eject is performed based on the flow shown in FIG. That is, by outputting a driving waveform signal as shown in FIG. 25 to the loading motor M ₂ , high speed driving is performed in the direction of the arrow R1 for a certain period of time, and after a certain period of time, medium speed driving is performed. Then, the displacement speed of the slide plate 4 from the loading position to the unloading position is fast in the first half and slightly slower in the latter half, so that the cassette eject operation is performed very quickly. Further, since the latter half speed is medium, the mechanical impact when the slide plate 4 and the spindle elevating plate body 3 interlocked with the latter are stopped can be suppressed to the same level as in the conventional case.

Further, during the above-mentioned operation process, the cassette pull-in pin 35 keeps the pull-in groove 208 of the disc cassette DK.
The slide plate 4 is displaced to the unloading position at the time of exiting from. Then, the lock member 24, the restriction of which is released as described above, rotates in the direction of the arrow B by the spring force of the torsion coil spring 25, and the slide plate 4
Output pin 6 that is locked to the lock pin 26 of the slide plate 4 and displaces the slide plate 4 to the unloading position.
Even if 0 is returned from the position a to the reference position, the slide plate 4 is held at the unloading position.

On the other hand, when the slide plate 4 is slid as described above, the retracting bent piece 61 of the slide plate 4 presses the pressed portion 87a of the sub-slider 87 of the head lifting mechanism I. Then, as described above, the main slider 85 is also displaced in the direction of the H'arrow next to the sub-slider 87, and the second pressing pin 91 of the sub-slider 87 presses the pin portion 104 of the first lifter control member 101 upward to move the first slider.
The lifter control member 101 is displaced from the upper position to the lower position by the spring force of the tension coil spring 103. The displacement of the first lifter control member 101 causes the lifter 1 to move.
When the lever portion 113b of 13 is pushed, the lifter 113 is displaced to the upper position and the magnetic head 80 is brought into an unloading state. Further, the lever portion 113b of the lifter 113 is locked to the comb tooth portion 105 of the first lifter control member 101, and the head carriage 71 is locked.

In this embodiment, the case where the disk cassette DK and the disk drive device are for magneto-optical recording is shown, but the present invention can be applied to those for magnetic recording or optical recording.

In this embodiment, in the apparatus in which both the cassette holder 2 and the spindle lifting plate body 3 are lifted and lowered separately, the temperature sensor S ₅ is provided on the flexible substrate 121 arranged on the spindle lifting plate body 3. However, the present invention can be similarly applied to a device in which the cassette holder 2 is fixed and only the spindle elevating plate body 3 is moved up and down.
Also, in a device in which only the cassette holder 2 moves up and down,
Flexible substrate 1 arranged on a fixing member such as a chassis
21 is provided with a temperature sensor S ₅ .

38 and 39 show another embodiment of the present invention. In FIG. 38, the case where the disc cassette DK is in the cassette mounted state in the disc drive device DD is shown, and the temperature sensor S ₅ is pressed against the cassette insertion rear surface of the disc cassette DK (area E shown by hatching in FIG. 38). It is arranged to do. That is, the cassette insertion slot 300 of the disk drive device DD
Is pressed against the outer surface of the case 201 of the disk cassette DK close to. The mounting of the temperature sensor S ₅ and the like are the same as those in the above-described embodiment, and thus the description thereof is omitted.

Next, the reason why the temperature sensor S ₅ is pressed against the cassette insertion rear surface of the disk cassette DK will be described. In FIG. 38, only the disc drive device DD is placed in a constant temperature bath at about 50 ° C., and the disc cassette DK (about 30 ° C.) at room temperature is placed in the disc drive device DD.
Attach to. Then, as shown in FIG. 38, the first detection point D ₁ and the second detection point D ₂ of the disc drive device DD, the first detection point K ₁ and the second detection point K ₂ of the disc cassette DK, and the disc D itself are detected. The temperature of each of the disk points d ₁ and d is measured. The first detection point D ₁ and the second detection point D ₂ of the disk drive device DD measure the chassis with a thermocouple, and the first detection point K ₁ and the second detection point K ₂ of the disk cassette DK are the outer surface of the case 201. The temperature at the disk point d ₁ of the disk D itself was measured with an infrared radiation thermometer in a non-contact manner with the disk drive device DD as a read state. During the temperature measurement, the operating condition of the disk drive device DD is as follows: spindle motor on → laser diode on → focus on → tracking on →
Still on.

Focusing on the temperature of the disk drive device DD and the temperature of the disk D, the result shown in FIG. 39 (a) was obtained. That is, when the disc cassette DK of about 30 ° C. is placed in the disc drive device DD of about 50 ° C., it takes about 500 seconds for the temperature of the disc D to reach the temperature of the disc drive device DD. In other words, in the meantime (50
If the writing operation is performed for a time shorter than 0 second), writing with an appropriate laser power will not be performed. Therefore, even if the temperature of the disk drive device DD itself is detected, an appropriate laser power value cannot be calculated.

On the other hand, focusing on the temperature of the disc cassette DK and the temperature of the disc D, the result shown in FIG. 39 (b) was obtained. That is, the second of the disc cassette DK
Although the temperature at the detection point K ₂ rises faster than that at the disc D, the first detection point K ₁ of the disc cassette DK
Then, the temperature rises almost the same as the temperature of the disk D, and the temperature change is almost the same. This is because when a disc cassette DK having a lower temperature than the disc drive device DD is inserted,
Since easy it is warmed by ambient air near the cassette insertion slot 300, the direction of the first detection point K ₁ second detection point K ₂
The temperature rises faster than. Then, since the disk D is rotating, due to the influence of the relatively high temperature portion,
It is considered that the temperature of the disk D rises almost the same as the temperature at the first detection point K ₁ . It should be noted that the fact that the temperature starts at about 36 ° C. even though the disc cassette DK at about 30 ° C. is inserted into the disc drive device DD takes several seconds to insert the cassette, so the disc cassette DK was warmed up during this period. This is considered to be due to the influence of the disk drive device DD.

That is, the temperature of the disk D can be accurately detected by the temperature of the first detection point K ₁ of the disk cassette DK, and the laser power can be optimized. As a result, accurate signals can be recorded and high density recording can be performed.

[0100]

As described above, according to the present invention, the flexible substrate is provided on the member relatively close to the cassette holder in the cassette mounted state rather than the cassette standby state, and the elastic substrate is elastically deformable. Since a temperature sensor is provided in this elastically deformable portion, the temperature detection of the disk cassette is inexpensive because the parts used are essentially only the temperature sensor, and a flexible board is used for the wiring of the temperature sensor. By using it, there is an effect that it is not necessary to consider the routing of the cable.

Further, since the temperature sensor is arranged so as to be in pressure contact with the cassette insertion rear surface of the disc cassette in the cassette mounted state, there is an effect that the temperature of the disc can be accurately detected.

[Brief description of drawings]

FIG. 1 is a perspective view of a disk drive device (embodiment example).

FIG. 2 is an exploded perspective view of a disk drive device (embodiment example).

FIG. 3 is an exploded perspective view of a cassette holder, a slide plate and the like (embodiment example).

FIG. 4 is an exploded perspective view of a slide plate, a spindle lifting plate body, and the like (embodiment example).

5A is a perspective view of a cassette holder, and FIG. 5B is a partial cross-sectional view of the cassette holder (embodiment example).

FIG. 6 is a perspective view of a cassette eject mechanism (embodiment example).

FIG. 7 is a perspective view of a head mechanism (embodiment example).

FIG. 8 is a perspective view of a magnetic head lifting mechanism (embodiment example).

FIG. 9 is a perspective view of a linear / rotational motion conversion unit of the magnetic head lifting mechanism (embodiment example).

FIG. 10 is an exploded perspective view of a linear / rotary motion conversion unit of the magnetic head lifting mechanism (embodiment example).

FIG. 11 is a vertical cross section of the disk drive device in a cassette standby state (embodiment example).

FIG. 12 is a vertical cross-sectional view of the disk drive device with the cassette mounted (embodiment example).

13A is a cross-sectional view of the disk drive device in a cassette standby state, and FIG. 13B is a cross-sectional view of the disk drive device in a cassette mounted state (embodiment example).

14A is a cross-sectional view of the disk drive device in a cassette standby state, and FIG. 14B is a cross-sectional view of the disk drive device in a cassette mounted state (embodiment example).

FIG. 15 is a side view of the head mechanism in an unloading state (embodiment example).

FIG. 16 is a side view of the head mechanism in a loading state (embodiment example).

FIG. 17 is a diagram showing the relationship between the rotational position of the output pin and the action (embodiment example).

FIG. 18 is a diagram showing an output of each detection switch with respect to a rotation angle (embodiment example).

FIG. 19 is a perspective view of the vicinity of an output gear (embodiment example).

FIG. 20 is a side view (embodiment example) showing a state in which the first pressing pin presses the inclined portion and the second lifter control member is rotated.

FIG. 21 is a side view (embodiment example) showing a state in which the second pressing pin presses the pin and the first lifter control member is rotated.

22A is a perspective view showing an attached state of a temperature sensor (embodiment example), and FIG. 22B is a perspective view showing an attached state of a temperature sensor of a modified example.

FIG. 23 is a block diagram of a control circuit (embodiment example).

FIG. 24 is a circuit diagram of a motor drive circuit of a loading motor (embodiment example).

FIG. 25 is a drive waveform diagram during each operation (embodiment example).

FIG. 26 is a flowchart when the magnetic head descends (example embodiment).

FIG. 27 is a flowchart at the time of cassette ejection (embodiment example).

FIG. 28 is a circuit diagram of a portion of the spindle motor using back electromotive force (embodiment example).

FIG. 29 is a flowchart when switching between a normal mode and a sleep mode (embodiment example).

FIG. 30 is a plan view (embodiment example) showing a state where the front end face of the disc cassette is in contact with the shutter opening pin.

FIG. 31 is a plan view showing a state where the shutter is fully opened (embodiment example).

FIG. 32 is a plan view (embodiment example) showing a state where the front end face of the disc cassette is in contact with the release lever portion of the lock member.

FIG. 33 is a plan view (embodiment example) showing the moment when the lock member is unlocked.

FIG. 34 is a plan view (embodiment example) showing a state where the cassette pull-in pin pulls in the disc cassette.

FIG. 35 is a plan view (embodiment example) showing a state in which the disc cassette is located at the insertion completion position.

FIG. 36 is a perspective view of the disc cassette seen from the upper surface side.

FIG. 37 is a perspective view of the disc cassette seen from the lower surface side.

FIG. 38 is a schematic plan view of another disk drive device with the disk cassette mounted (another embodiment).

FIG. 39 (a) is a diagram showing a temperature rise characteristic of a disc;
FIG. 7B is a diagram showing temperature rise characteristics of each position of the case and the disk (another embodiment).

FIG. 40 is a schematic configuration diagram (conventional example) of an apparatus including temperature detection means.

[Explanation of symbols]

DK ... disk cassette S ₅ ... temperature sensor 2 ... cassette holder 3 ... spindle lifting plate member (member to be relatively close to the cassette holder) 121 ... flexible substrate 121a ... elastically deformable portion

Claims (2)

[Claims] 1. A cassette holder having a disc cassette accommodating a disc that can be inserted / removed, allows insertion / removal of the disc cassette in a cassette standby state, and recording / reproducing to / from the disc in a cassette mounted state. In a disk drive device that enables the flexible substrate to be provided in a member relatively close to the cassette holder in the cassette mounted state rather than the cassette standby state, and the flexible substrate is elastically deformed by utilizing its own elasticity. A disk drive device comprising a temperature sensor which constitutes a part and which does not abut against the disk cassette in the cassette standby state and presses against the disk cassette in the cassette mounted state. 2. The disk drive device according to claim 1, wherein the temperature sensor is arranged so as to be in pressure contact with a cassette insertion rear surface of the disk cassette in a cassette mounted state.