JP2005050464A - Magnetic head elevating/lowering mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a magnetic head elevating/lowering mechanism which reduces load to be concentrated on a head support arm in which a magnetic head is provided. <P>SOLUTION: The magnetic head elevating/lowering mechanism is equipped with a base chassis 7 having the rotatary drive 59 of a recording medium 4 and an optical pickup device 64, a holder 6 which holds a recording medium cartridge 5 and makes the recording medium 4 attach to and detach from the rotation driving mechanism 59 by being operated to rise and fall to the base chassis 7, a magnetic head device 71 which has a magnetic head 73 which is faced inside the holder 6 from a head insertion port 96 formed in the top plate part 82 of the holder 6 and a head support arm 74 which supports the magnetic head 73 which is extended on the top plate part 82 and a connecting member 72 which connects the head support arm 74 and the optical pickup device 64 and a rise and fall operating plate 104 which is provided in the top plate part 82 and operates the rise and fall of the magnetic head 73 over the inside and the outside of the holder 6 by supporting the head support arm 74. Moreover, in the head support arm 74, a connection part 55 with the connecting member 72 has flexibility and the connecting part 55 bend and is deformed by being brought into sliding contact with the top plate part 82 according to the rising and falling action of the holer 6. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a lifting mechanism for a magnetic head mechanism that applies an external magnetic field to a recording medium.

  2. Description of the Related Art Conventionally, there are recording and / or reproducing apparatuses (hereinafter referred to as “recording / reproducing apparatuses”) that record or reproduce information signals on an information recording medium such as a magneto-optical disk. As shown in FIG. 32, this type of recording / reproducing apparatus 300 has a cartridge holder 301 that holds a cartridge in which an information recording medium such as a magneto-optical disk is stored, and is opposed to the cartridge holder 301 and is held by the cartridge holder 301. A base in which a magnetic head device 302 and an optical pickup device 303 for recording or reproducing an information signal with respect to an information recording medium in the cartridge and a rotation driving mechanism 304 for rotating the information recording medium are provided on the cartridge holder side. A chassis 305 and a slider 306 for loading or unloading the cartridge by moving the cartridge holder 301 close to and away from the base chassis 305 are provided.

  As shown in FIG. 33, the base chassis 305 is provided with side walls 310, 310 on both side surfaces orthogonal to the cartridge insertion direction. A guide groove 312 for guiding the movement of 306 is provided. In addition, the base chassis 305 is provided with an eject lever 313 that pushes the cartridge to the insertion port on the main surface portion so as to be rotatable. The eject lever 313 is urged to rotate toward the insertion port side where the cartridge is always discharged by a tension coil spring 314 provided between the eject lever 313 and the slider 306. Further, the eject lever 313 is restricted from rotating by slidably coming into contact with the extending portion 317 of the slider 306, and can be rotated to the insertion port side by moving the slider 306 forward.

  A slider 306 is engaged with the base chassis 305 so as to be slidable in the cartridge insertion direction. As shown in FIGS. 34 and 35, the slider 306 includes a connecting portion 316 that is long to the left and right, extending portions 317 and 318 that protrude rearward from the left and right ends of the connecting portion 316, and the extending portions 317 and 318, respectively. Side surfaces 319 and 320 that are respectively suspended from the side edges are integrally formed. Cam grooves 321 and 322 for engaging the cartridge holder 301 are formed in the side surface portions 319 and 320 so as to be separated from each other in the front-rear direction. The cam grooves 321 and 322 are each formed with an upper horizontal portion 321a and 322a, an inclined portion 321b and 322b, and a lower horizontal portion 321c and 322c successively from the rear side. A support pin 325 formed on the cartridge holder 301 is slidably engaged with the cam grooves 321 and 322, and the support pin 325 is guided along the cam grooves 321 and 322 by sliding the slider 306. The cartridge holder 301 is moved close to and away from the base chassis 305.

  The cartridge holder 301 guided by the slider 306 includes a top plate portion 326, side plate portions 327 and 328 that are respectively suspended from the left and right side edges of the top plate portion 326, and a lower edge of the side plate portions 327 and 328. The receiving plate portions 329 and 330 that protrude toward each other are integrally formed. The top plate portion 326 is formed with a head insertion port 326a into which the magnetic head portion of the magnetic head device 302 is inserted. A head shift lever 331 is rotatably supported at the rear edge of the head insertion port 326a. As shown in FIG. 36, the head shift lever 331 is spaced from the left edge in the front-rear direction, and a rotation restricting piece 331a and a substantially V-shaped actuating piece 331b are projected leftward. In the cartridge holder 301, a top lever 326 and a head lever 331 are supported together with a cam lever 333 that constitutes a head moving mechanism for moving the magnetic head up and down so as to be movable in the front-rear direction.

  As shown in FIG. 37, the cam lever 333 includes a supported part 334 that is long in the front and rear direction, a protruding part 335 that protrudes rightward from the supported part 334, and a cam leg 336 that protrudes downward from the supported part 334. It is integrally formed. The protruding portion 335 protrudes rightward from the right edge of the supported portion 334, and a cam piece 337 formed by bending a part of the protruding portion 335 is provided at the tip. In addition, the cam leg 336 is formed as a cam portion 338 at a portion below the center in the vertical direction. The cam portion 338 is formed with an inclined portion 338a that is displaced backward as it goes from the upper side to the lower side.

  The magnetic head device 302 is provided with a head support arm 345 through a substantially U-shaped connecting member from the pickup base of the optical pickup device 303 provided in the base chassis 305, and this head support arm 345 is connected to the head shift lever 331. It is placed. A magnetic head 345 a is provided at the front end of the head support arm 345 so as to correspond to the objective lens formed on the pickup base. Further, an arm restricting plate 346 for restricting excessive displacement of the head support arm 345 upward is provided above the head support arm 345. The arm restricting plate 346 is attached to the connecting member and presses the head support arm 345 from above. Further, the arm restricting plate 346 is formed with a front end portion 346a at the front side edge portion of the head insertion port 326a in order to prevent an excessive lift on the head insertion port 326a formed in the top plate portion 326 of the cartridge holder 301. The locking piece 332 is locked.

  A joint lever 340 for sliding the slider 306 is supported on the side wall 310 of the base chassis 305 so as to be movable in the front-rear direction. As shown in FIG. 38, the joint lever 340 is provided with an actuated piece 340a in contact with the gear mechanism at the lower edge from the front end, and a pressing piece 340b in contact with the slider 306 at the upper edge. Yes. Further, the joint lever 340 is biased rearward by a tension coil spring 341 suspended between the joint lever 340 and the side wall 310 of the base chassis 305.

  A drive lever 348 for moving the cam lever 333 is provided on the main surface portion of the base chassis 305 so as to be movable in the front-rear direction. As shown in FIG. 39, the drive lever 348 has an engagement hole 348a, and the cam leg 336 of the cam lever 333 is inserted into and engaged with the engagement hole 348a. As a result, the drive lever 348 moves the cam lever 333 back and forth along the inclined portion 338a as it moves back and forth. The drive lever 348 is provided with one end of a tension coil spring 349 provided between the drive lever 348 and a spring locking projection provided on the main surface of the base chassis 305, and is biased forward of the base chassis 305.

  In addition, the recording / reproducing apparatus 300 is formed with a limit lever, an operating lever, a DC motor as a driving source, and a gear mechanism that transmits the rotational force of the DC motor. In such a recording / reproducing apparatus 300, since the drive lever 348 is moved forward in the state before the cartridge is inserted, as shown in FIG. 40, the cam lever 333 has a lower end portion of the cam leg 336 at the drive lever. 348 is engaged with the engagement hole 348a. At this time, in the head shift lever 331, the actuating piece 331b is in contact with the proximal end of the cam piece 337 of the cam lever 333, the head support arm 345 is in a substantially horizontal state, and the magnetic head 345a is inserted into the cartridge holder 301. Retracted to a position where it does not interfere with the cartridge.

  Next, when the cartridge is inserted into the cartridge holder 301, the eject lever 313 pressed against the cartridge body is rotated rearward, and the slider 306 whose movement is restricted by the eject lever 313 is pulled by the biasing force of the tension coil spring. Moved backwards. As the slider 306 moves rearward, the cartridge holder 301 is brought into contact with the main surface portion of the base chassis 305 with the support pins 325 being guided in the cam grooves 321 and 322. As a result, a recording medium such as a magneto-optical disk housed in the cartridge is mounted on the rotation drive mechanism 304.

  As the cartridge holder is moved downward, the cam lever 333 is also moved downward, and the cam portion 338 of the cam leg 336 engaged with the engagement hole 348a of the drive lever 348 has an upper portion via an inclined portion 338a. Engage with the engagement hole 348a. Therefore, the cam lever 333 is moved slightly rearward with respect to the cartridge holder 301. As the cam lever 333 moves rearward, the head shift lever 331 is held on the top plate portion 326 of the cartridge holder 301 lowered by the actuated piece 331b coming into contact with the top of the cam piece 337 of the cam lever 333. The recording / reproducing apparatus 300 reproduces the recording medium in this state. When recording an information signal on a recording medium, the drive lever 348 is moved backward via the gear mechanism, the limit lever, and the operating lever when the DC motor is driven. The holder 301 is moved rearward. At this time, as shown in FIG. 41, the head shift lever 331 is such that the actuated piece 331 b gets over the cam lever 333 and the rotation restricting piece 331 a is the opening edge of the head insertion port 326 a formed in the top plate portion 326 of the cartridge holder 301. Since the head support arm 345 is inserted into the cartridge holder 301, the magnetic head 345a contacts the recording medium. When the recording of the information signal is stopped, the DC motor is driven in reverse, the drive lever 348 is moved forward, and the cam lever 333 is also moved forward with respect to the cartridge holder 301. As a result, the head shift lever 331 retracts the magnetic head 345 a provided on the head support arm 345 onto the top plate portion 326 of the cartridge holder 301 because the actuated piece 331 b comes into contact with the top of the cam piece 337 of the cam lever 333. Let

  When an eject operation is performed in a state where reproduction or recording is stopped, the joint lever 340 in which the operated piece 340a is pressed by the gear mechanism driven by the drive motor is moved forward. When the joint lever 340 is moved forward, the slider 306 is moved forward by the pressing piece 340b, and the cartridge holder 301 in which the support pins 325 are engaged with the cam grooves 321 and 322 of the slider 306 is raised from the base chassis 305. To go. When the cartridge holder 301 is raised, the cam lever 333 is configured such that the cam portion 338 of the cam leg 336 engaged with the engagement hole 348a of the drive lever 348 passes through the inclined portion 338a from the upper portion and the lower portion engages with the engagement hole. 348a is engaged. Accordingly, since the cam lever 333 is moved slightly forward with respect to the cartridge holder 301, the actuated piece 331b of the head shift lever 331 is in contact with the base end of the cam piece 337 of the cam lever 333 and is rotated substantially horizontally. . Accordingly, the magnetic head 345 a of the head support arm 345 supported by the head shift lever 331 is retracted on the top plate portion 326 of the cartridge holder 301.

  Further, as the slider 306 moves forward, the eject lever 313 whose rotation is restricted by the slider 306 can be rotated by the tension coil spring 314. At this time, the cartridge holder 301 is raised to the insertion / removal position, and the magnetic head 345a is retracted on the cartridge holder 301. Therefore, the eject lever 313 can eject the cartridge without interfering with the magnetic head 345a. it can.

  In the recording / reproducing apparatus 300 described above, when the magnetic head 345a is brought into sliding contact with the signal recording surface of the information recording medium and retracted out of the cartridge holder 301, as shown in FIGS. This is done by bending the provided head support arm 345 into the cartridge holder 301. Therefore, in the head support arm 345, the load relating to the bending deformation is concentrated at the bending position into the cartridge holder 301.

  Further, due to a drop impact or the like, the engagement between the distal end portion 346 a of the arm regulating plate 346 and the locking piece 332 provided in the head insertion port 325 is disengaged, and the head support arm 345 is caused to face the cartridge holder 301. May not be possible.

JP 2001-23327 A

  SUMMARY OF THE INVENTION An object of the present invention is to provide a magnetic head lifting mechanism that reduces a load concentrated on a head support arm provided with a magnetic head.

  In order to solve the above-described problems, a magnetic head lifting mechanism according to the present invention includes a rotation drive mechanism that rotates an information recording medium and an optical pickup device that records or reproduces information signals on the information recording medium. A holder for holding the recording medium cartridge in which the information recording medium is stored, and a holder for attaching and detaching the information recording medium to and from the rotary drive mechanism by being lifted and lowered with respect to the base chassis, and the holder A magnetic head that faces the inside of the holder through a head insertion opening formed in the top plate portion of the recording medium and applies an external magnetic field to the information recording medium, and extends on the top plate portion of the holder to support the magnetic head And a magnetic head device having a connecting member for connecting the head support arm and the optical pickup device, and a top plate portion. And a lifting operation plate that lifts and lowers the magnetic head in and out of the holder according to operation by supporting the head supporting arm, and the head supporting arm has a connection portion with the connecting member. It has flexibility, and the connection portion is bent and deformed by being brought into sliding contact with the top plate portion of the holder in accordance with the lifting and lowering operation of the holder.

  The magnetic head elevating mechanism according to the present invention includes a base chassis provided with a rotation drive mechanism for rotating an information recording medium, an optical pickup device for recording or reproducing information signals on the information recording medium, and information A holder for holding the recording medium cartridge in which the recording medium is accommodated and moving up and down with respect to the base chassis, and a holder for attaching and detaching the information recording medium to and from the rotational drive mechanism, and a top plate portion of the holder are formed. A magnetic head that faces the inside of the holder from the head insertion opening and applies an external magnetic field to the information recording medium, a head support arm that extends on the top plate portion of the holder and supports the magnetic head, and A connecting member for connecting the head support arm and the optical pickup device; and the head support provided between the connecting member and the head support arm. A magnetic head device having a rotation support member for rotatably supporting the arm in the up-and-down direction of the holder with respect to the connecting member, and provided on the top plate portion, and supporting the head support arm for operation. In response, the magnetic head includes an elevating operation plate for elevating the inside and outside of the holder, and the head support arm has a flexible connection portion with the rotation support member, and the holder is moved up and down. As a result, the connection member is rotated by the rotation support member and is slidably contacted with the top plate portion of the holder to be bent and deformed.

  According to the magnetic head elevating mechanism as described above, in a state where the cartridge holder is separated from the base chassis, the cartridge holder is brought into contact with the connecting portion between the head support arm and the connecting member from below and biased upward. Yes. At this time, since the connecting portion is bent and deformed, a load applied to the connecting portion as the cartridge holder is raised can be absorbed. Further, when the connection portion is urged upward by the cartridge holder, the rotation support member is rotated upward. Therefore, since the connection part attached to the rotation support member is rotated upward, the amount of refraction is reduced and the load on the connection part can be reduced.

  Hereinafter, a recording and / or reproducing apparatus (hereinafter referred to as “recording / reproducing apparatus”) to which a magnetic head lifting mechanism according to the present invention is applied will be described in detail with reference to the drawings. A recording / reproducing apparatus 1 to which the present invention is applied is a disk recording / reproducing apparatus that records and reproduces information signals with respect to, for example, a magneto-optical disk. As shown in FIG. An apparatus main body 2 and a recording / reproducing mechanism 3 disposed in the apparatus main body 2 are provided. The recording / reproducing mechanism 3 has a cartridge holder 6 for holding a disk cartridge 5 of a magneto-optical disk 4 inserted in the recording / reproducing apparatus 1 and a magneto-optical disk 4 of a disk cartridge 4 inserted in the cartridge holder 6. And a slider 8 and a guide chassis 9 for bringing the cartridge holder 6 and the base chassis 7 close to and away from each other.

  The recording / reproducing apparatus 1 is incorporated in an apparatus main body of an information processing apparatus (not shown) such as a personal computer, a PDA, or an AV device, and transmits / receives data to / from the information processing apparatus to be stored in the disk cartridge 5 Information signals are recorded on or reproduced from the stored magneto-optical disk 4.

  Here, the disc cartridge 5 that can be mounted on the recording / reproducing apparatus 1 will be described with reference to FIG. In this disk cartridge 5, a magneto-optical disk 4 capable of recording an information signal such as a musical sound signal is rotatably accommodated in a cartridge body 14 formed by abutting and joining a pair of upper and lower halves 12 and 13. A clamping plate 16 made of a magnetic material that can be magnetically attracted by a magnet attached to the central portion of the magneto-optical disk 4 housed in the cartridge main body 14 is made to face outward at the center of the lower surface side of the cartridge main body 14. A central opening 17 is formed. In addition, a portion of the signal recording area formed on the main surface of the magneto-optical disk 4 housed in the cartridge main body 14 is exposed to the outside over the inner and outer circumferences at opposite positions on the upper and lower surfaces of the cartridge main body 14. The recording / reproducing openings 18 and 19 are formed. These recording / reproducing openings 18 and 19 are located at the center in the left-right direction of the cartridge body 14 and are formed from the vicinity of the center of the cartridge body 14 to the side surface 14a.

  Further, a shutter member 21 that opens and closes the recording / reproducing openings 18 and 19 is attached to one side surface 14a of the cartridge body 14 so as to be movable in the arrow B direction and the counter arrow B direction in FIG. The shutter member 21 includes a first shutter portion 22 that closes the recording / reproducing opening 18, a second shutter portion 23 that closes the recording / reproducing opening 19, the first shutter portion 22, and the second shutter portion 23. Are formed by bending a thin metal plate into a U-shaped cross section. A shutter mounting recess 25 is provided from the periphery of the recording / reproducing openings 18 and 19 to the back surface 14c at opposing positions on the upper and lower surfaces of the cartridge body 14 facing each other. 14 is attached to the shutter mounting recess 25 so as to be fitted from one side surface 14a, and is moved along the one side surface 14a of the cartridge body 14. When the shutter member 30 is in a position where the recording / reproducing openings 18 and 19 are closed, the shutter member 30 is locked by a shutter lock member (not shown) disposed in the cartridge main body 14 and its movement is restricted. When the disc cartridge 5 is inserted into the recording / reproducing apparatus 1, the shutter member 21 is unlocked by the shutter lock member by the shutter opening piece on the recording / reproducing apparatus 1 side, and the recording / reproducing openings 18, 19 are opened. The moving operation is performed in the direction of arrow B in FIG.

  In addition, on the lower surface of the cartridge main body 14, positioning concave portions 28 and 29 are provided on the front surface 14b side and the rear surface 14c side to engage the positioning pins 53 on the recording / reproducing apparatus 1 side. This is a reference hole with which the positioning reference pin on one side is engaged.

  The disc cartridge 5 thus formed is inserted into the recording / reproducing apparatus 1 from the direction of arrow C in FIG. 2 with the front surface 14b orthogonal to the moving direction of the shutter member 21 as the insertion end. Then, the shutter member 21 is moved in the direction of arrow B in FIG. 2, and causes a part of the magneto-optical disk 4 to face outward in the radial direction from the recording / reproducing openings 18 and 19. At the same time, the magneto-optical disk 4 rotatably accommodated in the cartridge body 14 is magnetically attracted and rotated by the disk rotation driving mechanism on the recording / reproducing apparatus 1 side. In the magneto-optical disk 4, the magnetic head unit 73 provided at the tip of the magnetic head device 71 on the recording / reproducing apparatus 1 side enters from the one recording / reproducing opening 18 to apply an external magnetic field to the magneto-optical disk 4. At the same time, the optical signal is written by irradiating the magneto-optical disk 4 with the light beam emitted from the optical pickup device 64 of the recording / reproducing apparatus 1 via the other recording / reproducing opening 19.

  As shown in FIG. 1, the recording / reproducing apparatus 1 that uses the disk cartridge 5 as described above as a recording medium includes a recording / reproducing mechanism 3 that is loaded with the disk cartridge 5 and performs recording / reproducing of an information signal. The apparatus main body 2 is configured by including an attachment member 42 to be attached and a cover 43 that covers an upper surface of the attachment member 42 to which the recording / reproducing mechanism 3 is attached, and the attachment member 42 and the cover 43 are connected to each other.

  The cover member 43 constituting the front portion of the apparatus main body 2 has an insertion opening 44 into which the cartridge 5 is inserted. The cartridge 5 is inserted into the insertion opening 89 of the cartridge holder 6 described later in the insertion opening 44. A leading escutcheon 45 is provided.

  As shown in FIGS. 3 and 4, the recording / reproducing mechanism 3 includes a base chassis 7 to which the disk cartridge 5 is mounted and a cartridge holder 6 that holds the inserted disk cartridge 5. The base chassis 7 and the cartridge holder 6 are close to and away from each other while holding the disc cartridge 5. When the disc cartridge 5 is inserted into the cartridge holder 6, the base chassis 7 and the cartridge holder 6 move toward each other. Is mounted on the base chassis 7. The base chassis 7 and the cartridge holder 6 are moved away from each other when the disk cartridge 5 mounted on the base chassis 7 is ejected.

  As shown in FIGS. 4 and 5, the base chassis 7 is formed in a flat, substantially rectangular shape using a highly rigid metal plate. The base chassis 7 is provided with a mounting portion 52 on one main surface portion to which the disk cartridge 5 is mounted. Positioning pins 53, 53 a that engage with the positioning recesses 29, 29 a of the disk cartridge 5 protrude from the mounting portion 52 so that the disk cartridge 5 can be positioned and mounted. The disk cartridge 5 is mounted on the mounting portion 52 with its mounting position positioned by engaging the positioning recesses 29 and 29a with the positioning pins 53 and 53a.

  Further, on the upper surface side of the base chassis 7, a cartridge detection switch (not shown) that detects that the disk cartridge 5 is mounted in the mounting portion 52 is disposed. The cartridge detection switch is pressed by the cartridge holder 6 when the cartridge holder 6 comes close to the base chassis 7, and detects that the disc cartridge 5 is mounted on the mounting portion 52. The cartridge detection switch is mounted on a printed wiring board 256 disposed on the lower surface side of the base chassis 7 and protrudes from the opening provided in the base chassis 7 to the upper surface side of the base chassis 7.

  As shown in FIG. 5, a disk rotation driving mechanism 59 that rotates the magneto-optical disk 4 housed in the disk cartridge 5 mounted in the mounting section 52 is attached to a substantially central portion of the base chassis 7. The disk rotation drive mechanism 59 includes a spindle motor 61 and a disk table 63 that is integrally attached to the spindle 62 of the spindle motor 61. The spindle motor 61 is attached to the lower surface side of the base chassis 7 so that the spindle 62 protrudes from the upper surface side of the base chassis 7. Further, the disk table 63 is integrally attached to the tip end side of the spindle 62 protruding to the upper surface side of the base chassis 7.

  The magneto-optical disk 4 housed in the disk cartridge 5 is placed on the disk table 63 of the disk rotation drive mechanism 59 that has entered the cartridge body 14 from the central opening 17 when the disk cartridge 5 is mounted in the mounting portion 52. The clamping plate 16 is attracted by a magnet built in the disk table 63 to be centered and clamped in a state where it can rotate integrally with the disk table 63.

  As shown in FIG. 5, the base chassis 7 is an optical pickup that emits a light beam that is clamped by a disk table 63 and that scans the signal recording area of the magneto-optical disk 4 that is driven to rotate together with the disk table 63. A device 64 is attached. The optical pickup device 64 includes a semiconductor laser that is a light source that emits a light beam that scans the signal recording area of the magneto-optical disk 4, a light detection element that detects a return light beam reflected from the magneto-optical disk 4, and a semiconductor laser. An optical block 65 containing an optical element such as a beam splitter that separates the emitted light beam and the returned light beam reflected from the optical disk, and the light beam emitted from the semiconductor laser converges on the signal area of the magneto-optical disk 4. The objective lens 66 to be irradiated and the light beam irradiated to the magneto-optical disk 4 through the objective lens 66 are focused on the signal recording area of the magneto-optical disk 4 and are formed on the magneto-optical disk 4. The objective lens 66 is moved along the optical axis direction of the objective lens 66 and the plane direction orthogonal to the optical axis direction so as to follow the recorded track. And a biaxial actuator for driving displacement.

  The optical pickup device 64 is arranged on the lower surface side of the base chassis 7 so that the objective lens 66 is opposed to the main surface of the magneto-optical disk 4 on the disk table 63 through a pickup opening 67 formed in the base chassis 7. It is installed. The optical pick-up device 64 is supported by a guide shaft 68 having a shaft insertion hole provided on one end side of the optical block 65 attached to the lower surface side of the base chassis 7 so as to be movable toward and away from the disk table 63. A feed screw 69 provided in parallel with the guide shaft 68 is inserted into the other end of the optical block 65. The feed screw 69 is rotated by the thread feed motor 70, whereby the optical pickup device 64 inserted through the feed screw 69 is fed in the radial direction of the magneto-optical disk 4.

  The optical block 65 is connected to a flexible circuit board 77 connected to a printed wiring board 256 disposed on the mounting member 42. The optical block 65 receives a drive signal from the control unit formed on the printed wiring board 253 of the mounting member 42 via the flexible circuit board 77 and is operated to send it in the radial direction of the magneto-optical disk 4.

  As shown in FIG. 6, a magnetic head device 71 that records information signals on the magneto-optical disk 4 is attached to the optical block 65 of the optical pickup device 64 in cooperation with the optical pickup device 64. The magnetic head device 71 is disposed opposite to the optical pickup device 64 with the magneto-optical disk 4 rotated by the disk rotation drive mechanism 59 interposed therebetween, and is emitted from the optical pickup device 64 of the magneto-optical disk 4. In order to apply an external magnetic field modulated based on an information signal to be recorded at a position irradiated with the light beam, the magnetic field is moved in the radial direction in synchronization with the optical pickup device 64.

  As shown in FIGS. 3 and 6, the magnetic head device 71 is connected to the optical block 65 of the optical pickup device 64 via a connecting member 72. The connecting member 72 that connects the magnetic head device 71 to the optical block 65 is formed by bending a highly rigid metal plate into a U shape, the lower end side is fixed to the lower surface side of the optical block 65, and the magnetic head device 71 is connected to the upper end side. Is fixed. The connecting member 72 connects the magnetic head device 71 to the optical pickup device 64 so as to face the top plate portion 82 of the cartridge holder 6 that holds the disk cartridge 5.

  As shown in FIG. 7, the magnetic head device 71 supported by the connecting member 72 connected to the optical pickup device 64 is in contact with the signal recording surface of the magneto-optical disk 4 so that the magnetic head device 71 is moved inside the slider. , A head support arm 74 on which the magnetic head unit 73 is supported on the distal end side, an arm support plate 75 that restricts excessive displacement of the head support arm 74, a head support arm 74, A connection plate 55 to which the arm support plate 75 is connected, and a rotation support member 56 that is attached to the connection plate 55 so as to be rotatable in the arrow L direction in FIG. .

  The head support arm 74 that supports the magnetic head portion 73 on the tip side is formed by punching a thin metal plate having elasticity. The magnetic head unit 73 is supported on the distal end side of an elastically displaceable head support arm 74, so that when the signal recording area of the magneto-optical disk 4 is scanned, the magneto-optical disk 4 is driven to rotate due to surface vibration. In this case, the head support arm 74 is elastically deformed to prevent the magnetic recording disk 4 from being lifted from the main surface, and the signal recording area can be scanned accurately.

  The arm support plate 75 extends to the upper surface side of the head support arm 74, thereby restricting excessive deformation of the head support arm 74. Further, the arm support plate 75 is formed with a locking portion 57 that is locked to a locking piece 97 of a head insertion opening 96 formed in a top plate portion 82 of the cartridge holder 6 to be described later at the distal end portion 75a. . The locking portion 57 has a concave contact surface that comes into contact with the locking piece 97, and a locking wall 57a is formed at the tip. Then, the locking portion 57 abuts from below the locking piece 97, so that the upward displacement of the arm support plate 75 is restricted, and the locking piece 97 is locked by the locking wall 57 a. The arm support plate 75 is prevented from being detached from the locking piece 97. Therefore, the arm support plate 75 can be prevented from coming out above the locking piece 97 due to an impact caused by dropping or the like of the recording / reproducing apparatus 1.

  The connection plate 55 includes a connection portion 55 a to which the base end side of the head support arm 74 and the arm support plate 75 is connected, and a support portion 55 b that supports the connection portion 55 a and is connected to the rotation support member 56. The connecting portion 55a is formed by punching a thin metal plate and has flexibility. Accordingly, when the cartridge holder 6 is separated from the base chassis 7, the connection plate 55 is slidably contacted with the top plate portion 82 and bent downward, and the head support arm 74 whose upward deformation is restricted by the locking piece 97. And the load concerning the arm support plate 75 is reduced.

  That is, as shown in FIG. 8, when the cartridge holder 6 and the base chassis 7 are moved away from each other, the cartridge holder 6 and the optical block 65 of the optical pickup device 64 provided on the base chassis 7 are connected. In the magnetic head device 71 disposed on the top plate portion 82 of the cartridge holder 6, the side edge portion of the top plate portion 82 of the cartridge holder 6 is brought into contact with the connection plate 55 from below and is biased upward. . On the other hand, as described above, the head support arm 74 and the arm support plate 75 are engaged with the engagement piece 97 in which the engagement portion 57 formed at the distal end portion of the arm support plate 75 protrudes from the top plate portion 82. Since the upper displacement is restricted by being stopped, a load is generated when the proximal end sides of the head support arm 74 and the arm support plate 75 are pushed up by the cartridge holder 6. Here, since the connection portion 55a of the connection plate 55 is bent and deformed to have flexibility, it is possible to absorb such a load and prevent the head support arm 74 and the arm support plate 75 from being loaded. can do. As shown in FIGS. 9 and 10, when the cartridge holder 6 and the base chassis 7 are brought close to each other, the connection plate 55 is set to be approximately the same height as the top plate portion 82 of the cartridge holder 6. The load applied to the connecting portion 55a is removed without contacting the portion 82 from below.

  The connection plate 55 is rotatably connected, for example, by screwing the support portion 55b to the rotation support member 56. The rotation support member 56 includes a connection hole 56a that is rotatably connected to the rotation support portion 72a of the connecting member 72, and an attachment portion 56b to which the connection plate 55 is attached. An insertion shaft 58 through which the rotation support portion 72a of the connecting member 72 is inserted is inserted into the connection hole 56a. Further, the attachment portion 56b is attached by, for example, screwing the support portion 55b of the connection plate 55.

  The coupling member 72 extends downward from the base chassis 7 by being bent at a substantially right angle from the rotation support portion 72 a that supports the rotation support member 56, and the optical block of the optical pickup device 64. 65 and a connection piece 72b connected to 65. The rotation support portion 72a is formed with an insertion hole 72c through which the insertion shaft 58 is inserted. The rotation support portion 72a is connected to the connection hole 56a of the rotation support member 56 and then inserted into the rotation support member 56. Are rotatably connected. The insertion shaft 58 is prevented from being removed from the insertion hole 72c by attaching a washer 58a. In addition, the rotation support portion 72 a receives the mounting portion 56 b of the rotation support member 56 biased downward by the torsion coil spring 60 when the torsion coil spring 60 is locked between the rotation support member 56. The rotation support member 56 is in contact with the cartridge holder 6 and is supported substantially in parallel with the top plate portion 82 of the cartridge holder 6. The connection piece 72b formed by bending from the rotation support portion 72a extends to the lower surface side of the base chassis 7 and is connected to the optical block 65 of the optical pickup device 64 by screws or the like. Accordingly, the magnetic head device 71 is moved along the radial direction of the magneto-optical disk 4 together with the optical block 65 by being connected to the optical block 65 via the connecting member 72.

  The connecting member 72 is connected to the turning support member 56 so as to be turnable, whereby the head support arm 74, the arm support plate 75, and the connection plate 55 are prevented from being deformed upward by the locking piece 97. This reduces the load on the connecting portion 55a. That is, as shown in FIG. 8, the cartridge holder 6 and the base chassis 7 are moved away from each other, and the side edge portion of the top plate portion 82 of the cartridge holder contacts the connecting portion 55a of the connecting plate 55 from below. When the head support arm 74, the arm support plate 75, and the connection plate 55 are urged upward by being in contact with each other, the rotation support member 56 is rotated upward. Therefore, the connection plate 55 attached to the attachment portion 56b of the rotation support member 56 is rotated upward so that the amount of refraction of the connection portion 55a is reduced. Thereby, the load related to the head support arm 74 and the arm support plate can be reduced, the amount of bending deformation of the connection portion 55a of the connection plate 55 can be reduced, and the load related to the connection plate can be reduced. As shown in FIGS. 9 and 10, when the cartridge holder 6 and the base chassis are brought close to each other, the connection plate 55 is not brought into contact with the top plate portion 82 from below, so that the rotation support member 56. The mounting portion 56 b is rotated downward by the urging force of the torsion coil spring 60 and has a height substantially the same as the top plate portion 82 of the cartridge holder 6.

  Such a magnetic head device 71 is connected to the optical pickup device 64 via the connecting member 72 so as to face the optical pickup device 64 with the magneto-optical disk 4 rotated by the disk rotation drive mechanism 59 interposed therebetween. Be placed. When the magnetic head device 71 records an information signal on the magneto-optical disk 4, the head support arm 74 extended on the top plate portion 82 of the cartridge holder 6 is inserted into the head insertion mechanism by the head lifting mechanism 101. The cartridge 96 enters the cartridge holder 6 through the opening 96 and comes close to the magneto-optical disk 4. The magnetic head portion 73 supported on the front end side of the head support arm 74 enters the cartridge main body 14 of the disk cartridge 5 attached to the attachment portion 52 on the base chassis 7 from the recording / reproducing opening 18, An external magnetic field is applied to the signal recording area with a large magnetic field strength in sliding contact with the signal recording surface of the magneto-optical disk 4.

  When reproducing the information signal recorded on the magneto-optical disk 4, it is not necessary to apply an external magnetic field from the magnetic head device 71. Since it is only necessary to scan the signal recording area, the head lifting arm 101 and the head support arm 74 and the head support arm 74 and The magnetic head unit 73 is separated from the main surface of the magneto-optical disk 4. Also in the stop state in which the rotation of the magneto-optical disk 4 is stopped, the magnetic head unit 73 is separated from the main surface of the magneto-optical disk 4 and the head support arm 74 is moved to the outside of the cartridge body 14. Furthermore, when ejecting the disk cartridge 5 or when inserting the disk cartridge 5, the head support arm 74 is provided with a cartridge body to prevent the magnetic head portion 73 from colliding with the disk cartridge 5 and being damaged. 14 is moved outward. The head lifting mechanism 101 that lifts and lowers the head support arm 74 will be described in detail later.

  The base chassis 7 has an insertion opening through which a gear train 224, first and second drive gears 226, 227 and a DC motor 222 of a drive mechanism 221 disposed in a guide chassis 9 described later are inserted in a main surface portion. 76 is formed. The insertion opening 76 is slightly larger than the gear train 224, the first and second drive gears 226, 227, and the DC motor 222 disposed on the main surface portion of the guide chassis 9. The insertion opening 76 allows the base chassis 7 and the guide chassis 9 to be close to each other when the disc cartridge 5 is not inserted into the recording / reproducing mechanism 3 and the base chassis 7 is separated from the cartridge holder 6. The gear train 224, the first and second drive gears 226 and 227, and the DC motor 222 are inserted and face the main surface portion of the base chassis 7. Further, when the disc cartridge 5 is inserted into the recording / reproducing mechanism 3 and the base chassis 7 is brought close to the cartridge holder 6, the insertion opening 76 rises from the guide chassis 9, and the gear train 224, the first and second drives. The gears 226 and 227 and the DC motor 222 are lowered to the lower surface side and retracted from the main surface portion of the base chassis 7. Therefore, the base chassis 7 can be mounted on the mounting portion 52 without causing the disk cartridge 5 to interfere with the drive gear or the motor.

  Thus, in a state where the disk cartridge 5 is not inserted, the base chassis 7 is lowered to the guide chassis 9 side, and the drive mechanism 221 disposed on the guide chassis 9 faces the mounting portion 52 of the base chassis 7. When the disk cartridge 5 is inserted, the base chassis 7 is raised from the guide chassis 9 and the drive mechanism 221 disposed in the guide chassis 9 is retracted from the mounting portion 52 of the base chassis 7. Therefore, the recording / reproducing apparatus 1 does not need to provide a clearance for the height of the drive mechanism 221 between the guide chassis 9 and the base chassis 7 at all times, and can reduce the thickness of the apparatus main body 2.

  The base chassis 7 is formed with side walls 78 and 78 rising from both side edges in a direction orthogonal to the insertion direction of the disk cartridge 5. The side walls 78 and 78 are formed with guide shafts 79 and 80 which are inserted in base guide grooves 139 and 140 formed in the slider 8 which will be described later, separated from each other in the front-rear direction. The base chassis 7 is moved up and down by the guide shafts 79 and 80 being guided by the base guide grooves 139 and 140 of the slider 8, and is brought close to and away from the cartridge holder 6.

  Next, the cartridge holder 6 for loading the disk cartridge 5 into the mounting portion 52 will be described.

  As shown in FIGS. 4 and 11, the cartridge holder 6 is formed by bending a thin metal plate having spring elasticity such as stainless steel and is large enough to accommodate and hold the disk cartridge 5. The cartridge holder 6 has a top plate portion 82 formed in a substantially rectangular shape having a size sufficient to cover the upper surface side of the disk cartridge 5, and the cartridge holder 6 is provided on opposite sides of the top plate portion 82. First and second cartridge holding portions 83 and 84 are provided to support both sides of the disc cartridge 5 to be inserted. The first and second cartridge holding portions 83 and 84 are formed by bending the top plate portion 82 on both sides vertically and forming side walls 85 and 86 of the cartridge holder 6, and the top ends of the side walls 85 and 86 are arranged on the top plate. The cartridge support pieces 87 and 88 are formed by being bent so as to be parallel to the portion 82.

  The cartridge holder 6 has an open portion between the first and second cartridge holding portions 83 and 84 on the front surface 6a side orthogonal to both sides where the first and second cartridge holding portions 83 and 84 are formed. A cartridge insertion / removal port 89 is formed, and the disk cartridge 5 is inserted between the first and second cartridge holding portions 83 and 84 through the cartridge insertion / removal port 89. At this time, the disk cartridge 5 is inserted into the cartridge holder 6 through the cartridge insertion / removal port 89 with the front surface 14b as an insertion end, and the one side surface 14a side to which the shutter member 21 is attached and the other side surface facing the one side surface 14a are The first and second cartridge holding portions 83 and 84 are supported.

  Note that a substantially central portion in the longitudinal direction of the side wall 86 constituting the first cartridge holding portion 83 of the cartridge holder 6 enters a shutter opening member entry groove formed on the one side surface 14a side of the disk cartridge 5 to lock the shutter. A shutter opening piece 92 that opens the recording / reproducing openings 18 and 19 by moving the shutter member 21 in the direction of arrow B in FIG. It is folded back inward.

  Further, the shutter member 21 is held at a position where the recording / reproducing openings 18 and 19 of the disk cartridge 5 are opened at a position closer to the cartridge insertion / removal opening 89 than the position where the shutter opening piece 92 is provided on the side wall 86. When the disk cartridge 5 is ejected from the cartridge holder 6, the shutter member 21 is held with respect to the cartridge main body 14 that is moved in the direction protruding from the cartridge holder 6, and the shutter member 21 closes the recording openings 18 and 19. A shutter holding piece 93 that moves in the direction is provided. The shutter holding piece 93 is formed integrally with the side wall 86 by making a U-shaped cut in the side wall 86. The shutter holding piece 93 is formed so as to extend from the proximal end portion of the side wall 86 toward the distal end portion side, and an engagement protrusion that engages with the engagement hole of the shutter member 21 is formed on the distal end portion side. . The engaging protrusion is formed by bending a part of the shutter holding piece 93 on the front end side so as to protrude inward of the cartridge holder 6.

  Further, guide protrusions 98 and 99 are provided on the side walls 85 and 86 so as to be engaged with holder guide grooves 137 and 138 formed in the slider 8 so as to be separated from each other in the front-rear direction. The cartridge holder 6 is moved closer to and away from the base chassis 7 by the guide protrusions 98 and 99 being guided by the holder guide grooves 137 and 138 of the slider 8.

  A cartridge pressing piece 95 that presses and supports the upper surface of the insertion end side of the disk cartridge 5 inserted into the cartridge holder 6 is integrally formed on the top plate portion 82 of the cartridge holder 6. The cartridge pressing piece 95 is formed integrally with the top plate portion 82 so as to extend in the insertion direction of the disk cartridge 5 into the cartridge holder 6 by making a U-shaped cut in the top plate portion 82. ing. The cartridge pressing piece 95 is displaced so that the tip side protrudes inward of the cartridge holder 6 so as to press the disk cartridge 5 inserted into the cartridge holder 6 inward of the cartridge holder 6. A protruding portion that protrudes inward of the cartridge holder 6 is provided on the tip side of the cartridge pressing piece 95. The cartridge pressing piece 95 inserts the disk cartridge 5 into the cartridge holder 6 in a stable state while preventing the disk cartridge 5 from floating from the cartridge support pieces 87 and 88. The cartridge pressing piece 95 presses the disc cartridge 5 held by the cartridge holder 6 toward the mounting portion 52 when the cartridge holder 6 is in a position close to the base chassis 7.

  Further, the top plate portion 82 of the cartridge holder 6 is formed with a head insertion opening portion 96 through which the magnetic head portion 73 of the magnetic head device 71 described above enters the cartridge holder 6. The head insertion opening 96 is formed on the recording / reproducing opening 18 of the disk cartridge 5 inserted into the cartridge holder 6 and is opened when the shutter member 21 is moved by the shutter opening piece 92. The recording / reproducing opening 18 and a part of the magnetic disk 4 in the radial direction are exposed outward from the top plate 82. Further, the head insertion opening 96 is provided with a locking piece 97 for locking a locking portion 57 provided at the tip 75 a of the arm support plate 75 of the magnetic head device 71. The locking piece 97 is formed such that a support portion 97a is raised from both ends of the front side edge of the head insertion opening 96, and a locking wall 57a of the locking portion 57 of the arm support plate 75 can be inserted forward. A stop plate 97b is extended over both front side edges.

  The top plate portion 82 of the cartridge holder 6 as described above is provided with a head lifting mechanism 101 that moves the head support arm 74 up and down in order to move the magnetic head portion 73 close to and away from the magneto-optical disk 4 according to the operation mode. ing. As shown in FIGS. 11 and 12, the head elevating mechanism 101 is supported on a top plate portion 82 of the cartridge holder 6 so as to be rotatable, and an elevating operation member 102 that elevates and lowers the head support arm 74. And an operation lever 103 for rotating the member 102.

  The lifting operation member 102 has a substantially rectangular rotation operation plate 104 that is positioned on the lower surface side of the head support arm 74 and that rotates the head support arm 74, and the head support arm 74 of the rotation operation plate 104. A pair of support arms 105, 105 are formed on both sides in a direction orthogonal to the extending direction. The support arms 105 and 105 are extended in parallel with the extending direction of the head support arm 74 of the magnetic head device 71, and a long hole 105a extending in the extending direction of the support arms 105 and 105 is formed in the main surface portion. A fixed shaft 106 protruding from the plate portion 82 is slidably engaged. The support arms 105 and 105 are movable along the direction in which the long hole 105 a is formed while the long hole 105 a slides on the fixed shaft 106. Therefore, the rotation operation plate 104 is movable in the extending direction of the support arms 105, 105, that is, in the extending direction of the head support arm 74 of the magnetic head device 71.

  Further, the lifting operation member 102 is disposed so that the rotation operation plate 104 spans the head insertion opening 96 provided in the top plate portion 82, and the head from the side edge on the back surface 6 b side of the cartridge holder 6. Overhanging the opening 96 for insertion is arranged. The rotating operation plate 104 is formed with a stepped portion 104a whose side edge on the front surface 6a side is lowered toward the inside of the cartridge holder 6. The rotation operation plate 104 moves on the head insertion opening 96 when the support arms 105 are moved in the extending direction.

  An arm support plate 75 and a head support arm 74 of the magnetic head device 71 are extended on the upper surface of the rotation operation plate 104. The step 104 a of the rotation operation plate 104 supports the head support arm 74, thereby holding the magnetic head 73 on the head insertion opening 96 of the cartridge holder 6.

  An operation lever 103 for operating the lifting operation member 102 is attached to the top plate portion 82 of the cartridge holder 6 so as to be rotatable in the front-rear direction that is the same as the extending direction of the head support arm 74 of the magnetic head device 71. The operation lever 103 includes an operation protrusion 114 having a distal end portion extending toward the side wall 85, an arm portion 115 extending from the operation protrusion 114 toward the lifting operation member 102, an operation protrusion 114, and an arm portion. 115 is integrally formed with a rotation support portion 116 provided between the operation lever 103 and the operation lever 103 so as to be rotatable.

  The operation protrusion 114 extends to the second cartridge holding portion 84 side, and the tip end portion is held between the lifting lever 202 described later. The arm portion 115 is rotatably connected by the support arm 105 of the lifting operation member 102 and the fixed shaft 117. The operation lever 103 is rotatable in the front-rear direction of the cartridge holder 6 around a rotation support portion 116 that is rotatable by a fixed shaft. The operation lever 103 is connected to the arm portion 115 by rotating the arm portion 115 via the rotation support portion 116 when the operation protrusion 114 is slid in the front-rear direction by an elevating lever 202 described later. The lifting operation member 102 is operated in the front-rear direction.

  Specifically, when recording an information signal on the magneto-optical disk 4 of the disk cartridge 5 inserted in the cartridge holder 6, the operation protrusion 114 is moved in the direction of arrow D in FIG. Moved to. When the operation protrusion 114 is moved, the arm lever 115 is rotated to the back surface 6 b side of the cartridge holder 6 via the rotation support portion 116. As a result, the support arm 105 and the rotation operation plate 104 of the rotation operation member 102 connected to the distal end portion of the arm portion 115 are also moved to the back surface 6b side. When the rotary operation plate 104 is moved to the back surface 6b side, the head support arm 74 supported by the stepped portion 104a bends downward, and the magnetic head portion 73 provided at the tip portion slides on the magneto-optical disk 4. Be touched.

  When no information signal is recorded on the magneto-optical disk 4, the operation projection 114 is moved in the direction of the arrow D in FIG. 6 is rotated to the front surface 6a side. Accordingly, the support arm 105 and the rotation operation plate 104 of the rotation operation member 102 are also moved to the front surface 6a side, and the head support arm 74 is supported by the stepped portion 104a, so that it is in sliding contact with the magneto-optical disk 4. The magnetic head unit 73 is raised above the head insertion opening 96.

  As shown in FIGS. 4 and 11, the slider 8 is supported on the cartridge holder 6 so as to be movable in the front-rear direction. The slider 8 includes a connecting portion 125 that is long to the left and right, extended portions 126 and 127 that protrude rearward from the left and right ends of the connecting portion 125, and side surfaces that are respectively suspended from the side edges of the extending portions 126 and 127. The parts 128 and 129 are integrally formed. On one side surface 128, a spring locking piece 131 is projected. The other end of the coil spring 169 whose one end is locked to the spring locking piece 168 on the side surface portion of the guide chassis 9 is locked to the spring locking piece 131, so that the slider 8 is positioned in front of the guide chassis 9. Be energized.

  A restricting piece 133 that engages with an eject member 147 to be described later is provided at the rear end portion of the extending portion 126. The restriction piece 133 is formed in a substantially rectangular shape and is bent toward the inner side of the slider 8.

  Side pins 128 and 129 are provided with guide pins 135 and 136 spaced apart from each other in the front-rear direction. The guide pins 135 and 136 are engaged with the horizontal guide grooves 157 and 158 provided in the guide walls 154 and 155 of the guide chassis 9 from the inside.

  In addition, holder guide grooves 137 and 138 and base guide grooves 139 and 140 are formed in the side surfaces 128 and 129 so as to be separated from each other in the front-rear direction. When the cartridge holder 6 is assembled to the slider 8 in the holder guide grooves 137 and 138, as shown in FIG. 13, the guide protrusions 98 and 99 protruding from the side walls 85 and 86 of the cartridge holder 6 are formed from the inside. Engaged. Further, guide shafts 79 and 80 projecting from the side wall 78 of the base chassis 7 are engaged with the base guide grooves 139 and 140 from the inside.

  In the holder guide groove 137 located on the front side, a lower horizontal portion 137a, an inclined portion 137b, and an upper horizontal portion 137c are successively formed from the rear side. The holder guide groove 138 located on the rear side is formed with a lower horizontal portion 138a, an inclined portion 138b, and an upper horizontal portion 138c successively from the rear side. The base guide groove 139 located on the front side is formed with an upper horizontal portion 139a, an inclined portion 139b, and a lower horizontal portion 139c successively from the rear side. The base guide groove 140 located on the rear side is formed with an upper horizontal portion 140a, an inclined portion 140b, and a lower horizontal portion 140c successively from the rear side.

  Furthermore, a pressed piece 144 that is pressed by a pressing portion 174 of a slide lever 163 (described later) is provided on one side surface 128 slightly on the front side of the spring locking piece 131. When the disk cartridge 5 is ejected, the slider 8 is slid to the back side against the urging force of the coil spring 169 by the pressed piece 144 being pressed to the back side by the slide lever 163.

  The slider 8 is slid to the front side by the coil spring 169 to guide the cartridge holder 6 and the base chassis 7 engaged with the holder guide grooves 137 and 138 and the base guide grooves 139 and 140 in a direction close to each other. To do. That is, when the slider 8 is slid to the front side, the guide protrusions 98 and 99 projecting from the side walls 85 and 86 of the cartridge holder 6 engaged with the holder guide grooves 137 and 138 become the upper horizontal part 137c. , 138c to the lower horizontal portions 137a, 138a through the inclined portions 137b, 138b, the cartridge holder 6 is lowered. Further, when the slider 8 is slid to the front side, the guide shafts 79 and 80 projecting from the side wall 78 of the base chassis 7 engaged with the base guide grooves 139 and 140 become the lower horizontal portions 139c and 140c. To the upper horizontal portions 139a and 140a through the inclined portions 139b and 140b, and the base chassis 7 is raised.

  Further, when the slider 8 is slid to the back side by a slide lever 163 described later, the cartridge holder 6 and the base chassis 7 engaged with the holder guide grooves 137 and 138 and the base guide grooves 139 and 140 are separated from each other. To guide. That is, when the slider 8 is slid to the back side, the guide protrusions 98 and 99 projecting from the side walls 85 and 86 of the cartridge holder 6 engaged with the holder guide grooves 137 and 138 become lower horizontal parts. The cartridge holder 6 is lifted by moving from 137a, 138a to the upper horizontal portions 137c, 138c via the inclined portions 137b, 138b. When the slider 8 is slid to the back side, the guide shafts 79 and 80 projecting from the side wall 78 of the base chassis 7 engaged with the base guide grooves 139 and 140 are removed from the upper horizontal portions 139a and 140a. The base chassis 7 is lowered by moving to the lower horizontal portions 139c and 140c via the inclined portions 139b and 140b.

  Next, the guide chassis 9 that guides the horizontal slide of the slider 8 and the vertical movement of the cartridge holder 6 and the base chassis 7 will be described.

  The guide chassis 9 is assembled from the outside to the assembly in which the cartridge holder 6, the base chassis 7 and the slider 8 shown in FIG. 3 are assembled. As shown in FIG. 14, a substantially rectangular main surface portion 153, A pair of guide walls 154 and 155 are formed to rise from the side surface of the main surface portion 153 in a direction orthogonal to the insertion direction of the disk cartridge 5 and guide the movement of the slider 8, the cartridge holder 6 and the base chassis 7. The guide walls 154 and 155 are formed with horizontal guide grooves 157 and 158 that guide the horizontal movement of the slider 8 while being separated from each other in the front-rear direction. Further, the guide walls 154 and 155 are formed with vertical guide grooves 159 and 160 for guiding the vertical movement of the cartridge holder 6 and the base chassis 7 at the rear ends.

  Horizontal guide grooves 157 and 158 for guiding the movement of the slider 8 in the horizontal direction are formed in the front end portions 154a and 155a and the rear end portions 154b and 155b in the longitudinal direction of the guide walls 154 and 155, respectively. The horizontal guide grooves 157 and 158 are substantially horizontal grooves with the rear ends 154b and 155b side of the guide walls 154 and 155 being open ends. The horizontal guide grooves 157 and 158 are slidably engaged with guide pins 135 and 136 that protrude from the side surfaces 128 and 129 of the slider 8 so as to be separated from each other in the front-rear direction. Therefore, the guide chassis 9 can reliably move the slider 8 in the horizontal direction.

  Further, vertical guide grooves 159 and 160 for guiding the vertical movement of the cartridge holder 6 and the base chassis 7 are formed in the rear end portions 154b and 155b in the longitudinal direction of the guide walls 154 and 155, respectively. The vertical guide grooves 159 and 160 are substantially vertical grooves whose upper ends are open ends. The vertical guide grooves 159 and 160 are slidably engaged with the guide protrusions 99 protruding from the side walls 85 and 86 of the cartridge holder 6 and the guide shafts 80 protruding from the side walls 78 and 78 of the base chassis 7. Has been. The vertical guide grooves 159 and 160 can be moved only in the vertical direction by restricting the movement of the cartridge holder 6 and the base chassis 7 in the front-rear direction by engaging the guide protrusion 99 and the guide shaft 80. .

  The vertical guide grooves 159 and 160 may be formed narrower on the lower side than the upper side which is the open end side. That is, the vertical guide grooves 159 and 160 are engaged with the guide protrusion 99 of the cartridge holder 6 that is formed wide on the upper side and the guide shaft 80 of the base chassis 7 that is formed narrow on the lower side. Is done. Thus, even when the cartridge holder 6 is lowered to the base chassis 7 side, the vertical guide grooves 159 and 160 are not lowered to the lower side where the engaging protrusion 46 of the cartridge holder 6 is formed narrow. Therefore, it is possible to prevent the cartridge holder 6 from approaching the base chassis 7 side more than necessary.

  Further, the main surface portion 153 has an opening through which the disk rotation driving mechanism 59 such as the spindle motor 61 and the disk table 63 disposed in the base chassis 7, the optical block 65 of the optical pickup device 64, and the thread feed motor 70 are inserted. A portion 161 is formed. When the base chassis 7 is brought close to the guide chassis 9 in a state where the disk cartridge 5 is not inserted into the recording / reproducing mechanism 3 and the base chassis 7 is separated from the cartridge holder 6, the opening 161 is formed in the base chassis 7. The lower surface of the disk rotation drive mechanism 59 and the optical pickup device 64 attached to the lower surface side of the optical pickup device 64 are inserted. Therefore, the disk rotation drive mechanism 59 and the optical pickup device 64 protrude downward between the disk rotation drive mechanism 59 and the optical pickup device 64 attached to the lower surface side of the base chassis 7 and the main surface portion 153 of the guide chassis 9. It is possible to avoid interference between the disk rotation drive mechanism 59 and the optical pickup device 64 and the main surface portion 153 of the guide chassis 9 when the base chassis 7 and the guide chassis 9 are close to each other without providing a predetermined clearance corresponding to the minute. In addition, since it is not necessary to provide a predetermined clearance between the base chassis 7 and the guide chassis 9, the entire apparatus can be reduced in thickness.

  Further, as shown in FIGS. 12 and 14, the guide chassis 9 is provided with an eject member 147 for ejecting the disk cartridge 5 held by the cartridge holder 6. The eject member 147 is rotatably provided in the vicinity of the rear end portion of the main surface portion 153 on the guide wall 154 side, and is biased forward by a torsion coil spring 148.

  As shown in FIG. 14, the eject member 147 rises from a rotation portion 149 that is rotatably attached to an attachment piece 156 that is formed on the rear end portion of the main surface portion 153 of the guide chassis 9, and the rotation portion 149. The contact portion 150 is formed so as to be in contact with the disk cartridge 5, and the restriction portion 151 is formed by being bent by the contact portion 150 and restricts the rotation of the eject member 147.

  The rotating portion 149 is inserted into a rotating shaft 162 projecting from the mounting piece 156 of the guide chassis 9, and the cartridge insertion / removal port 89 side where the disk cartridge 5 is inserted / removed around the rotating shaft 162. It is possible to rotate freely.

  The contact portion 150 is formed perpendicular to the rotating portion 149 and is in contact with the front surface 14 b on the insertion end side of the cartridge body 14 inserted into the cartridge holder 6. Further, the contact portion 150 is urged toward the front side of the guide chassis 9 that always ejects the disk cartridge 5 by engaging one end of the torsion coil spring 148 inserted through the rotation shaft 162. When the disk cartridge 5 is inserted into the cartridge holder 6, the contact portion 150 is rotated backward by being pressed against the cartridge body 14 against the urging force of the torsion coil spring 148, and ejects the disk cartridge 5. In doing so, the cartridge body 14 is rotated forward by the urging force of the torsion coil spring 148 to push the cartridge body 14 toward the cartridge insertion / removal port 89.

  The restricting portion 151 that restricts the rotation of the eject member 147 is bent from the abutment portion 150 and formed at substantially the same height as the slider 8. In the restricting portion 151, a roller 152 that rolls on the outer edge of the restricting piece 133 formed on the extending portion 126 of the slider 8 is rotatably formed at the tip end portion. The roller 152 restricts the rotation of the eject member 147 by engaging with the restriction piece 133 of the slider 8 so as to be able to roll. That is, in the state where the disc cartridge 5 is inserted, the ejecting member 147 is pressed against the cartridge main body 14 and the restricting portion 151 is rotated backward. At this time, the slider 8 is also slid forward by the coil spring 169 because the roller 152 is rolled from the front surface portion 133 a that restricts the sliding of the restriction piece 133 forward of the slider 8 to the side surface portion 133 b. The eject member 147 is held by the restriction piece 133 and is held behind the guide chassis 9 when the roller 152 comes into contact with the side surface portion 133b of the restriction piece 133 slid forward. Further, when the disk cartridge 5 is ejected, the slider 8 is slid rearward by a gear mechanism and a slide lever, which will be described later, so that the roller 152 can roll from the side surface portion 133b of the regulating piece 133 to the front surface portion 133a. . Therefore, the eject member 147 is rotated forward by being urged forward by the urging force of the torsion coil spring 148, and the abutting portion 150 abutting against the disk cartridge 5 causes the cartridge main body 14 to move to the cartridge insertion / removal port 89 side. Extrude to discharge.

  As shown in FIGS. 3 and 14, the slide lever 163 that slides the slider 8 backward is attached to the guide wall 154 of the guide chassis 9 so as to be movable in the front-rear direction. The slide lever 163 is formed long in the front-rear direction, and guide holes 165, 165 are formed in the front-rear direction. The slide lever 163 is attached to the guide wall 154 by engaging the guide pins 166 and 166 with the guide holes 165 and 165.

  As shown in FIG. 15, the slide lever 163 is provided with an engagement piece 164 on the lower edge from the rear end. The engagement piece 164 is positioned on the rotation locus of the pressing protrusion 226a of the driving gear 226 that constitutes the driving mechanism 221 described later, and is pressed by the pressing protrusion 226a, so that the driving gear 226 is rotated. The entire slide lever 163 is moved along the guide pins 166 and 166 engaged with the guide holes 165 and 165. The slide lever 163 is provided with a pressing portion 174 that protrudes upward at the upper edge between the pair of guide holes 165 and 165. The pressing portion 174 presses the pressed piece 144 of the slider 8 when the entire slide lever 163 moves backward, and moves the slider 8 backward against the biasing force of the coil spring 169. The slide lever 163 is provided with a spring locking portion 175 on the lower side on the rear side. The other end of the coil spring 177 that is an urging member that is locked to the spring locking portion 176 provided on the guide wall 154 of the guide chassis 9 is locked to the spring locking portion 175. Therefore, the slide lever 163 is always moved forward by the biasing force of the coil spring 177. Then, when the engagement piece 164 is pressed by the pressing protrusion 226a of the driving gear 226 constituting the driving mechanism 221 described later, the slide lever 163 is moved rearward against the urging force of the coil spring 177, and the pressing portion 174 slides the slider 8 backward to eject the cartridge 5.

  As shown in FIGS. 14 and 15, a driving mechanism 221, which will be described later, and an operation lever 103 constituting the head elevating mechanism 101 are linked to the left end portion of the main surface portion 153 of the guard chassis 9. Is provided to the operation lever 103. The link mechanism 180 controls the operation lever 103 that constitutes the head lifting mechanism 101 to raise and lower the magnetic head unit 73, the driving lever 181 that moves the lifting lever 202, and the amount of movement of the driving lever 181. The limit lever 191 for restricting and the limiter spring 211 attached to the limit lever 191 are provided.

  The drive lever 181 is attached to the rear end of the guide wall 154 of the guide chassis 9 so as to be movable in the front-rear direction. As shown in FIGS. 3 and 14, the drive lever 181 is formed long in the front-rear direction, and has guide holes 182 and 182 formed at both front and rear ends, and is slidably locked by guide pins 184 and 184, respectively. Yes.

  In addition, a spring locking piece 185 is provided at the substantially central portion in the front-rear direction of the drive lever 181 so as to protrude to the lower surface side. One end of this spring locking piece 185 is locked to the other end of a tension coil spring 187 that is a biasing member locked to a spring locking piece 186 provided on the lower surface of the guide wall 154 of the guide chassis 9. Yes. Therefore, the drive lever 181 is always urged backward. Further, the drive lever 181 is provided with a pressed portion 188 that is pressed by the limit lever 191 at the front end portion. The drive lever 181 is slid forward against the urging force of the tension coil spring 187 when the pressed portion 188 is pressed by the limit lever 191. As the drive lever 181 moves in the front-rear direction, the operation lever 103 is moved back and forth via the elevating lever 202.

  The drive lever 181 is provided with a spring locking piece 190 on the upper surface side in which a tension coil spring 189 is suspended between the drive lever 181 and a lifting lever 202 described later at a substantially intermediate portion in the front-rear direction. When the drive lever 181 is pressed forward by the limit lever 191, the drive lever 181 is slid integrally with the lift lever 202 via the tension coil spring 189.

  As shown in FIG. 15, a limit lever 191 is rotatably supported on the lower surface of the guide chassis 9 adjacent to the drive lever 181. The limit lever 191 protrudes toward the guide wall 154 of the guide chassis 9 and presses the pressed portion 188 of the drive lever 181. The engagement recess 193 engages with the second drive gear 227 of the drive mechanism 221. , And a limiter spring 211 that urges the limit lever 191 to be locked.

  The limit lever 191 has an engagement recess 193 positioned on the rotation locus of the engagement projection 227a of the second drive gear 227, and can engage with the engagement projection 227a. Further, the limit lever 191 is engaged with the engaging convex portion 227a even when the limit lever 211 is engaged with the engaging convex portion 227a and rotated in the rotation direction of the drive gear 227 by the locking of the limiter spring 211. Is released, the limiter spring 211 elastically returns the engagement recess 193 to the initial position where it can be engaged with the engagement protrusion 227a again.

  In the limit lever 191, when the second drive gear 227 is rotationally driven by the drive mechanism 221, the engagement convex portion 227 a of the second drive gear 227 is engaged with the engagement concave portion 193, and the arrow F in FIG. Rotated in the direction. As a result, the limit lever 191 has the pressing portion 192 rotated in the direction of arrow D in FIG. 15 to slide the pressed portion 188 of the drive lever 181 forward of the guide chassis 9, and the operation lever 103 and The lifting operation member 102 is moved to lower the head support arm 74 of the magnetic head device 71 into the head insertion opening 96.

  When the drive gear 227 is further rotated, the limit lever 191 is abutted against a locking piece 196 projecting from the main surface portion 153 of the guide chassis 9 as shown in FIG. . In addition, if a rotational force is applied to the second drive gear 227 and the limit lever 191 in a state where the limit lever 191 is abutted against the locking piece 196 and the rotation is restricted, a load on these members is large, and wasteful power is consumed. Therefore, the power supply to the drive motor 222 is controlled to be stopped after an arbitrary time. Then, when the recording state is shifted to the stop state and the reproduction state, the second drive gear 227 is rotated in the direction of the opposite arrow H in FIG. 15 by the drive motor 222, and the limit lever 191 is engaged with the second drive gear 227. The engagement with the convex portion 227a is released, and a rotational force in the direction opposite to the locking piece 196 is applied by the limiter spring 211, so that the pressing force to the drive lever 181 is released. Accordingly, the drive lever 181 is slid in the direction of the opposite arrow D in FIG. 15 by the tension coil spring 187. As a result, the operating lever 103 and the lifting operation member 102 are moved via the lifting lever 202, and the head support arm 74 of the magnetic head device 71 is lifted onto the head insertion opening 96.

  As shown in FIGS. 3 and 17, the drive lever 181 and the operation lever 103 are connected by an elevating lever 202. The elevating lever 202 is disposed between the guide wall 154 of the guide chassis 9 and the drive lever 181, has a guide hole (not shown), and is slidably locked to the guide wall 154 by the guide pin 184. The elevating lever 202 is formed to be approximately the same size as the drive lever 181, and an engaging portion 203 that holds the operation lever 103 is formed at the front end portion in the front-rear direction so as to protrude from the upper side portion. An operation protrusion 114 of the operation lever 103 attached to the top portion 82 of the cartridge holder 6 so as to be rotatable in the front-rear direction is slidably held by the engagement portion 203.

  Further, the lifting lever 202 is provided with a spring locking piece 183 protruding from the upper surface at the upper edge portion of the rear end portion, to which a tension coil spring 189 suspended from the driving lever 181 is locked. The elevating lever 202 is connected to the drive lever 181 via the tension coil spring 189, so that when the drive lever 181 is slid in front of the guide chassis 9, both are slid in front of the guide chassis 9.

  Further, the elevating lever 202 has a rear end portion bent outward and a locking portion 204 for locking the rear end portion of the drive lever 181. When the driving lever 181 is slid rearward by the locking portion 204 being locked at the rear end portion of the driving lever 181, the locking portion 204 is pressed by the driving lever 181 and moved backward. Slide.

  The lift lever 202 is slid forward by the tension coil spring 189 when the drive lever 181 is slid forward of the guide chassis 9 via the limit lever 191. Thereby, the raising / lowering lever 202 rotates the operation protrusion 114 of the operation lever 103 held in the engaging portion 203 to the front side. In the operation lever 103, the arm portion 115 is rotated to the back side opposite to the operation protrusion 114 via the rotation support portion 116, and the rotation operation plate 104 is slid to the back surface 6 b side of the cartridge holder 6. As a result, the head support arm 74 of the magnetic head device 71 supported by the rotation operation plate 104 is lowered into the head insertion opening 96.

  Further, when the drive lever 181 is disengaged from the limit lever 191 and is slid rearward by the tension coil spring 187, the elevating lever 202 is pressed by the drive lever 181 and slid rearward. Thereby, the elevating lever 202 slides the operation protrusion 114 of the operation lever 103 held in the engagement portion 203 backward. In the operation lever 103, the arm portion 115 is rotated to the front surface side opposite to the operation protrusion 114 via the rotation support portion 116, and the rotation operation plate 104 is slid to the front surface 6 a side of the cartridge holder 6. As a result, the support arm 74 of the magnetic head device 71 supported by the rotation operation plate 104 is retracted onto the head insertion opening 96. Further, the slide lever 163 and the slider 8 are manually operated on the back side in an emergency such as when the drive lever 181 is slid to the front of the guide chassis 9 by the limit lever 191 and the power is lost when the magnetic head unit 73 is lowered, The ejecting operation of the disk cartridge 5 is performed in a state where the contact piece 231 of the slider 8 moves the lift lever 202 to the back side and the magnetic head portion 73 is always lifted.

  Next, the drive mechanism 221 that directly moves the drive lever 181 and the limit lever 191 constituting the link mechanism 180 as described above will be described with reference to FIG. The drive mechanism 221 includes a drive motor 222 serving as a drive source, a gear train 224 including a plurality of gears meshed with a worm 223 attached to a drive shaft of the drive motor 222, and a final stage of the gear train 224. A first drive gear 226 meshed with the gear and a second drive gear 227 meshed with the first drive gear 226 are formed to be rotatable by a shaft member caulked by the guide chassis.

  The drive motor 222 is disposed on the lower surface of the guide chassis 9 and rotates the first and second drive gears 226 and 227 via a gear train 224 engaged with a worm 223 attached to the drive shaft.

  The first drive gear 226 meshed with the gear train 224 is integrally provided with a pressing protrusion 226a on the upper surface. When the first drive gear 226 is rotated in the direction of arrow G in FIG. 18, the pressing protrusion 226a is abutted against the engagement piece 164 of the slide lever 163 from the front side, and the slide lever 163 is attached to the pressing lever 226a in FIG. Slide in the direction of the half-turn arrow D. As a result, the first drive gear 226 slides the slide lever 163 and the slider 8 to the back side, and rotates the eject member 147 to the front side.

  The second drive gear 227 that meshes with the first drive gear 226 is integrally provided with an engaging projection 227a on the upper surface. The engaging convex portion 227a engages with the engaging concave portion 193 of the limit lever 191 when the second drive gear 227 is rotated in the direction of arrow H in FIG. Rotate in the F direction. As a result, the second drive gear 227 rotates the pressing portion 192 of the limiter spring 191 in the direction of arrow D in FIG. The member 102 is slid to bring the magnetic head unit 73 into sliding contact with the magneto-optical disk 4.

  Further, as shown in FIG. 19, the second drive gear 227 is integrally provided with a convex portion 227b on the lower surface. The convex portion 227b is rotated when the second drive gear 227 is rotated, and an initial position detection switch 228 is disposed on the rotation locus. The second drive gear 227 can detect that the first and second drive gears 226 and 227 are rotated to the initial position when the initial position detection switch 228 is pressed by the convex portion 227b. When the initial position detection switch 228 is pushed by the convex portion 227b of the second drive gear 227 and it is detected that the first and second drive gears 226 and 227 are rotated to the initial position, the drive motor 222 The drive is stopped.

  As shown in FIG. 3, a cartridge insertion / removal port 89 of the cartridge holder 6 is opened and closed in front of the pair of guide walls 154 and 155 of the guide chassis 9 to prevent foreign matters such as dust from entering inside. An open / close lid 215 is attached.

  Next, attachment of the recording / reproducing mechanism 3 configured as described above to the attachment member 42 shown in FIG. 1 will be described. The attachment member 42 is formed in a substantially rectangular box shape with a top surface opened by bending a metal plate. On the bottom surface of the mounting member 42, a first arrangement portion 251 in which the recording / reproducing mechanism 3 is arranged on the front side is provided, and a second arrangement in which a rigid printed wiring board 253 is arranged on the back side. An installation part 252 is provided. Note that a printed circuit board 253 provided in the second arrangement unit 252 has a control circuit for driving and controlling the recording / reproducing mechanism 3 and an interface circuit for exchanging data with the information processing apparatus in accordance with the USB standard. Etc. are incorporated.

  The first placement portion 251 is formed in a substantially rectangular shape at a position one step lower than the second placement portion 252. An attachment piece 254 of the recording / reproducing mechanism 3 is formed in the first arrangement portion 251 in the vicinity of each corner portion and spaced from the bottom surface. These attachment pieces 254 have an attachment hole 254a in the center. The first placement portion 251 is provided with a printed wiring board 256 that is connected to the printed wiring board 253 via a flexible circuit board. The printed wiring board 256 is connected to the other end of a flexible wiring board 77 having one end connected to the optical block 65 provided in the base chassis 7.

  On the other hand, as shown in FIG. 14, the substantially rectangular guide chassis 9 constituting the recording / reproducing mechanism 3 is provided with mounting support pieces 255 in the vicinity of each corner portion. These attachment support pieces 255 are provided with a through hole 255a at the center, and the through hole 255a is partially cut away and opened. In the recording / reproducing mechanism 3, a damper member (not shown) for attaching the recording / reproducing mechanism 3 to the attachment member 42 in a floating state is attached to the through-hole 255 a, and is connected to the attachment piece 254 via the damper member.

  Incidentally, in the recording / reproducing apparatus 1 configured as described above, a control circuit for controlling the operation of the recording / reproducing mechanism 3 is incorporated in the printed wiring board 253 and the printed wiring board 256 disposed on the mounting member 42. Yes. The control circuit has a control unit configured with a microcomputer or the like. On / off of a cartridge detection switch that detects insertion of the disk cartridge 5 is input to this control unit, and a signal from a detection switch that detects the drive state of the drive mechanism 221 is input. The control unit controls the spindle motor 61, the optical pickup device 64, the thread feed motor 70 of the optical pickup device 64, the magnetic head unit 73, and the like that constitute the disk rotation drive mechanism 59 and the drive source of the drive mechanism 221. The drive motor 222 is controlled.

  The control unit detects whether or not the disk cartridge 5 is mounted on the mounting unit 52 by detecting that the cartridge detection switch is turned on, and only when the disk cartridge 5 is mounted on the mounting unit 52. The spindle motor 61, the optical pickup device 64, the magnetic head unit 73, etc. for rotating the magneto-optical disk 4 are allowed to be driven. Then, the control unit drives the spindle motor 61, the optical pickup device 64, the thread feed motor 70 of the optical pickup device 64, the magnetic head 73, etc. in accordance with the input from the information processing apparatus to which the recording / reproducing apparatus 1 is assembled. Enables signal recording and playback.

  Further, the control unit stops driving the drive motor 222 in response to an input from the initial position detection switch 228. Further, when recording data on the disk cartridge 5 held in the cartridge holder 6, the control unit drives the magnetic head unit 73 to rotate forward so that the magnetic head unit 73 slides on the magneto-optical disk 4. When ejecting the held disk cartridge 5, the disk cartridge 5 is driven in reverse.

  As described above, the control unit controls the operation of the entire apparatus. When an eject operation signal is input during the recording operation, the control unit appropriately updates the TOC (Table Of Contents) which is the management information of the recording data. Then stop the recording operation. That is, the control unit stops driving the spindle motor 61, the optical pickup device 64, and the magnetic head unit 73. Then, the control unit drives the drive motor 222 in the reverse direction to retract the magnetic head unit 74 from the cartridge main body 14. Thereafter, the control unit controls the drive motor 222 to rotate in the reverse direction in the direction of raising the magnetic head unit 73 and to start ejecting the disk cartridge 5 mounted on the mounting unit 52.

  Note that when an eject operation signal is input during the recording operation, the control unit ends the recording operation, that is, the disk cartridge 5 is ejected after updating the TOC, and the TOC is not updated. The data recorded in is not damaged.

  Note that this control may be performed on the recording / reproducing apparatus 1 side, or may be performed on software on the information processing apparatus side.

  The recording / reproducing apparatus 1 configured as described above inserts a disk cartridge 5 as described below, performs recording / reproduction of an information signal, and ejects the disk cartridge 5. First, a state before the disk cartridge 5 is loaded will be described.

  As shown in FIG. 20, the eject member 147 is positioned at the rotation end in the direction of arrow R in FIG. 20 by the biasing force of the torsion coil spring 148, and the roller 152 of the restricting portion 151 of the eject member 147 The regulating piece 133 is in contact with the front surface portion 133a. Thus, the slider 8 is held on the rear side of the cartridge holder 6 against the urging force of the coil spring 169.

  Since the slider 8 is held on the rear side of the cartridge holder 6, the guide protrusions 98 and 99 of the cartridge holder 6 are arranged on the upper horizontal portions of the holder guide grooves 137 and 138 of the slider 8 as shown in FIG. 137c and 138c are engaged. Accordingly, the cartridge holder 6 is held at an insertion / removal position where the disk cartridge 5 separated from the base chassis 7 is inserted / removed. At this time, the clearance between the cartridge holder 6 and the cover 43 becomes the minimum value (for example, approximately 0.1 mm), and the magnetic head device 71 disposed on the top plate 82 of the cartridge holder 12 is disposed within this clearance. It is installed. Here, since the magnetic head device 71 is not driven in a state where the disk cartridge 5 is not stored, a space necessary for storing the magnetic head device 71 is secured.

  Similarly, since the slider 8 is held on the rear side of the cartridge holder 6, the guide shafts 79 and 80 of the base chassis 7 are respectively formed in the lower horizontal portions 139 c and 140 c of the base guide grooves 139 and 140 of the slider 8. Is engaged. Therefore, the base chassis 7 is held at a position separated from the cartridge holder 6. At this time, the clearance between the base chassis 7 and the printed wiring board 256 disposed on the lower surface portion of the mounting member 42 has a minimum value (for example, approximately 0.1 mm), and is disposed in the base chassis 7 within this clearance. A flexible circuit board 77 for connecting the optical block 65 of the optical pickup device 64 and the printed circuit board 256 is accommodated. Here, since the optical block 65 is not driven in a state where the disk cartridge 5 is not stored, a space necessary for storing the flexible circuit board 77 is secured. Further, the base chassis 7 is moved to a position away from the cartridge holder 6 and at the same time is brought close to the guide chassis 9, and the insertion opening 76 formed in the mounting portion 52 of the base chassis 7 is provided in the guide chassis 9. The gear train 224 of the drive mechanism 221, the first and second drive gears 226 and 227, and the DC motor 222 are inserted.

  At this time, as shown in FIG. 8, in the magnetic head device 71, the side edge portion on the back side of the top plate portion 82 of the cartridge holder 6 is brought into contact with the connection plate 55 from below and is urged upward. Therefore, the magnetic head device 71 can absorb the load applied to the connection plate 55 as the cartridge holder 6 is raised by bending and deforming the connection portion 55a of the connection plate 55. Further, in the magnetic head device 71, when the connection plate 55 is biased upward by the cartridge holder 6, the rotation support member 56 is rotated upward about the insertion hole 72 c of the coupling member 72. Therefore, the connection plate 55 attached to the attachment portion 56b of the rotation support member 56 is rotated upward so that the amount of refraction of the connection portion 55a is reduced and the load applied to the connection plate 55 is reduced. I am letting.

  At this time, the slide lever 163 attached to the guide wall 154 of the guide chassis 9 is held at the moving end on the front side by the biasing force of the coil spring 177. Further, as shown in FIG. 19, the convex portion 227 b formed on the second drive gear 227 is in a state where the initial position detection switch 228 provided on the main surface portion 153 of the base chassis 9 is pushed. When the initial position detection switch 228 is pressed, it is detected that the first and second drive gears 226 and 227 are in the initial position, and the rotation of the drive motor 222 is stopped. At this time, as shown in FIG. 22, the first drive gear 226 of the drive mechanism 224 is in a position where the pressing protrusion 226 a is separated from the engagement piece 164 of the slide lever 163, and the second drive gear 227 is The engaging convex portion 227a is at a position separated from the engaging concave portion 193 of the limit lever 191.

  Further, as shown in FIG. 23, the drive lever 181 is slid rearward of the guide chassis 9 by the tension coil spring 187, and the elevating lever 202 is also slid rearward of the guide chassis 9 together with the drive lever 181. Therefore, the operation protrusion 114 of the operation lever 103 held by the engagement portion 203 of the elevating lever 202 is slid in the direction opposite to the arrow D in FIG. 20, and the arm portion 115 and the elevating operation are moved via the rotation support portion 116. The member 102 is slid in the direction of arrow I in FIG. 20 to support the head support arm 74 above the head insertion opening 96 formed in the top plate 82 of the cartridge holder 6. As a result, the magnetic head unit 73 is retracted to a position that does not interfere with the disk cartridge 5 inserted into the cartridge holder 6.

  As shown in FIG. 13, the disc cartridge 5 is inserted from the cartridge insertion / removal port 89 of the cartridge holder 6 with the front surface 14 b of the cartridge body 14 as the insertion end. In the disk cartridge 5, first, the front end portions of the cartridge support pieces 87 and 88 of the cartridge holder 6 in which the lower surface portion constituted by the lower half 13 on the front surface 14 b side of the cartridge main body 14 is located close to the cartridge insertion / removal port 89. While being guided by, the cartridge is further pushed by the user, and enters the cartridge holder 6.

  When the disk cartridge 5 is inserted into the cartridge holder 6 from the cartridge insertion / removal port 89, the shutter opening piece 92 is relatively engaged with the guide groove provided on the one side surface 14a of the cartridge body 14, and the inside of the guide groove is By moving to the front surface 14b side, the shutter member 21 is unlocked, and subsequently the edge of the shutter member 21 is pressed to move the shutter member 21 to the back surface 14c side of the cartridge body 14 in the shutter mounting recess 25. . As the shutter member 21 is slid, the engagement protrusion 94 of the shutter holding piece 93 is engaged with the engagement hole of the shutter member 21, and the shutter member 21 holds the recording / reproducing openings 18 and 19 in an open state. Is done.

  24, the rotating portion 150 of the eject member 147 is pressed backward by the inserted disk cartridge 5, and the eject member 147 resists the urging force of the torsion coil spring 148, and is shown by the arrow R in FIG. It is rotated in the direction.

  As shown in FIG. 24, when the eject member 147 is rotated in the direction opposite to the arrow R in FIG. 24, the roller 152 of the restricting portion 151 rolls from the front face portion 133a to the side face portion 133b of the restricting piece 133 of the slider 124. 12, the engagement of the restriction piece 133 with the front surface portion 133b is released, and the restriction portion 151 does not restrict the sliding of the slider 6 forward, so that the slider 8 is moved to the cartridge holder 6 by the biasing force of the coil spring 169. Slide forward. In FIG. 24, the eject member 147 ejects the disk cartridge 5 when the slider 8 is slid forward, so that the roller 152 of the restricting portion 151 comes into contact with the side surface portion 133b of the restricting piece 133 of the slider 8. The rotation in the arrow R direction is restricted.

  When the slider 124 is moved forward, the guide protrusions 98 and 99 of the cartridge holder 6 are respectively lowered from the upper horizontal portions 137c and 138c of the holder guide grooves 137 and 138 through the inclined portions 137b and 138b. It moves to part 137a, 138a, and it adjoins to the base chassis 7. FIG. At this time, since the guide protrusion 99 is guided by the vertical guide grooves 159 and 160 formed in the guide walls 154 and 155 of the guide chassis 9, the cartridge holder 6 is lowered without sliding in the front-rear direction. As shown in FIG. 25, the cartridge holder 6 is moved approximately 0.6 mm toward the base chassis 7, and a maximum clearance (for example, 0.7 mm) is formed between the cartridge holder 6 and the cover 43. Therefore, a sufficient space is secured between the cartridge holder 6 and the cover 42 for driving the magnetic head device 71 disposed on the top plate 82 of the cartridge holder 6.

  At this time, when the cartridge holder 6 is brought close to the base chassis 7 side, the magnetic head device 71 has the connection plate 55 at substantially the same height as the top plate portion 82 of the cartridge holder 6 as shown in FIG. Therefore, the load applied to the connecting portion 55a is removed without being brought into contact with the top plate portion 82 from below. Further, in the magnetic head device 71, since the connection plate 55 is not brought into contact with the top plate portion 82 from below, the mounting portion 56b of the rotation support member 56 is rotated downward by the biasing force of the torsion coil spring 60. Thus, the height is approximately the same as the top plate portion 82 of the cartridge holder 6.

  When the slider 8 is moved forward, the guide shafts 79 and 80 of the base chassis 7 are simultaneously moved from the lower horizontal portions 139c and 140c of the base guide grooves 139 and 140 to the upper horizontal portions via the inclined portions 139b and 140b, respectively. It moves to 139a, 140a and comes close to the cartridge holder 6. At this time, since the guide shaft 80 is guided by the vertical guide grooves 159 and 160 formed in the guide walls 154 and 155 of the guide chassis 9, the base chassis 7 is raised without sliding in the front-rear direction. Further, as shown in FIG. 25, the base chassis 7 is moved approximately 1.8 mm toward the cartridge holder 6 and has a maximum clearance (for example, 1.9 mm) between the base chassis 7 and the printed wiring board 256 disposed on the mounting member 42. ) Is formed. Therefore, there is sufficient space between the base chassis and the printed wiring board 256 for the flexible circuit board 77 that connects the printed wiring board 256 and the optical block 65 disposed in the base chassis 7 to move together with the optical block 65. Secured.

  As described above, when the disk cartridge 5 is inserted and the cartridge holder 6 and the base chassis 7 are brought close to each other, the rising amount of the base chassis 7 is made larger than the lowering amount of the cartridge holder 6. Therefore, in the recording / reproducing apparatus 1, even when an obstacle such as a finger of a user who has inserted the disk cartridge 5 is inserted into the cartridge insertion / removal port 89 and the lowering of the cartridge holder 6 is obstructed, the base chassis 7 is raised. As a result, the disk cartridge 5 can be mounted on the mounting portion 52, and the lowering amount of the cartridge holder 6 is relatively short, so that the load on the recording / reproducing mechanism 3 can be reduced.

  When the cartridge holder 6 and the base chassis 7 come close to each other and reach the mounting position, the disk cartridge 5 held by the cartridge holder 6 is mounted on the mounting portion 52 configured in the base chassis 7. Here, the positioning recess 29 provided on the main surface of the cartridge body 14 on the lower half 13 side is engaged with the positioning pin 53 projecting from the base chassis 7, whereby the disk cartridge 5 is attached to the mounting portion. 52 is mounted in a state of being positioned. At this time, as shown in FIG. 12, the positioning recess 29 of the disk cartridge 5 has a center slightly shifted from the center of the positioning pin 53, for example, a position shifted by 1 mm. It is drawn in. As a result, the disk cartridge 5 is pulled into the positioning pin 53 and mounted on the mounting portion 52 of the base chassis 7 even when the disk cartridge 5 is not inserted to the deepest portion of the cartridge holder 6. Therefore, when the cartridge holder 6 and the base chassis 7 are brought close to each other without the disk cartridge 5 being inserted to the deepest part of the cartridge holder 6, the disk cartridge 5 is sandwiched between the cartridge holder 6 and the base chassis 7. It can be avoided.

  Then, when the cartridge holder 6 and the base chassis 7 are moved to the moving end in the proximity direction, the disk table 63 constituting the disk rotation drive mechanism 59 enters from the central opening 17 of the cartridge body 14, and the cartridge body The clamping plate 16 of the magneto-optical disk 4 accommodated in 14 is magnetically attracted and held in a state where it is centered. As a result, the magneto-optical disk 4 can be rotated integrally with the disk table 63.

  Next, the reproducing operation of the information signal recorded on the magneto-optical disk 4 will be described. When the information signal is reproduced by the user, the spindle motor 61 is driven, and the magneto-optical disk 4 is rotated by CLV (Constant Linear Velocity), CAV (Constant Angular Velocity), or the like. Then, the optical pick-up device 64 is fed in the radial direction of the magneto-optical disk 4 while being guided by the guide shaft 68 by rotating the feed screw 69 by driving the thread feed motor 70. The optical pickup device 64 emits a light beam from a semiconductor laser, converges with an objective lens 66, and irradiates the signal recording surface of the magneto-optical disk 4. Then, the optical pickup device 64 reads the information signal recorded on the magneto-optical disk 4 by detecting the returning light beam reflected by the magneto-optical disk 4 with a photodetector. At this time, the optical pickup device 64 drives the biaxial actuator and is driven and displaced in the focusing direction and the tracking direction of the objective lens 66 based on the focusing servo signal and the tracking servo signal. For example, first, the optical pickup device 64 is moved to the innermost circumference side of the magneto-optical disk 4 and reads the TOC recorded on the innermost circumference of the magneto-optical disk 4. Then, after reading out the TOC, the track jumps to the track designated by the user, and the information signal designated by the user is read out. When the user performs an operation to stop reproduction, the spindle motor 61 stops the rotation of the disk table 63 and stops the driving of the optical pickup device 64.

  At this time, as shown in FIG. 26, in the recording / reproducing mechanism 3, the slide lever 163 is slid forward by the coil spring 177, and the drive lever 181 is slid rearward by the tension coil spring 187. Further, as shown in FIG. 22, the drive mechanism 221 is stopped, the pressing protrusion 226 a of the first drive gear 226 is separated from the engagement piece 164 of the slide lever 163, and the engagement of the second drive gear 227 is stopped. The mating projection 227a is in the initial position where the engagement of the limit lever 191 with the engagement recess 193 is released.

  Next, a recording operation in which the user processes the magneto-optical disk 4 using an information processing apparatus and records processing data stored in the hard disk or the like, for example, music data or image data, on the magneto-optical disk 4 will be described. When an information signal recording operation is performed by the user, the drive motor 222 is driven to rotate forward, and the second drive gear 227 is moved from the initial position through the gear train 224 and the first drive gear 226 in the direction indicated by the arrow H in FIG. To be rotated. Then, as shown in FIG. 15, the engaging convex portion 227a of the rotating second drive gear 227 and the engaging concave portion 193 of the limit lever 191 are engaged, and the limit lever 191 moves in the direction of arrow F in FIG. It rotates and the press part 192 is moved ahead. When the pressing portion 192 of the limit lever 191 is moved forward, as shown in FIG. 17, the pressed portion 188 of the drive lever 181 is moved forward, and the drive lever 181 and the lift lever 202 are slid forward.

  As the lifting lever 202 moves forward, as shown in FIG. 27, the operation protrusion 114 of the operation lever 103 held by the engaging portion 203 slides forward, and the arm portion 115 moves the rotation support portion 116. It is moved back through. Accordingly, the rotation operation plate 104 of the lifting operation member 102 connected by the arm portion 115 and the support arm 105 moves to the back surface 6 b side of the cartridge holder 6. As a result, the stepped portion 104a of the rotating operation plate 104 is also retracted toward the back surface 6b, and the head support arm 74 of the magnetic head device 71 supported by the stepped portion 104a is moved to the head of the cartridge holder 6 as shown in FIG. The magnetic head portion 73 enters the insertion opening 96 and is brought into sliding contact with the signal recording surface of the magneto-optical disk 4.

  In addition, when the limit lever 191 is rotated in the direction of arrow F in FIG. Thereafter, the drive motor 222 is stopped to prevent an excessive load from being applied to the second drive gear 227 and the limit lever 191.

  Next, the magneto-optical disk 4 is rotated integrally with the disk table 63 by the spindle motor 61 and the optical pickup device 64 is guided by the guide shaft 68 by the thread feed motor 70 and moved in the radial direction of the magneto-optical disk 4. . At this time, the magneto-optical disk 4 is irradiated with a light beam from the recording / reproducing opening 19 of the cartridge main body 14 via the objective lens 66 of the biaxial actuator of the optical pickup device 64 and magneto-optically via the magnetic head 73. A magnetic field is applied to the disk 4 and information signals are recorded.

  When the user stops the recording operation of the recording / reproducing apparatus 1, the recording / reproducing apparatus 1 accesses the innermost peripheral side of the magnetic head unit 73 and the magneto-optical disk 4, and the magnetic head unit 73 and the optical pickup device 67. Updates the TOC. Then, the drive motor 222 is reversely driven in the opposite direction, and the second drive gear 227 is rotated in the other direction via the gear train 224 and the first drive gear 226. In the drive motor 222, the first and second drive gears 226 and 227 are rotated to the initial position by the convex portion 226b provided on the lower surface of the first drive gear 226 pressing the initial position detection switch 228. When this is detected, the drive is stopped. As shown in FIG. 22, when the drive gear 227 returns to the initial position, the limit lever 191 is disengaged from the engaging convex portion 227a and the engaging concave portion 192, and the limiter spring 221 is inverted in FIG. It is rotated in the direction of arrow F, and the pressing portion 192 is moved backward. The drive lever 181 from which the pressing force from the pressing portion 192 is released is slid rearward by a tension coil spring 187 suspended between the guide chassis 9. Further, when the drive lever 181 is slid rearward, the elevating lever 202 whose rear end is locked to the locking portion 204 is also slid rearward.

  Therefore, also in the operation lever 103 held by the engaging portion 203 of the elevating lever 202, the operation protrusion 114 moves rearward, and the arm portion 115 moves forward via the rotation support portion 116. Therefore, the rotation operation plate 104 of the lifting operation member 102 connected by the arm portion 115 and the support arm 105 moves to the front surface 6 a side of the cartridge holder 6. As a result, the stepped portion 104a of the rotating operation plate 104 is also retracted to the front surface 6a side, the head support arm 74 of the magnetic head device 71 is supported by the stepped portion 104a, and rises above the head insertion opening 96 of the cartridge holder 6. Then, the magnetic head unit 73 is retracted from the cartridge holder 6.

  At the same time, the drive of the spindle motor 61 stops, the rotation of the magneto-optical disk 4 stops, and the drive of the optical pickup device 64 stops, whereby the information signal recording operation ends.

  Next, an operation when ejecting the disk cartridge 5 mounted on the mounting portion 52 of the base chassis 7 will be described. When an eject operation button provided in the recording / reproducing apparatus 1 or the information processing apparatus in which the recording / reproducing apparatus 1 is incorporated is operated, the drive motor 222 is driven in reverse, and the first drive gear 226 is connected via the gear train 224. Is rotated from the initial position in the direction of arrow G in FIG. As a result, as shown in FIGS. 28A to 28C, the first drive gear 226 presses the engagement piece 164 of the slide lever 163 rearward by the pressing protrusion 226a. As shown in FIG. 29, the slide lever 163 slides the slider 8 in the opposite direction of the arrow D in FIG. 30 while sliding backward against the urging force of the coil spring 177.

  As shown in FIG. 28, the rotation direction of the first and second drive gears 226 and 227 when the disk cartridge 5 is ejected causes the head support arm 74 of the magnetic head device 71 to be retracted from the cartridge holder 6. The direction of rotation is the same. Accordingly, even when the head support arm 74 is lowered into the cartridge holder 6, the head support arm 74 is always retracted from the cartridge holder 6 when the disk cartridge 5 is ejected, and the magnetic head device 71 and the disk cartridge 5 are ejected from the cartridge holder 6. Interference can be prevented.

  As the slider 8 is moved rearward, as shown in FIG. 21, the guide protrusions 98 and 99 of the cartridge holder 6 are changed from the lower horizontal portions 137a and 138a of the holder guide grooves 137 and 138 to the inclined portions 137b and 137b, respectively. It is moved to the upper horizontal portions 137c and 138c via 138b and is separated from the base chassis 7. At this time, since the guide protrusion 99 is guided by the vertical guide grooves 159 and 160 formed in the guide walls 154 and 155 of the guide chassis 9, the cartridge holder 6 is reliably raised without sliding in the front-rear direction. The When the cartridge holder 6 is moved away from the base chassis 7, the clearance between the cartridge holder 6 and the cover 43 becomes a minimum value (for example, approximately 0.1 mm), and the top of the cartridge holder 6 is within this clearance. A magnetic head device 71 disposed on the plate 82 is disposed. Here, since the magnetic head device 71 is not driven in a state where the disk cartridge 5 is ejected, a space necessary for housing the magnetic head device 71 is secured.

  At this time, as described above, in the magnetic head device 71, as shown in FIG. 8, the side edge portion on the back side of the top plate portion 82 of the cartridge holder 6 is brought into contact with the connection plate 55 from below and attached upward. It is energized. Therefore, the magnetic head device 71 can absorb the load applied to the connection plate 55 as the cartridge holder 6 is raised by bending and deforming the connection portion 55a of the connection plate 55. Further, in the magnetic head device 71, when the connection plate 55 is biased upward by the cartridge holder 6, the rotation support member 56 is rotated upward about the insertion hole 72 c of the coupling member 72. Therefore, the connection plate 55 attached to the attachment portion 56b of the rotation support member 56 is rotated upward so that the amount of refraction of the connection portion 55a is reduced and the load applied to the connection plate 55 is reduced. I am letting.

  As the slider 8 is moved rearward, the guide shafts 79 and 80 of the base chassis 7 are simultaneously moved from the upper horizontal portions 139a and 140a of the base guide grooves 139 and 140 to the lower horizontal portions via the inclined portions 139b and 140b, respectively. 139c and 140c are moved away from the cartridge holder 6. At this time, since the guide shaft 80 is guided by the vertical guide grooves 159 and 160 formed in the guide walls 154 and 155 of the guide chassis 9, the base chassis 7 is raised without sliding in the front-rear direction. By moving the base chassis 7 away from the cartridge holder 6, the clearance between the base chassis 7 and the printed wiring board 256 disposed on the mounting member 42 becomes a minimum value (for example, approximately 0.1 mm). A flexible circuit board 77 for connecting the optical block 65 and the printed wiring board 256 is disposed in the clearance. Here, since the optical block 65 is not driven in a state where the disk cartridge 5 is ejected, a space necessary for housing the flexible circuit board 77 is secured.

  Further, when the slider 8 is slid rearward, the eject lever 147 is also slid rearward by the restricting piece 133 provided in contact with the roller 152, and the restriction on the rotation in the arrow R direction in FIG. The The eject lever 147 is urged by the torsion coil spring 148 and is rotated in the direction of arrow R in FIG. 30 while the roller 152 rolls from the side surface portion 133b of the regulating piece 133 toward the front surface portion 133a. As a result, the eject member 147 pushes the disk cartridge 5 in contact with the contact portion 150 toward the cartridge insertion / removal port 89 side.

  Here, as the slider 8 is slid rearward, first, the cartridge holder 6 and the base chassis 7 are separated by the holder guide grooves 137 and 138 and the base guide grooves 139 and 140 formed in the slider 8, and then ejected. It is formed so that the engagement between the roller 152 of the member 147 and the front surface portion 133b of the regulating piece 133 is released. That is, the holder guide grooves 137 and 138 and the base guide grooves 139 and 140 of the slider 8 are provided with inclined portions 137b to 140b for guiding the cartridge holder 6 and the base guide 7 so as to approach and separate from each other, and of the inclined portions 137b to 140b. Upper and lower end portions are respectively provided with upper horizontal portions 137c, 138c, 139a, 140a and lower horizontal portions 137a, 138a, 139c, 140c in the horizontal direction. Is slidable.

  The slider 8 slides backward to separate the cartridge holder 6 and the base chassis 7 by the inclined portions 137b to 140b, and then slides further backward to regulate the rotation of the eject member 147. It is formed so that the contact between the side portion 133a of the regulating piece 133 and the roller 152 is released. Therefore, when the slider 8 is slid rearward, the cartridge holder 6 is first raised to the insertion / removal position, and then the eject member 147 is rotated to eject the disk cartridge 5. Thus, before the cartridge holder 6 is raised to the insertion / removal position, the disk cartridge 5 is pushed out to the eject member 147, and the disk cartridge 5 and the disk rotation drive mechanism 59 provided in the base chassis 7 remain engaged. It is possible to prevent the situation where the disk cartridge 5 is pushed out and the situation where the disk cartridge 5 collides with the vicinity of the cartridge outlet of the information processing apparatus or the like serving as the recording / reproducing apparatus 1 or the host device.

  Thus, since the cartridge holder 6 is moved to the insertion / removal position, the eject member 147 is rotated in the direction of arrow R in FIG. 14 b is pressed forward and a part of the disk cartridge 5 is ejected from the recording / reproducing apparatus 1.

  When the disc cartridge 5 is ejected from the cartridge holder 6, the engagement protrusion 94 of the shutter holding piece 93 is engaged with the engagement hole of the shutter member 21. , The recording / reproducing openings 18 and 19 formed in the cartridge body 14 are closed.

  The first drive gear 226 continues to rotate in the direction of arrow G in FIG. 18 from the drive motor 222, so that the pressing protrusion 226 a of the drive gear 226 is disengaged from the engagement piece 164 of the slide lever 163. . The slide lever 163 is slid forward of the guide chassis 9 by the coil spring 177 suspended between the guide chassis 9 and returned to the initial position. In addition, the first drive gear 226 is configured such that the first and second drive gears 226 and 227 are moved to the initial positions when the convex portion 227b provided on the lower surface of the second drive gear 227 pushes the initial position detection switch 228. And the drive of the drive motor 222 is stopped.

  In addition, the head lifting mechanism according to the present invention can use a magnetic head device that does not have the rotation support member 56 when a space cannot be provided on the back side of the apparatus main body 2. As shown in FIG. 31, the magnetic head device 260 is connected to the optical block 65 of the optical pickup device 64 via a connecting member 262. The connecting member 262 for connecting the magnetic head device 260 to the optical block 65 has a lower end side fixed to the lower surface side of the optical block 65 and a magnetic head device 260 fixed to the upper end side. The connecting member 262 connects the magnetic head device 260 to the optical pickup device 64 so as to face the top plate portion 82 of the cartridge holder 6 that holds the disk cartridge 5.

  As shown in FIG. 31, the magnetic head device 260 supported by the connecting member 262 connected to the optical pickup device 64 has a magnetic head element inside the slider that is slidably contacted with the signal recording surface of the magneto-optical disk 4 and moved. , A head support arm 264 with the magnetic head portion 263 supported on the distal end side, an arm support plate 265 that restricts excessive displacement of the head support arm 264, a head support arm 264, and And a connection plate 266 to which the arm support plate 265 is connected.

  The head support arm 264 that supports the magnetic head portion 263 on the tip side is formed by punching a thin metal plate having elasticity. The magnetic head unit 263 is supported on the distal end side of the elastically displaceable head support arm 264, so that when the signal recording area of the magneto-optical disk 4 is scanned, the magneto-optical disk 4 generates surface vibration and is driven to rotate. In this case, the head support arm 264 is elastically deformed, so that it is prevented from lifting from the main surface of the magneto-optical disk 4, and the signal recording area can be scanned accurately.

  The arm support plate 265 extends to the upper surface side of the head support arm 264, thereby restricting excessive deformation of the head support arm 264 upward. Further, the arm support plate 265 has a locking portion 267 that is locked to a locking piece 97 of the head insertion opening 96 formed in the top plate portion 82 of the cartridge holder 6 described later at the tip end portion 265a. . The locking portion 267 has a concave contact surface that contacts the locking piece 97, and a locking wall 267a is formed at the tip. Then, the locking portion 267 abuts from below the locking piece 97, so that the upward displacement of the arm support plate 265 is restricted, and the locking piece 97 is locked by the locking wall 267 a. The arm support plate 265 is secured from the locking piece 97. Therefore, the arm support plate 265 can be prevented from coming out above the locking piece 97 due to an impact caused by dropping of the recording / reproducing apparatus 1 or the like.

  The connection plate 266 includes a connection portion 266 a to which the base end side of the head support arm 264 and the arm support plate 265 is connected, and a support portion 266 b that supports the connection portion 266 a and is connected to the coupling member 262. The connecting portion 266a is formed by punching a thin metal plate and has flexibility. Therefore, when the cartridge holder 6 is separated from the base chassis 7, the connection plate 266 is slidably contacted with the top plate portion 82 and bent downward, and the head support arm 264 whose upward deformation is restricted by the locking piece 97. And the load on the arm support plate 265 is reduced.

  That is, when the cartridge holder 6 and the base chassis 7 are moved away from each other, they are connected to the optical block 65 of the optical pickup device 64 provided in the base chassis 7 and the top plate portion of the cartridge holder 6. In the magnetic head device 260 disposed on 82, the side edge of the top plate portion 82 of the cartridge holder 6 is brought into contact with the connection plate 266 from below and is biased upward. On the other hand, as described above, the head support arm 264 and the arm support plate 265 are engaged with the engagement piece 97 in which the engagement portion 267 formed at the distal end portion of the arm support plate 265 protrudes from the top plate portion 82. Since excessive displacement is restricted by being stopped, a load is generated when the proximal end sides of the head support arm 264 and the arm support plate 265 are pushed up by the cartridge holder 6. Here, since the connection portion 266a of the connection plate 266 is bent and deformed to have flexibility, it is possible to absorb such a load and prevent the head support arm 264 and the arm support plate 265 from being loaded. can do. Note that when the cartridge holder 6 and the base chassis 7 are brought close to each other, the connection plate 266 is brought to substantially the same height as the top plate portion 82 of the cartridge holder 6, so that it contacts the top plate portion 82 from below. And the load applied to the connecting portion 266a is removed.

  The connection plate 266 is connected by, for example, screwing the support portion 266b to the connecting member 262. The connecting member 262 supports the connection plate 266, and is connected to the optical block 65 of the optical pickup device 64 by extending downward from the base chassis 7 by being bent at a substantially right angle from the support portion 262a. And a piece 262b. The support portion 262 a is connected to the support portion 266 b of the connection plate 266 and supports the connection plate 266 substantially parallel to the top plate portion 82 of the cartridge holder 6. The connection piece 262b formed by bending from the support portion 262a extends to the lower surface side of the base chassis 7, and is connected to the optical block 65 of the optical pickup device 64 by screws or the like. Accordingly, the magnetic head device 260 is moved along the radial direction of the magneto-optical disk 4 together with the optical block 65 by being connected to the optical block 65 via the connecting member 262.

  Such a magnetic head device 260 does not take a space on the back side of the apparatus main body 2, and even when the rotation support member 56 cannot be provided, the flexible connecting plate 266 is bent, The load due to the cartridge holder 6 being pushed up from below can be absorbed. Accordingly, the apparatus body 2 can be made thinner and space-saving due to the cartridge holder 6 and the base chassis 7 being closely spaced from each other, and the load on the magnetic head device 260 can be reduced.

  As described above in detail, in the recording / reproducing apparatus 1 to which the magnetic head elevating mechanism according to the present invention is applied, the magnetic head device 71 is not shown in the state where the cartridge holder 6 and the base chassis 7 are separated from each other. As shown in FIG. 8, the side edge portion on the back side of the top plate portion 82 of the cartridge holder 6 is brought into contact with the connection plate 55 from below and biased upward. Therefore, the magnetic head device 71 can absorb the load applied to the connection plate 55 as the cartridge holder 6 is raised by bending and deforming the connection portion 55a of the connection plate 55. Further, in the magnetic head device 71, when the connection plate 55 is biased upward by the cartridge holder 6, the rotation support member 56 is rotated upward about the insertion hole 72 c of the coupling member 72. Therefore, the connection plate 55 attached to the attachment portion 56b of the rotation support member 56 is rotated upward so that the amount of refraction of the connection portion 55a is reduced and the load applied to the connection plate 55 is reduced. Can be made.

  Further, the magnetic head device 71 is provided with a locking piece 97 in a head insertion opening 96 formed in the top plate portion 82 of the cartridge holder 6, and is provided at the tip of an arm support plate 75 on the locking piece 97. The locking portion 57 is locked. Therefore, the arm support plate 75 can be prevented from coming out above the locking piece 97 due to an impact caused by dropping or the like of the recording / reproducing apparatus 1.

  Further, according to the recording / reproducing apparatus 1 to which the head elevating mechanism according to the present invention is applied, the base holder 7 in which the optical pickup device 64 is disposed together with the cartridge holder 6 that holds the disc cartridge 5 is moved toward and away from each other. Therefore, when the optical block 65 of the optical pickup device 64 is not driven, the clearance between the base chassis 7 and the printed wiring board 256 disposed on the mounting member 42 is moved together with the optical block 65. The height necessary for housing the flexible circuit board 77 can be suppressed.

  Therefore, only the cartridge holder that holds the disk cartridge is moved in the vertical direction, and in the recording / reproducing apparatus in which the base chassis on which the optical pickup device is disposed is fixed, between the optical pickup and the lower surface portion of the apparatus main body, While it is always necessary to ensure a sufficient clearance for the movement of the flexible circuit board, according to the present invention, it is sufficient to ensure the clearance necessary for housing the flexible circuit board 77. The height can be suppressed, the apparatus main body 2 can be thinned, and the portability of the apparatus main body 2 can be improved.

  Further, in the recording / reproducing apparatus 1, when the disc cartridge 5 is inserted, the amount of ascending of the base chassis 7 is formed larger than the amount of descending of the cartridge holder 6. Therefore, the recording / reproducing apparatus 1 can prevent the chucking failure due to the cartridge holder 6 not being lowered even when an obstacle such as a finger of the user into which the cartridge cartridge 5 is inserted is inserted into the cartridge insertion / removal port 89. The disk cartridge 5 can be mounted on the mounting portion 52 by raising the chassis 7.

  Furthermore, since the insertion opening 76 is formed in the base chassis 7 so that the gear train and the drive motor provided in the guide chassis 9 can be inserted, the base chassis 7 is moved to the guide chassis 9 side when the base chassis 7 is lowered. By allowing the gear train and the drive motor to face the main surface portion of the chassis 7, it is not necessary to provide a clearance corresponding to the height of the gear train and the drive motor, and when the base chassis 7 is raised from the guide chassis 9. The gear train and the drive motor are retracted from the main surface portion of the base chassis 7 and do not interfere with the disk cartridge 5.

  Further, when the disc cartridge 5 is ejected, the slider 8 first moves the ejector member 147 after separating the cartridge holder 6 and the base chassis 7 and moving them to the ejection position. Therefore, before the cartridge holder 6 is raised to the insertion / removal position, the disk cartridge 5 is pushed out to the eject member 147, and the disk cartridge 5 is kept engaged with the disk rotation drive mechanism 59 of the base chassis 7. The situation where it is pushed out can be prevented.

  Further, according to the recording / reproducing apparatus 1 to which the present invention is applied, in order to move the base chassis 7 on which the optical pickup device 64 is disposed together with the cartridge holder 6, only the cartridge holder is moved in the vertical direction. Requires less loading time than a fixed device.

  In the recording / reproducing apparatus 1 to which the present invention is applied, the cartridge holder 6 and the base chassis 7 can be moved close to and away from each other by sliding one slider 8, and therefore the loading for moving the cartridge holder and the base chassis separately. Compared to the mechanism, the number of parts can be reduced.

  The recording / reproducing apparatus 1 of the disk cartridge 5 using the magneto-optical disk 4 as a recording medium has been described above as an example. However, the present invention is also applicable to a recording / reproducing apparatus of a disk cartridge using an optical disk or a flexible magnetic disk as a recording medium. can do.

  In the recording / reproducing apparatus 1, the cartridge holder 6 that holds the disk cartridge 5 together with the base chassis 7 is also configured to move toward and away from each other. Only the chassis 7 may be movable toward the cartridge holder 6, and the cartridge holder 6 may not be moved.

  In this case, the holder guide grooves 137 and 138 are not formed on the side surfaces 128 and 129 of the slider 8, but only the base guide grooves 139 and 140 are formed. The base guide grooves 139 and 140 retract the spindle motor 61 and the optical block 65 provided in the base chassis 7 from the movement locus of the cartridge 5 when the cartridge 5 is ejected, and hold it in the cartridge holder 6 when the cartridge 5 is inserted. The base chassis 7 is formed so as to be lifted and lowered by a height that can be securely attached to the optical disk 4 of the cartridge 5. Further, since the cartridge holder 6 is fixed to the base chassis 7 without being approached or separated, the cartridge holder 6 is previously provided with a sufficient clearance to operate the magnetic head device 71 with the cover 43. .

  As a result, only the base chassis 7 moves closer to or away from the cartridge holder 6 in accordance with the movement of the slider 8 and the cartridge holder 6 does not move. Therefore, the user's finger or the like that has inserted the disk cartridge into the cartridge insertion / removal port 89 There is no obstacle to loading of the disk cartridge 5.

  Further, the recording / reproducing apparatus according to the present invention may be configured such that only the cartridge holder 6 can be moved toward the base chassis 7 and the base chassis 7 does not move, as in the prior art.

1 is a perspective view showing a recording / reproducing apparatus to which the present invention is applied. It is a perspective view showing a disk cartridge. It is a perspective view which shows a recording / reproducing mechanism. It is a disassembled perspective view which shows a recording / reproducing mechanism. It is a perspective view which shows a base chassis. It is a perspective view which shows the optical block with which the magnetic head apparatus was connected. It is a disassembled perspective view which shows a magnetic head apparatus. It is sectional drawing which shows a magnetic head apparatus when a cartridge holder and a base chassis exist in the position which mutually separated. It is sectional drawing which shows a magnetic head apparatus when a cartridge holder and a base chassis exist in the position which mutually adjoined. It is sectional drawing which shows a magnetic head apparatus when a magnetic head part is slidably contacted with a magneto-optical disk. It is a perspective view which shows a slider and a cartridge holder. It is a top view which shows a recording / reproducing mechanism. It is a perspective view which shows the assembly with which the slider, the cartridge holder, and the base chassis were assembled | attached. It is a perspective view which shows a guide chassis. It is a figure which shows the gear mechanism in recording operation. It is a top view which shows the limit lever in the state in which the magnetic head is lowered | hung. It is a figure which shows the recording / reproducing mechanism in recording operation. It is a figure which shows the gear mechanism in eject operation. It is a top view which shows the initial position detection switch pressed by the 2nd drive gear. FIG. 6 is a diagram showing a recording / reproducing mechanism during a disk cartridge ejection operation. It is sectional drawing which shows the state which the cartridge holder and the disc board | substrate separated. It is a figure which shows the gear mechanism in the state in which the disc cartridge is not inserted. It is a figure which shows the recording / reproducing mechanism in the state in which the disc cartridge is not inserted. It is a figure which shows the recording / reproducing apparatus in reproduction | regeneration operation. It is sectional drawing which shows the state which the cartridge holder and the disc board | substrate approached. It is a figure which shows the recording / reproducing apparatus in reproduction | regeneration operation. It is a figure which shows the recording / reproducing mechanism in recording operation. It is a top view which shows engagement with the 1st drive gear and slide lever at the time of eject operation. It is a figure which shows the recording / reproducing apparatus in discharge operation | movement of a disc cartridge. It is a figure which shows a recording / reproducing mechanism when a disc cartridge is discharged | emitted. It is a perspective view which shows the other magnetic head apparatus based on this invention. It is a perspective view which shows the conventional recording / reproducing apparatus. It is a perspective view which shows the base chassis of the conventional recording / reproducing apparatus. It is a top view which shows the slider of the conventional recording / reproducing apparatus. It is a side view which shows the slider of the conventional recording / reproducing apparatus. It is a side view which shows the head shift lever of the conventional recording / reproducing apparatus. It is a perspective view which shows the cam lever of the conventional recording / reproducing apparatus. It is a side view which shows the joint lever of the conventional recording / reproducing apparatus. It is a top view which shows the drive lever of the conventional recording / reproducing apparatus. It is a side view which shows the conventional recording / reproducing apparatus with which the disc cartridge is inserted in the cartridge holder. It is a side view which shows the conventional recording / reproducing apparatus which shows the state in which the cartridge holder was adjoined to the base chassis.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Recording / reproducing apparatus, 2 Apparatus main body, 3 Recording / reproducing mechanism, 4 Magneto-optical disk, 5 Disk cartridge, 6 Cartridge holder, 7 Base chassis, 8 Slider, 9 Guide chassis, 29 Positioning recessed part, 42 Mounting member, 43 Cover, 52 Mounting part, 53 Positioning pin, 55 Connection plate, 56 Rotation support member, 57 Locking part, 58 Insertion shaft, 59 Disk rotation drive mechanism, 60 Torsion coil spring, 64 Optical pickup device, 65 Optical block, 67 Pickup opening 71 Magnetic head device, 72 Connecting member, 73 Magnetic head portion, 74 Head support arm, 75 Arm support plate, 76 Insertion opening, 77 Flexible circuit board, 78 Side wall, 79, 80 Guide shaft, 82 Top plate portion, 85, 86 side wall, 89 cartridge insertion / removal port, 96 f Opening slot for insertion, 97 Locking piece, 98, 99 Guide protrusion, 101 Head lifting mechanism, 102 Lifting operation plate, 103 Operation lever, 104 Rotating operation plate, 105 Support arm, 114 Operation protrusion, 115 Arm portion , 125 connecting portion, 126, 127 extending portion, 128, 129 side surface portion, 133 regulating piece, 135, 136 guide pin, 137, 138 holder guide groove, 139, 140 base guide groove, 144 pressed piece, 147 eject member 148 torsion coil spring, 149 rotating part, 150 contact part, 151 restricting part, 152 roller, 154, 155 guide wall, 157,158 horizontal guide groove, 159,160 vertical guide groove, 163 slide lever, 174 pressing part, 180 Link mechanism, 181 Drive lever, 188 Pressed part, 191 Limit lever, 202 Lifting lever, 203 Engagement part, 211 Limiter spring, 221 Drive mechanism, 226 First gear, 226a Pressing convex part, 227 Second gear, 227a Engaging convex part, 227b Convex part, 228 Initial position switching Switch, 230 Pressing piece, 231 Contact piece, 260 Magnetic head device, 262 Connecting member, 263 Magnetic head portion, 264 Head support arm, 265 Arm support plate, 266 Connection plate, 267 Locking portion

Claims (6)

A base chassis provided with a rotation drive mechanism for rotating the information recording medium and an optical pickup device for recording or reproducing information signals with respect to the information recording medium;
A holder for holding the recording medium cartridge in which the information recording medium is housed and moving the information recording medium to and from the rotation drive mechanism by being moved up and down with respect to the base chassis;
A magnetic head that faces the inside of the holder from a head insertion opening formed in the top plate portion of the holder and applies an external magnetic field to the information recording medium; and the magnetic head extended on the top plate portion of the holder A magnetic head device having a head support arm for supporting the head, and a connecting member for connecting the head support arm and the optical pickup device;
An elevating operation plate that is provided on the top plate portion and supports the head support arm to elevate and lower the magnetic head in and out of the holder according to an operation;
The head support arm has a flexible connection portion with the coupling member, and the connection portion is flexibly deformed by slidingly contacting the top plate portion of the holder in accordance with the lifting and lowering operation of the holder. Magnetic head lifting mechanism.   The magnetic head device includes an arm support plate that restricts excessive displacement of the head support arm onto the holder, and a distal end portion of the arm support plate is provided on a top plate portion of the holder. 2. The magnetic head lifting mechanism according to claim 1, wherein the magnetic head lifting mechanism is in contact with the piece.   3. The magnetic head lifting mechanism according to claim 2, wherein a locking portion that is locked to the locking piece is bent at a tip portion of the arm support plate. A base chassis provided with a rotation drive mechanism for rotating the information recording medium and an optical pickup device for recording or reproducing information signals with respect to the information recording medium;
A holder for holding the recording medium cartridge in which the information recording medium is housed and moving the information recording medium to and from the rotation drive mechanism by being moved up and down with respect to the base chassis;
A magnetic head that faces the inside of the holder from a head insertion opening formed in the top plate portion of the holder and applies an external magnetic field to the information recording medium; and the magnetic head extended on the top plate portion of the holder A head support arm that supports the head support arm, a connection member that connects the head support arm and the optical pickup device, and the head support arm that is provided between the connection member and the head support arm. A magnetic head device having a rotation support member rotatably supported in the up-and-down direction of the holder;
An elevating operation plate that is provided on the top plate portion and supports the head support arm to elevate and lower the magnetic head in and out of the holder according to an operation;
The head support arm has a flexible connection portion with the rotation support member, and is rotated by the rotation support member when the holder is moved up and down, and the connection portion is connected to the holder. A magnetic head lifting mechanism that is slidably contacted with the top plate and deformed by bending.   The magnetic head device includes an arm support plate that restricts excessive displacement of the head support arm onto the holder, and a distal end portion of the arm support plate is provided on a top plate portion of the holder. 5. The magnetic head lifting mechanism according to claim 4, wherein the magnetic head lifting mechanism is in contact with the piece. 6. The magnetic head lifting mechanism according to claim 5, wherein a locking portion that is locked to the locking piece is bent at a tip portion of the arm support plate.

Images