JP5241320B2 - Disk unit - Google Patents

Description

  The present invention relates to a disk device provided with an adjustment mechanism that adjusts the angle of the head facing the disk by changing the tilt angle of a guide member that guides the head.

  A disk device that reproduces information recorded on a disk by an optical head or records information on a disk is supported so that the optical head can reciprocate by a guide member, and has a screw shaft that extends in parallel with the guide member. The optical head is moved by the rotational force of the screw shaft.

  In this type of disk device, it is necessary to adjust the direction of the optical head so that the optical head faces the recording surface of the disk clamped on the turntable in an optimal direction.

  As described in Patent Document 1 and Patent Document 2 below, the conventional disk device changes the mounting angle of a guide member that guides the optical head and a screw shaft that applies a moving force to the optical head, In general, the facing angle of the optical head with respect to can be adjusted.

  Further, as a disk device, an optical head is guided by a pair of guide members extending in parallel, and a screw shaft is provided on the side of one guide member, and a moving force is applied from the screw shaft to the optical head. is there. In this structure, since the guide structure of the optical head and the path for applying a moving force to the optical head are separated, the optical head is easily supported while being supported on both sides and maintained in a posture. In addition, an engagement portion is provided in the leaf spring supported by the optical head, and the engagement portion is elastically pressed to the outer periphery of the screw shaft, so that the screw shaft is moved after the optical head reaches the end due to troubles in electrical control. Even if the screw continues to rotate, the screw shaft can be idled with respect to the engaging portion, and it is easy to suppress a fatal failure.

  However, in a disk device provided with a pair of guide members and a screw shaft, the angle of at least one of the guide members is maintained so that the parallelism of the pair of guide members can be maintained in order to adjust the tilt angle of the optical head with respect to the disk. It will be necessary to adjust. Thus, if the direction of the optical head is adjusted by tilting the pair of guide members, the parallelism between the movement trajectory of the optical head guided and moved by the guide member and the axis of the screw shaft may not be maintained. In this case, the applied pressure between the engaging portion and the screw shaft changes depending on the movement position of the optical head, and the load on the screw shaft is likely to vary. If a large transfer motor for driving the screw shaft is used, the optical head can be moved with relatively high accuracy regardless of the fluctuation of the load. However, when a small motor is used, the optical head may not be accurately transferred to the target position due to fluctuations in the load.

  Patent Document 3 below discloses a disk device that guides an optical head with a pair of guide members and adjusts the angle of one guide member and a screw shaft together.

In this disk device, one end of the sliding main shaft which is one guide member and one end of the screw shaft are fixed to the same engaging member, and this engaging member is attached to the chassis portion so that the angle can be adjusted. The mounting angle of the sliding main shaft and the mounting angle of the screw shaft can be adjusted together.
JP 2001-351251 A JP 2003-187463 A JP 2005-267672 A

  However, the angle adjusting mechanism of the disk device described in Patent Document 3 is such that one end of the sliding main shaft and one end of the screw shaft are both fixed to the engaging member. When adjusting by separating them, bending stress tends to act on the sliding main shaft and the screw shaft, which may impair the linearity of the sliding main shaft and increase the rotational load on the screw shaft.

  Further, since one end of the sliding main shaft and one end of the screw shaft are fixed to the engaging member, when the engaging member is inclined, the parallelism between the sliding main shaft and the screw shaft is lost. Therefore, there is a need for a guide mechanism for operating the engaging member to which the end portions of the two shafts are fixed so as to approach and separate from the chassis portion while maintaining the posture.

  In this regard, in FIG. 3 of Patent Document 3, a concave portion is formed in the chassis portion, and the engaging member is guided so as to be able to move up and down within the concave portion, and an adjustment screw provided in the central portion of the concave portion. Discloses a structure in which the engaging member is moved up and down. However, in this structure, since the engaging member is supported by one adjusting screw, the posture of the engaging member is unstable, and the frictional force is also reduced because the engaging member and the side wall of the recess slide. It becomes difficult to adjust the engaging member to move up and down smoothly.

  The present invention solves the above-described conventional problems. In the head that is guided by the guide member and moved by the screw shaft, the posture of the guide member and the screw shaft can be adjusted in a stable state, and the head moves. An object of the present invention is to provide a disk device that can reduce the load when the operation is performed.

The present invention provides a chassis with a rotational drive unit that drives a disk, a head that performs at least one of a recording operation and a reproducing operation, a first guide member and a second guide member that guide the head, and the first In a disk device in which a screw shaft provided in parallel with the guide member and rotated by a transfer motor is mounted, and the head moves to face the surface of the disk by the rotational force of the screw shaft,
A bracket is provided for rotatably supporting the screw shaft, the bracket including a connecting plate portion extending in parallel with the screw shaft, a pair of pressing portions located on both sides of the connecting plate portion, and the connecting plate portion. And a fulcrum protrusion that protrudes away from the chassis is formed, and the chassis is provided with a mounting surface and an intermediate support portion facing the mounting surface with a space therebetween,
The connecting plate portion is disposed between the attachment surface and the intermediate support portion, and the intermediate elastic member biases the connecting plate portion away from the attachment surface, so that the support protrusion is the intermediate support portion. Pressed against
With both ends of the first guide member is pressed toward the mounting surface by each of the pressing portion, an elastic member for urging the end portions of the first guide member in a direction away from said mounting surface Is provided ,
The inclination angle of the bracket, the tilt adjusting mechanism for adjusting the contact portion between the support projections and the intermediate support as a fulcrum is provided, along with the inclination angle of the screw shaft is adjustable together with the bracket, the mounting The inclination angle of the first guide member with respect to the surface can be adjusted at the same time.

  The disk device of the present invention can adjust the angle of the first guide member and the angle of the screw shaft together. Therefore, the relative position between the first guide member and the screw shaft can be maintained, and it is easy to prevent the problem that the rotational load of the screw shaft fluctuates due to the change in the moving position of the head.

  Further, when the inclination angle of the bracket supporting the screw shaft is changed, the first guide member is pressed by a pressing portion provided on the bracket, and the angle of the first guide member is changed. Since the bracket that supports the screw shaft and the first guide member are independent members, excessive stress is not applied to the first guide member when the angle of the bracket is adjusted, and the first guide member Can be adjusted together.

  In the present invention, the first guide member is pressed by the pressing portions provided at two locations of the bracket to change the angle of the first guide member, but the urging force that pushes up the first guide member from the chassis acts on the first guide member. Since the elastic member is provided, it is possible to prevent an excessive bending stress from acting on the first guide member due to the deformation of the elastic member.

  In the present invention, the pressing portion provided on the bracket is formed to be inclined with respect to the mounting surface of the chassis, and a vertically extending restricting portion is provided on the mounting surface of the chassis. It is preferable that the first guide member is pressed toward the chassis and pressed against the restricting portion by a component force of a pressing force acting on the first guide member from a portion.

  In the above configuration, the first guide member does not move in a direction parallel to the mounting surface of the chassis, and the posture of the first guide member can be adjusted only in the direction in which the angle with the mounting surface of the chassis changes. It becomes like this.

  In the present invention, the tilt adjustment mechanism has a pair of adjustment screws that are inserted into the bracket and screwed into the chassis at two positions spaced apart in the axial direction of the screw shaft. When the screwing amount of the screw is changed, the inclination angle of the bracket can be changed.

  The disk device of the present invention is a common elastic member, and urges both the first guide member and the bracket away from the chassis, so that the number of elastic members is minimized. This elastic member can prevent excessive stress from acting on both the bracket and the first guide member.

  In the above invention, the inclination of the screw shaft can be adjusted by rotating the bracket around the center support portion, and the inclination of the first guide member can be adjusted accordingly. Thus, since the bracket is tilted with the intermediate support portion as a fulcrum, the distance between the bracket and the chassis does not change extremely, and the tilt of the bracket can be adjusted efficiently by adjusting the screwing of the adjusting screw.

  Further, according to the present invention, the bracket is provided with a detection switch for detecting the moving position of the head.

  In the disk device of the present invention, the angle of the first guide member and the screw shaft can be adjusted together by an adjustment operation for tilting the bracket, but since the detection switch for detecting the moving position of the head is mounted on the bracket, The relative position between the detection switch and the detection switch is not greatly changed by adjustment work, and the head can always be detected at the same position by the detection switch.

  The disk device of the present invention can adjust the head tilt while always maintaining the relative position between the guide member that guides the head and the screw shaft that applies the moving force to the head. Easy to prevent fluctuations. Therefore, it is possible to use a relatively small transfer motor. Further, during the adjustment operation, extreme stress does not act on the screw shaft and the first guide member, and the inclination of both the screw shaft and the first guide member is adjusted with the minimum number of parts. Can do.

  FIG. 1 is a side view showing a main part of a disk device according to an embodiment of the present invention. FIG. 2 is a perspective view showing the drive chassis of the disk device with the lower surface facing upward, and FIG. 3 is an exploded perspective view of a mechanism mounted on the lower surface of the drive chassis. 4 is a cross-sectional view of the drive chassis shown in FIG. 2 cut along line IV-IV.

  A disk device 1 shown in FIG. 1 has a housing 2 formed of a metal plate, and an insertion port 4 is opened in a front surface portion 3 of the housing 2. Inside the housing 2, a conveyance roller 5 and a synthetic resin sliding member 6 facing above the conveyance roller 5 are provided inside the insertion port 4. The conveying roller 5 is pressed against the sliding member 6 by the biasing force of the spring member, and the disc D inserted from the insertion port 4 is sandwiched between the conveying roller 5 and the sliding member 6, and the rotational force of the conveying roller 5. Is fed into the inside of the housing 2.

  A drive chassis 10 is provided inside the housing 2. As shown in FIG. 2, the drive chassis 10 is formed by pressing a metal plate. Inside the housing 2, dampers 7 shown in FIG. 2 are fixed at a plurality of locations. The damper 7 has oil sealed inside a rubber bag. The damper 7 has a fixed portion 7 a shown in FIG. 2 fixed inside the housing 2, and support portions 10 a provided at a plurality of locations of the drive chassis 10 are supported by the damper 7. The drive chassis 10 is elastically supported.

  As shown in FIG. 1, a pair of support pieces 10 b are formed on the drive chassis 10 by bending upward on the back side of the housing 2 on the X2 side. FIG. 2 shows one support piece 10b. A support shaft 11 is fixed to each support piece 10b, and a clamp base 12 is provided on the drive chassis 10 so as to be pivotally supported with the support shaft 11 as a fulcrum. The clamp base 12 is urged to rotate counterclockwise by a spring member (not shown). As shown in FIG. 1, when the disk D inserted from the insertion port 4 is carried into the housing 2, the clamp base 12 is lifted by a clamp release member (not shown).

  The drive chassis 10 is provided with a rotation drive unit 13. As shown in FIG. 2, in the rotation drive unit 13, the spindle motor 14 is fixed to the lower surface 10 c of the drive chassis 10, and the rotation shaft 15 of the spindle motor 14 is connected to the upper surface of the drive chassis 10 as shown in FIG. 1. The turntable 16 is fixed to the rotating shaft 15 so as to protrude upward from 10 d.

  A clamper 17 is rotatably supported on the tip of the clamp base 12 above the turntable 16.

  When the center hole of the disk D carried into the housing 2 reaches the turntable 16, the lifting force applied to the clamp base 12 from the clamp release member is released, and the clamp base 12 is moved by the biasing force of the spring member. It is turned counterclockwise. The center hole of the disk D is fitted into the turntable 16 and the protrusion 16a, and the peripheral part of the center hole of the disk D is sandwiched between the support part 16b of the turntable 16 and the clamper 17.

  As shown in FIG. 2, the drive chassis 10 is formed with a large opening 10e on the side of the rotation drive unit 13, and the head 20 is in the radial direction of the disk D within the opening 10e. It is movably provided in the α2 direction.

  The head 20 has a head base 21 formed of a light metal material such as an aluminum alloy. The head base 21 is integrally formed with a pair of reference bearing portions 21a and a reference bearing portion 21b that protrude to the left in FIG. 2, and a circular reference sliding hole 21c is opened in the reference bearing portion 21a. A circular reference sliding hole 21d is opened in the bearing portion 21b. The reference sliding hole 21c and the reference sliding hole 21d are formed on the same line. The head base 21 is formed with a guide protrusion 21e that protrudes to the right in FIG. 2. As shown in FIG. 4, the guide protrusion 21e opens in a U-shape toward the right in FIG. A sliding recess 21f is formed.

  Inside the head base 21, a light emitting element such as a semiconductor laser, an objective lens that gives the light emitted from the light emitting element to the recording surface of the disk D, and reflected light reflected from the recording surface of the disk D are received. Built-in light receiving element. The objective lens is provided on the surface facing the Z1 side of the head base 21, that is, the upper surface facing upward in FIG. The optical axis of the objective lens is directed in the Z1 direction, but is adjusted so that the optical axis Z1 is as parallel as possible to the axis O of the rotation shaft 15 of the spindle motor 14 by an inclination adjustment mechanism described later.

  A reference shaft 22 that is a first guide member is provided on one side of the opening 10e formed in the drive chassis 10, and a slide shaft 23 that is a second guide member is provided on the other side. Is provided. Reference sliding holes 21c and 21d formed in the head base 21 are supported so as to be slidable on the reference shaft 22 with almost no gap, and the head 20 is guided in the α1-α2 direction with respect to the reference shaft 22. A sliding recess 21 f formed on the other side of the head base 21 is supported so as to be slidable on the sliding shaft 23. The sliding recess 21f is combined with the sliding shaft 23 with almost no gap in the vertical direction (Z1-Z2 direction) in FIG. 4, but is combined with a margin in the horizontal direction in FIG. It is.

  As shown in FIGS. 3 and 4, the lower surface 10 c of the drive chassis 10 is an attachment surface to which the reference shaft 22 and the like are attached. As shown in FIG. 3, a pair of fixed projections 10f and 10f are formed on the lower surface 10c on the side of the opening 10e, and the fixed projection 10g is similarly formed on the α2 side of the fixed projections 10f and 10f. Protrusions are formed. A female screw hole 10h is formed on the α1 side of the fixed protrusions 10f, 10f, and a female screw hole 10i is also formed on the α1 side of the fixed protrusion 10g.

  As shown in FIG. 3, a first leaf spring 31 and a second leaf spring 36 are attached to the lower surface 10 c of the drive chassis 10. The first plate spring 31 and the second plate spring 36 are made of a thin plate spring metal material such as a phosphor bronze plate or a stainless plate.

  The first leaf spring 31 is provided with a flat support plate portion 32. A pair of fitting holes 32a and 32a and a screw escape hole 32b located on the α1 side are opened in the support plate portion 32. Yes. The first leaf spring 31 is attached so that the fitting holes 32a and 32a are fitted into the fixing protrusions 10f and 10f, respectively, and the support plate portion 32 is in close contact with the lower surface 10c of the drive chassis 10. After the fitting holes 32a and 32a are press-fitted into the fixing protrusions 10f and 10f, or after the fitting holes 32a and 32a are inserted through the fixing protrusions 10f and 10f, the fixing protrusions 10f and 10f are crushed and fixed, or a support plate The support plate 32 is fixed to the lower surface 10c of the drive chassis 10 without moving, such as by bonding the portion 32 to the lower surface 10c. Further, the screw escape hole 32b formed in the support plate portion 32 is positioned so as to overlap with the female screw hole 10h.

  The first leaf spring 31 is integrally formed with an elastic portion 33 that is bent in the Z2 direction from the end portion on the α1 side of the support plate portion 32. The elastic part 33 has an inclined urging part 33a and an end face restricting part 33b bent from the inclined urging part 33a. A restricting piece 10j standing in the Z2 direction is formed on the drive chassis 10 at a position facing the elastic part 33, and a restricting part 10k extending from the lower surface 10c perpendicularly to the Z2 direction is formed on the side of the restricting piece 10j. It has become. The inclined urging portion 33a is inclined so as to move away from the restricting portion 10k as it moves away from the lower surface 10c in the Z2 direction.

  As shown in FIG. 4, one end 22a of the reference shaft 22 is pressed toward the Z2 direction away from the lower surface 10c by an urging force acting from the inclined urging portion 33a of the elastic portion 33, and It is pressed against the restricting portion 10k by the component force. Further, the end surface restricting portion 33b formed on the elastic portion 33 is in contact with the end surface 22b of the reference shaft 22, and the reference shaft 22 is restricted so as not to move in the axial direction.

  As shown in FIG. 3, the second leaf spring 36 includes a support plate portion 37 and an elastic portion 38 that is bent with an inclination angle with respect to the support plate portion 37. A fitting hole 37 a is opened in the support plate portion 37. The support plate portion 37 is fixed so that it does not move in close contact with the lower surface 10c of the drive chassis 10 by fitting the fitting hole 37a into the fixing protrusion 10g, press-fitting, fixing by caulking, or bonding. Has been. Further, the elastic portion 38 is in a state where it rises from the lower surface 10c and can be elastically deformed.

  As shown in FIG. 3, a restriction piece 10m is bent to the side of the elastic part 38, and a restriction part 10n extending vertically from the lower surface 10c of the drive chassis 10 in the Z2 direction is formed on the restriction piece 10m. . The other end 22c of the reference shaft 22 is guided by the restricting portion 10n and is urged toward the Z2 direction away from the lower surface 10c by the elastic portion 38. Further, a screw escape hole 38 a is opened in the elastic portion 38 of the second leaf spring 36, and this screw escape hole 38 a is positioned so as to overlap with the female screw hole 10 i formed in the drive chassis 10.

  As shown in FIGS. 2 and 3, a bracket 40 is provided on the side of the reference shaft 22 and on the first leaf spring 31 and the second leaf spring 36.

  The bracket 40 is formed by bending a metal plate. The bracket 40 includes a connection plate portion 41 extending substantially parallel to the reference shaft 22, a first support side plate 42 bent in the Z2 direction from an end portion on the α1 side of the connection plate portion 41, and Z2 from an end portion on the α2 side. It has the 2nd support side plate 43 bent in the direction.

  A transfer motor 51 is fixed to the outside of the second support side plate 43. The transfer motor 51 is a stepping motor, and a screw shaft 52 is attached to its rotating shaft. The screw shaft 52 protrudes from a hole 43 a formed in the second support side plate 43, and the tip end portion of the screw shaft 52 is rotatably supported by a bearing portion provided in the first support side plate 42. .

  The bracket 40 is formed with a screw mounting portion 44 that is bent in the horizontal direction from the end portion on the Z2 side of the first support side plate 42, and the first pressing that is bent from the screw mounting portion 44 to the Z1 side. A piece 45 is provided. An inclined pressing portion 45 a is formed on the end side of the first pressing piece 45. The pressing portion 45a is inclined so as to approach the restricting portion 10k as the distance from the lower surface 10c of the drive chassis 10 increases. Further, the bracket 40 is formed with a screw mounting portion 46 extending horizontally from the side portion of the second support side plate 43, and the second pressing piece is interposed between the second support side plate 43 and the screw mounting portion 46. 47 is formed. The second pressing piece 47 extends obliquely in the Z2 direction, and one side thereof serves as a pressing portion 47a. The pressing portion 47a is inclined so as to approach the restricting portion 10n as it moves away from the lower surface 10c of the drive chassis 10 in the Z2 direction.

  As shown in FIG. 3, the connecting plate portion 41 of the bracket 40 is provided with a fulcrum protrusion 41a that protrudes in the Z2 direction. A support protrusion 10p cut and raised from the lower surface 10c in the Z2 direction is bent on the drive chassis 10, and an intermediate support portion 10q bent from the support protrusion 10p is provided substantially parallel to the lower surface 10c. The first leaf spring 31 is integrally formed with an intermediate elastic portion 34 that protrudes leftward from the support plate portion 32. The intermediate elastic portion 34 is bent in the Z2 direction from the support plate portion 32 and extends obliquely, and faces the lower side of the intermediate support portion 10q.

  As shown in FIG. 2, in the bracket 40, the portion having the fulcrum protrusion 41 a of the connecting plate portion 41 enters between the intermediate elastic portion 34 and the intermediate support portion 10 q, and the connecting plate portion 41 is elastically generated by the intermediate elastic portion 34. Is urged in the Z2 direction, and the fulcrum protrusion 41a is pressed against the surface of the intermediate support portion 10q facing the Z1 side. A screw mounting hole 44 is formed in the screw mounting portion 44 of the bracket 40, and an adjustment screw 55 inserted through the screw mounting hole is screwed into a female screw hole 10 h formed in the drive chassis 10. The screw mounting portion 46 formed on the α2 side is also formed with a screw mounting hole, and the adjustment screw 56 inserted through the screw mounting hole is screwed into the female screw hole 10i formed in the drive chassis 10. Yes.

  Thus, when the bracket 40 is attached to the lower surface 10c of the drive chassis 10, one end 22a of the reference shaft 22 is formed on the elastic portion 33 of the first leaf spring 31 as shown in FIG. It is sandwiched between the inclined urging portion 33a and the pressing portion 45a of the first pressing piece 45 formed on the bracket 40. The end 22a of the reference shaft 22 is urged in the Z2 direction by the elastic force of the inclined urging portion 33a, and the end 22a of the reference shaft 22 is urged by the elastic force of the same inclined urging portion 33a. Thus, the pressing portion 45a of the bracket 40 is biased in the Z2 direction. Furthermore, the end 22a is pressed against the restricting portion 10k by the horizontal component of the biasing force in the Z2 direction by the inclined biasing portion 33a and the horizontal component of the pressing force in the Z1 direction by the pressing portion 45a.

  The other end 22 c of the reference shaft 22 is sandwiched between the elastic portion 38 of the second leaf spring 36 and the pressing portion 47 a of the second pressing piece 47 formed on the bracket 40. The end 22c of the reference shaft 22 is urged in the Z2 direction by the elastic force of the elastic part 38 of the second leaf spring 36, and the end 22c of the reference shaft 22 by the elastic force of the same elastic part 38. The pressing portion 47a of the bracket 40 is urged in the Z2 direction via. Further, the end 22a of the reference shaft 22 is pressed against the restricting portion 10n by the horizontal component force of the pressing force in the Z1 direction by the pressing portion 47a.

  Further, one end surface 22 b of the reference shaft 22 is regulated by hitting an end surface regulating portion 33 b formed on the elastic portion 33 of the first leaf spring 31, and the other end surface 22 d of the reference shaft 22 is regulated on the α 2 side of the bracket 40. It is restricted by hitting the screw mounting portion 46. Therefore, the reference shaft 22 is held so as not to move in the axial direction.

  In the state where the bracket 40 is attached to the drive chassis 10, the end portion on the α1 side and the end portion on the α2 side of the bracket 40 are the elastic portion 33 of the first leaf spring 31 and the elastic portion 38 of the second leaf spring 36. The urging force is urged in the Z2 direction together with the reference shaft 22 at a position slightly away from the lower surface 10c of the drive chassis 10. Further, the intermediate elastic portion 34 of the first leaf spring 31 is biased so that the fulcrum protrusion 41a is pressed against the intermediate support portion 10q at a position where the connecting plate portion 41 of the bracket 40 is separated from the lower surface 10c.

  Therefore, when the adjustment screw 55 is tightened, the inclination of the bracket 40 and the reference shaft 22 can be adjusted so that the α1 side end of the bracket 40 and the α1 side end 22a of the reference shaft 22 approach the lower surface 10c. On the other hand, when the adjustment screw 56 is tightened, the inclination of the bracket 40 and the reference shaft 22 can be adjusted so that the end of the bracket 40 on the α2 side and the end of the reference shaft 22 on the α2 side approach the surface 10c. It is.

  In this embodiment, the first leaf spring 31, the second leaf spring 36, the adjustment screw 55, and the adjustment screw 56 constitute an inclination adjustment mechanism.

  As shown in FIG. 2, a holding plate spring 60 is provided on the lower surface 10 c of the drive chassis 10 on the side opposite to the bracket 40 with the opening 10 e interposed therebetween. The holding leaf spring 60 is made of the same kind of metal leaf spring material as the first leaf spring 31 and the second leaf spring 36.

  The holding plate spring 60 has a support plate portion 61 extending in the α1-α2 direction. A pair of fixed protrusions 10r and 10r are formed to protrude in the Z2 direction on the lower surface 10c of the drive chassis 10, and a pair of mounting holes formed in the support plate portion 61 are press-fitted into or attached to the fixed protrusions 10r and 10r. The holding plate spring 60 is fixed so that the support plate portion 61 does not move on the lower surface 10c of the drive chassis 10 by fixing the holes by caulking or by attaching the support plate portion 61 to the lower surface 10c.

  The holding plate spring 60 has the end portion on the α1 side of the support plate portion 61 bent in the Z2 direction, and further bent in a U shape as shown in FIG. Similarly, the end portion on the α2 side of the support plate portion 61 is also bent in the Z2 direction, and the holding portion 63 is formed by being bent in a U-shape similarly to the holding portion 62. One end 23a of the sliding shaft 23 is elastically held in the holding portion 62 without rattling in the Z1-Z2 direction, and the other end 23b of the sliding shaft 23 is held in the holding portion 63. It is held elastically without rattling.

  As shown in FIG. 4, the holding unit 62 and the holding unit 63 are located slightly away from the lower surface of the drive chassis 10 in the Z2 direction. As shown in FIG. 2, the adjusting screw 65 is inserted into the holding portion 62 on the α1 side, the adjusting screw 65 is screwed to the drive chassis 10, and the adjusting screw 66 is inserted into the holding portion 63 on the α2 side. A screw 66 is screwed to the drive chassis 10.

  When the adjusting screw 65 is tightened, the sliding shaft 23 is tilted so that the end portion 23a on the α1 side faces the Z1 side, and when the adjusting screw 66 is tightened, the end portion 23b on the α2 side faces the Z1 side. Lean on.

  The holding leaf spring 60, the adjusting screw 65, and the adjusting screw 66 constitute a sliding side tilt adjusting mechanism.

  As shown in FIG. 2, a transfer leaf spring 71 is fixed to the Z2 side surface of the head base 21. An engagement portion such as a female screw or a protrusion is provided at the tip of the transfer plate spring 71, and this engagement portion is slidably fitted in the thread groove 53 of the screw shaft 52.

  Further, a limit switch 74 is fixed to the connecting plate portion 41 of the bracket 40 on the α2 side. A detection piece 73 is bent integrally with the transfer plate spring 71. When the head 20 reaches the moving end on the α2 side, which is the inner peripheral side of the disk D, by the rotational force of the screw shaft 52, the detection piece 73 causes a limit. The actuator of the switch 74 is pushed, and the detection output of the limit switch 74 is switched.

Next, the disk device adjustment operation will be described.
As shown in FIG. 2, after each component is incorporated into the lower surface 10 c of the drive chassis 10, the adjustment operation of the mounting angle of the head 20 is performed.

  This adjustment operation is performed by adjusting the inclination of the reference shaft 22 that is a guide reference of the head 20 and further adjusting the inclination of the sliding shaft 23 in accordance with the inclination of the reference shaft 22.

  The inclination angle of the bracket 40 can be changed by changing the screwing amounts of the adjustment screw 55 and the adjustment screw 56 constituting the inclination adjustment mechanism on the bracket 40 side. At this time, since the position of the contact portion between the fulcrum protrusion 41a of the bracket 41 and the intermediate support portion 10q does not always change, even if the adjustment screw 55 and the adjustment screw 56 are rotated, the entire bracket 40 remains on the lower surface of the drive chassis 10. It is not far away from 10c, or conversely, it does not approach the lower surface 10c more than necessary. Further, since the adjustment screw 55 is provided on the α1 side and the adjustment screw 56 is provided on the α2 side across the contact point between the fulcrum protrusion 41a and the intermediate support portion 10q, the screwing amounts of the adjustment screw 55 and the adjustment screw 56 are changed. The bracket 40 tilts with the contact point as a fulcrum, and the tilt adjustment of the bracket 40 and the screw shaft 52 supported by the bracket 40 is easy.

  When the inclination of the bracket 40 is adjusted, the reference shaft 22 is pushed by the pressing portions 45a and 47a provided on the bracket 40, and the angle of the reference shaft 22 is also changed. Since the relative position of the reference shaft 22 and the bracket 40 is determined by the contact portion between the reference shaft 22 and the pressing portions 45a and 47a, when the bracket 40 is inclined, the inclination of the reference shaft 22 is changed together. It is done.

  As described above, the adjustment of tilting the bracket 40 with the contact portion between the fulcrum protrusion 41a and the intermediate support portion 10q as a fulcrum enables the inclination of the reference shaft 22 to be similarly changed with high accuracy. The tilt adjustment of the reference shaft 22 can be easily performed by the same adjustment work as well as the tilt adjustment of the 40 and the screw shaft 52 is facilitated.

  In addition, the reference shaft 22 moves in the Z1-Z2 direction in a state where the reference shaft 22 is in contact with the restricting portion 10k and the restricting portion 10n extending vertically from the lower surface 10c of the drive chassis 10 in the Z2 direction. Therefore, when adjusting the adjusting screws 55 and 56, the reference shaft 22 does not move in a direction parallel to the lower surface 10c of the drive chassis 10, and only the tilt angle in the Z1-Z2 direction is adjusted. Therefore, by rotating the adjusting screws 55 and 56, the inclination of the optical axis of the objective lens provided in the head 20 in the radial direction can be adjusted with high accuracy, and the optical axis and the rotary shaft 15 of the spindle motor 14 can be adjusted. Adjustment can be made so that the axis O is parallel.

  The bracket 40 and the reference shaft 22 can be tilted together, but the bracket 40 and the reference shaft 22 are members independent of each other, and are pressed against each other by the elastic force of the elastic portions 33 and 38 to determine the relative positions. It has been. Therefore, an excessive bending stress is not applied to the screw shaft 52 and the reference shaft 22 supported by the bracket 40 when adjusting the inclination.

  After adjusting the inclination of the reference shaft 22 as described above, the amount of tightening of the adjusting screws 65 and 66 attached to the holding portions 62 and 63 of the holding leaf spring 60 is adjusted to adjust the inclination of the sliding shaft 23. To do. With this adjustment operation, the parallelism between the sliding shaft 23 and the reference shaft 22 can be determined with reference to the reference shaft 22.

  In the disk device 1, the disk D inserted and inserted from the insertion port 4 is clamped by being sandwiched between the turntable 16 and the clamper 17, and the disk D is rotationally driven by the rotational force of the spindle motor 14. Then, when the screw shaft 52 is rotationally driven by the transfer motor 51 held by the bracket 40, the engaging portion 72 of the transfer plate spring 71 slides on the screw groove 53 of the screw shaft 52, and the head 20 is α1. -It is moved in the α2 direction.

  Since the inclination of the bracket 40 and the reference shaft 22 is adjusted together without changing the relative position, the parallelism between the screw shaft 52 and the reference shaft 22 does not greatly change after the adjustment. Therefore, during the movement of the head 20 in the α1-α2 direction, the variation in the elastic force of the transfer plate spring 71 to the screw shaft 52 is small, and the variation in the sliding frictional resistance between the engaging portion 72 and the screw groove 53 is small. Thus, the moving load is less likely to fluctuate.

  When the head 20 moves in the α2 direction by the moving force of the transfer motor 51 and reaches the moving end on the inner peripheral side of the disk D, the limit switch 74 is switched by the detection piece 73 provided on the transfer plate spring 71. Control such as stopping the transfer motor 51 is performed. As described above, the relative position between the bracket 40 and the reference shaft 22 is not changed by the adjustment operation, and the limit switch 74 is mounted on the bracket 40. Therefore, the transfer leaf spring 71 that moves with reference to the reference shaft 22 is used. And the relative position of the limit switch 74 can always be constant. Therefore, the detection accuracy of the movement end of the head 20 by the limit switch 74 can always be maintained high.

The side view which shows the principal part of the disc apparatus of embodiment of this invention, A perspective view showing the drive chassis mounted on the disk device with the bottom surface facing upward, An exploded perspective view of a mechanism attached to the lower surface of the drive chassis, Sectional drawing which cut | disconnected the drive chassis shown in FIG. 2 by the IV-IV line,

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Disk apparatus 2 Housing | casing 4 Insertion slot 5 Conveyance roller 10 Drive chassis 10q Intermediate support part 10k, 10n Restriction part 12 Clamp base 13 Rotation drive part 14 Spindle motor 16 Turntable 17 Clamper 20 Head 21 Head base 21c, 21d Reference slide Hole 21f Sliding recess 22 Reference shaft (first guide member)
23 Sliding shaft (second guide member)
31 First leaf spring 33 Elastic portion 34 Intermediate elastic portion 36 Second leaf spring 38 Elastic portion 40 Bracket 41a Support point projections 44 and 46 Screw mounting portions 45a and 47a Pressing portion 51 Transfer motor 52 Screw shafts 55 and 56 Adjustment screw 71 Transfer leaf spring 72 Engaging portion 73 Detection piece 74 Limit switch D Disc

Claims (7)

A chassis, a rotational drive unit that drives a disk, a head that performs at least one of a recording operation and a reproducing operation, a first guide member and a second guide member that guide the head, and the first guide member; In a disk device in which a screw shaft provided side by side and driven to rotate by a transfer motor is mounted, and the head moves opposite to the surface of the disk by the rotational force of the screw shaft,
A bracket is provided for rotatably supporting the screw shaft, the bracket including a connecting plate portion extending in parallel with the screw shaft, a pair of pressing portions located on both sides of the connecting plate portion, and the connecting plate portion. And a fulcrum protrusion that protrudes away from the chassis is formed, and the chassis is provided with a mounting surface and an intermediate support portion facing the mounting surface with a space therebetween,
The connecting plate portion is disposed between the attachment surface and the intermediate support portion, and the intermediate elastic member biases the connecting plate portion away from the attachment surface, so that the support protrusion is the intermediate support portion. Pressed against
With both ends of the first guide member is pressed toward the mounting surface by each of the pressing portion, an elastic member for urging the end portions of the first guide member in a direction away from said mounting surface Is provided ,
The inclination angle of the bracket, the tilt adjusting mechanism for adjusting the contact portion between the support projections and the intermediate support as a fulcrum is provided, along with the inclination angle of the screw shaft is adjustable together with the bracket, the mounting A disk device characterized in that an inclination angle of the first guide member with respect to a surface can be adjusted simultaneously. The pressing portion provided on the bracket, the formed inclined with respect to the mounting surface, the mounting surface is provided with a restricting portion extending vertically, said first guide member from the pressing portion the component force of the pressing force acting on the end of the first guide member, a disk apparatus according to claim 1, characterized in that pressed against the restricting portion with pushed toward the mounting surface. The elastic member that urges the end portion of the first guide member is provided with a slope urging portion that is inclined with respect to the mounting surface, and the slope of the first guide member is provided by the slope urging portion. 3. The disk device according to claim 2, wherein the end portion is urged away from the mounting surface, and the end portion of the first guide member is pressed against the restricting portion by a component force of the urging force. 4. The elastic member is provided with an end surface restricting portion integral with the inclined biasing portion, and movement of the first guide member in the axial direction is restricted by the end surface restricting portion. Disk unit. 5. The disk device according to claim 1, wherein the intermediate elastic member and the elastic member that urges the end portion of the first guide member are formed on a common leaf spring. 6. The tilt adjustment mechanism has a pair of adjustment screws inserted into the bracket and screwed into the chassis at two positions spaced apart in the axial direction of the screw shaft, and the screwing amount of the adjustment screw changing the disk device according to any one of claims 1 to 5 tilt angle of the bracket is changed.   7. The disk device according to claim 1, wherein the bracket is provided with a detection switch for detecting a moving position of the head.

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