KR100490386B1 - Magnetic head feeder of hard disk drive - Google Patents

Abstract

The magnetic head conveying apparatus of the disclosed hard disk drive is a locking means for locking the rotor so that it does not flow when the magnetic head is located in the parking area of the hard disk, and includes a first hook portion provided on one side of the rotor and the first hook portion. And a link member provided with a second hook portion to selectively prevent the rotation of the rotor by being elastically coupled with the other, and deformed to push the link member when heated by a predetermined heat source, so that the second hook portion is deviated from the engagement position with the first hook portion. And a bimetal member for moving the link member, and an elastic member for providing an elastic force to the link member so that the second hook portion is moved in the direction in which the second hook portion is coupled with the first hook portion. The magnetic head conveying apparatus having such a configuration locks or unlocks the rotor by using a bimetal member that is reversibly deformed, thereby preventing the magnetic head from moving abnormally regardless of the magnitude of the external impact.

Description

Magnetic Head Feeder of Hard Disk Drive

The present invention relates to a magnetic head conveying apparatus of a hard disk drive, and more particularly, to a magnetic head conveying apparatus of a hard disk drive having an improved structure for locking the magnetic head in a parking area.

In general, as shown in FIG. 1, a hard disk 20 rotatably installed in the base 10 and recording predetermined information, and a magnetic head 50 for recording and reading information. A magnetic head conveying apparatus for conveying to a desired track position on the hard disk 20 is provided. Here, the hard disk 20 includes a recording area 22 in which information is recorded, and a parking area 21 provided therein so that the magnetic head 50 rests when the rotation of the hard disk 20 is stopped. Separated by. In addition, the magnetic head conveying apparatus, the magnetic head 50 is mounted, the rotor 30 is installed to be rotatable around the pivot shaft member 34 provided on the base 10, and the rotor 30 And a locking means for locking the rotor 30 after the magnetic head 50 is seated in the parking area 21. First, the rotor 30 includes a suspension arm 31 supporting the magnetic head 50 and a swing arm 32 rotatably installed through a pivot bearing 34a with respect to the pivot shaft member 34. The bobbin part 33 is wound around the coil 35 for generating electromagnetic force. The stator 40 includes a magnet 41 for generating a magnetic force line and a yoke 42 for forming a magnetic path. have. Therefore, the electromagnetic force is generated by the interaction between the magnetic force line generated by the magnet 41 and the yoke 42 and the current flowing through the coil 35, so that the rotor 30 in the direction according to Fleming's left hand law. ) Will be rotated. Next, the locking means locks the rotor 30 so as not to flow after the magnetic head 50 is seated in the parking area 21 as described above, and the magnet member 43 installed in the stator 40. ), A damper 60 coupled to the protrusion 36 provided at the end of the bobbin portion 33 of the rotor 30, and a magnetic plate 61 bonded to one end of the damper 60. . Therefore, when the rotor 30 is rotated so that the magnetic head 50 mounted on the suspension part 31 enters the parking area 21 of the hard disk 20, as shown in the drawing, the bobbin part ( The magnetic plate 61 coupled to the side 33 is attached to the magnet member 43. Therefore, until the electromagnetic force for rotating the rotor 30 again acts, the rotor 30 remains locked by the magnetic coupling of the magnetic plate 61 and the magnet member 43. The reason for locking the rotor 30 in this way is as follows. First, the suspension part 31 supporting the magnetic head 50 provides an elastic force in a direction in which the magnetic head 50 is in close contact with the horizontal plane of the hard disk 20. Therefore, unless the external force is applied, the magnetic head 50 is kept in close contact with the horizontal surface of the hard disk 20. However, when the hard disk 20 starts to rotate, wind is generated around the magnetic head 50 by the rotation, and the wind lifts the magnetic head 50 from the horizontal surface of the hard disk 20. Generates. Therefore, since the hard disk 20 is rotated when the information is written to or read from the recording area 22 of the hard disk 20, the magnetic head 50 is predetermined in the horizontal plane of the hard disk 20. It becomes a non-contact state spaced apart. Therefore, no scratches or the like due to friction with the magnetic head 50 occur in the recording area. However, when the rotation of the hard disk 20 is completely stopped, such as when the power is turned off, the lift force for lifting the magnetic head 50 also disappears. 21) Rotate the rotor 30 so as to be positioned above. Accordingly, even if lift is lost as the rotation of the hard disk 20 is stopped, the magnetic head 50 is seated in the parking area 21 irrelevant to information recording and reproducing, so that the recording area 22 is not adversely affected. However, if the magnetic head 50 is seated in the parking area 21 and an impact is applied from the outside to push the magnetic head 50 back to the recording area 22, then the hard disk 20 is driven again. In this case, contact with the recording area 22 continues to occur until the magnetic head 50 is floated again, thereby causing a defect such as a scratch in the recording area 22. Therefore, in order to prevent such a defect, the locking means is adopted so that the rotor 30 does not rotate even when an external impact is applied.

However, in the conventional locking means, the magnetic plate 61 and the magnet member 43 lock the rotor 30 in dependence on the force of magnetic coupling, so that the force of greater than the magnetic force in the locked state. When the impact is applied, there is a problem that the locking is released. In addition, in order to rotate the locked rotor 30 again, as described above, the electromagnetic force generated by the coil 35 and the magnet 41 is a magnetic force between the magnetic plate 61 and the magnet member 43. Since the rotor 30 starts to move by surpassing the coupling force, the magnetic plate 61 and the magnet member 43 cannot be made large in a magnetically coupled force. That is, when the magnetic plate 61 and the magnet member 43 make the force that is magnetically coupled too small, the locking is easily released even by a small impact from the outside. When the magnetic plate 61 is made too large, the magnetic force is generated by generating an electromagnetic force. There is a possibility that the locking will not be released well even if it tries to rotate.

The present invention has been made in view of the above-mentioned problems, and hardening of the magnetic head does not release the magnetic head regardless of the magnitude of the shock transmitted from the outside after parking, and the structure is improved so that the locking can be easily released at the moment of unlocking. The object is to provide a magnetic head feeder for a disk drive.

The present invention for achieving the above object is a rotatable installation in the base and a magnetic head for recording / reproducing information on the hard disk on one side and a parking area in which the magnetic head is formed on the hard disk; And a stator for rotating the rotor so as to move across the recording area, and locking means for locking the rotor so that it does not flow when the magnetic head is positioned in the parking area of the hard disk. In the apparatus, the locking means comprises: a first hook portion provided on one side of the pivot; A link member having a second hook portion provided at one side thereof to selectively prevent the rotation of the rotor by being elastically coupled with the first hook portion; It is installed to be adjacent to the other side of the link member, and deformed to push the other side of the link member when heated by a predetermined heat source, so that the second hook portion to move the link member in a direction deviating from the engagement position with the first hook portion A bimetal member for moving; And an elastic member providing an elastic force to the link member so that the second hook portion is moved in a direction coupled with the first hook portion.

In addition, the magnetic head conveying apparatus of the hard disk drive according to another aspect of the present invention, the rotatable rotatable on the base and equipped with a magnetic head for recording / playing information on the hard disk on one side, the magnetic head is A stator for rotating the rotor so as to move across the parking area and the recording area formed on the hard disk, and locking means for locking the rotor so as not to flow when the magnetic head is located in the parking area of the hard disk. A magnetic head conveying apparatus of a hard disk drive, the locking means comprising: a protrusion provided at one side of the pivot; A first lever member rotatably installed on the base and interfering with one surface of the protrusion when the magnetic head is positioned in the parking area to prevent rotation of the rotor; A bimetal member installed adjacent to the first lever member and deformed to press one side of the first lever member when heated by a predetermined heat source to rotate the first lever member in a direction deviating from an interference position with the protrusion; ; A locking pin provided in the base; The locking jaw is coupled to the first lever member to be in contact with the other surface of the protrusion and is provided at one side to be coupled with the locking pin. When the first lever member is rotated in a direction out of an interference position with the protrusion, the The locking jaw is coupled to the locking pin to stop the first lever member, and when the rotor is rotated so that the magnetic head is located in the parking area, the locking lever is pushed into contact with the other surface of the protrusion to stop the first lever member. A second lever member to release the engaging pin and the engaging jaw; And an elastic member for elastically biasing the first lever member in a direction that interferes with one surface of the protrusion.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 to 4 show a magnetic head conveying apparatus of a hard disk drive according to the first embodiment of the present invention.

First, as shown in FIG. 2, the magnetic head conveying apparatus according to the present invention includes a rotatable member 300 rotatably installed on the base 100 on which the hard disk 200 is installed and the magnetic head 500 mounted on one side thereof. And a stator 400 for rotating the rotor 300 such that the magnetic head 500 moves over the parking area 210 and the recording area 220 formed in the hard disk 200. Here, the rotor 300 is a swing arm rotatably coupled to the suspension part 310 for supporting the magnetic head 500 and a pivot bearing 341 with respect to the rotation shaft 340 provided in the base 100. And a bobbin part 330 in which a coil 350 for generating electromagnetic force is wound, the stator 400 includes a magnet 410 for generating a magnetic force line, and a yoke 420 for forming a magnetic path. It is composed of

In addition, the locking means for locking the rotor 300 when the magnetic head 500 is located in the parking area 210 of the hard disk 200, the first hook provided at the end of the rotor 300 The link member 600 provided with a part 360, a second hook portion 601 that is selectively elastically coupled to the first hook portion 360, and the second hook portion 601 is the first hook portion An elastic member for providing an elastic force to the link member 600 so as to rotate in a direction coupled with the 360, for example, a tension spring 630, and the second hook portion 601 may be connected to the first hook portion 360. A bimetal member 620 is provided to rotate the link member 600 in a direction away from the engaged position. The bimetal member 620 is accommodated in a predetermined case 700, and the link member 600 is hinged to one side of the case 700.

In addition, the bimetal member 620 is heated by the heating plate 610 that generates heat in accordance with the supply of current, by the heating is deformed as shown in dashed lines in Figure 3 to push one end of the link member 600. do. To this end, the bimetal member 620 uses a thermal expansion coefficient higher than that of the metal 621 disposed on the link member 600 side 622 disposed below. This is to allow the central portion of the bimetal member 620 to protrude convexly and deform as the temperature increases. Reference numeral 800 in the drawing represents a lead wire for supplying current to the heat generating plate 610, and reference numeral 900 represents a stopper for restricting the rotation range of the rotor 300.

In the above configuration, when the power is turned on, current is supplied to the heating plate 610 through the lead wire 800. Therefore, resistance heat by the current is generated, and as the heat is transferred, the bimetal member 620 starts to thermally expand. In this case, since the metal having a relatively high thermal expansion coefficient is positioned on the link member 600 side, the bimetal member 620 is deformed as the center portion is convexly protruded as shown in FIG. 4. Accordingly, the protruding center portion of the bimetal member 620 pushes one end of the link member 600 to rotate in the clockwise direction of the drawing, whereby the second hook portion 601 is the first hook portion 360. Escape from the location where it interferes with. Therefore, from this time, the rotation of the rotor 300 becomes possible, and the magnetic head 500 installed in the rotor 300 can be smoothly moved to any position on the hard disk 200. After the rotor 300 is rotated such that the magnetic head 500 exits the recording area 220 of the hard disk 200 as shown in FIG. 4, the current supplied to the heating plate 610 is cut off. Then, the bimetal member 620 is returned to its original shape, and the link member 600 is restored to its original position by the tension spring 630, that is, the position which can interfere with the first hook portion 360.

On the contrary, when the rotation of the hard disk 200 is stopped, such as when the power is turned off, an electromagnetic force is generated by the interaction between the current flowing through the coil 350 and the magnetic force line generated in the magnet 410, The rotor 300 is rotated so that the magnetic head 500 enters the parking area 210. Accordingly, as described above, the first hook part 360 is elastically coupled to the second hook part 601 which is restored to its original position by the tension spring 630 and is in the air, and thus, the rotor 300 is turned back. Lock it so it doesn't go. That is, it returns to the state of FIG. Thereafter, as the power is turned off, the rotation of the hard disk 200 stops, and the lift force for lifting the magnetic head 500 disappears, so that the magnetic head 500 is seated in the parking area 210.

As described above, since the magnetic head feeder according to the present embodiment locks the rotation of the rotor 300 by using the first and second hook portions 360 and 601, the locking is not released even under a strong impact, and the locking release system The bimetal member 620 is deformed to simplify the interference between the first and second hook portions 360 and 601.

Meanwhile, in the first embodiment, one end of the link member 600 is directly contacted with the center portion of the bimetal member 620 so as to be pushed according to the deformation of the bimetal member 620, as shown in FIG. 5. Likewise, between the bimetal member 620 and the link member 600 ', the rod member 701 is interposed between the bimetal member 620 and the link member 600' via a rod member 701 that is elastically restorable by the compression spring 703. It may be configured to push the link member 600 '. At this time, it is preferable to install a rubber 702 to prevent the impact and wear at the end of the rod member 701.

6 to 8 show a magnetic head feed apparatus according to the second embodiment of the present invention. In the drawings, the same reference numerals as those of the first embodiment described above denote the same members.

Referring to the drawings, in this embodiment, the locking means for locking the rotor 300 is configured as follows. That is, the magnetic head 500 is installed in the parking area 210 by being rotatably installed around the protrusion 370 provided on one side of the rotor 300 and the rotation shaft 641 provided on the base 100. When positioned, the first lever member 640 which prevents rotation of the rotor 300 by interfering with one surface 371 of the protrusion 370, and is heated by the heating plate 720 that generates heat in response to the supply of current. The bimetal member 730 is deformed to press one side of the first lever member 640 and the first lever member 640 to be in contact with the other surface 372 of the protrusion 370, and has a base at one side thereof. The second lever member 650 provided with the engaging jaw 651 coupled with the engaging pin 660 provided at 100 and the first lever member 640 interfere with the one surface 371 of the protrusion 370. A tension spring 670 is provided as an elastic member that elastically biases in the direction. Here, the second lever member 650 rotates together with the first lever member 640 while the first lever member 640 is rotated in a direction out of an interference position with the protrusion 370. 651 is coupled to the engaging pin 660 to stop the rotation of the first lever member 640, when the rotor 300 is rotated so that the magnetic head 500 is located in the parking area 210, The locking pin 660 and the locking jaw 651 which stop the rotation of the first lever member 640 by being pushed in contact with the other surface 372 of the protrusion 370 are configured to be released. Reference numeral 910 in the drawing represents a stopper for regulating the rotation range of the rotor 300, reference numeral 710 denotes a case in which the heating plate 720 and the bimetal member 730 is accommodated, reference numeral 810 denotes the heating plate ( The lead wires for supplying current to the 720 are shown, respectively.

In the above configuration, when the power is turned on, current is supplied to the heating plate 720 through the lead wire 810. Therefore, resistance heat by the current is generated, and as the heat is transferred, the bimetal member 730 is thermally expanded, and as shown in FIG. 7, the center part is convexly protruded. Accordingly, the protruding center portion of the bimetal member 710 pushes one side of the first lever member 640 to rotate the first lever member 640 in the clockwise direction of the drawing. As a result, the first lever member 640 comes out of a position that interferes with one surface 371 of the protrusion 370. Therefore, from this time, the rotor 300 may be rotated, and the magnetic head 500 installed in the rotor 300 may be moved to an arbitrary position on the hard disk 200. In this case, the second lever member 650 is rotated clockwise with the rotation of the first lever member 640, so that the locking jaw 651 is caught by the locking pin 660. When the locking jaw 651 is caught by the locking pin 660 in this way, the rotation of the first and second lever members 640 and 650 is stopped in this state unless an external force is applied. In addition, as the locking is released, after the rotor 300 is rotated so that the magnetic head 500 exits the recording area 220 of the hard disk 200, the current supplied to the heating plate 720 is blocked. . The bimetal member 710 then returns to its original shape. However, the first and second lever members 640 and 650 stand by in a stopped state at the position by the engagement of the locking jaw 651 and the locking pin 660.

On the contrary, when the rotation of the hard disk 200 is stopped, such as when the power is turned off, an electromagnetic force is generated by the interaction between the current flowing through the coil 350 and the magnetic force line generated in the magnet 410, The rotor 330 is rotated so that the magnetic head 500 enters the parking area 220. At this time, the other surface 372 of the protrusion 370 is in contact with the second lever member 650 to push the second lever member 650 counterclockwise in the drawing. As a result, the locking jaw 651 held by the locking pin 660 is released, and at the same time, the elastic force of the tension spring 670 acts to rotate the first lever member 640 to its original position. Thus, as shown in FIG. 8, the rotor 300 is locked so that the first lever member 640 returns to a position where the first lever member 640 interferes with the one surface 371 of the protrusion 370 again. Then, as the power is turned off, the rotation of the hard disk 200 stops, and the lift force that lifts the magnetic head 500 disappears, so that the magnetic head 500 is seated in the parking area 210.

Meanwhile, in the second embodiment, as shown in FIG. 9, between the bimetal member 710 and the first lever member 640 ′, a rod member 704 that is elastically recoverable by the compression spring 706. ), An end portion of the rod member 704 may be configured to push the first lever member 640 '. At this time, it is preferable to install a rubber 705 to prevent the impact and wear at the end of the rod member 704. In addition, rubber may be installed on one surface 371 and the other surface 372 of the protrusion 370 in contact with the first and second lever members 640 and 650 to obtain a buffering and abrasion preventing effect.

As described above, the magnetic head conveying apparatus of the hard disk drive according to the present invention locks and unlocks the rotation of the rotor by using a bimetal member which is operated in accordance with on / off of the power supply. It is possible to prevent the magnetic head from moving abnormally.

It is to be understood that the invention is not limited to that described above and illustrated in the drawings, and that more modifications and variations are possible within the scope of the following claims.

1 is a plan view showing a magnetic head transfer device of a conventional hard disk drive,

2 is a plan view showing a magnetic head feed apparatus according to a first embodiment of the present invention,

3 and 4 are views for explaining the main operation of the magnetic head transfer device shown in FIG.

5 is a view showing a modified example of the first embodiment shown in FIG.

6 is a plan view showing a magnetic head feed apparatus according to a second embodiment of the present invention,

7 and 8 are views for explaining the main operation of the magnetic head conveying apparatus shown in FIG.

9 is a view showing a modified example of the second embodiment shown in FIG.

<Description of Symbols for Major Parts of Drawings>

100 ... base 200 ... hard disk

210 ... Parking area 220 ... Recording area

300 ... 310 310 ... Suspension

320 swing arm 330 bobbin

340 rotating shaft 350 coil

360 ... 1st hook part 370 ... protrusion part

400 ... stator 410 ... magnet

420 yoke 500 magnetic head

600 ... Link member 620,710 ... Bimetal member

610,720 heating element 700,720 case

640 ... 1st lever member 650 ... 2nd lever member

800,810 ... lead wire 900,910 ... stopper

Claims (7)

A rotor rotatably mounted on the base and having a magnetic head mounted on one side thereof for recording / reproducing information on the hard disk, and rotating the rotor so that the magnetic head is moved across the parking area and the recording area formed on the hard disk. A magnetic head conveying apparatus for a hard disk drive, comprising: a stator for locking and locking means for locking the rotor so that the magnetic head does not flow when the magnetic head is located in a parking area of the hard disk. The locking means is: A first hook portion provided at one side of the pivot; A link member having a second hook portion provided at one side thereof to selectively prevent the rotation of the rotor by being elastically coupled with the first hook portion; It is installed to be adjacent to the other side of the link member, and deformed to push the other side of the link member when heated by a predetermined heat source, so that the second hook portion to move the link member in a direction deviating from the engagement position with the first hook portion A bimetal member for moving; And an elastic member for providing an elastic force to the link member such that the second hook portion is moved in a direction coupled with the first hook portion. The method of claim 1, Between the bimetal member and the other side of the link member, a rod member for pushing the other side of the link member while being pushed in accordance with the deformation of the bimetal member is interposed therebetween. The method of claim 2, Magnetic head transfer apparatus of the hard disk drive, characterized in that the rubber for the buffer is coupled to the end of the rod member in contact with the other side of the link member. A rotor rotatably mounted on the base and having a magnetic head mounted on one side thereof for recording / reproducing information on the hard disk, and rotating the rotor so that the magnetic head is moved across the parking area and the recording area formed on the hard disk. A magnetic head conveying apparatus for a hard disk drive, comprising: a stator for locking and locking means for locking the rotor so that the magnetic head does not flow when the magnetic head is located in a parking area of the hard disk. The locking means is: A protrusion provided on one side of the pivot; A first lever member rotatably installed on the base and interfering with one surface of the protrusion when the magnetic head is positioned in the parking area to prevent rotation of the rotor; A bimetal member installed adjacent to the first lever member and deformed to press one side of the first lever member when heated by a predetermined heat source to rotate the first lever member in a direction deviating from an interference position with the protrusion; ; A locking pin provided in the base; The locking jaw is coupled to the first lever member to be in contact with the other surface of the protrusion and is provided at one side to be coupled with the locking pin. When the first lever member is rotated in a direction out of an interference position with the protrusion, the The locking jaw is coupled to the locking pin to stop the first lever member, and when the rotor is rotated so that the magnetic head is located in the parking area, the locking lever is pushed into contact with the other surface of the protrusion to stop the first lever member. A second lever member to release the engaging pin and the engaging jaw; And an elastic member for elastically biasing the first lever member in a direction that interferes with one surface of the protrusion part. The method of claim 4, wherein And between the bimetal member and the first lever member, a rod member pushing the first lever member while being pushed according to the deformation of the bimetal member. The method of claim 5, Magnetic head transfer device of the hard disk drive, characterized in that the rubber for the buffer is coupled to the end of the rod member in contact with the first lever member. The method according to any one of claims 4 to 6, Magnetic head conveying apparatus of the hard disk drive, characterized in that the rubber is installed on one surface and the other surface of the protrusion in contact with the first and second lever members.

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