JP4991931B2 - Data eraser - Google Patents

Description

  Embodiments described herein relate generally to a data erasing apparatus, and more particularly, to a data erasing apparatus of a magnetic disk device as a storage device used in a computer.

  2. Description of the Related Art Conventionally, a computer such as a personal computer needs a storage medium for storing programs and data. Recently, a hard disk device using a disk (disk) coated with a magnetic material on the surface is used as the storage medium. It is popular. This hard disk device is built in a computer or connected to the outside of the computer via a cable, and reads and writes data to and from at least one disk built in through a head. Is. The storage capacity of this hard disk device is increasing year by year.

  Computers, on the other hand, are new models year by year as the operating system (OS) that drives them advances, the processing speed of the CPU (central processing unit) increases, the communication functions expand, and the capacity of the hard disk drive increases. Have been put on the market, and older computers tend to be replaced by newer computers in a short period of time.

  By the way, there are various types of hard disk devices written during use of the hard disk device in the hard disk device built in the old computer discarded by the replacement with the new computer and the hard disk device discarded by the replacement with the new computer having a large storage capacity. Large amount of data remains. Among such data, there is something that would be a problem if leaked to a third party such as personal information or internal company information. Therefore, the hard disk device is generally subjected to data erasure processing using computer software before being discarded.

  However, this data erasing process is a process that enables overwriting of the disk in the hard disk device, and the data recorded so far does not completely disappear from the disk. Then, in such a hard disk device in which data has not been completely erased, if a malicious third party uses special software, there is a possibility that the remaining data will be read out.

  As a method of completely erasing data recorded in the hard disk device, there is a method of writing meaningless data on the entire surface of the magnetic disk of the hard disk device or passing a strong magnetic field such as a permanent magnet through the magnetic disk of the hard disk device. Thus, a method for forcibly erasing data is known. For the former method, the existence of a service organization that performs this method and commercially available software that performs this method is known. For the latter method, there is known a data erasing device that erases data by applying a strong magnetic field to the magnetic disk while suppressing the strength of the magnetic field applied to the spindle motor of the hard disk device ( For example, see Patent Document 1). Since the data erasing apparatus described in Patent Document 1 is intended to reproduce a magnetic disk, the magnetic disk apparatus is rotated by a spindle motor and one end of the magnetic disk apparatus is placed in a magnetic field sandwiched between permanent magnets. The data on the magnetic disk is erased by passing it through.

  However, the above-mentioned method of writing meaningless data on the entire surface of the magnetic disk of the hard disk device has a problem that it takes time to write the data because the capacity of the hard disk device is large. However, there was a problem that the disposal cost increased. On the other hand, the data erasing apparatus described in Patent Document 1 that erases data by magnetic saturation through a magnetic field through a magnetic disk requires equipment for rotating a spindle motor, and there is a problem that the apparatus becomes large. There is also a problem that data is not completely erased unless the spindle motor rotates for some reason. As described above, the conventional data erasing apparatus does not consider the erasure of data only for the purpose of preventing the data leakage from the discarded hard disk device without considering the reproduction use of the magnetic disk. .

  Therefore, the present inventors have proposed a second embodiment of Patent Document 2 in order to prevent leakage of horizontal recording data stored in a magnetic disk device such as a hard disk device to be discarded or other magnetic recording media. A simple data erasing device capable of reliably erasing the hard disk device with a simple operation by inserting or removing the hard disk device placed on the tray into or out of the data erasing device as shown in FIG. Proposed.

Japanese Patent Laying-Open No. 2001-331904 (Claims, FIGS. 1 and 4) Japanese Patent Laying-Open No. 2004-110908 (FIGS. 10 and 12)

  However, in the data erasing apparatus proposed by the present inventors in the second embodiment of Patent Document 2, the data recorded on the magnetic recording medium by applying the erasing magnetic field only from one direction to the hard disk device is recorded. Since the data was erased, the magnet used for the magnetic circuit that generates the erasing magnetic field requires a large magnet, which increases the size of the data erasing device, increases the weight, and prevents the magnetic shielding mechanism from leaking outside. There is a problem that the size of the data erasing apparatus is high due to the increase in size.

  The reason for using a large magnet for the data erasing device is that when the erasing magnetic field is applied only from one direction to the hard disk device, the data parallel to the external magnetic field can be easily demagnetized, This is because it is difficult to demagnetize the data in the direction of 90 degrees with respect to the external magnetic field, and it is necessary to generate a magnetic field of about twice the coercive force of the magnetic recording medium for complete erasure of the data.

  Therefore, the present invention enables the erasing magnetic field to be applied to the hard disk device to be applied from multiple directions so as to reduce the size of the magnet used in the magnetic circuit that generates the erasing magnetic field, thereby reducing the size of the data erasing device, An object of the present invention is to provide a data erasing apparatus that can reduce the cost of the data erasing apparatus by reducing the weight and reducing the size of the magnetic shielding mechanism that prevents leakage of magnetism to the outside.

According to the embodiment, the data erasing device is a data erasing device that erases data recorded on the magnetic disk in the magnetic disk device by using a magnetic field generated from a permanent magnet having an N pole and an S pole. In addition, an opening is provided on at least one side surface, and a main body case provided with a passage for reciprocating the magnetic disk device is provided in the inside, and the passage is parallel to the magnetic disk. A magnetic field generator provided along at least one of the two surfaces and arranged adjacent to each other so that the plurality of permanent magnets have a mutually adsorbing polarity, and the magnetic disk device is placed along the path. And a tray provided in the main body case so as to be capable of reciprocating. A rotating plate having an accommodating portion for accommodating the magnetic disk device in the tray; A rotating mechanism is provided to degrees rotation, the rotation mechanism has a biasing mechanism for urging in a direction to rotate the rotary plate, when the rotational force is applied to the rotating plate by the urging mechanism, the A first latch mechanism that latches the rotating plate and stops at the first position, and rotates the rotating plate by the biasing mechanism when the latch of the rotating plate by the first latch mechanism is released. The rotation plate is rotated by a predetermined angle by the rotation mechanism when the tray returns to the opening through the passage with respect to the position of the tray when the tray moves forward in the passage. It will be in the state.

(A) is an exploded perspective view of a magnetic disk device from which data is erased by the data erasing device according to the embodiment, and (b) is a perspective view of the magnetic disk device showing a state in which the magnetic disk device of (a) is assembled. . (A) is a perspective view showing the configuration of the data erasing device previously proposed by the present inventors, and (b) is an explanatory diagram for explaining the principle of erasing data on the magnetic disk device by the data erasing device of (a). is there. (A) is a perspective view showing another configuration of the data erasing apparatus previously proposed by the present inventors, and (b) is an explanation for explaining the principle of erasing data on the magnetic disk device by the data erasing apparatus of (a). FIG. (A) is a plan view for explaining the application direction of an external erasing magnetic field applied to a magnetic recording medium in the data erasing apparatus previously proposed by the present inventors; (b) is a data erasing shown in FIGS. The perspective view which shows the shape of the tray provided with the accommodation groove | channel of the magnetic disc apparatus used for an apparatus, (c) is the area | region which is easy to demagnetize on the magnetic disc from which data is erased by the external erasing magnetic field shown in (a) It is explanatory drawing which shows the area | region where it is hard to degauss. (A) is a top view explaining the application direction of the external erasing magnetic field applied to the magnetic recording medium in the data erasing apparatus according to the embodiment, and (b) is provided with a disk device housing groove of the first shape. FIG. 4C is a plan view showing the shape of the first embodiment of the tray used in the data erasing apparatus, and FIG. 4C is a second view of the tray used in the data erasing apparatus of the present invention having a disk device housing groove of the second shape. The top view which shows the shape of 2 Example, (d) is a top view which shows the shape of 3rd Example of the tray provided with the disk apparatus accommodation groove | channel of 3rd shape, and is used for the data erasing apparatus of embodiment. It is. (A) is a perspective view which shows the whole structure of the data erasing apparatus of this invention provided with the tray of 4th Example, (b) shows the state by which a part of tray was pulled out from the data erasing apparatus of (a). It is a partial expansion perspective view of the data erasing device shown. (A) is a top view which shows the structure of the outer tray which comprises the tray of the 4th Example used for the data erasing apparatus based on embodiment shown in FIG. 6, (b) is an outer tray shown in (a). It is an assembly drawing which shows the structure of the inner tray combined. (A) is a plan view showing the tray of the fourth embodiment in a state where the inner tray is accommodated in the outer tray shown in FIG. 7 (a), and (b) is a state where the inner tray is pulled out from the outer tray of (a). FIG. (A) is a plan view showing the tray of the fourth embodiment in a state where the magnetic disk device is set on the inner tray shown in FIG. 8 (b), and (b) is the fourth embodiment shown in (a). It is a top view which shows the state in which the inner tray was accommodated in the outer tray in the tray of an example. (A) is a diagram showing an initial position in the data erasing apparatus shown in FIG. 6 of the tray of the fourth embodiment shown in FIG. 9 (b), and (b) is the fourth position shown in (a). It is a top view which shows the state which the tray of the Example moved in the data erasing apparatus, and contact | abutted with the push bar provided in the data erasing apparatus. FIG. 10A is a plan view showing a state in which the tray of the fourth embodiment shown in FIG. 10B moves in the data erasing apparatus toward the initial position in the data erasing apparatus, and FIG. FIG. 10 is a plan view showing a state in which the tray of the fourth embodiment shown in FIG. 4 is stopped at the initial position in the data erasing apparatus and the inner tray is pulled out from the outer tray. FIG. 13 is a plan view for explaining a state in which the magnetic disk device is taken out from the inner tray in the state of FIG. 11B and then the rotary table in the inner tray is manually returned to the state of FIG.

  FIG. 1A is an exploded perspective view of a magnetic disk device 1 from which data is erased by the data erasing device according to the embodiment. The magnetic disk device 1 is a hard disk device and is hermetically sealed with a base 2 made of aluminum alloy and a cover 9. A spindle motor 3 is mounted on the base 2 with screws 4, and at least one magnetic disk 5 is fixed to the spindle motor 3 with screws 8 via clamps 7. The magnetic disk 5 is a disk-shaped storage medium for storing data, and the number of magnetic disks 5 fixed to the spindle motor 3 is determined by the specifications of the magnetic disk device 1. Spacers 6 are inserted between the magnetic disks 5 and between the magnetic disk 5 and the clamp 7.

  An actuator 11 is swingably attached to a portion of the base 2 adjacent to the magnetic disk 5. At the tip of the actuator 11, there is a head portion 12 having a head for writing data to the magnetic disk 5 or reading data from the magnetic disk 5. The end of the actuator 11 opposite to the head 12 is driven by a voice coil motor (VCM) 13 that is also fixed on the base 2. When the cover 9 is fixed to the base 2 with the screw 10 after the members described above are attached to the base 2, the state shown in FIG.

  FIG. 2A shows the configuration of the data erasing device 60 previously proposed by the present inventors. FIG. 2B shows the principle of erasing data in the magnetic disk device 1 by the data erasing device 60. FIG. Explain. The data erasing device 60 is configured to have a case 62 containing two permanent magnets 27 and 28 (permanent magnets will be simply referred to as magnets hereinafter) disposed adjacently on the yoke 26, and to be freely inserted into and removed from the case 62. And a drawer-type tray 61. The magnetic disk device 1 which is a magnetic recording medium for erasing data is mounted on the tray 61 and is taken in and out of the case 62.

  The yoke 26 is fixed to the ceiling side of the case 62, and the magnets 27 and 28 are disposed in the front-rear direction with respect to the passage of the tray 61 in the case 62. The widths of the magnets 27 and 28 are formed larger than the width of the magnetic disk device 1. The magnets 27 and 28 are arranged such that the yoke 26 side has an S pole and the outer space side has an N pole magnet 28 on the entrance side of the case 62, and the yoke 26 side has an N pole and the outer space side has an S pole magnet 27. It is arranged on the back side when viewed from the entrance side. Further, the magnetic disk device 1 from which data is to be erased is placed on the tray 61 and taken in and out of the case 62. On the tray 61, a groove (recess) for receiving the magnetic disk device 1 is usually provided.

  Then, a magnetic field indicated by symbol A in FIG. 10B is generated in the case 62 by the magnets 27 and 28 disposed in the case 62. The magnetic field A is composed of a magnetic flux directed from the magnet 28 to the magnet 27, and the magnetic field A at the boundary between the magnets 27 and 28 has a horizontal component. Since the magnets 27 and 28 are disposed on the front side of the case 62, the tray 61 on which the magnetic disk device 1 is mounted is attached to the case 62 at least once with respect to the magnetic field A generated by the magnets 27 and 28. The data recorded on the magnetic disk 5 in the magnetic disk device 1 is erased by this magnetic field A by taking it in and out.

  Thereafter, if the same operation is performed with the magnetic disk device 1 mounted on the tray 61 turned upside down, the data recorded on the magnetic disk 5 in the magnetic disk device 1 is surely erased by the magnetic field A. In FIG. 2A, the passage for inserting and removing the tray 61 with respect to the case 62 and the handle provided on the tray 61 are not shown.

  In the data erasing device 60 shown in FIG. 2, the size of the magnets 27 and 28 is increased, and the maximum magnetic flux area M of the magnets 27 and 28 is approximately the same as the diameter D of the magnetic disk 5 in the magnetic disk device 1. ing. Accordingly, the weight of the data erasing device 60 is increased due to the large magnets 27 and 28, and the device cost is increased.

  FIG. 3A shows a configuration of a data erasing device 60A showing another configuration of the data erasing device previously proposed by the present inventors. FIG. 3B illustrates the principle of erasing data on the magnetic disk device 1 in the data erasing device 60A. In addition to the configuration of the data erasing device 60 described with reference to FIG. 2, the data erasing device 60 </ b> A has two magnets 27 and 28 arranged adjacent to each other on the yoke 26 in another set of cases 62. The point is different. The structure of the drawer-type tray 61 configured to be freely inserted into and removed from the case 62 is the same as that of the tray 61 described in FIG.

  The second magnets 27 </ b> A and 28 </ b> A are configured in plane symmetry with the magnets 27 and 28 attached to the ceiling portion of the case 62 with respect to the passage of the tray 61 in the case 62. The widths of the magnets 27 and 28 and the magnets 27A and 28A are the same and are formed larger than the width of the magnetic disk device 1. The magnets 27 and 28 and the magnets 27A and 28A are arranged on the entrance side of the case 62 with the S poles on the yokes 26 and 26A side and the N poles on the external space side, the N poles on the yokes 26 and 26A side, the outside Magnets 27 and 27A having S poles on the space side are arranged on the back side when viewed from the entrance side of the case 62. Further, the magnetic disk device 1 from which data is to be erased is placed on the tray 61 and taken in and out of the case 62.

  A magnetic field indicated by a symbol B in FIG. 12B is generated in the case 62 by the magnets 27 and 28 and the magnets 27A and 28A arranged in the case 62. The magnetic field B is composed of a magnetic flux from the magnet 28 to the magnet 27 and a magnetic flux from the magnet 28A to the magnet 27A, and the magnetic field B at the boundary portion between the magnets 27 and 28 and the boundary portion between the magnets 27A and 28A is in the horizontal direction. Of ingredients. Since the magnets 27 and 28 and the magnets 27A and 28A are arranged on the front surface side of the case 62, the tray 61 on which the magnetic disk device 1 is mounted is at least attached to the case 62 with respect to the magnetic field B generated by them. The data recorded on the magnetic disk 5 in the magnetic disk device 1 is erased by this magnetic field B by taking it out once.

  In the data erasing device 60A, the magnetic disk device 1 moves through a path between the magnets 27, 28 and the magnets 27A, 28A arranged in plane symmetry, and the magnetic field B exists above and below the magnetic disk device 1, so the tray 61 It is not necessary to perform the same operation by turning the magnetic disk device 1 mounted on the upside down. Also in FIG. 3A, a path for inserting and removing the tray 61 with respect to the case 62, a handle provided on the tray 61, and a groove for accommodating the magnetic disk device 1 provided on the tray are illustrated. Is omitted.

  In the data erasing apparatus 60A shown in FIG. 3A, the sizes of the magnets 27 and 28 and the magnets 27A and 28A are increased. Therefore, the magnetic flux maximum region M of the magnets 27 and 28 and the magnets 27A and 28A is approximately the same as the diameter D of the magnetic disk 5 in the magnetic disk device 1. Therefore, it is desirable to reduce the size of the magnets 27 and 28 and the magnets 27A and 28A also in the data erasing device 60A.

  FIG. 4A illustrates the application direction of the external erasing magnetic field applied to the magnetic recording medium 1 in the data erasing apparatus previously proposed by the present inventors. Reference numeral 5 denotes a magnetic disk, and 11 denotes an actuator. In the data erasing apparatus previously proposed by the present inventors, the direction of the external erasing magnetic field BX for erasing the data on the magnetic disk 5 by demagnetization is parallel to the axis AX of the apparatus with respect to the axis AX of the magnetic disk apparatus 1. It was direction.

  FIG. 4B shows the shape of the tray 61 used in the data erasing devices 60 and 60A shown in FIGS. The tray 61 is provided with a receiving groove 63 for fixing the magnetic disk device 1 on the tray 61. The auxiliary grooves 64 provided above and below the housing groove 63 are for facilitating removal of the magnetic disk device 1 housed in the housing groove 63, and are not particularly required.

  FIG. 4C shows that the magnetic disk 5 from which data is erased by the external erasing magnetic field BX in the direction shown in FIG. 4A has a region E that is easily demagnetized and a region D that is difficult to demagnetize. Is. With respect to the axis AX of the apparatus shown in FIG. 4A, the direction of the external erasing magnetic field BX for erasing the data on the magnetic disk 5 by demagnetization is parallel to the axis AX of the apparatus. The data in the data cylinder 14 in the direction parallel to the direction of the external erasing magnetic field BX (data in the area indicated by E in the figure) is easily demagnetized, but the direction perpendicular to the direction of the external erasing magnetic field BX on the magnetic disk 5 The data in the data cylinder 14 (data in the region indicated by D in the figure) was difficult to be degaussed.

  Therefore, in order to sufficiently erase the data in the region D shown in FIG. 4C, a large magnet is used as the magnet used in the magnetic circuit for generating the erasing magnetic field. As a result, the size of the data erasing device is increased, the weight is increased, and the size of the magnetic shielding mechanism for preventing the leakage of magnetism to the outside is increased, resulting in a problem that the cost of the data erasing device is high.

  FIG. 5A illustrates the application direction of the external erasing magnetic field applied to the magnetic disk 5 of the magnetic disk apparatus 1 in the data erasing apparatus according to the embodiment. Reference numeral 11 denotes an actuator. In the data erasing apparatus of the present invention, in addition to the external erasing magnetic field BX applied in parallel to the axis AX of the magnetic disk device 1, the external erasing magnetic field CX tilted with respect to the axis AX of the magnetic disk device 1 has a magnetic disk device. 1 is applied.

  The inclination direction of the external erasing magnetic field CX further applied to the magnetic disk device 1 is preferably 45 ° clockwise or counterclockwise with respect to the axis AX of the magnetic disk device 1, but may be other angles. Further, the inclination direction of the external erasing magnetic field CX further applied to the magnetic disk device 1 may be perpendicular to the axis AX of the magnetic disk device 1. In the embodiment described below, the inclination direction of the external erasing magnetic field CX further applied to the magnetic disk device 1 is inclined by 45 ° with respect to the axis AX of the magnetic disk device 1.

  That is, the data erasing apparatus according to the embodiment is obtained by changing the tray 61 in the data erasing apparatuses 60 and 60A described with reference to FIGS. Here, an example of a tray according to an embodiment instead of the tray 61 will be described below.

  FIG. 5B shows the shape of the tray 21 of the first example used in the data erasing apparatus according to the embodiment. In the tray 21 of the first embodiment, in addition to the disk device housing groove 63 and the auxiliary groove 64 described in FIG. 4B, a disk device inclined by 45 ° with respect to the center line of the disk device housing groove 63 A receiving groove 31 is provided. The disk device housing groove 31 is the position of the magnetic disk 5 in the magnetic disk device 1 when the magnetic disk device 1 is housed in the groove 31 when the magnetic disk device 1 is housed in the disk device housing groove 63. The magnetic disk device 1 is provided so as to have the same position as the magnetic disk 5. In this way, the width of the degaussing circuit built in the data erasing device can be reduced.

  When erasing data of the magnetic disk device 1 using the tray 21 of the first embodiment, the magnetic disk device 1 is accommodated in the disk device accommodation groove 63 of the tray 21, and the tray 21 will be described with reference to FIG. The first degaussing operation to be taken in and out of the data erasing device 60A is executed. Next, the magnetic disk device 1 is re-accommodated in the disk device accommodation groove 31 of the tray 21, and a second demagnetization operation is performed for taking the tray 21 into and out of the data erasing device 60A described with reference to FIG.

  In the embodiment, the demagnetization work in the direction parallel to the center line of the magnetic disk device 1 and the demagnetization work in the inclined direction are performed in this way, so that the magnet used for the data erasing device 60A shown in FIG. The size can be reduced, the weight of the data erasing device 60A can be reduced, and the device cost can be reduced.

  FIG. 5C shows the shape of the tray 22 of the second example used in the data erasing apparatus according to the embodiment. The tray 22 of the second embodiment is provided with a disk device housing groove 32 and a disk device housing groove 63A that are inclined by 45 ° to the left and right with respect to the center line of the tray 22. The disk device housing groove 32 and the disk device housing groove 63A are provided so that the positions of the magnetic disks 5 in the magnetic disk device 1 overlap when the magnetic disk device 1 is housed in these grooves 32 and 63A.

  When erasing data of the magnetic disk device 1 using the tray 22 of the second embodiment, the magnetic disk device 1 is accommodated in the disk device accommodation groove 32 of the tray 22 and the tray 22 will be described with reference to FIG. The first degaussing operation to be taken in and out of the data erasing device 60A is executed. Next, the magnetic disk device 1 is re-accommodated in the disk device-accommodating groove 63A of the tray 22, and the second degaussing operation is performed for taking the tray 22 into and out of the data erasing device 60A described in FIG.

  When the tray 22 of the second embodiment is used, the demagnetization work is performed in two directions inclined at 45 ° to the left and right with respect to the center line of the magnetic disk device 1, and the data shown in FIG. The magnet used for the erasing device 60A can be reduced in size, the weight of the data erasing device 60A can be reduced, and the device cost can be reduced.

  FIG. 5C shows the shape of the tray 23 of the third example used in the data erasing apparatus according to the embodiment. In the tray 23 of the third embodiment, in addition to the disk device housing groove 63 and the auxiliary groove 64 described in FIG. 4B, a disk device inclined by 90 ° with respect to the center line of the disk device housing groove 63 An accommodation groove 33 and an auxiliary groove 35 are provided. The disk device housing groove 33 is the position of the magnetic disk 5 in the magnetic disk device 1 when the magnetic disk device 1 is housed in the groove 33, when the magnetic disk device 1 is housed in the disk device housing groove 63. It is provided so as to overlap the position of the magnetic disk 5 in the magnetic disk device 1.

  When erasing data of the magnetic disk device 1 using the tray 23 of the third embodiment, the magnetic disk device 1 is accommodated in the disk device accommodation groove 63 of the tray 23, and this tray 23 will be described with reference to FIG. The first degaussing operation to be taken in and out of the data erasing device 60A is executed. Next, the magnetic disk device 1 is re-accommodated in the disk device accommodation groove 33 of the tray 23, and a second demagnetization operation is performed for taking the tray 23 into and out of the data erasing device 60A described with reference to FIG.

  Also in the demagnetization work using the tray 23 of the third embodiment, the demagnetization work in the direction parallel to the center line of the magnetic disk device 1 and the demagnetization work in the inclined direction are performed. The magnet used for the data erasing device 60A can be reduced in size, the weight of the data erasing device 60A can be reduced, and the device cost can be reduced.

  In the first to third embodiments described above, only the tray 61 of the data erasing devices 60 and 60A described in FIGS. 2 and 3 is replaced with any one of the trays 21 to 23 of the present invention. In the fourth embodiment to be described next, the entire data erasing apparatus is changed.

  FIG. 6A shows an overall configuration of the data erasing apparatus 30 according to the embodiment including the tray of the fourth example. In the fourth embodiment, a tray to be described later is built in the apparatus, and the tray 61 cannot be taken out like the data erasing apparatuses 60 and 60A described with reference to FIGS. A door 36 is provided on the front side of the data erasing device 30. The door 36 is opened, and a magnetic disk device for demagnetizing by pulling out a built-in tray is set. After the magnetic disk device is set on the tray, when the start switch 37 is pressed, the tray automatically reciprocates within the data erasing device 30.

  In addition, a degaussing circuit 20 similar to the data erasing device 60A described with reference to FIG. The degaussing circuit 20 includes an upper demagnetizing circuit 20A composed of a yoke 26 and magnets 27 and 28, and a lower demagnetizing circuit 20B composed of a yoke 26A and magnets 27A and 28A.

  FIG. 6B shows a state where the door 36 of the data erasing apparatus 30 shown in FIG. 6A is opened and a part of the tray 24 of the fourth embodiment is pulled out. The tray 24 of this embodiment is composed of an inner tray 40 and an outer tray 50. When the door 36 is opened, the outer tray 50 remains in the data erasing device 30, and the inner tray 40 is pulled out from the outer tray 50. Yes.

  FIG. 7A shows the configuration of the outer tray 50 that constitutes the tray used in the data erasing apparatus 30 of the fourth example according to the embodiment shown in FIG. 6, and FIG. The structure of the inner tray 40 combined with the outer tray 50 shown to 7 (a) is shown. The inner tray 40 is incorporated in the outer tray 50 and is configured to be pulled out from the outer tray 50.

  The outer tray 50 includes a base 51 having opposing side walls 51 </ b> A and a rear wall 51 </ b> B, and a cover 52 that covers the upper surface of the base 51. A region 56 on the base 51 surrounded by the side wall 51 </ b> A and the rear wall 51 </ b> B on both sides of the outer tray 50 is an inner tray storage portion 56 that stores the inner tray 40. An inner tray 40 is attached to the inner side of the side wall 51A, and a slide mechanism 54 for moving the inner tray 40 is provided. Further, a through hole 55 for inserting a push rod described later is provided at a predetermined position of the rear wall 51B.

  There is an opening in the front part of the outer tray 50, and a rotating gate 53 for preventing the accommodated inner tray 40 from jumping out of the outer tray 50 is attached to this portion. The inner tray 40 can move with respect to the outer tray 50 with the rotating gate 53 open.

  The inner tray 40 includes a base 43 and a cover 49 attached on the base 43. Both side surfaces of the base 43 of the inner tray 40 are attached to the slide mechanism 54 of the outer tray 50. A disc-shaped rotating plate 44 that is rotatably attached to the base 43 is provided at the center of the inner tray 40. A disk device housing groove 46 for housing the magnetic disk device 1 is provided on the rotating plate 44. The auxiliary grooves that are normally provided in the disk device housing grooves 46 are not shown.

  A rectangular latch groove 44C is provided on the outer peripheral portion of the rotating plate 44, and a lever 48 for projecting the rotating plate 44 from the outside is provided at a position substantially diagonal to the latch groove 44C. Yes. Further, in this embodiment, a tension spring 47 is stretched between the vicinity of the base of the lever 48 and a predetermined position of the base 43 around the rotating plate 44 (one side surface side of the base 43). 47, the rotating plate 44 is given a rotational force that rotates counterclockwise.

  On the other hand, when the inner tray 40 is accommodated in the outer tray 50, a through hole 45 communicating with the through hole 55 is provided at a position facing the through hole 55 of the outer tray 50, and the through hole 45 and the rotating plate 44 are provided. A first latch lever 41 is provided in a region of the base 43 between the periphery of the first latch lever 41. The first latch lever 41 includes first and second arms 41A1 and 41A2 that are pivotally supported by the rotation shaft 41A. The free end of the second arm 41 </ b> A <b> 2 is located in the through hole 45. In addition, a tension spring 41B is provided between the second arm 41A2 and the base 43, and the tip of the first arm 41A1 is pressed against the circumferential portion of the rotating plate 44 by the spring 41B. It has become.

  Therefore, when the rotating plate 44 is rotated clockwise by an external force applied to the lever 48, the first arm is moved when the latch groove 44A provided in the rotating plate 44 comes to the position of the first latch lever 41. The tip of 41A1 enters the latch groove 44A. When the external force applied to the lever 44 is eliminated in this state, the rotating plate 44 tries to rotate counterclockwise by the spring 47, but this rotation is stopped by the first arm 41A1 that has entered the latch groove 44A. This state is the state shown in FIG. In this state, the disk device housing groove 46 provided in the rotating plate 44 is inclined in a direction in which the center line rotates 45 ° clockwise with respect to the center line of the inner tray 40.

  Further, a second latch lever 42 is provided immediately on the side opposite to the side portion of the base 43 on which the first latch lever 41 is provided. The second latch lever 42 includes first and second arms 42A1 and 42A2 that are pivotally supported by the rotating shaft 42A. A tension spring 42B is provided between the second arm 42A2 and the base 43, and the tip of the first arm 42A1 is pressed against the circumferential portion of the rotating plate 44 by the spring 42B. Yes. In addition, a release lever 42 </ b> C that can move the first arm 42 </ b> A <b> 1 away from the circumferential portion of the rotating plate 44 is connected to the first arm 42 </ b> A <b> 1.

  The cover 49 is attached to a position indicated by a two-dot chain line on the base 43. In a state where the cover 49 is attached to the base 43, the tip of the lever 48 protruding from the rotating plate 44 is exposed from the edge of the cover 49. Further, the cover 49 is provided with a circular hole 49 </ b> A that overlaps the rotating plate 44 when attached to the base 43, and a release hole 49 </ b> B that overlaps the release lever 42.

  FIG. 8A shows the tray 24 of the fourth embodiment in a state in which the inner tray 40 shown in FIG. 7B is accommodated in the outer tray 50 shown in FIG. 7A. In a state where the inner tray 40 is accommodated in the outer tray 50, the rotation gate 53 provided on the outer tray 50 is positioned on the base 51, so that the inner tray 40 does not jump out of the outer tray 50. Note that the illustration of the cover 49 of the inner tray 40 and the cover 52 of the outer tray 50 is omitted so that the internal structure of the tray 24 becomes clear. The tray 24 is built in the data erasing apparatus 30 shown in FIG.

  FIG. 8B shows a state where the rotation gate 53 of the tray 24 shown in FIG. 8A is opened and the inner tray 40 is pulled out from the outer tray 50. The inner tray 40 can be pulled out of the outer tray 50 automatically or manually. This state corresponds to the state shown in FIG.

  FIG. 9A shows the tray 24 in a state where the magnetic disk device 1 is set in the disk receiving groove 46 of the inner tray 40 shown in FIG. 8B. The inner tray 40 in which the magnetic disk device 1 is set is returned to the outer tray 50 automatically or manually. FIG. 9B shows a state in which the tray 24 in which the magnetic disk device 1 is set is accommodated in the outer tray 50.

  FIG. 10A shows an initial position in the data erasing apparatus 30 shown in FIG. 6 of the tray 24 of the fourth embodiment shown in FIG. 9B. The tray 24 containing the magnetic disk device 1 moves in the direction of the arrow M in the data erasing device 30 from this initial position. As described with reference to FIG. 6A, the degaussing circuit 20 is provided in the data erasing device 30. The magnetic disk device 1 passes through the degaussing circuit 20 while the tray 24 is moving in the data erasing device 30, and the data recorded on the magnetic disk 5 is erased by the degaussing circuit 20.

  On the inner wall on the back side of the data erasing device 30, a push rod 38 protrudes at a position facing the through hole 55 of the tray 24. When the tray 24 moves through the data erasing device 30 and reaches the final position (passage end), the push rod 38 enters the through hole 55 of the tray 24 as shown in FIG. Reaching the hole 45, the second arm 41A2 of the first latch lever 41 located in the through hole 45 is pushed. When the second arm 41A2 is pushed, the first latch lever 41 rotates against the urging force of the spring 41B.

  When the first latch lever 41 rotates, the engagement between the first arm 41A1 and the latch groove 44A of the rotating plate 44 is released, and the rotating plate 44 rotates counterclockwise by the pulling force of the spring 47, and FIG. The state shown in (b) is obtained. In this state, the spring 47 is not contracted any further and the rotation of the rotating plate 44 is stopped, and the first arm 42A1 of the second latch lever 42 enters the latch groove 44A of the rotating plate 44. As a result, the rotation plate 44 is stopped from rotating clockwise and counterclockwise at this position. In this state, the magnetic disk device 1 housed in the disk device housing groove 46 provided on the rotating plate 44 is inclined in a direction in which the center line rotates 45 ° counterclockwise with respect to the center line of the inner tray 40. It becomes a state.

  When the first arm 41A1 and the latch groove 44A of the rotating plate 44 are disengaged and the rotating plate 44 rotates counterclockwise by the pulling force of the spring 47, a stopper is provided on the base 43 side. A protrusion may be provided on the side, and the stopper may lock the protrusion so that the state shown in FIG.

  After the tray 24 is in the state shown in FIG. 10B, the tray 24 moves in the direction of the arrow N in the data erasing device 30 as shown in FIG. 11A and returns to the initial position. When the tray 24 returns to the initial position, the tray 24 passes through the degaussing circuit 20 and the data recorded on the magnetic disk 5 is erased by the degaussing circuit 20. In this case, since the orientation of the magnetic disk device 1 accommodated in the tray 24 is different by 90 ° compared to when the tray 24 advances toward the back of the data erasing device 30, the tray 24 is at the back of the data erasing device 30. The portion of the data that was difficult to be erased when proceeding toward is erased.

  After the tray 24 returns to the initial position in the data erasing device 30, when the door 36 shown in FIG. 6 is automatically or manually opened, the inner tray 40 slides from the outer tray 50 as shown in FIG. Withdrawn by mechanism 54. In this state, the magnetic disk device 1 from which data has been erased can be taken out from the disk device housing groove 46 of the inner tray 40.

  Then, as shown in FIG. 12, after the magnetic disk device 1 from which the data has been erased is taken out from the disk device housing groove 46 of the inner tray 40, the release is visible in the release hole 49B provided in the inner tray 49 by the operator. The lever 42C is pushed in the direction indicated by the arrow P. Then, the engagement between the first arm 42A1 of the second latch lever 42 and the latch groove 44A of the rotating plate 44 is released. In this state, when the lever 48 is moved in the direction of arrow R by the operator, the rotating plate 44 rotates against the pulling force of the tension spring 47. In FIG. 12, a cover 49 of the inner tray 40 and a cover 52 of the outer tray 50 are shown.

  The latch groove 44A is moved by the rotation of the rotating plate 44, and the first arm 41A1 of the first latch lever 41 eventually enters the latch groove 44A. When the operator releases his hand from the lever 48 with the first arm 41A1 entering the latch groove 44A, the rotating plate 44 tries to rotate counterclockwise by the pulling force of the spring 47. This rotation is latched. It is stopped by the first arm 41A1 of the first latch lever 41 that has entered the groove 44A. This state is the same as the state shown in FIG. Therefore, the operator can perform the next data erasing operation of the magnetic disk device 1 from the state shown in FIG.

  In the data erasing apparatus 30 of the fourth embodiment described above, the inner tray 40 constituting the tray 24 is related to the disk receiving grooves 32 and 63A in the tray 22 of the second embodiment described in FIG. Are automatically switched by the rotating plate 44, and the tray 24 is automatically reciprocated in the data erasing device 30. Therefore, in the embodiment, the inner tray 40 constituting the tray 24 is automatically switched by the rotating plate 44 between the disk receiving grooves 31 and 63 in the tray 21 of the first embodiment described in FIG. Naturally, an embodiment in which the relationship between the disk receiving grooves 33 and 63 in the tray 23 of the third embodiment described with reference to FIG.

  Further, when the tray 24 is automatically reciprocated in the data erasing device 30, there is an angle difference of 90 ° between the angle of the magnetic disk device 1 in the forward path and the angle of the magnetic disk device 1 in the backward path. The angle of the disk device housing groove at the initial position with respect to the center line of the inner tray is not particularly defined.

  In the above embodiment, an example of the magnetic disk device (hard disk device) 1 has been described as a magnetic recording medium from which data is erased by the data erasing devices 30, 50, 50A. However, the data erasing device 30 according to the embodiment is described. , 50, 50A, the magnetic recording medium from which data is erased is not particularly limited.

  The present invention has been described in detail with particular reference to preferred embodiments thereof. For easy understanding of the present invention, specific embodiments of the present invention will be described below.

(Supplementary note 1) A data erasing device for erasing data recorded on a magnetic recording medium using a magnetic field generated from a permanent magnet having N and S poles,
A body case provided with an opening on at least one side surface, and provided with a passage for reciprocating the magnetic recording medium inside the opening;
A magnetic field generating source provided along at least one of the surfaces of the passage parallel to the magnetic recording medium and arranged adjacent to each other so that the plurality of permanent magnets have a mutually adsorbing polarity;
A tray having a size capable of accommodating the magnetic recording medium and reciprocating in the main body case along the path;
The data erasing apparatus according to claim 1, wherein the tray is provided with first and second receiving grooves for receiving the magnetic recording medium so as to intersect at a predetermined angle. (1)
(Supplementary note 2) The data erasing device according to supplementary note 1, wherein
The magnetic recording medium is a magnetic disk device;
The first and second accommodation grooves provided in the tray are arranged so that the magnetic disk portions overlap each other even when the magnetic disk device is accommodated in any of the accommodation grooves. A data erasing device.
(Supplementary note 3) The data erasing device according to supplementary note 1, wherein
The center line of the first receiving groove is parallel to the center line of the tray, and the center line of the second receiving groove is inclined by 45 ° with respect to the center line of the tray. A data erasing device. (2)
(Supplementary note 4) The data erasing device according to supplementary note 1, wherein
The center line of the first receiving groove is parallel to the center line of the tray, and the center line of the second receiving groove is inclined by 90 ° with respect to the center line of the tray. A data erasing device.
(Supplementary note 5) The data erasing device according to supplementary note 1, wherein
One center line of the first receiving groove is inclined by 45 ° with respect to the center line of the tray, and the center line of the second receiving groove is set with respect to the center line of the first receiving groove. A data erasing apparatus characterized by being inclined by 90 °.
(Supplementary Note 6) A data erasing apparatus for erasing data recorded on a magnetic recording medium using a magnetic field generated from a permanent magnet having N and S poles,
A body case provided with an opening on at least one side surface, and provided with a passage for reciprocating the magnetic recording medium inside the opening;
A magnetic field generating source provided along at least one of the surfaces of the passage parallel to the magnetic recording medium and arranged adjacent to each other so that the plurality of permanent magnets have a mutually adsorbing polarity;
A tray having a size capable of accommodating the magnetic recording medium and reciprocating in the main body case along the path;
The tray is provided with a rotating plate provided with an accommodating groove for accommodating the magnetic recording medium, and is provided with a rotating mechanism of the rotating plate,
The rotation plate is rotated by a predetermined angle by the rotation mechanism when the tray returns to the opening through the passage with respect to the position of the tray when the tray moves forward in the passage. A data erasing device characterized by being in a state. (3)
(Supplementary note 7) The data erasing apparatus according to supplementary note 6, wherein
The tray is composed of an inner tray having a rotating plate provided with the housing groove, and an outer tray for housing the inner tray,
The outer tray reciprocates in the passage;
A data erasing apparatus configured such that when the outer tray is at an initial position in the passage, the inner tray is pulled out from the outer tray and the rotating plate is positioned outside the data erasing apparatus. . (4)
(Supplementary note 8) The data erasing device according to supplementary note 7, wherein the inner tray includes:
An urging mechanism for rotating the rotating plate counterclockwise;
A first latch mechanism that latches rotation of the rotating plate and stops it in a first position when a counterclockwise rotational force is applied to the rotating plate by the biasing mechanism;
A second latch mechanism that latches the rotating plate at a second position when the rotating plate is unclockwise rotated by the first latching mechanism unlatched;
A release mechanism for releasing the latched state of the second latch mechanism; and
A data erasing apparatus, comprising: a lever capable of manually rotating the rotating plate to return to the first position when the release mechanism is in a latch release state. (5)
(Supplementary note 9) The data erasing apparatus according to supplementary note 8, wherein
A release protrusion for releasing the latch of the rotating plate by the first latch mechanism is provided at the end portion of the passage,
The data is characterized in that when the outer tray reaches the end portion of the passage, the protrusion comes into contact with the first latch mechanism, whereby the latch of the rotating plate by the first latch mechanism is released. Eraser.
(Supplementary note 10) The data erasing device according to supplementary note 6, wherein
A data erasing apparatus, wherein a rotation angle of the rotating plate by the rotating mechanism is 90 °.
(Supplementary note 11) The data erasing device according to supplementary note 6, wherein
A data erasing apparatus, wherein a rotation angle of the rotating plate by the rotating mechanism is 45 °.

DESCRIPTION OF SYMBOLS 1 ... Magnetic disk apparatus (hard disk apparatus), 5 ... Magnetic disk, 20 ... Demagnetizing circuit,
21 to 24, trays of embodiments, 30, 60, 60A, data erasing device,
31-33, 46, 63 ... disk device accommodation groove, 38 ... push rod,
40 ... Inner tray, 41 ... First latch lever, 42 ... Second latch lever,
44 ... Rotating plate, 45, 55 ... Through hole, 47 ... Tension spring, 50 ... Outer tray

Claims (8)

A data erasing device for erasing data recorded on a magnetic disk in a magnetic disk device using a magnetic field generated from a permanent magnet having N and S poles,
A main body case provided with an opening on at least one side surface, and provided therein with a passage for reciprocating the magnetic disk device, which is continuous with the opening;
A magnetic field generating source provided along at least one of the paths parallel to the magnetic disk, and arranged adjacent to each other so that the plurality of permanent magnets have a polarity that attracts each other;
A tray on which the magnetic disk device is mounted, and a tray that is reciprocally movable in the main body case along the passage.
The tray is provided with a rotating plate having an accommodating portion for accommodating the magnetic disk device, and a rotating mechanism for rotating the rotating plate by a predetermined angle,
The rotating mechanism includes a biasing mechanism that biases the rotating plate in a rotating direction, and latches the rotating plate when the rotating force is applied to the rotating plate by the biasing mechanism, and the first position A first latch mechanism that stops at a time when the latch of the rotary plate by the first latch mechanism is released, the rotary plate is rotated by the biasing mechanism,
The rotating plate is rotated by a predetermined angle by the rotating mechanism when the tray returns through the passage toward the opening with respect to a position relative to the tray when the tray moves forward through the passage. A data erasing device that becomes inactive. A release protrusion for releasing the latch of the rotating plate by the first latch mechanism is provided at the end portion of the passage,
When the tray reaches the end portion of the passageway, by the projection comes into contact with the first latching mechanism of claim 1, latching of the rotary plate by said first latch mechanism is released Data eraser. The rotating mechanism includes a second latch mechanism that latches the rotating plate at a second position when the rotating plate is unlatched by the first latching mechanism and the rotating plate rotates.
The data erasing apparatus according to claim 1, further comprising: a release mechanism that releases the latch state of the second latch mechanism. The rotation mechanism includes a lever that is coupled to the rotation plate and is configured to manually rotate the rotation plate to return to the first position when the release mechanism is in the second latch release state. Item 4. The data erasing device according to Item 3. The tray includes an outer tray that is reciprocally movable in the passage, and an inner tray that is provided with the rotating plate and the rotating mechanism and is supported on the outer tray so as to be reciprocally movable.
2. The structure according to claim 1, wherein when the outer tray is at an initial position in the passage, the inner tray is pulled out from the outer tray and the rotating plate is positioned outside the main body case. The data erasing device described. Data erasing device according to any one of 5 to the rotation angle of the rotating plate claims 1 a 90 ° by the rotating mechanism.   6. The data erasing apparatus according to claim 1, wherein a rotation angle of the rotating plate by the rotating mechanism is 45 degrees. A data erasing device for erasing data recorded on a magnetic disk in a magnetic disk device,
  A main body case provided with a passage for reciprocating the magnetic disk device;
  A plurality of permanent magnets, each having a north pole and a south pole, are provided at positions facing the magnetic disk of the magnetic disk device passing through the passage in parallel in the main body case, and have a polarity that attracts each other. A magnetic field generation source arranged adjacent to and applying a magnetic field to the magnetic disk;
  A tray on which the magnetic disk device is mounted, and a tray that is reciprocally movable in the main body case along the passage.
  The tray is provided with a rotating plate having an accommodating portion for accommodating the magnetic disk device, and a rotating mechanism for rotating the rotating plate by a predetermined angle,
  The rotating mechanism includes a biasing mechanism that biases the rotating plate in a rotating direction, and latches the rotating plate when the rotating force is applied to the rotating plate by the biasing mechanism, and the first position A first latch mechanism that stops at a time when the latch of the rotary plate by the first latch mechanism is released, the rotary plate is rotated by the biasing mechanism,
  The rotating plate is rotated by a predetermined angle by the rotating mechanism when the tray returns through the passage toward the opening with respect to a position relative to the tray when the tray moves forward through the passage. A data erasing device that becomes inactive

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