KR890007483Y1 - Magnetic disk devices - Google Patents

Abstract

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Description

Magnetic disk device

1 is a front view showing a cutout of a portion showing a magnetic disk device according to an embodiment of the present invention;

2 is a sectional view of a portion near the head of the apparatus of FIG.

A perspective view showing the first magnetic head of FIG. 3 and the supporting plate thereof.

4 is an exploded perspective view of the apparatus of FIG.

FIG. 5 is a perspective view showing the second magnetic head and its supporting plate of FIG.

6 is an exploded perspective view of the apparatus of FIG.

* Description of parts of the main parts of the drawings

3: disk 8,16: magnetic head

9,17 head support plate 25,26,33,34 winding

The present invention relates to a magnetic disk device for recording or playing back information using a floppy disk or similar magnetic disk.

The elastic sheet supporting a pair of magnetic heads of the conventional double-sided floppy disk device was formed of an elastic copper alloy having a low electrical resistivity in order to obtain an electromagnetic shielding effect.

However, since the copper alloy has a low elastic modulus, if the resistance of sliding between the head and the disk increases, the head will resonate, causing problems in that recording or reproduction cannot be performed accurately.

It is therefore an object of the present invention to provide a magnetic disk device in which resonance of the head does not occur.

In order to achieve the above object, in the present invention, the first head support plate is composed of gimbals using materials capable of obtaining an electron shielding effect.

In addition, the second head support plate was formed of a material having a higher modulus of elasticity than the first head support plate, and also constituted by gimbals.

In the above-described configuration, the first head support plate having the electron shielding effect is formed of a material having a lower elastic modulus than the second head support plate and is easy to resonate.

On the other hand, since the second head support plate has a gimbal configuration, it is easy to resonate structurally, but since the elastic modulus is higher than that of the first head support plate, the resonant frequency is increased, and the occurrence of resonance that is not suitable for recording or reproducing is prevented.

Next, with reference to FIGS. 1 to 6, a magnetic disk device related to an embodiment of the present invention will be described.

As in FIG. 1, a magnetic disk device is a magnetic disk cartridge 1, generally referred to as a floppy disk, for recording or reproducing information, and a flexible magnetic disk housed in the case 2 of the cartridge 1 It has the rotating mechanism 4 for rotating (3).

The rotating mechanism 4 is composed of a disk rotating motor 5, a rotating table 6 coupled thereto, and a clamper 7 for fixing the disk 3 to the rotating table 6.

The disc cartridge 1 has a surface direction that is the same as or substantially parallel to the rotational surface of the disc 3, in other words orthogonal to the axial direction of the swivel 6, with the clamper 7 open from the swivel 6. Fitted in the direction.

The first magnetic head 8 at the bottom of the disk 3 is attached to the elastic first head support plate 9, and the peripheral edge of the first head support plate 9 is a synthetic resin carriage. It is fixed to (10).

This carriage 10 is rigid and not easily deformed since it is the foundation for supporting the first magnetic head 8.

The carriage 10 is guided to the guide rod 11 and can move freely in the radial direction of the disc 3, and for the stepping motor 12 and the lead screw, ie screws, shown in principle in FIG. It is driven by the radial movement mechanism 14 which consists of (13).

A magnetic shield plate 15 formed of a permalloy is fixed to a portion of the carriage 10 that faces the first magnetic head 8.

The second magnetic head 16 on the upper side of the magnetic disk 3 is attached to the elastic second head support plate 17, and the edge around the second head support plate 17 has an upper carriage. It is stuck to the rocking arm 18 made of synthetic resin moving to (10).

Since this swing arm 18 is a foundation part for supporting the second magnetic head 16, it is relatively rigid and does not deform easily.

This swing arm 18 has a hinge function and is attached to the carriage 10 by a plate spring 19 which biases it counterclockwise as in FIG.

The swinging arm 18 thus moves in the radial direction of the disc simultaneously with the carriage 10.

Reference numeral 20 denotes a return spring, that is, a torsion spring, which biases the swing arm 18 in the counterclockwise direction as shown in FIG.

Reference numeral 21 denotes a magnetic shield composed of permroy, and is attached to the swinging arm 18 so as to face the second magnetic head 16.

The swinging arm 18 is forcibly rotated clockwise by the elasticity of the springs 19 and 20 when the cartridge 1 is not attached, and is maintained at the position of the dotted line in FIG.

As is apparent from FIGS. 3 and 4 showing the second and first magnetic heads 8 and their supporting plates 9, showing a cut away portion of FIG. 1, the first magnetic head 8 is recorded. And a reproducing magnetic core 23, an erasing magnetic core 24, a recording and reproducing winding 25, a holding winding 26, and ceramic sliders 27a and 27b, Both the recording and reproducing windings 25 and the erasing windings 26 are arranged on the surface facing the disk 3 of the head support plate 9.

The sliders 27a and 27b are nonmagnetic ceramics, and have a function of protecting the magnetic core 23 for recording and reproducing and the magnetic core 24 for erasing, while being able to slide well against the disk 3. .

The recording and reproducing windings 25 and the erasing windings 26 are arranged on the surface side of the head support plate 9 against the disk 3 so that the head support plate 9 can be made clear as shown in FIG. The windings 25 and 26 do not protrude on the back side, and the protruding amounts of the magnetic cores 23 and 24 are extremely small.

Conventionally, since the windings 25 and 26 are arranged on the back side of the head support plate 9 of FIG. 2, the protrusion amount of the magnetic cores 23 and 24 toward the back side is large. little.

The assembly of the first magnetic head 8 and the first head support plate 9 shown in FIG. 3 can be obtained by the following process.

First, an assembly of a structure in which the sliders 27a and 27b are fixed to both the recording, reproducing and erasing magnetic cores 23 and 24 shown in FIG. 4 is prepared.

The surface 50a of this assembly 50 is provided with a magnetic gap for recording or reproducing and a gap for turner erasing.

Then, a winding 25 for recording or reproducing the first head support plate 9 shown in FIG. 4 and an erasing winding 26 are provided.

Furthermore, since the displacement in the vertical direction with respect to the disk 3 surface of the first magnetic head 8 is obtained in the first head support plate 9, the center portion 51 and the carriage (with which the magnetic head 8 is attached) A slit 53 is provided between the edge 52 and the periphery fixed with respect to 10), and the center part 51 is supported by the periphery edge 52 by four slender connection parts.

Next, to the erasing magnetic core 24 of the assembly 50 of FIG. 4, the erasing winding 26, which is wound in advance in a cylindrical shape, is attached as shown in FIG.

Next, the edge of the erasing magnetic core 24 and the lead wire of the erasing winding 26 are inserted into the holes 9b of the first head support plate 9, and the center portion 30 of the immediately lower portion of the slider 27a The lower surface and the lower surface of the side 28 of the slider 27b abut on the first head support plate 9, and the sliders 27a and 27b are bonded to the first head support plate 9 (not shown). )).

At this time, the end portion of the recording or reproducing magnetic core 23 projects through the hole 9a of the first head support plate 9 toward its rear surface.

Next, the recording and reproducing winding 25 wound in a cylindrical shape in advance is engaged with the magnetic core 23 through the life 9a of the first head support plate 9.

At this time, even if the end of the winding 25 protrudes toward the rear surface of the first head support plate 9 through the hole 9a, there is no problem even if it does not protrude.

However, it is led out from the lead wire hole 9a of the winding 25 toward the back surface of the head support plate 9.

Next, the recording and reproducing windings 25 and the erasing windings 26 are fixed with an adhesive (not shown) to the assembly 50 between the sliders 27a and 27b and the magnetic cores 23 and 24. Let's do it.

Next, the magnetic core of the back bar, that is, the seam portion, is fixed to the end of the magnetic core 23 for recording and reproducing on the back side of the first head support plate 9 with an adhesive (not shown).

Next, a separate external lead wire (not shown) is connected to the lead wires of the windings 25 and 26 on the rear surface side of the first head support plate 9, and then to the lead wire portions of the windings 25 and 26. A protective resin (not shown) is applied, and the lead wire portion is fixed to the first head support plate 9, and the ends of the windings 25 and 26 are also fixed to the first head support plate 9.

The first head support plate 9 is formed of a beryllium copper spring plate having a resistivity of 5 × 10 ⁻⁸ Pa.m or less and a thickness of 80 μm in order to obtain an electron shielding effect.

Therefore, the elastic modulus of the first head support plate 9 is about 12 x 13 x 10 ¹⁰ N / m 2 and is relatively small.

If the elastic modulus of the first head support plate 9 is made small and made of gimbal springs, the first magnetic head 8 slides between the sliding surface and the disk 3. When the resistance becomes large, the first magnetic head 8 easily resonates.

Therefore, in this embodiment, as shown in FIG. 3 and FIG. 4, the first head support plate 9 is made into a non-gimbal structure to prevent resonance.

That is, the first head support plate 9 is slightly elastically displaced in the vertical direction (Z-axis direction) with respect to the surface of the disk 3, but is perpendicular to the X-axis direction (disc radial direction) and the Y-axis direction ( The track tangential direction) is configured so as not to be substantially displaced, and resonance is prevented.

Furthermore, since the recording and reproducing windings 25 of the first magnetic head 8 are arranged toward the disk of the first head support plate 9 having an electromagnetic shielding effect, the lower side of the first head support plate 9 is provided. Electromagnetic waves coming in from are blocked from the first head support plate 9 and prevented from flowing into the winding 25.

At this time, since the first head support plate 9 is a beryl copper with a low resistivity, an eddy current easily flows, and a good electron shielding effect can be obtained.

As evident in FIGS. 2, 5 and 6, the second magnetic head 16 includes a recording or reproducing magnetic core 31 and an erasing magnetic core 32 for recording or reproducing. The winding 33, the erasing winding 34, and the ceramic zeder slider 35 are formed, and the windings 33 and 34 are disposed on the rear surface opposite to the surface of the head support plate 17 facing the disk. It is.

Therefore, the amount of protrusion of the magnetic cores 31 and 32 with respect to the upper side (back side) of the head support plate 17 is very small.

As a result, the thickness of the swinging arm 18 becomes smaller than before.

The back surface of which the windings 25, 26, 33, 34 of the first and second magnetic heads 8, 16 are opposed to the disks of the respective head support plates 9, 17, respectively. By placing them toward the side, the height from the bottom of the carriage 10 to the highest point of the swinging arm 18 indicated by the dotted line in FIG. 1 becomes about 48 mm.

In contrast, in the conventional configuration in which the windings 25, 26, 33, and 34 are disposed opposite to the disk side of the head support plates 9 and 17, the height at the same position as above is about 58 mm.

Thus it is achieved in a significantly thin form.

The second head support plate 17 shown in Figs. 5 and 6 is provided with holes 17a and 17b for fitting the windings 33 and 34 through.

For this reason, the second magnetic head 16 is also assembled in the same manner as the first magnetic head 8, and the lead bars of the back bars 31a and the windings 33 and 34 are on the upper side of the head support plate 17. Is placed on.

For this reason, the second magnetic head 16 is also assembled in the same manner as the first magnetic head 8, and the lead bars of the back bars 31a and the windings 33 and 34 are on the upper side of the head support plate 17. Is placed on.

The second head support plate 17 has a central portion 61 to which the second magnetic head 16 is attached and a first annular portion 62 surrounding it, as is apparent from FIGS. 5 and 6. And a second annular portion 63 surrounding the portion.

Thus, the central portion 61 and the first annular portion 62 are connected by a pair of thin connecting portions 64 and 65 positioned on one straight line, and the first annular portion 62 and the first annular portion 62 The annular part 63 of 2 is connected by a pair of thin connection parts 66 and 67 located on the other straight line orthogonal to a straight line.

Therefore, this 2nd support plate 17 is comprised with the gimbal spring.

The second head support plate 17 is attached to the swinging arm 18 by the second annular portion 63.

Accordingly, the second head support plate 16 is displaced in the X axis direction and the Y axis direction about the second pivot 36.

Thus, when the second head support plate 17 is constituted by gimbals, there is a fear that the head 16 will resonate when the head 16 slides on the disc 3.

Thus, if the second head support plate 17 is formed of a material having a relatively small elastic modulus such as beryllium copper, resonance is more likely to occur.

Therefore, in the present embodiment, the second head support plate 17 is made of a steel sheet having a modulus of elasticity about 1.6 times larger than the copper copper constituting the first head support plate 9.

Moreover, the thickness of the second head support plate 17 is about 50 mu m.

In this way, when the second head support plate 17 is formed of a material having a large elastic modulus, even if the head support plate has a gimbal spring structure that can be rotated in both the X-axis direction (disc radial direction) and the Y-axis direction (track tangential direction) It is difficult to produce resonance that is inconvenient to reproduce.

In other words, since steel having a high modulus of elasticity is used for the head support plate 17, the resonance frequency moves to a higher side, and resonances that are harmful to recording and reproducing are not generated.

However, the resistivity of the steel constituting the second head support plate 17 is about 20 x 10 ^-8 Pa.m, which is larger than the resistivity of beryllium copper.

Therefore, a large electron shielding effect cannot be expected for the second head support plate 17 of this embodiment.

Therefore, in the present embodiment, the shielding ring 22 for arranging the effect of the electron shielding is disposed so as to surround the upper portion of the second magnetic head 16.

The shielding ring 22 is made of, for example, copper alloy or aluminum alloy having a resistivity of 3 × 10 ⁻⁸ Pa.m or less, and is fixed to the swinging arm 18.

In the disk apparatus constructed as described above, the disk 3 is attached on the swivel table 6, and the solid line is drawn from the dotted line position in FIG. 1 with the swing spring 18 hinged around. When rotated to the position of, the disk 3 is fitted to the pair of heads 8 and 16 that are substantially opposed to each other so that recording and reproducing are possible.

At this time, the first head support plate 9 so that the upper second magnetic head 16 collides toward the lower first magnetic head 8, but the lower first magnetic head 8 can be displaced in the Z-direction. The shock is absorbed because it is supported by.

When the disk 3 is rotated to record and reproduce, and slides on the disk 3 with the heads 8 and 16, the first head support plate 9 is formed of non-gimbal even if the material has a low elastic modulus. On the other hand, since the first head support plate 9 is made of a material having a large elastic modulus even in the gimbal configuration, resonance of both the heads 8 and 16 hardly occurs.

Although the embodiment of the present invention has been described above, the present invention is not limited thereto, and the following modifications are possible.

(a) It is also applicable to 3.5-inch floppy disk devices and other disk devices in which a magnet is placed on the swivel 6 without using the clamper 7, thereby attracting a metal hub in the center of the disk and rotating the disk. .

(b) Although the mechanism 14 for moving the head in the radial direction of the disk is shown in principle based on the screw rod 13, the present invention is not limited thereto, but may be a rolled steel belt system or the like.

(c) The sludge 27 may be made of synthetic resin having high lubricity.

As is apparent from the above, the first head support plate prevents resonance while securing the electron shielding effect, and the second head support plate prevents the generation of resonance despite being gimbal support.

Therefore, resonance can be generated while obtaining the electron shielding effect to some extent, thereby making it possible to obtain good reproduction or reproduction.

Claims (3)

A first mechanism that elastically supports the rotating mechanism 4 of the magnetic disk, the first magnetic head 8 that contacts and contacts the one surface of the disk, and records and reproduces the signal. The head support plate 9, the carriage 10 to which the first head support plate is attached so as to support the first magnetic head via the first head support plate 9, and the first magnetic head. A second magnetic head 16 which contacts the other side of the disk to record and reproduce signals, a second head support plate 17 which elastically supports the second magnetic head 16, and a second A swing arm 18 attached freely to the carriage to support the head support plate of the head and to selectively contact the second magnetic head to the disk, and to contact the disk with the second magnetic head to the swing arm. The knitting means for imparting knitting force in the direction, the carriage and the swinging arm In a magnetic disk device having a mechanism for moving in the radial direction, the first head support plate is composed of non-gimbal using a material capable of obtaining an electromagnetic shielding effect, and the second head support plate is more elastic than the first head support plate. A magnetic disk device comprising gimbals using a high modulus material. A magnetic disk device according to claim 1, wherein the first head support plate is a copper alloy plate, and the second head support plate is a steel plate. The magnetic disk device according to claim 2 of the utility model registration claim in which the copper alloy plate is a beryllium copper plate.