JPS59223984A - Magnetic disk device - Google Patents

Abstract

PURPOSE:To improve the cooling effect to the exothermic part of a disk enclosure and the working property and maintenance property of the disk enclosure, by mounting the disk enclosure, from which a motor for driving a magnetic disk medium and another motor for driving a magnetic head are projected, on the external one side face of a housing and installing a cooling fan to the front of the housing. CONSTITUTION:When a cooling fan 12 is driven in a magnetic disk device in which each unit, such as a disk enclosure 4, a control circuit section, a power supply unit 16, etc., are arranged, the cooling air flows into the inside of the magnetic disk device from the front face of a front panel 1 and to the rear side of the device along the upper and side surfaces of the disk enclosure 4 and the control circuit section as shown by the arrow E after the air is raised inside the front panel 1 and bent by the upper surface of the box body 3 of the device as shown by the arrow D. Since the exothermic section of the disk enclosure 4 installed to the bottom face side of the enclosure 4 is faced to one side of the box body 3, the exothermic section can be cooled when the cooling air flows to the rear side of the device as shown by the arrow E.

Description

Detailed Description of the Invention (1) Technical Field of the Invention The present invention relates to a magnetic disk device that has a cooling fan on the front side of the device and each unit is arranged inside the device housing, and particularly relates to a magnetic disk device that has a cooling fan on the front side of the device and each unit is arranged inside the device housing. The present invention relates to a magnetic disk device in which units are arranged to improve effectiveness.

■ Prior Art and Problems As shown in Figure 1, the conventional magnetic disk drive in this building has a laminar flow type cooling fan 2 inside the front panel 1 on the front side of the machine. In order to increase the cooling effect, the magnetic disk medium surface sealed inside the housing 71 of the disk enclosure 4 is mounted near the rear of the cooling fan 2 in the housing 3 so that the surface of the magnetic disk medium is parallel to the bottom surface of the housing 3. A heat generating section protruding from the bottom side is mounted toward the bottom surface of the housing 3, a control circuit section 5 is provided on the side of the disk enclosure 4, and a power supply unit 6 is arranged at the rear of the device. Recently, as the rotational speed of magnetic disks has increased, the heat generating part of the DC motor that drives the magnetic disks has become larger, and the inside of the device housing 3 has become denser, causing the inside of the magnetic disk device to have a sieve temperature. It was something like that.

However, as shown in FIG. 1, the cooling air generated by the cooling fan 2 flows into the interior from the front side of the front panel 1 as shown by arrow A, and then rises inside the front panel 1 as shown by arrow B. It is bent at the top surface of the device housing 3, and flows along the top and sacrum surfaces of the disk enclosure 4 toward the rear of the device.

The reason for this will be explained using FIG. 1.2. In FIG. 2, the same parts as in FIG. 1 are represented by the same numbers. Cooling air is taken in from the front panel 1 in the direction shown in the figure, and is sent at pressure P in the direction of arrow B' by the cooling fan 2.

However, if cooling air is sent at a pressure P' in the direction of arrow C in the figure, P>P' due to the structure of the cooling fan 2, so sufficient airflow cannot be obtained and the cooling effect inside the disk enclosure is poor. Become.

Therefore, the cooling air must flow in the direction of arrow B shown in FIG. However, since the cooling air flows to the upper part, heat generating parts such as spindle motors and rotary voice coil motors protruding from the bottom wall 1111 of the housing of the taste enclosure 4 are Cooling air! The cooling effect was poor. Therefore, the spindle motor, voice coil motor, etc. of the disk enclosure 4 overheat, causing a failure of the device.

The following problems also occur due to the damage to the disk enclosure itself, which will be explained using FIGS. 3, 4, and 5. FIG. 3 is a top view of the housing of the disk enclosure 4 in FIG. 1. FIG. 4 is a top plan view of the disk enclosure 4 seen from inside the housing sink bottom. In the drawing, 7 is a signal cable for readout, convolution, etc. 8, 8' is a cable to a rotary voice coil motor for driving a magnetic head, and a couple to a spindle motor for driving a magnetic disk, 9 is a cable for all cooling effects. A spindle motor protrudes outside the housing of the disk enclosure 4 in order to avoid the cooling effect, 10 a rotary voice coil motor that similarly protrudes outside the disk enclosure in order to avoid cooling effects, 22 an elastic cushioning material such as anti-vibration rubber, 23 24 is a mounting member, 24 is a mounting screw, and 25 is a floor surface of the housing.

The disk enclosure 4 is removable from the magnetic disk enclosure 25 by inserting a mounting screw 24 into a through hole in a side edge of a mounting member 23 fixed to the disk enclosure 4.
is inserted into the elastic cushioning material 22 such as anti-vibration rubber. However, as shown in FIGS. 3 and 4, the disk enclosure 4 includes a cable 8' for supplying power for driving the spindle motor 9, a cable 8 for driving the rotary voice coil motor 10, and a cable 8 for reading information. , a signal cable 7 for controlling the signal is connected and routed around it, and furthermore, another signal cable 11 is also routed. As shown in FIG. 1, when the disk enclosure 4 is installed horizontally with respect to the magnetic disk medium surface inside its housing, each cable will cover the top of the mounting screw 24. Therefore, when removing or attaching the disk enclosure 4, the work of tightening and loosening the mounting screws 24 from the top of the disk enclosure 4 with a screwdriver or the like becomes extremely troublesome. Furthermore, I had to handle the screwdriver etc. with care so as not to damage each cable. Furthermore, as the mounting density of magnetic disk housings increases recently, the above-mentioned deficiencies will further increase. Further, as shown in FIG. 4, on the bottom side of the disk enclosure 4, there is a pivot section inside a rotary voice coil motor section 10 for seeking the sensing head provided inside the housing, and a pivot section is provided inside the rotary voice coil motor section 10 for seeking the sensing head provided inside the housing. During transportation, it is necessary to fix the pivot section with the wing nut 12, but since the bottom side of the disk enclosure 4 faces the bottom surface of the device housing 3, the work of fixing the pivot section and maintenance are easy. It was.

(31. Name of the Invention The present invention has been made to solve the above-mentioned problems. Therefore, it provides a magnetic disk enclosure device that can improve the cooling effect on the heat-generating portion of a disk enclosure and improve workability and maintainability. The purpose is to

(4) Structure of the device and the above object according to the present invention, a housing is provided with a magnetic disk medium and a magnetic head, and a spindle motor for driving the magnetic disk medium and a magnetic head drive are provided on the outside/side surface of the housing. A magnetic disk device equipped with a voice coil motor and a disk enclosure protruding from the disk enclosure, and having a cooling fan on the front surface, wherein the disk enclosure is arranged so that the magnetic disk medium is perpendicular to the bottom surface of the magnetic disk device housing. This is achieved by providing a magnetic disk device characterized in that one side of the disk enclosure from which the spindle motor and voice coil motor portion are protruded faces the side surface of the magnetic disk device housing.

(5) Embodiments of the Invention Hereinafter, embodiments of the present invention will be explained in detail with reference to the accompanying drawings. .

FIG. 6 is a perspective view showing a magnetic tissue device according to the present invention. A front panel 1 is provided on the WiJ surface side of the device, and a cooling fan 2 is provided inside this front panel 1.

The cooling fan 2 is used to cool each unit disposed within the device housing 3, and is a laminar flow type fan with high blowing pressure.

A disk enclosure 4 is arranged on one side near the rear of the cooling fan 2, for example, on the left side ( ) 11j of the housing 3 in Fig. 6. This disk enclosure 4 has a plurality of stacked magnetic disks as recording media inside its housing, and is further provided with a magnetic head that seeks out the medium surface of the magnetic disks to contain or eject them. A spindle motor for driving a magnetic disk, a voice coil motor for driving a magnetic head, etc. are installed on the outside of the housing so that the surface of the magnetic disk is approximately perpendicular to the surface of the housing, and protrudes from the bottom side of the housing. The heat generating portion of the cooling fan 2 is installed so that the cooling air from the cooling fan 2 can pass through the bottom surface side of the device housing 30 so that the heat generating portion thereof faces the side bend of the device housing 30 .

A control circuit s15 is arranged adjacent to the disk enclosure 4 and on the other side near the rear of the cooling fan 12, for example, on the right side inside the housing 3 in FIG. This compensation 1 circuit s15 sets the position of the magnetic head, selects any one of a plurality of magnetic heads, or issues write and read commands. A '#i source unit 16 is disposed at the rear of the apparatus within the apparatus housing 3. In FIG. 6, reference numeral 17 is an interface unit for inputting and outputting signals with other devices.

Next, referring to FIGS. 6, 7, 8, and 9, a structure in which the disk enclosure is installed approximately vertically will be explained in detail.

FIG. 7 is an explanatory view of the mounting part showing the mounting structure of the disk enclosure according to the present invention.

The disk enclosure 4 is attached to the floor surface 25 at a predetermined position of the magnetic disk device housing. At the four corners of the bottom surface of the disk enclosure 4 (see FIG. 8), elastic cushioning material 22, 22, etc., such as anti-vibration rubber, is provided. As shown in FIG. 9, a support rail 30 having a U-shaped cross section is attached to the bottom of the support frame 39 with a support frame A7. As shown in FIG. 7, both end portions of the support frame 39 are raised up to an appropriate height along the 111th surface of the disk enclosure 4, and the upper end portions of the upright pieces 31 and 31 are folded approximately horizontally. At the same time, a mounting screw 32 is attached to the bent portion.

The mounting screws 32 are used to mount the disk enclosure 4 into the magnetic disk device by fixing the nine upright pieces 31, 31 to a mounting frame 35, which will be described later.

A mounting flanges 35.35 are erected by welding or the like on the floor surface 25 around the mounting position of the disk enclosure 4 in the magnetic nice device. This mounting frame 35
is for attaching the disk enclosure 4 to a predetermined position in the magnetic disk drive, and is installed along the rising piece 31.31 of the support frame 39 at a location corresponding to the rising piece 31.31. It stands tall and its upper end is bent almost horizontally.

In FIGS. 8 and 9, numeral 36 is a spindle motor for driving the magnetic disk, numeral 37 is a rotary voice coil motor section for seeking the magnetic head, and numeral 12 is a rotation f, and In order to attach such a disk enclosure 4 to the floor surface 25 in the magnetic tape device, first, as shown in FIG. .35...
・Place the disk enclosure 4 on the floor surface 25 between the two. At this time, the above mounting frame 35, 35...
The upright pieces 31.31... of the support frame 39 of the disk enclosure 4 are positioned so as to face each of the nine upright pieces 31,31...
...Screw for reporting screwed onto the upper end 32.32.
The axis line of ...... is attached to the above mounting frame 35.35...
...Align it with the screw hole carved in the upper end. Next, rotate the mounting screws 32, 32, . . . and screw them into the screw holes of the mounting frames 35, 35, . The nine pieces 31, 31... are fastened and fixed to mounting frames 35, 35,..., which are erected from the floor surface 25. In this way, the disk enclosure 4 has elastic cushioning materials 22, 22...
It is attached so that it can be buffered via...

In this way, when the cooling fan 12 is driven in the magnetic disk drive in which the disk enclosure 4, the control circuit section 15, the power source unit 16, and other units are arranged, the cooling air is generated as shown in FIG. arrow C
As shown in , it flows into the interior from the anterior sacrum of the front panel 1, and then rises inside the front panel 1 and is bent at the soil surface of the device casing 3 as shown by the arrow E. Then, the liquid flows to the rear side of the device through the front and side surfaces of the disk enclosure 4 and the control circuit section 15. At this time, since the heat generating portion on the bottom side of the disk enclosure 4 is directed toward one side of the device housing 3, when the cooling air flows in the direction of arrow E, the heat generating portion is cooled.

That is, as shown in FIG. 9, cooling air is increased in the direction of arrow C by the cooling fan 2 and sent out in the direction of the arrow. The cooling air sent out in the direction of the arrow is dispersed and flows as shown by the arrow E to cool the spindle motor 36 and rotary whirlpool motor 37, which have many heat generating parts.

More cables? , 8, 8' cover the mounting screws 32 as in the conventional case, and do not become an obstacle when installing or removing the enclosure 4, and as shown in FIG. 8' can be arranged so that it does not pass through the upper part of the mounting screw 32.

In addition, since the bottom side of the disk enclosure 4 is directed toward one side of the device housing 3, when the housing 3 is opened, the pivot part of the voice coil motor on the bottom if] side is fixed by the wing nut 12. can be easily done.

(6) Effects of the Invention Since the present invention is configured as described above, a cooling fan is provided for heat generating parts such as a spindle motor for driving a magnetic disk, a rotary voice coil motor, etc. provided on the bottom side of the disk enclosure 4. 12, which improves the cooling effect of the heat-generating part. Also, since the heat-generating part of the disk enclosure faces the side of the device housing, there is no effect of heat on printed circuit boards, etc. w can be reduced. Therefore, it is possible to prevent the soil dr'2 taste enclosure 40 from overheating and to reduce the cause of failure of the device. Further, according to the present invention, the cables 7, 8', 8 can be arranged without occupying the space above the mounting screw 32.

Furthermore, since the present invention is configured as described above, the mounting frames 35, 35, etc. are installed upright from the floor surface 25 of the device.
・Rising pieces 31, 31 of the support frame 39 raised on the peripheral side of the disk enclosure 4...
By fixing the disk enclosure 4, it is possible to perform the installation work at a position higher than the floor surface 25, and it is possible to improve the workability of mounting the disk enclosure 4 even in a high-density magnetic disk device.

Also, the bottom side of the above disk enclosure is the device housing 3.
By opening the housing 3, it is possible to easily expose the pivot portion of the rotary voice coil motor portion that seeks the magnetic head provided on the bottom side. Therefore, the work of fixing the pivot part when transporting the magnetic tisf device can be easily carried out (15
), and the maintainability of the part can be improved as well.

[Brief explanation of the drawing]

FIG. 1 is an internal layout diagram showing a conventional magnetic disk device, FIG. 2 is a diagram for explaining the cooling fan, FIGS. 3 and 4 are diagrams for explaining the structure of the disk enclosure, 5 is a diagram for explaining the mounting structure of a conventional disk enclosure, FIG. 6 is an internal layout diagram showing the magnetic disk enclosure according to the present invention, and FIGS. 7, 8, and 9 are diagrams showing the disk enclosure according to the present invention. FIG. 3 is a diagram for explaining the mounting structure of the In the drawing, 1 is the front panel, 2 is the cooling fan,
3 is a magnetic disk housing, 4 is a disk enclosure,
1.8.8' is a cable, 9.36 is a spindle motor, 10.37 is a voice coil motor section, 22 is an elastic buffer, 30 is a support rail, 31 is a rising piece of the support frame, 'j32 is a mounting screw , 35 is a mounting frame. (16) """-゛, :5'Figure 1 2'1 Figure 2 Figure 3 Section Arm (Saikotsuha)

Claims (1)

[Claims] 1) A magnetic disk medium and a magnetic head are installed inside the housing, and a disk enclosure with a spindle motor for driving the magnetic disk medium and a voice coil motor for driving the magnetic head protruding from the outside side of the housing is installed, and a cooling fan is installed on the front side. A magnetic disk drive having a magnetic disk drive, wherein the disk enclosure is mounted such that the magnetic disk medium is perpendicular to the bottom surface of the magnetic disk drive housing, and one side of the disk enclosure from which a spindle motor and a voice coil motor portion are protruded. A magnetic disk device characterized in that the magnetic disk device is opposed to a side surface of a magnetic disk device casing.