JPH0793966A - Magnetic disk apparatus - Google Patents

Abstract

PURPOSE:To improve a temperature distribution by a method wherein opposite housing faces are brought into direct contact with disks at both end parts of a plurality of connected magnetic disk drives or a heat-shielding member or a circuit board is inserted between the housing faces so as to prevent heat from being dissipated from the faces. CONSTITUTION:A plurality of magnetic disks, magnetic heads and carriage mechanisms are sealed hermetically by a housing 2, and a magnetic disk drive 1 is formed. When the cooling air is ventilated around one drive 1, a temperature distribution lacks uniformity because an area which is cooled is different between the disk in the central part and the disks at both end parts. In a disk drive unit 14 which is constituted of a plurality of drives 1, housing faces 2a at the adjacent drives 1 are formed so as to come into direct contact. Then, only housing faces 2b are cooled by the cooling air, and the temperature of the disks is brought close to uniformity. In addition, heat-insulating materials 3 may be installed at both end parts of the unit 14, and heat-dissipating fins may be installed on the faces 2b. In addition, it is effective to insert a heat- shielding member or a circuit board between the faces 2a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling housing structure and a cooling system for a magnetic disk device, and more particularly to a cooling housing structure and a cooling system for a magnetic disk device which can be easily replaced and maintained when a magnetic disk drive fails. .

[0002]

2. Description of the Related Art In recent years, magnetic disk devices are
As typified by an array device, many tens to several hundreds of magnetic disk drives using a small-diameter disk of 5 inches or less are mounted in one housing, and a magnetic disk device thus densely mounted. The development of the cooling enclosure structure will be important in the future.

In a conventional magnetic disk device containing a magnetic disk drive, as described in JP-A-62-65287, an air jet generated by a fan is blown directly onto the housing of the magnetic disk drive to cool it. .
Further, in a conventional collective type magnetic disk device containing a plurality of magnetic disk drives, as described in Japanese Patent Laid-Open No. 2-266599, the magnetic disk drives and circuits are held in a case, and the magnetic disk drives are arranged from the bottom to the top. It was cooled by installing a fan that generated an air flow.

[0004]

The prior art disclosed in Japanese Patent Laid-Open No. 62-65287 is a very efficient cooling method using a jet flow of a fan, but the arrangement of the fan and the magnetic disk drive is bad. In addition, temperature distribution may occur in the magnetic disk drive due to the velocity distribution of the air flow at the air outlet of the fan, which may cause thermal off-track in the magnetic disk drive of the servo surface servo system, leading to a decrease in positioning accuracy. is there. Further, if this cooling system is used in a magnetic disk device in which a plurality of magnetic disk drives are housed in one housing with high density, a large number of fans are required. Further, in the prior art disclosed in Japanese Patent Laid-Open No. 2-266599, even if the velocity distribution of the air flow is uniform, the air flows through the entire magnetic disk drive, so that the temperature of the magnetic disks at both ends is equal to that of the central magnetic disk. The temperature becomes lower than the temperature, and in the magnetic disk drive of the servo surface servo system, it may cause thermal off-track, which may lead to deterioration in positioning accuracy.

It is an object of the present invention to efficiently cool a magnetic disk drive in which a plurality of magnetic disk drives are housed in a single housing at a high density in consideration of the temperature distribution of the magnetic disk drives and suppress the temperature rise. In addition, replacement and maintenance of the magnetic disk drive is the minimum unit
(EN) It is an object to provide a cooling housing structure and a cooling system that can be easily performed by (unit), particularly a cooling method that focuses on uniforming the temperature distribution of a magnetic disk.

[0006]

In order to achieve the above object, in the magnetic disk device of the present invention, heat radiation to the cooling air from the two housing surfaces facing the magnetic disks at both ends of the magnetic disk drive is prevented. As a first method, the housing surface of the adjacent magnetic disk drive is
Direct contact was made. As a second method, a heat insulating member was inserted between the housing surfaces of adjacent magnetic disk drives. Further, as a third method, a circuit board is inserted between the housing surfaces of the adjacent magnetic disk drives. In addition, a plurality of magnetic disk drives are combined to form one disk unit, and each magnetic disk drive can be mounted in the housing by a plug-in method. further,
A detector for detecting the temperature of the magnetic disk drive or a detector for detecting the operating condition of the blower is also added.

[0007]

According to the present invention, between the adjacent magnetic disk drives, the two housing surfaces facing the magnetic disks at both ends are in direct contact with each other, or the heat insulating member or the circuit board is inserted between the two housing surfaces. The heat radiation from is suppressed. Therefore, heat is radiated from the housing surface except from the two housing surfaces facing the magnetic disks at both ends, and the temperature in the spindle direction is equalized including the temperatures of the magnetic disks at both ends and the central part.
The thermal off-track is suppressed, and the positioning accuracy is improved. Further, since the handling unit is composed of a disk unit and adopts the plug-in system, it is easy to put the magnetic disk drive in and out of the device case at the time of replacement / maintenance. Further, since the magnetic disk drive is provided with a detector, a control system such as cooling air amount control becomes possible and the temperature of the magnetic disk drive can be controlled.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a front view when the housing 2a surface of an adjacent magnetic disk drive 1 is directly contacted, and FIG. 2 is a perspective view thereof. Seven magnetic disk drives 1 are connected, and heat insulating materials 3 for preventing heat radiation from the magnetic disk drives 1 are provided at both ends.

First, an embodiment of the magnetic disk drive 1 will be described with reference to FIG. FIG. 3 is a cross-sectional view of the magnetic disk drive 1, which is hermetically sealed by a housing 2 so as to seal the inside from ambient air, and a plurality of magnetic disks 4 for storing information are stored in the spindle hub 5 inside.
Is rotating at a high speed, and a large number of head arms 7 each having a magnetic head 6 for reading and writing information on the magnetic disk 4 mounted at its tip are accessed at high speed by a voice coil motor 8 via a carriage mechanism. The head 6 is accurately positioned at a predetermined position on the magnetic disk 4. Reference numeral 9 denotes a spindle bearing, and a drive motor 10 for rotating the magnetic disk 4 is provided inside the spindle hub 5. The structure of the magnetic disk drive 1 need not be limited to this. For example, in this embodiment, the drive motor 1
0 is provided in the spindle hub 5 (not shown)
However, an external motor directly connected to the outside of the housing 2 may be used. Further, the magnetic head 6 and the carriage mechanism may be a linear type which makes a linear motion or a swing type which makes an arcuate rotary motion. The number of magnetic disks 4 may be any number. The magnetic disk drive 1 having a diameter of 5.25 inches or less, which is often used for disk arrays and the like, is the main object of the present invention, but a larger diameter may be used. Further, the magnetic disk 4 may be placed vertically (in the direction of the spindle 5) or may be placed horizontally. In such a magnetic disk drive 1, the temperature of the magnetic disk drive 1 rises due to windage loss due to the high speed rotation of the magnetic disk 4, loss due to the drag of a large number of head arms 7, heat generation of the voice coil motor 8, and the like. Therefore, cooling of the magnetic disk drive 1 is indispensable. Here, the 5.25 inch (φ13 which is often used for the disk array etc. which is the main object of the present invention.
In the case of a magnetic disk drive 1 of 3 mm or less, the total amount of heat generated due to loss per unit is not so large, but since it is mounted in a high density in the device case, sufficient consideration must be given to cooling the entire magnetic disk device. Is.

FIG. 4 is an explanatory view showing the purpose of the present invention. When cooling air 11 is blown around the magnetic disk drive 1 as shown in FIG. 3 to cool it (conventional general cooling method), the entire housing 2 is cooled, so that the magnetic disk 4
Temperature distribution is as shown in FIG. The circles indicate measurement points, which correspond to the magnetic disk 4 in the partial cross-sectional view shown in the right figure. The temperature of the magnetic disk 4 is higher in the central disk 4 and lower in both end disks 4 because the central disk 4 is cooled only in the outer peripheral portion of the disk 4 via the housing 2b. This is because the entire surfaces of the disks 4 at both ends are cooled via the housing 2a. Such temperature distribution on the disk 4 causes heat off-track in the magnetic disk drive 1 of the servo surface servo system, leading to a decrease in positioning accuracy. In particular, if this temperature distribution is large, the written information may not be readable. The goal of the present invention is to bring the temperature distribution of the magnetic disk 4 closer to the temperature distribution of FIG. 4B, and to make the temperatures of the disks 4 at both ends and in the center part uniform. As a method of achieving this, it is conceivable to make the amount of heat radiation from each disk 4 at both ends equal to that in the central part. Here, the present invention is mainly effective for cooling the magnetic disk drive 1 having three or more magnetic disks 4.

The housing 2a surface of the magnetic disk drive 1 shown in FIGS. 1 and 2 which is in direct contact is a surface (two surfaces) corresponding to the portion A in the sectional view of the magnetic disk drive 1 shown in FIG. The other housing surfaces (four surfaces) 2b are cooled by the cooling air 11 flowing around. Here, the housing surface 2b to be cooled may be provided with heat dissipation fins 12 for improving heat dissipation performance. The shape of the radiation fin 12 may be a straight fin or a pin-shaped protrusion fin. Further, if it is intended to make the temperature of the magnetic disk 4 uniform at both ends and the central part, only the portion B of the housing surface 2a shown in FIG. May be. FIG. 6 is a diagram for explaining the effect of the present invention, and is a cross-sectional view of the central portion of FIG. 1 seen from the front. If the housing surfaces 2a facing the magnetic disks 4a at both ends are in direct contact with the adjacent magnetic disk drives 1 and the internal calorific values of all the magnetic disk drives 1 are the same, an arrow is drawn from the housing surface 2a. Thirteen
The heat is not transferred in the direction of a, so to speak, it is in a heat insulating state, and the heat radiation to the cooling air 11 is prevented. On the other hand, since the housing surface 2b is cooled by the cooling air 11, heat is satisfactorily radiated from the housing surface 2b in the direction of the arrow 13b. Since this cooling is performed in the same manner for each magnetic disk 4 including both end magnetic disks 4a, it is possible to approach the temperature distribution (uniform temperature) of the magnetic disk 4 described in FIG. 4B. Here, in terms of heat, it is best to directly bring the housing surfaces 2a into close contact with each other by direct contact, but it may be only in partial contact or close contact due to reasons such as workability, grease, etc. You may make it contact by the inclusion of. In addition, the cooling air may be separated by a very narrow gap such that the cooling air cannot easily flow.

In FIG. 1, one disk unit 14 may be constituted by seven magnetic disk drives 1 connected together. Of course, it is not necessary to limit the number of magnetic disk drives 1 constituting one disk unit 14 to this. In a magnetic disk device in which a large number of magnetic disk drives 1 are housed in one housing with high density, in general, the magnetic disk drive 1 has a small diameter of the magnetic disk 4.
Is often used, the workability and the like are often improved when handled as the disk unit 14 rather than the individual magnetic disk drive 1. Further, in the figure, since the heat insulating material 3 is provided at both ends of the disk unit 14, the magnetic disk drives 1 at both ends cannot directly contact (insulate) the housings of the adjacent magnetic disk drives 1. This is because. It is better that the heat insulating material 3 has a lower thermal conductivity and a larger thickness, but it is not a good idea to make it too thick in terms of high-density mounting. Polyurethane, glass wool, cork, glass, ceramics, bakelite, fibers, etc. are mentioned as an example of a material having a small thermal conductivity suitable for the heat insulating material 3.

Next, an example of a case of a magnetic disk drive that houses a plurality of magnetic disk drives 1 and disk units 14 will be described. FIG. 7 is a front view showing an example of the apparatus housing 15, with the door 16 opened, and FIG. 8 is a sectional view seen from the side of FIG.

Reference numeral 17 denotes a fan, which is an example of a blowing means, which is provided in the lower portion of the apparatus casing 15, 18 is an inlet for the cooling air 11 provided in the lower portion, and 19 is an outlet provided in the upper portion. The cooling air 11 has a structure that flows from the lower part to the upper part of the device housing 15. The cooling air 11 flows in the vicinity of the surface of the housing 2b other than the surface of the housing 2a which is brought into direct contact between the adjacent magnetic disk drives 1, and each magnetic disk drive 1 is cooled and controlled to have the temperature distribution of FIG. 4B. It Reference numeral 20 is a heating element such as a drive power source for the entire magnetic disk device system. The disk unit 14 includes a plurality of magnetic disk drives 1 (seven in the figure) and a unit case 2 made of a frame such as an angle.
The plurality of disk units 14 are stacked in the device housing 15. In the figure, five disk units 14 are regularly stacked in the front part and the rear part, respectively, with a space L between them, and a total of 70 (= 7 × 5 × 2) magnetic disk drives 1 are provided. It is mounted in high density. Here, the spacing L and the pitches p ₁ and p ₂ at the time of stacking are related to the necessity of cooling the magnetic disk drive 1 and the like, and when a certain cooling performance is required, the spacing L and the pitches p ₁ and p ₂ are set. It is desirable to separate them and smooth the flow of the cooling air 11. On the other hand, when the amount of heat generation is small and the cooling performance is not so required, the spacing L and the pitches p ₁ and p ₂ may be reduced to increase the mounting density. Further, although the fan 17 is used as an example of the blowing unit in FIG. 7, a blower or a compressor having a high pressure may be used. Further, in FIG. 7, a blowing type fan 17 (having a positive pressure inside the device casing 15) is used, but a fan 17 is provided on the upper part of the device casing 15 and a suction type (negative pressure inside the device casing 15) is used. It may be used as fan 17 of.

From the viewpoint of the failure rate of the blowing means, the device housing 15
It is desirable that the number of air blowers in the inside is small, and it is good that the number is the minimum necessary. Therefore, if the same amount of cooling air can be supplied, it is better to use a small number of large blowing means. Further, if there is a margin, it is advisable to add a spare blower in addition to the regular blower so that the system can be operated immediately when the regular blower fails.

FIG. 8 shows a state in which the disk unit 14a at the uppermost front part is housed in the apparatus casing 15.
It can be easily put in and taken out by sliding on a rail 22 provided on a frame of the apparatus housing 15.

Next, an embodiment of the mounting method of the disk unit 14 will be described. FIG. 9 shows a mounting substrate 2 for mounting each magnetic disk drive 1 near the side surface of a disk unit 14 composed of a plurality of magnetic disk drives 1.
In the example in which 3 is provided, a plurality of magnetic disk drives 1 constituting one disk unit 14 are attached to one large mounting substrate 23. The mounting board 23 may simply be for mounting the magnetic disk drive 1, but may also serve as a drive and control circuit board for the magnetic disk drive 1 as shown in the figure. Reference numeral 24 is a board-mounted electronic component such as an IC chip. In this case as well, the housing surface 2a that is in direct contact is thermally insulated, and the other housing surface 2b is
Are cooled by the cooling air 11, and the mounting substrate 23 is also cooled by the same cooling air 11. Using one mounting board 23 in this way has the advantage that the board-mounted electronic components 24 such as IC chips on the mounting board 23 can be shared between the magnetic disk drives 1 in the disk unit 14.
In addition, considering the advantage that it can be shared, the mounting substrate 2
It suffices that the number of 3 is smaller than the number of the magnetic disk drives 1. For example, in FIG. 9, the mounting substrate 23 may be divided into two.

FIG. 10 shows an example in which a plurality of disk units 14 mounted by the mounting substrate 23 shown in FIG. 9 are stacked in high density. In both the front row and the rear row, the heat insulating material 3 at the end is shared between the disk units 14 stacked in the vertical direction, and the mounting boards 23 of the front and rear disk units 14 face each other. The disk units 14 configured in such a high density are housed in the device housing 15 as described above.

Next, an example of a method of mounting the magnetic disk drive 1 on the mounting substrate 23 will be described. FIG. 11 shows an embodiment of a plug-in system in which mounting plugs 25a and 25b are provided on the mounting substrate 23 and a part of the magnetic disk drive 1. Also in this case, one mounting board 23 is used, and the board mounting electronic components 24 such as IC chips are mounted on both surfaces of the mounting board 23. The mounting substrate 23 is fixed to a part of the unit case 21 described above. Of course, if the mounting board 23 has a margin, the board mounting electronic component 24 such as an IC chip may be mounted on one surface of the mounting board 23. In the figure, the magnetic disk drive 1 on the right side is already attached to the mounting substrate 23 by the plug-in method, and the magnetic disk drive 1 on the left side is removed. Here, the cooling air 11 flows around the magnetic disk drive 1 and the mounting substrate 23.

In the embodiment shown in FIGS. 9 to 11, only one mounting substrate 23 is provided for one disk unit 14, but it may be separated for each magnetic disk drive 1. That is, if one disk unit 14 is composed of seven magnetic disk drives 1, the mounting board 2
7 are provided, and each magnetic disk drive 1 is attached to each mounting substrate 23.

Next, another embodiment of the present invention will be described with reference to FIGS.
3 will be described. 12 is a front view when the heat insulating member 26 is inserted between the surfaces of the housings 2a of the adjacent magnetic disk drives 1, and FIG. 13 is a partial perspective view thereof. A plurality of magnetic disk drives 1 are connected via a heat insulating member 26 to form one disk unit 14. The heat insulating member 26 may be the same material as the heat insulating material 3 at the end portion, but the thickness t thereof needs to be appropriately selected. 12 and 1
The mounting method of the disk unit 14 shown in FIG.
And so on. Here, when the vibration of the magnetic disk drive 1 is large and it is desired to prevent the influence on the other magnetic disk drives 1, the heat insulating member 26 may also serve as an anti-vibration material. In this case, the heat insulating member 26 is preferably an elastic body such as rubber. In addition, the adjacent magnetic disk drive 1
If the electromagnetic waves affect each other, the heat insulating member 26 may also serve as the effect of the electromagnetic shield material. Further, the heat insulating member 26 may be made to have both the effect of the vibration proof material and the effect of the electromagnetic shield material.

Next, an example of the shape of the heat insulating member 26 will be described. FIG. 14 shows the solid heat insulating member 26 used in FIGS. 12 and 13, and the shape of the end is not limited to this. The heat insulating member 26 is the housing 2 a of the magnetic disk drive 1.
Although it is desirable that the surfaces are closely attached to each other, it may have a very narrow gap that does not allow the cooling air to easily flow due to mounting reasons. Also, FIG.
Reference numeral 5 denotes a hollow heat insulating member 26, which has retained air 27 inside. 16 is a perspective view of FIG. Further, FIG. 17 shows an example in which a large number of ribs 28 are provided in order to subdivide the retained air 27 inside. When the staying air 27 is provided inside the heat insulating member 26 as described above, the heat conductivity of air is poor, and thus the heat insulating effect is great. This effect is due to the accumulated air inside 2
It is large enough to subdivide 7.

Next, an example of a method of attaching the heat insulating member 26 will be described. For example, as shown in FIG. 14, it is preferable that the heat insulating member 26 has a small surface friction coefficient and can be easily inserted between the two magnetic disk drives 1. However, the heat insulating member 26 is made of rubber or the like, and its surface friction is large. When the coefficient is large and cannot be inserted easily, the configuration shown in FIGS. 18 and 19 may be used. The heat insulating member 26 of FIG. 18 has a gap 29 in the center, and by compressing the gap 29, the heat insulating member 2
6 can be easily inserted between the two magnetic disk drives 1. Then, as shown in FIG. 19, after inserting the heat insulating member 26, the inserting member 30 is inserted into the gap 29 to bring the heat insulating member 26 into close contact with the two magnetic disk drives 1. Of course, the shapes of the gap 29 and the insertion member 30 need not be limited to this. In addition, although one heat insulating member 26 is inserted between the magnetic disk drives 1 in FIGS. 14 to 19,
As shown in the embodiment of FIG. 20, the heat insulating member 26 is previously formed on both housings 2a of each magnetic disk drive 1.
It is also possible to attach a and 26b and connect the magnetic disk drive 1 configured as above.

The following system may be added to the disk unit 14 constructed by using the heat insulating member 26 as described above. That is, FIG. 21 shows that the heating member 3 is provided inside the heat insulating member 26 inserted between the magnetic disk drives 1.
1 is provided, 32 is a detector, 33 is a signal line, 34
Is a power line, and 35 is a control device. The heating member 31 may be a resistor such as a foil-shaped or linear heater, and the heating amount is controlled according to the output value of the detector 32. Next, an example of the control method will be described. As the detector 32, for example, either a temperature detector or a position signal detector is adopted. First, when a temperature detector such as a thermocouple or thermistor is adopted, the temperature of the magnetic disk 4 in the magnetic disk drive 1 as shown in FIG. 3 or the temperature of the surrounding air is detected. The detected temperatures are three points, that is, the two magnetic disks 4 facing both housings 2a and the central magnetic disk 4, and if the temperatures of the magnetic disks 4 at both ends are still lower than the temperature of the central magnetic disk 4, the magnetic disks are detected. The heating amount of the heating member 31 is controlled so that the temperatures of 4 are the same. Next, the case where the position signal detector is adopted will be described. Position information is detected by the magnetic disk 4 and the magnetic head 6 at three points, that is, two magnetic disks 4 facing both housing 2a surfaces in the magnetic disk drive 1 as shown in FIG. The amount of deviation of the magnetic disks 4 at both ends with respect to the central magnetic disk 4 is obtained, and the heating amount of the heating member 31 is controlled by an amount corresponding to the amount of deviation.

Although one mounting board 23 is used for one disk unit 14 in FIG. 9 and the like, FIG. 22 shows another embodiment in which the mounting board 23 is separated for each magnetic disk drive 1. That is, the magnetic disk drive 1a is mounted on the mounting board 23a, and the magnetic disk drive 1b is mounted on the mounting board 2a.
Each of the 3b is mounted by a plug-in method. For this reason, when the magnetic disk drive 1 is taken out of or inserted into the disk unit 14 or the device housing 15, one magnetic disk drive 1 and one mounting substrate 23 are set. Further, each magnetic disk drive 1 is mounted on the mounting substrate 23.
It can also serve as the drive and control circuit board.

Next, some other embodiments using the heat insulating member 26 will be described. In the disk unit 14 including the plurality of magnetic disk drives 1 described in FIGS. 12, 21 and 22, it is not necessary to operate all the magnetic disk drives 1 at the same time. For example, the outermost magnetic disk drive 1 may be a spare magnetic disk drive 1 that is operated when the other magnetic disk drive 1 fails during operation. Further, the spare magnetic disk drive 1 may be provided in one disk unit 14 or may be provided in two or more units, and the installation position thereof is not limited to the extreme end. FIG. 23 shows a heat insulating member in which the housing shape of the magnetic disk drive 1 is not that of FIG. 3, but the housing shapes of the parts (B parts) 2a and 2b having the magnetic disk 4 and the part 2c having the carriage mechanism and the voice coil motor 8 are different. In one example of the installation method of 26, the heat insulating member 26 is provided only in the important portion 2 a that influences the temperature of the magnetic disk 4. In this case, the surface of the housing 2c having the carriage mechanism and the voice coil motor 8 may be positively cooled. Further, FIG. 24 shows an installation example of the heat insulating member 26 in the case where the drive motor 10 for the magnetic disk 4 is an external motor directly connected to the outside of the housing 2. The heat insulation member 26 has a concave portion for providing an air layer around the drive motor 10. A heat insulating member 26 is provided. Here, when the driving motor 10 generates a large amount of heat, the cooling air 11 may be caused to flow into the recess. At this time, the temperature distribution of the magnetic disk 4 is shown in FIG.
It is necessary to adjust the amount of cooling air flowing through the recess so as to approach (b).

Next, another embodiment of the present invention will be described with reference to FIGS.
6 will be described. 25 is a front view when the circuit board 36 is inserted between the surfaces of the housings 2a of the adjacent magnetic disk drives 1, and FIG. 26 is a partial perspective view thereof. A plurality of magnetic disk drives 1 are connected via a circuit board 36 to form one disk unit 14. Here, the circuit board 36 to be inserted is a drive and control circuit board for each magnetic disk drive 1, and a large number of electronic components such as the IC chip 24 are mounted on the board. The housing 2a of the magnetic disk drive 1 is fixed with screws 37. Then, each magnetic disk drive 1 is mounted on the mounting substrate 23 by the plug-in method as described above. Also in this case, the mounting substrate 23 may be separated for each magnetic disk drive 1 as shown in FIG. 22, and the mounting may not be the plug-in method. Here, I on the circuit board 36
When the amount of heat generated by the electronic components such as the C chip 24 is large, a slight amount of cooling air 11a may be flown around the circuit board 36. Also at this time, it is necessary to adjust the amount of cooling air flowing around the circuit board 36 so that the temperature distribution of the magnetic disk 4 approaches that in FIG. 4B. Also in this embodiment, when the magnetic disk drive 1 is taken out of or inserted into the disk unit 14 or the apparatus housing 15, one magnetic disk drive 1 and one mounting substrate 23 are set.

Next, another embodiment of the apparatus housing structure of the present invention will be described with reference to FIG. FIG. 27 shows an example of the device casing 15 corresponding to FIG. In the method of cooling the device housing 15 shown in FIG. 8, the magnetic disk 4 of each magnetic disk drive 1 is used.
Even if the temperature distribution is reduced, there is a problem that the temperature of the entire magnetic disk drive 1 rises in the flow direction of the cooling air 11 (from the bottom to the top in the figure). This is because the temperature of the air that cools the magnetic disk drive 1 and the like gradually rises. However, when the amount of heat generated by each magnetic disk drive 1 or the substrates 23 and 36 is small or the amount of cooling air is large, this does not cause much problem. If there is a problem, there is a method as shown in FIG. 27. The fan 17, which is a blowing unit, is provided at the upper part of the apparatus housing 15 and is a suction type fan. In addition to the main inlet 18 and the main outlet 19 of the cooling air 11 of the device casing 15, ambient air 38 sequentially flows into the device casing 15 along the side of the device casing 15 along the flow direction of the main cooling air 11. An air supply hole 39 is provided. For this reason, fresh and cool air sequentially flows into the device housing 15 from the air supply hole 39, and the temperature rise of the main cooling air flow 11 along the flow direction can be moderated. The air supply holes 39 may be provided intermittently on the side surface of the device casing 15 as shown in FIG.
It may be provided in the shape of an elongated slit continuous to the side surface of the device housing 15 along the flow direction of 1. In the embodiment, the air supply hole 39
The inflow of the air from is performed by the power of the fan 17 for supplying the main cooling air. Therefore, it is necessary to use the suction type fan 17. On the other hand, as another embodiment, another air blower is provided in each air supply hole 39 shown in FIG.
The ambient air may be forcedly guided into the device housing 15. In this case, the air blowing means provided in the air supply hole 39 may be a small fan, and the main cooling air supply fan 17 may be a blowing type fan instead of a suction type fan, and the fan 17 may be a device casing as shown in FIG. It may be provided in the lower part of 15.

Next, an embodiment of the temperature control method for the magnetic disk drive 1 will be described. One is a magnetic disk device having a device housing 15 as shown in FIGS. 7, 8 and 27, which is provided with a detector for detecting the temperature of the cooling air flowing through the magnetic disk drive 1 or its surroundings. Is used to control the amount of cooling air generated by the fan 17, which is a blower, to control the temperature of the magnetic disk drive 1 to a set value. The temperature detector may be a thermocouple or thermistor, and may be provided in each magnetic disk drive 1, but may be provided only in one representative magnetic disk drive 1 of each disk unit 14 stacked in the cooling air flow direction. good. When the temperature of the magnetic disk drive 1 detected by the temperature detector becomes higher than the set value, the amount of cooling air generated by the fan 17 is increased.
As one method of controlling the amount of cooling air generated by the fan 17, there is a method of changing the number of revolutions by changing the power supply frequency or the like supplied to the fan 17. Further, as another method, the number of fans 17 may be changed. That is, a spare fan may be provided in the device housing 15 and the spare fan may be operated when increasing the cooling air amount. On the contrary, when the amount of cooling air is reduced, a part of the operating fan 17 may be stopped. The other is a magnetic disk device having a device casing 15 as shown in FIGS. 7, 8 and 27, which is provided with a detector for detecting the operating condition of the fan 17 which is a blowing means, and the output signal of the detector is provided. Is a method of controlling the amount of cooling air generated by the fan 17 which is a blowing means, and controlling the temperature of the magnetic disk drive 1 to a set value. The operation status detector may detect the power input of the fan, and is provided in each fan 17.
When it is detected that one fan 17 has failed, the cooling air amount of another fan 17 is increased. The method of controlling the amount of cooling air generated by the fan 17 may be the same as the method described above. Although these two detectors may be provided individually, it is desirable to use the two detectors together if the reliability of the magnetic disk device is increased.

Next, another embodiment of the apparatus housing structure of the present invention will be described. When it is important to prevent dust from entering the device housing 15 and to reduce noise generated in the device, the surrounding cover surface and the door surface of the device housing 15 are completely covered with a muffling material, It is conceivable that the device casing 15 has a closed structure. A problem at this time is a rise in the temperature of the cooling air 11 in the apparatus housing 15, and means for cooling the magnetic air in the magnetic disk drive 1 to cool the heated cooling air 11 is required. As a countermeasure against this, a cooling device for cooling the cooling air 11 having a high temperature after cooling the magnetic disk drive 1 and the like is provided inside the device housing 15 which is closed, and the cooling air 11 is cooled.
It is conceivable to circulate in the order of the magnetic disk drive 1 → cooler → magnetic disk drive 1 in the device housing 15. The refrigerant that exchanges heat with the cooling air 11 in the cooler may be water, a refrigerant that undergoes a phase change between gas and liquid, or air, and this refrigerant may be manufactured in a refrigeration cycle unit that is provided outside the apparatus housing 15 and is separated. In some cases, the refrigeration cycle unit may be provided in a part of the device housing 15.
In such a case, the temperature of the magnetic disk drive 1 can be controlled by controlling the flow rate and temperature of the refrigerant. Further, it is possible to add a function such as a vibration damping material to the above-described sound deadening material to suppress the vibration of the apparatus housing 15.

[0031]

According to the present invention, in a magnetic disk device in which a plurality of magnetic disk drives are housed in one housing with high density, the magnetic disk drives are efficiently cooled in consideration of the temperature distribution of the magnetic disk drives, and It is possible to provide a cooling housing structure and a cooling system in which the replacement and maintenance of disk drives can be easily performed in units. In particular, it is effective in making the temperature distribution of the magnetic disk uniform, which greatly affects the positioning accuracy.

[Brief description of drawings]

FIG. 1 is a front view of a magnetic disk drive in direct contact.

FIG. 2 is a perspective view of FIG.

FIG. 3 is a sectional view of a magnetic disk drive.

FIG. 4 is an explanatory view showing the purpose of the present invention.

FIG. 5 is a sectional view of a magnetic disk drive showing a direct contact portion.

FIG. 6 is an explanatory view showing the effect of the present invention.

FIG. 7 is a front view of the device housing.

FIG. 8 is a sectional view of FIG.

FIG. 9 is a perspective view of a disc unit.

FIG. 10 is a perspective view of a disk unit mounted in high density.

FIG. 11 is a plan view of a magnetic disk drive mounted on a mounting substrate by a plug-in method.

FIG. 12 is a front view of a magnetic disk drive in which a heat insulating member is inserted.

13 is a perspective view showing one magnetic disk drive of FIG. 12. FIG.

FIG. 14 is a cross-sectional view of a solid heat insulating member.

FIG. 15 is a cross-sectional view of a hollow heat insulating member.

16 is a perspective view of FIG.

FIG. 17 is a perspective view of a hollow heat insulating member provided with ribs.

FIG. 18 is a sectional view of a solid heat insulating member having a gap.

FIG. 19 is a perspective view showing a method of inserting a solid heat insulating member.

FIG. 20 is a cross-sectional view of a heat insulating member attached to each magnetic disk drive.

FIG. 21 is a cross-sectional view of a heat insulating member having a heating member provided therein.

FIG. 22 is a perspective view of a disc unit having a separated mounting substrate.

FIG. 23 is a plan view of a magnetic disk drive in which a heat insulating member is inserted only in a necessary portion.

FIG. 24 is a plan view of a magnetic disk drive having a direct coupling motor having a heat insulating member inserted therein.

FIG. 25 is a front view of a magnetic disk drive in which a circuit board is inserted.

FIG. 26 is a perspective view of FIG. 25.

FIG. 27 is a cross-sectional view of a device housing having an air supply hole.

[Explanation of symbols]

1 ... Magnetic disk drive, 2 ... Housing, 3 ... Heat insulating material, 14 ... Disk unit.

Claims (1)

[Claims] 1. A magnetic disk device for housing a plurality of magnetic disk drives for storing information, a magnetic head for reading and writing the information, and a carriage mechanism for positioning the magnetic head, the housing being enclosed by a housing. A magnetic disk drive characterized in that the housing surfaces of the adjacent magnetic disk drives are brought into direct contact with each other.