JP2011119670A - Electronic equipment, electronic equipment storage cabinet, and cooling device used therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide electronic equipment which prevents dust from entering inside a cabinet without reduction of the flow rate of air passing through an intake fan. <P>SOLUTION: A cooling device 18 of electronic equipment 2 includes an intake fan 22 for sending cooling outside air into the inside of a cabinet 4, and a hood cover 24 provided so as to surround the windward side of the intake fan 22. The hood cover 24 has an intake opening 38, and a swirl flow flowing from the intake opening 38 to the intake fan 22 by the rotation of the intake fan 22 is formed in the hood cover 24. When the cooling outside air is introduced into the hood cover 24 through the intake opening 38, the dust included in the cooling outside air is centrifugally separated outwardly in radial direction by the swirl flow formed by the rotation of the intake fan 22. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an electronic device provided with a cooling mechanism for cooling a heat-generating component housed in a housing with outside air for cooling, an electronic device storage cabinet for storing the electronic device, and a cooling device used in these. .

  For example, electronic devices such as DVD recorders, audio players, and personal computers are configured by housing a circuit board, a drive unit, and the like inside a housing. The circuit board, the drive unit, and the like are mounted with heat-generating components such as semiconductor devices, for example, and the heat-generating components generate heat when the electronic device is energized. In order to fully exhibit the performance of the electronic device, it is necessary to cool the heat generating component, and conventionally, various cooling mechanisms for cooling the heat generating component have been proposed.

  FIG. 11 is a cross-sectional view illustrating a conventional electronic device. The illustrated electronic device 100 includes a housing 102 and an exhaust fan 104 for exhausting air inside the housing 102 to the outside. A plurality of circuit boards 108 are accommodated in the housing 102, and a heat generating component 106 is mounted on each circuit board 108. The housing 102 is provided with a plurality of air inlets 110. When the exhaust fan 104 is operated, the air inside the housing 102 is exhausted to the outside through the exhaust fan 104 due to the rotation thereof, thereby reducing the pressure inside the housing 102. As a result of the pressure difference between the inside and outside of the housing 102 in this way, the outside air for cooling is introduced into the inside of the housing 102 through the plurality of intake ports 110, and the heat generating components 106 in the housing 102 are cooled by the outside air for cooling. Is done.

  However, in such a cooling mechanism, dust enters the inside of the housing 102 through the plurality of air inlets 110 together with the outside air for cooling. Further, as the exhaust fan 104 rotates, a swirling flow is formed in the vicinity of the windward side of the exhaust fan 104. When dust reaches the vicinity of the windward side of the exhaust fan 104, it is centrifuged by this swirling flow, and most of the dust is accumulated inside the housing 102 without being discharged outside through the exhaust fan 104. If dust adheres to the circuit board 108 or the like in the housing 102, the operation of the circuit board 108 or the like may be adversely affected. Further, if a large amount of dust adheres to the blades of the exhaust fan 104, there is a possibility that the amount of air passing through the exhaust fan 104 may be reduced. Further, when dust adheres to the inlet 110 and its surroundings and closes the inlet 110, the outside air for cooling is, for example, a front panel (not shown) of the housing 102 and an operation knob (not shown). And the gap between the back panel (not shown) of the casing 102 and the terminal portion (not shown), and the like. Then, the dust enters the inside of the housing 102 through the gap and the like with the outside air for cooling, and the dust adheres to the gap and the surroundings as time passes to block the gap and the like. As a result, the outside air for cooling cannot be efficiently introduced into the housing 102, and the electronic device 100 may overheat.

  In order to prevent dust from entering the housing in this way, for example, a cooling mechanism for an electronic device as described in Patent Document 1 has been proposed. This electronic device includes a housing, an intake fan for sending cooling outside air into the housing, and a filter provided so as to cover the intake side of the intake fan. The casing is provided with a plurality of exhaust ports. When the intake fan operates, the cooling outside air is sent into the casing by the rotation, and the heat generating components in the casing are cooled by the cooling outside air. At this time, dust contained in the outside air for cooling that passes through the intake fan is captured by the filter, thereby preventing the dust from entering the housing. Moreover, the outside air for cooling sent into the housing is exhausted to the outside through a plurality of exhaust ports.

  In order to protect an electronic device used in a dusty environment from dust, for example, an electronic device storage cabinet as described in Patent Document 2 has been proposed. The electronic device storage cabinet includes a cabinet body for storing electronic devices, an intake fan for sending outside air for cooling into the cabinet body, a filter provided so as to cover the intake side of the intake fan, It has. The cabinet body is provided with a plurality of exhaust ports. Similarly to the electronic device described above, the cooling outside air is sent into the cabinet body by the rotation of the intake fan, and the electronic device in the cabinet body is cooled by the cooling outside air. Dust contained in the cooling air passing through the intake fan is captured by the filter.

Japanese Patent Laid-Open No. 11-174596 JP 2000-157344 A

  The electronic device cooling mechanism described in Patent Document 1 and the electronic device storage cabinet described in Patent Document 2 have the following problems. Since the outside air for cooling passes through the intake fan after passing through the filter, the amount of air passing through the intake fan is reduced as compared with the case where no filter is provided. There is a problem that the cooling efficiency of the electronic equipment in the storage cabinet is lowered. Further, when the filter is clogged, there is a problem that the air flow rate of the intake fan is further reduced.

  A first object of the present invention is to provide an electronic device that can prevent dust from entering the inside of a casing without reducing the air flow rate of an intake fan.

  A second object of the present invention is to provide an electronic device storage cabinet capable of preventing dust from entering the inside of the cabinet body without reducing the air flow rate of the intake fan.

  A third object of the present invention is to prevent dust from entering the inside of the electronic device or the electronic device storage cabinet for storing the electronic device without reducing the air flow rate of the intake fan. It is providing the cooling device which can do.

In the electronic device according to the first aspect of the present invention, a housing, a heat generating component housed in the housing, and cooling air is sent into the housing to cool the heat generating component. A cooling device, and the housing is an electronic device provided with an exhaust port for discharging outside air for cooling sent into the housing to the outside,
The cooling device includes an intake fan for sending outside air for cooling into the housing, and a hood cover provided so as to surround a windward side of the intake fan, and the hood cover includes an intake air An opening is provided, and a swirl flow that flows from the intake opening toward the intake fan is formed inside the hood cover by the rotation of the intake fan.
When cooling outside air is introduced into the hood cover through the intake opening, dust contained in the cooling outside air is centrifuged radially outward by the swirl flow formed by the rotation of the intake fan. It is characterized by that.

  Further, in the electronic device according to claim 2 of the present invention, the intake opening is opened in a direction substantially perpendicular to the axial direction of the intake fan, and the hood cover has a periphery around the intake opening. The auxiliary intake opening for introducing the cooling outside air into the inside of the hood cover and / or the auxiliary exhaust opening for discharging the air inside the hood cover to the outside are provided. .

  In the electronic device according to claim 3 of the present invention, the auxiliary exhaust opening is provided with dust collecting means for collecting dust discharged outside through the auxiliary exhaust opening. It is characterized by that.

  In the electronic device according to a fourth aspect of the present invention, a portion of the hood cover corresponding to the auxiliary exhaust opening is disposed outside the casing.

  In the electronic device according to claim 5 of the present invention, the intake opening of the hood cover is provided with a cylindrical portion extending toward the intake fan and in the axial direction of the intake fan. It is characterized by.

  Further, in the electronic device according to claim 6 of the present invention, the rotating shaft of the intake fan is provided with a swirl flow forming auxiliary protrusion that extends toward the intake opening of the hood cover. And

  Further, in the electronic device according to claim 7 of the present invention, a swirl flow forming auxiliary blade is provided on a rotation shaft of the intake fan, and the swirl flow forming auxiliary blade is connected to the intake opening of the hood cover and the intake opening. It is characterized by being rotatably arranged with the intake fan.

The electronic device storage cabinet according to claim 8 of the present invention is an electronic device storage cabinet for storing an electronic device,
A cabinet body in which the electronic device is housed, and a cooling device for cooling the electronic device by sending cooling air into the cabinet body, the cabinet body being fed into the cabinet body. There is an exhaust port for discharging the outside air for cooling to the outside,
The cooling device includes an intake fan for sending outside air for cooling into the cabinet body, and a hood cover provided so as to surround a windward side of the intake fan, and the hood cover includes an intake air An opening is provided, and a swirl flow that flows from the intake opening toward the intake fan is formed inside the hood cover by the rotation of the intake fan.
When cooling outside air is introduced into the hood cover through the intake opening, dust contained in the cooling outside air is centrifuged radially outward by the swirl flow formed by the rotation of the intake fan. It is characterized by that.

Moreover, in the cooling device according to claim 9 of the present invention, the heat generating component accommodated in the electronic device by sending the outside air for cooling into the electronic device or the electronic device storage cabinet for storing the electronic device. Or a cooling device for cooling the electronic device stored in the electronic device storage cabinet,
An intake fan, and a hood cover provided so as to surround a windward side of the intake fan. The hood cover is provided with an intake opening, and the intake fan is rotated from the intake opening by rotation thereof. It is configured to form a swirling flow that flows toward the intake fan,
When cooling outside air is introduced into the hood cover through the intake opening, dust contained in the cooling outside air is centrifuged radially outward by the swirl flow formed by the rotation of the intake fan. It is characterized by that.

  According to the first aspect of the present invention, since the hood cover is provided so as to surround the windward side of the intake fan, the intake air is sucked from the intake opening by the rotation of the intake fan inside the hood cover. A swirling flow that flows toward the fan can be effectively formed. When the outside air for cooling is introduced into the hood cover through the intake opening, the dust is heavier than the outside air for cooling. Therefore, the dust contained in the outside air for cooling is centrifugally separated radially outward by the swirling flow. The dust thus centrifuged is swirled in a predetermined direction in the inner peripheral area of the hood cover by swirling flow, and dust can be prevented from entering the inside of the housing through the intake fan. In addition, the cooling outside air introduced into the hood cover through the air intake opening passes through the air intake fan without passing through the filter as in the conventional case, thus preventing a reduction in the air flow rate of the air intake fan. can do. Therefore, it is possible to provide an electronic device that can increase the cooling efficiency of the heat-generating component and can prevent dust from entering the inside of the housing.

  Further, according to the electronic device according to claim 2 of the present invention, since the auxiliary intake opening is provided around the intake opening of the hood cover, the outside air for cooling passes through the auxiliary intake opening of the hood cover. By being introduced inside, the swirl flow can be generated more efficiently inside the hood cover. In addition, since an auxiliary exhaust opening is provided around the intake opening of the hood cover, the air inside the hood cover is exhausted to the outside through the auxiliary exhaust opening, and thus is centrifuged by the swirling flow. Dust can be discharged together with air through the auxiliary exhaust opening.

  In the electronic device according to claim 3 of the present invention, since the dust collecting means is provided in the auxiliary exhaust opening, the dust discharged outside through the auxiliary exhaust opening is collected by the dust collecting means. Can be collected.

  According to the electronic device according to claim 4 of the present invention, the portion corresponding to the auxiliary exhaust opening of the hood cover is disposed outside the housing, so that it is discharged to the outside through the auxiliary exhaust opening. The dust that has been collected does not enter the inside of the housing.

  In the electronic device according to claim 5 of the present invention, the intake opening of the hood cover is provided with the cylindrical portion extending toward the intake fan and in the axial direction of the intake fan. A separation region can be efficiently formed in the inner peripheral region of the hood cover in the vicinity of the opening. The pressure in the separation flow area is lower than the pressure near the windward side of the intake fan, and this pressure difference causes the centrifugally separated dust to draw a spiral trajectory with the inner peripheral area of the hood cover facing the intake opening. However, it turns in a predetermined direction. Thereby, dust can be efficiently discharged outside through the auxiliary exhaust opening.

  In the electronic device according to claim 6 of the present invention, since the rotating shaft of the intake fan is provided with the swirl flow forming auxiliary protrusion extending toward the intake opening of the hood cover, the intake fan In the vicinity of the windward side, the swirl flow is spread outward in the radial direction by the swirl flow forming auxiliary protrusions and is formed around the swirl flow forming auxiliary protrusions. Thereby, the flow velocity in the rotational direction of the swirling flow can be increased near the windward side of the intake fan, and dust can be efficiently centrifuged.

  According to the electronic device of the seventh aspect of the present invention, the swirl flow forming auxiliary blade is provided on the rotating shaft of the intake fan, and the swirl flow forming auxiliary blade includes the intake opening of the hood cover, the intake fan, It is arrange | positioned rotatably between these. By rotating the swirl flow assisting blade, the flow velocity in the rotation direction of the swirl flow is increased in the inner peripheral area of the hood cover, and an air flow that flows toward the outside in the radial direction is generated. It can be centrifuged well.

  In the electronic device storage cabinet according to claim 8 of the present invention, since the hood cover is provided so as to surround the windward side of the intake fan, the intake fan is rotated by the rotation of the intake fan inside the hood cover. A swirling flow that flows from the opening toward the intake fan can be effectively formed. When the outside air for cooling is introduced into the hood cover through the intake opening, the dust is heavier than the outside air for cooling. Therefore, the dust contained in the outside air for cooling is centrifugally separated radially outward by the swirling flow. The dust thus centrifuged is swirled in a predetermined direction in the inner peripheral area of the hood cover by the swirling flow, and dust can be prevented from entering the inside of the cabinet body through the intake fan. In addition, the cooling outside air introduced into the hood cover through the air intake opening passes through the air intake fan without passing through the filter as in the conventional case, thus preventing a reduction in the air flow rate of the air intake fan. can do. Therefore, it is possible to provide an electronic device storage cabinet that can increase the cooling efficiency of the electronic device in the cabinet body and can prevent dust from entering the cabinet body.

  In the cooling device according to claim 9 of the present invention, since the hood cover is provided so as to surround the windward side of the intake fan, the intake opening portion is rotated by the rotation of the intake fan inside the hood cover. Thus, a swirling flow that flows toward the intake fan can be effectively formed. When the outside air for cooling is introduced into the hood cover through the intake opening, the dust is heavier than the outside air for cooling. Therefore, the dust contained in the outside air for cooling is centrifugally separated radially outward by the swirling flow. The dust thus centrifuged is swirled in a predetermined direction in the inner peripheral area of the hood cover by the swirling flow, and the dust is prevented from entering the inside of the electronic device or the inside of the electronic device storage cabinet through the intake fan. Can be prevented. In addition, the cooling outside air introduced into the hood cover through the air intake opening passes through the air intake fan without passing through the filter as in the conventional case, thus preventing a reduction in the air flow rate of the air intake fan. can do. Therefore, the cooling efficiency of the heat generating component in the electronic device or the electronic device in the electronic device storage cabinet can be increased, and dust can be prevented from entering the electronic device or the electronic device storage cabinet. A cooling device can be provided.

It is sectional drawing which shows the electronic device by the 1st Embodiment of this invention. It is sectional drawing which shows the cooling device of FIG. It is a disassembled perspective view of the cooling device of FIG. It is sectional drawing of the cooling device by the AA line in FIG. (A) is sectional drawing which shows the cooling device of the electronic device by the 2nd Embodiment of this invention, (b) is a front view which shows the hood cover of (a). (A) is sectional drawing which shows the cooling device of the electronic device by the 3rd Embodiment of this invention, (b) is a front view which shows the hood cover of (a). It is sectional drawing which shows the cooling device of the electronic device by the 4th Embodiment of this invention. It is sectional drawing which shows the cooling device of the electronic device by the 5th Embodiment of this invention. It is a perspective view which shows the electronic device storage cabinet by the 6th Embodiment of this invention. It is sectional drawing which shows the cooling device of FIG. It is sectional drawing which shows the conventional electronic device.

Hereinafter, various embodiments of an electronic device, an electronic device storage cabinet, and a cooling device used in the electronic device according to the present invention will be described with reference to the accompanying drawings.
[First Embodiment]
First, with reference to FIGS. 1-4, the electronic device of 1st Embodiment and the cooling device used for this are demonstrated. 1 is a cross-sectional view showing an electronic apparatus according to a first embodiment of the present invention, FIG. 2 is a cross-sectional view showing the cooling device of FIG. 1, and FIG. 3 is an exploded perspective view of the cooling device of FIG. FIG. 4 is a cross-sectional view of the cooling device taken along line AA in FIG.

  Referring to FIG. 1, an electronic device 2 according to the present embodiment is configured by a DVD recorder, for example, and includes a box-shaped housing 4. A plurality of circuit boards 6 and 8 are accommodated in the housing 4, and heating members 10 and 12 such as semiconductor devices are mounted on the circuit boards 6 and 8, respectively. In addition to the circuit boards 6 and 8, various electronic components (for example, an optical pickup lens used for an optical system that performs recording or reproduction on an optical disk) are housed in the housing 4. However, only the circuit boards 6 and 8 are shown in FIG. An intake port 16 is provided in the side wall portion 14 a of the housing 4, and a cooling device 18 for sending the outside air for cooling into the interior of the housing 4 is attached to the intake port 16. Further, the respective side wall portions 14a to 14d of the housing 4 are provided with exhaust ports 20a to 20d for exhausting the outside air for cooling sent into the housing 4 to the outside.

  The cooling device 18 includes an intake fan 22 and a hood cover 24 provided so as to surround the windward side of the intake fan 22 (that is, the front periphery of the intake fan 22 and a part of the front thereof). 2 and 3). The intake fan 22 is an axial flow fan. The intake fan 22 includes a housing 26 attached to the intake port 16 of the housing 4, an impeller 28 that is rotatably supported by the housing 26, and a drive motor 30 that rotationally drives the impeller 28. Have. The impeller 28 has a rotating shaft 32 and a plurality of blades 34 extending radially outward from the rotating shaft 32. A bullet-shaped swirl flow forming auxiliary projection 36 is fixedly supported on the rotating shaft 32 of the impeller 28. The swirl flow forming auxiliary projection 36 extends to the vicinity of the central portion in the axial direction of the hood cover 24 toward an intake opening 38 (described later) of the hood cover 24. In addition, the diameter of the swirl flow forming auxiliary projection 36 is substantially equal to the diameter of the rotating shaft 32 of the impeller 28. When the impeller 28 of the intake fan 22 rotates in a predetermined direction, the swirl flow forming auxiliary protrusion 36 is rotated integrally with the impeller 28.

  The hood cover 24 is detachably attached to the housing 26 of the intake fan 22. The hood cover 24 is configured in a cannonball shape, the distal end side is configured in a hemispherical shape, and the proximal end side is configured in a cylindrical shape. The front periphery of the intake fan 22 is surrounded by the base end side of the hood cover 24, and a part of the front of the intake fan 22 is surrounded by the front end side thereof. A circular intake opening 38 is provided at the tip of the hood cover 24. The intake opening 38 is opened in a direction substantially perpendicular to the axial direction of the intake fan 22 (that is, the rotational axis direction of the impeller 28), and its center is on an extension line of the axial line of the intake fan 22 (or its In the vicinity). A pair of auxiliary openings 40 a and 40 b (which constitute an auxiliary intake opening and an auxiliary exhaust opening) are provided around the intake opening 38 of the hood cover 24. These auxiliary openings 40a and 40b are each formed in a substantially rectangular shape, and are arranged substantially symmetrically up and down across the intake opening 38. The lower auxiliary opening 40b is provided with a dust collecting filter 42 (which constitutes a dust collecting means). Parts corresponding to the auxiliary openings 40 a and 40 b of the hood cover 24 are disposed outside the housing 4. The opening area of the intake opening 38 is configured to be smaller than the transverse area on the proximal end side of the hood cover 24. In the present embodiment, the auxiliary openings 40a and 40b are each formed in a substantially rectangular shape. However, the auxiliary openings 40a and 40b may be formed in, for example, a circular shape, an elliptical shape, an oval shape, or the like. .

  When the auxiliary openings 40a and 40b are arranged in the vicinity of the intake opening 38, the auxiliary openings 40a and 40b constitute auxiliary intake openings for introducing the cooling outside air into the hood cover 24, and the intake openings. In the case where it is disposed at a position that is largely separated from the portion 38, an auxiliary exhaust opening for discharging the air inside the hood cover 24 to the outside is formed. Further, when the auxiliary openings 40a and 40b are arranged in the middle of the two parts as in the present embodiment, the auxiliary openings 40a and 40b are both auxiliary intake openings and auxiliary exhaust openings. Will be configured.

  Next, the flow of the outside air for cooling in the electronic device 2 of the present embodiment will be described. When the intake fan 22 operates and the impeller 28 rotates in a predetermined direction, the cooling outside air is introduced into the hood cover 24 through the intake opening 38 and the auxiliary openings 40a and 40b. At this time, by the rotation of the impeller 28, a swirl flow that flows from the intake opening 38 toward the impeller 28 is formed inside the hood cover 24 (see FIGS. 2 and 4). By this swirling flow, the cooling outside air introduced from the intake opening 38 flows in a spiral direction in a predetermined direction from the intake opening 38 toward the impeller 28. At this time, in the vicinity of the windward side of the impeller 28, the swirl flow is spread outward in the radial direction by the swirl flow formation auxiliary protrusion 36 and is formed around the swirl flow formation auxiliary protrusion 36. Further, as described above, since the opening area of the intake opening 38 is configured to be smaller than the cross-sectional area on the proximal end side of the hood cover 24, the inner peripheral area of the hood cover 24 in the vicinity of the intake opening 38 is A separation flow area 44 is formed.

  When external dust (indicated by x in FIG. 1, FIG. 2 and FIG. 4) enters the inside of the hood cover 24 from the intake opening 38 together with the outside air for cooling, the dust is sucked while drawing a spiral trajectory by the swirling flow. It flows from the opening 38 toward the impeller 28. During the flow, the dust is centrifuged radially outward by the swirling flow. As described above, the swirl flow is pushed outwardly in the radial direction by the swirl flow forming auxiliary protrusion 36, whereby the flow velocity in the rotation direction of the swirl flow is increased in the vicinity of the windward side of the impeller 28. Thereby, the pressure in the vicinity of the windward side of the impeller 28 becomes larger than the pressure in the separated flow area 44. As a result of this pressure difference, the dust centrifuged as described above flows in the inner peripheral area of the hood cover 24 toward the auxiliary openings 40a and 40b while drawing a spiral trajectory in a predetermined direction. . The dust is swung in a predetermined direction in the inner peripheral area of the hood cover 24, and a part of the dust is discharged to the outside through the pair of auxiliary openings 40 a and 40 b of the hood cover 24. Dust discharged through the auxiliary opening 40 b below the hood cover 24 is collected by a dust collecting filter 42.

  Even when a part of the centrifuged dust remains in the hood cover 24, the dust is swung in a predetermined direction in the inner peripheral region of the hood cover 24. There is no effect on the passing air volume. When the operation of the intake fan 22 is stopped, the centrifugally separated dust accumulates inside the hood cover 24. However, this dust can be removed by removing the hood cover 24 from the housing 26 of the intake fan 22. . The hood cover 24 may be formed of a transparent material such as polycarbonate so that dust accumulated in the hood cover 24 can be confirmed from the outside.

  The clean cooling outside air from which dust has been removed as described above is sent into the housing 4 through the intake fan 22 and cools the heat generating components 10 and 12 of the circuit boards 6 and 8 while the inside of the housing 4 is inside. Will begin to flow. As a result, the pressure inside the housing 4 rises and a pressure difference between the inside and outside of the housing 4 is generated, so that the outside air for cooling in the housing 4 is discharged to the outside through the plurality of exhaust ports 20a to 20d ( (See FIG. 1). In this way, dust can be prevented from entering the inside of the housing 4, thereby preventing, for example, dust from adhering to the circuit boards 6 and 8 in the housing 4 and malfunctioning of the circuit boards 6 and 8. In addition, it is possible to prevent dust from adhering to an optical pickup lens (not shown) in the housing 4 to cause a malfunction in recording or reproduction with respect to the optical disc.

  In order to efficiently generate a swirling flow inside the hood cover 24, it is preferable that the hood cover 24 surrounds the windward side of the intake fan 22, that is, at least the front periphery of the intake fan 22. In order for the cooling outside air to flow efficiently inside the housing 4, the sum of the opening area of the intake opening 38 and the opening areas of the pair of auxiliary openings 40 a and 40 b is the opening area of the intake fan 22. It is preferable that they are substantially equal and substantially equal to the sum of the opening areas of the plurality of exhaust ports 20a to 20d.

In addition, when there is a portion in the housing 4 where the cooling effect is particularly desired to be enhanced, an exhaust fan (not shown) may be provided at a portion of the housing 4 corresponding to the portion. In such a case, the outside air for cooling introduced into the inside of the housing 4 through the intake fan 22 is discharged to the outside of the housing 4 through the plurality of exhaust ports 20a to 20d, and the outside of the housing 4 through the exhaust fan. Will be discharged. At this time, the passing air volume of the exhaust fan is such that the inside of the housing 4 becomes a positive pressure in a state where the intake fan 22 and the exhaust fan are operating (that is, the pressure inside the housing 4 is higher than the external pressure). It is preferable to set the size so that it becomes high.
[Second Embodiment]
Next, with reference to FIG. 5, the electronic device of 2nd Embodiment and the cooling device used for this are demonstrated. FIG. 5A is a cross-sectional view showing an electronic apparatus cooling apparatus according to the second embodiment of the present invention, and FIG. 5B is a front view showing the hood cover of FIG. In each of the embodiments described below, the same reference numerals are given to substantially the same components as those in the first embodiment, and the description thereof is omitted.

  In the cooling device 18A of the electronic apparatus 2A of the present embodiment, a cylindrical portion 46 having a circular cross section is provided in the intake opening 38A of the hood cover 24A. The cylindrical portion 46 extends toward the impeller 28 of the intake fan 22 and in the axial direction of the intake fan 22. By providing the cylindrical portion 46 as described above, the separation region 44 can be efficiently formed in the inner peripheral region of the hood cover 24A in the vicinity of the intake opening 38A. Further, a rectifying ring 48 that protrudes radially inward is provided on the inner peripheral surface of the hood cover 24A on the base end side. The opening area of the rectifying ring 48 is configured to gradually increase from the intake opening 38A side toward the impeller 28 side in accordance with the shape of the swirling flow. The inner peripheral edge of one end portion of the rectifying ring 48 (end portion on the intake opening 38A side) is configured as a square radius. A plurality of (four in the present embodiment) auxiliary openings 40A having a circular shape are provided around the intake opening 38A of the hood cover 24A at intervals in the circumferential direction (FIG. 5). (See (b)). Note that the dust collection filter of the first embodiment is not provided in the auxiliary opening 40A.

As in the first embodiment, when the intake fan 22 operates and the impeller 28 rotates in a predetermined direction, the cooling outside air is introduced into the hood cover 24A through the intake opening 38A and the plurality of auxiliary openings 40A. Is done. At this time, by the rotation of the impeller 28, a swirl flow that flows from the intake opening 38A toward the impeller 28 is formed inside the hood cover 24A. When external dust enters the inside of the hood cover 24A through the intake opening 38A together with the cooling outside air, the dust flows from the intake opening 38A toward the impeller 28 while drawing a spiral trajectory by the swirling flow. The dust centrifuged by the swirling flow is bounced back to the intake opening 38 </ b> A side at one end of the rectifying ring 48. The dust bounced in this way flows along the inner peripheral area of the hood cover 24A toward the auxiliary opening 40A while drawing a spiral trajectory by the separation flow of the separation flow area 44 formed in the inner peripheral area of the hood cover 24A. become. The dust is swung in a predetermined direction in the inner peripheral area of the hood cover 24A, and a part of the dust is discharged to the outside through the plurality of auxiliary openings 40A of the hood cover 24A.
[Third Embodiment]
Next, with reference to FIG. 6, the electronic device of 3rd Embodiment and the cooling device used for this are demonstrated. FIG. 6A is a cross-sectional view showing an electronic device cooling apparatus according to a third embodiment of the present invention, and FIG. 6B is a front view showing the hood cover of FIG.

In the cooling device 18B of the electronic apparatus 2B of the present embodiment, the length of the hood cover 24B in the axial direction is configured to be shorter than that of the first and second embodiments. Correspondingly, the axial length of the swirl flow forming auxiliary projection 36B is configured to be shorter than those in the first and second embodiments. By comprising in this way, the protrusion amount of the hood cover 24B from the side wall part 14a of the housing | casing 4 can be restrained small, and space saving of the electronic device 2B can be achieved. Further, around the intake opening 38B, a plurality of (eight in the present embodiment) auxiliary openings 40B are provided at intervals in the circumferential direction (see FIG. 6B). ). Therefore, also in this embodiment, the same effect as the first and second embodiments is achieved.
[Fourth Embodiment]
Next, with reference to FIG. 7, the electronic device of 4th Embodiment and the cooling device used for this are demonstrated. FIG. 7 is a cross-sectional view illustrating a cooling device for an electronic device according to a fourth embodiment of the present invention.

  In the cooling device 18C of the electronic device 2C of the present embodiment, the hood cover 24C is configured in a cap shape having a circular cross section, and an intake opening 38C is provided at one end thereof. Around the intake opening 38C of the hood cover 24C, a plurality of auxiliary openings 40C configured in a circular shape are provided. The intake fan 22C is a centrifugal fan (a so-called sirocco fan). The intake fan 22C includes a housing 26C attached to the intake port 16 of the housing 4, an impeller 28C rotatably supported by the housing 26C, and a drive motor (not shown) for rotationally driving the impeller 28C. ) And. The impeller 28C includes a rotating shaft 32C and a plurality of blades 34C provided at intervals in the circumferential direction outside the rotating shaft 32C. A swirl flow forming auxiliary blade 52 is fixedly supported on the rotating shaft 32C of the impeller 28C via a support shaft 50. The swirl flow forming auxiliary blade 52 is connected to the intake opening 38C of the hood cover 24C, the impeller 28C, and the like. Between the two. The swirl flow forming auxiliary blade 52 is composed of one rectangular plate. The longitudinal direction of the swirl flow forming auxiliary blade 52 extends substantially symmetrically outward (ie, substantially perpendicular to the axial direction of the intake fan 22C) about the support shaft 50, and the width direction thereof is It extends substantially parallel to the axial direction of the intake fan 22C. A rectangular opening 54 is provided in the central portion of the swirl flow forming auxiliary blade 52, whereby the swirl flow forming auxiliary blade 52 is formed in a square shape as a whole. With this configuration, it is possible to suppress the influence of the passing air amount of the swirl flow forming auxiliary blade 52 on the passing air amount of the impeller 28C of the intake fan 22C. When the impeller 28C of the intake fan 22C rotates in a predetermined direction, the swirl flow forming auxiliary blade 52 is rotated integrally with the impeller 28C.

  When the intake fan 22C is operated and the impeller 28C rotates in a predetermined direction, the outside air for cooling is introduced into the hood cover 24C through the intake opening 38C and the plurality of auxiliary openings 40C. At this time, by the rotation of the impeller 28C and the rotation of the swirl flow forming auxiliary blade 52, a swirl flow that flows from the intake opening 38C toward the impeller 28C is formed inside the hood cover 24C. At this time, by the rotation of the swirl flow forming auxiliary blade 52, the flow velocity in the rotation direction of the swirl flow is increased in the inner peripheral region of the hood cover 24C, and an air flow flowing radially outward is generated. When external dust enters the inside of the hood cover 24C from the intake opening 38C together with the cooling outside air, the dust flows from the intake opening 38C toward the impeller 28C while drawing a spiral trajectory by the swirl flow. During the flow, the dust is centrifuged radially outward by the swirling flow and the airflow flowing outward in the radial direction described above, and is further separated by the separation flow region 44C formed in the inner peripheral region of the hood cover 24C. The hood cover 24C flows toward the auxiliary opening 40C while drawing a spiral trajectory. The dust is swung in a predetermined direction in the inner peripheral area of the hood cover 24C, and a part of the dust is discharged outside through the plurality of auxiliary openings 40C of the hood cover 24C.

In this embodiment, the swirl flow forming auxiliary blade 52 is configured in a square shape, but may be configured in, for example, a U shape, and may be configured in an appropriate shape. Further, the swirl flow forming auxiliary blade 52 may be configured by combining, for example, a plurality of rectangular plates.
[Fifth Embodiment]
Next, with reference to FIG. 8, the electronic device of 5th Embodiment and the cooling device used for this are demonstrated. FIG. 8 is a cross-sectional view illustrating a cooling device for an electronic device according to a fifth embodiment of the present invention.

  In the cooling device 18D of the electronic device 2D of the present embodiment, the hood cover 24D is configured in a cap shape having a circular cross section, and an intake opening 38D is provided at the tip thereof. A plurality of auxiliary openings 40D configured in a circular shape are provided around the intake opening 38D of the hood cover 24D. The intake fan 22D is an axial flow fan. A swirl flow forming auxiliary blade 52D is fixedly supported on the rotating shaft 32D of the impeller 28D via a support shaft 50D. The swirl flow forming auxiliary blade 52D is connected to the intake opening 38D of the hood cover 24D, the impeller 28D, and the like. Between the two. The swirl flow forming auxiliary blade 52D is composed of a single plate, and the shape thereof is formed so that the width gradually decreases outward from the support shaft 50D in the radial direction (a so-called mountain shape). The longitudinal direction of the swirl flow forming auxiliary blade 52D extends approximately symmetrically outward in the radial direction about the support shaft 50D (ie, substantially perpendicular to the axial direction of the intake fan 22D), and its width direction is It extends substantially parallel to the axial direction of the intake fan 22D.

Also in the present embodiment, as in the fourth embodiment, the rotation speed of the swirling flow in the inner peripheral region of the hood cover 24D is increased by the rotation of the swirling flow forming auxiliary blade 52D, and the radially outer side is increased. The airflow that flows toward
[Sixth Embodiment]
Next, with reference to FIG.9 and FIG.10, the electronic device storage cabinet of 6th Embodiment and the cooling device used for this are demonstrated. FIG. 9 is a perspective view showing an electronic device storage cabinet according to the sixth embodiment of the present invention, and FIG. 10 is a cross-sectional view showing the cooling device of FIG.

  The electronic device storage cabinet 112 of this embodiment includes a box-shaped cabinet body 114. For example, a server 116 (which constitutes an electronic device) is housed inside the cabinet body 114, and thus the server 116 used in a dusty environment is protected from dust. An opening 118 is provided on the front surface of the cabinet body 114, and a door member 120 is attached to the opening 118 so as to be freely opened and closed. The door member 120 is provided with a transparent glass window 121 so that the inside of the cabinet body 114 can be seen from the outside. By opening and closing the door member 120, the server 116 can be taken in and out of the cabinet body 114. An air inlet 124 is provided in the side wall 122 of the cabinet body 114, and a cooling device 18 </ b> E for sending cooling outside air into the cabinet body 114 is attached to the air inlet 124. Further, the side wall 122 of the cabinet body 114 is provided with a plurality of exhaust ports 126 for exhausting the cooling outside air sent into the cabinet body 114 to the outside.

  The hood cover 24D of the cooling device 18E is configured in substantially the same manner as in the fifth embodiment. A bullet-shaped swirl flow forming auxiliary projection 36E is fixedly supported on the rotation shaft 32E of the impeller 28E. Further, a pair of swirl flow forming auxiliary blades 52E extending substantially symmetrically outward in the radial direction is attached to the outer peripheral portion of the swirl flow forming auxiliary protrusion 36E. Each swirl flow forming auxiliary blade 52E is configured in an L-shaped plate shape. When the impeller 28E of the intake fan 22E rotates in a predetermined direction, the swirl flow formation assisting protrusion 36E and the pair of swirl flow formation assist blades 52E are respectively rotated integrally with the impeller 28E.

  In the cooling device 18E of this embodiment, when external dust enters the inside of the hood cover 24D from the intake opening 38D together with the cooling outside air, the dust draws a spiral trajectory by the swirling flow, as in the above embodiments. However, the air flows from the intake opening 38D toward the impeller 28E. During the flow, the dust is centrifuged radially outward by the swirling flow. Further, the swirling flow is pushed outwardly in the radial direction by the swirling flow forming auxiliary projection 36E, whereby the flow velocity in the rotating direction of the swirling flow is increased in the vicinity of the windward side of the impeller 28. Further, by the rotation of the pair of swirl flow forming auxiliary blades 52E, in the inner peripheral region of the hood cover 24D, the flow velocity in the rotation direction of the swirl flow is increased, and an air flow that flows outward in the radial direction is generated. In this manner, dust can be more effectively centrifuged by attaching the pair of swirl flow forming auxiliary blades 52E to the swirl flow forming auxiliary protrusions 36E.

  The clean cooling outside air from which dust has been removed by centrifugation as described above is sent into the cabinet body 114 through the intake fan 22E and flows through the cabinet body 114 while cooling the server 116. As a result, the pressure inside the cabinet body 114 rises and a pressure difference between the inside and outside of the cabinet body 114 is generated, so that the cooling outside air inside the cabinet body 114 is discharged to the outside through the plurality of exhaust ports 126.

  In addition to the server 116, the electronic device housed in the cabinet body 114 can be configured from various electronic devices such as a personal computer, a monitor, a router, and a HUB.

  As mentioned above, although various embodiment of the electronic device according to this invention, the electronic device storage cabinet, and the cooling device used for these was described, this invention is not limited to this embodiment, and deviates from the scope of the present invention. Various modifications or corrections are possible.

  In the first to third embodiments, the swirl flow forming auxiliary protrusion 36 is provided on the rotating shaft 32 of the impeller 28. However, the swirl flow forming auxiliary protrusion 36 may be omitted. Even in such a case, a swirl flow is formed inside the hood cover 24 (24A) (24B) by the rotation of the intake fan 22.

  In each of the above embodiments, the electronic device 2 (2A to 2D) is configured from a DVD recorder, but can be configured from various electronic devices such as an audio player, a personal computer, an air conditioner, a fan heater, and a television.

  In the above embodiments, the hood cover 24 (24A to 24D) is detachably attached to the housing 26 (26C) of the intake fan 22 (22C) (22D) (22E). (24A to 24D) and the housing 26 (26C) of the intake fan 22 (22C) (22D) (22E) may be integrally configured.

  Moreover, in each said embodiment, although comprised so that the cooling device 18 (18A-18E) might be laterally arranged, you may comprise so that it may arrange | position vertically. In each of the above embodiments, one cooling device 18 (18A to 18E) is provided for one electronic device 2 (2A to 2D) and the electronic device storage cabinet 112, but a plurality of cooling devices 18 are provided. (18A-18E) may be provided.

  In addition, the temperature in the casing of the electronic device (or in the cabinet body of the electronic device storage cabinet) is easily affected by the ambient temperature of the electronic device (or electronic device storage cabinet), and increases in the summer and decreases in the winter. There is a tendency. Therefore, a temperature detection sensor for detecting the ambient temperature of the electronic device (or electronic device storage cabinet) and a rotation speed control means for controlling the rotation speed of the intake fan based on the temperature detected by the temperature detection sensor are provided. You may do it. By this speed control means, the intake fan speed can be set higher in the summer and the intake fan speed can be set lower in the winter, thereby efficiently setting the intake fan speed and saving. Electricity can be achieved.

2, 2A to 2D, 100 Electronic equipment 4, 102 Case 10, 12, 106 Heat-generating component 18, 18A to 18E Cooling device 20a, 20b, 20c, 20d, 126 Exhaust port 22, 22C, 22D, 22E Intake fan 24, 24A-24D Hood cover 32, 32C, 32D, 32E Rotating shaft 36, 36B Swirling flow forming auxiliary projection 38, 38A-38D Inlet opening 40a, 40b, 40A-40D Auxiliary opening 42 Dust collecting filter 46, 46B Cylindrical parts 52, 52D Swirling flow forming auxiliary blade 112 Electronic equipment storage cabinet 114 Cabinet body 116 Server

Claims (9)

A housing, a heat generating component housed in the housing, and a cooling device for cooling the heat generating component by sending cooling outside air into the housing, An electronic device provided with an exhaust port for discharging outside air for cooling sent into the outside,
The cooling device includes an intake fan for sending outside air for cooling into the housing, and a hood cover provided so as to surround a windward side of the intake fan, and the hood cover includes an intake air An opening is provided, and a swirl flow that flows from the intake opening toward the intake fan is formed inside the hood cover by the rotation of the intake fan.
When cooling outside air is introduced into the hood cover through the intake opening, dust contained in the cooling outside air is centrifuged radially outward by the swirl flow formed by the rotation of the intake fan. An electronic device characterized by that.   The intake opening is opened in a direction substantially perpendicular to the axial direction of the intake fan, and around the intake opening of the hood cover, cooling air is introduced into the hood cover. The electronic device according to claim 1, wherein an auxiliary exhaust opening for exhausting air inside the auxiliary intake opening and / or the hood cover to the outside is provided.   3. The electronic apparatus according to claim 2, wherein the auxiliary exhaust opening is provided with dust collecting means for collecting dust discharged to the outside through the auxiliary exhaust opening.   4. The electronic device according to claim 2, wherein a portion of the hood cover corresponding to the auxiliary exhaust opening is disposed outside the housing. 5.   The cylindrical portion that extends toward the intake fan and in the axial direction of the intake fan is provided in the intake opening of the hood cover. Electronics.   6. The electronic apparatus according to claim 1, wherein a rotating flow forming auxiliary protrusion that extends toward the intake opening of the hood cover is provided on a rotation shaft of the intake fan. .   A swirl flow forming auxiliary blade is provided on the rotation shaft of the intake fan, and the swirl flow forming auxiliary blade is rotatably disposed between the intake opening of the hood cover and the intake fan. The electronic device according to claim 1, wherein: An electronic device storage cabinet for storing electronic devices,
A cabinet body in which the electronic device is housed, and a cooling device for cooling the electronic device by sending cooling air into the cabinet body, the cabinet body being fed into the cabinet body. There is an exhaust port for discharging the outside air for cooling to the outside,
The cooling device includes an intake fan for sending outside air for cooling into the cabinet body, and a hood cover provided so as to surround a windward side of the intake fan, and the hood cover includes an intake air An opening is provided, and a swirl flow that flows from the intake opening toward the intake fan is formed inside the hood cover by the rotation of the intake fan.
When cooling outside air is introduced into the hood cover through the intake opening, dust contained in the cooling outside air is centrifuged radially outward by the swirl flow formed by the rotation of the intake fan. An electronic equipment storage cabinet characterized by that. The electronic device or the electronic device housed in the electronic device housing cabinet by sending the outside air for cooling into the electronic device or an electronic device housing cabinet for housing the electronic device or the electronic device housed in the electronic device housing cabinet A cooling device for cooling
An intake fan, and a hood cover provided so as to surround a windward side of the intake fan. The hood cover is provided with an intake opening, and the intake fan is rotated from the intake opening by rotation thereof. It is configured to form a swirling flow that flows toward the intake fan,
When cooling outside air is introduced into the hood cover through the intake opening, dust contained in the cooling outside air is centrifuged radially outward by the swirl flow formed by the rotation of the intake fan. A cooling device characterized by that.

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