KR100550142B1 - Apparatus for radiating heat in vacuum cleaner - Google Patents

Abstract

The present invention relates to a vacuum cleaner heat dissipation device, which minimizes the influence on the existing main air flow path running toward the motor along the direction of the central axis. The inlet pipe is formed so that the air introduced from the outside is first delivered to the heating element according to the predetermined bypass flow path, and then proceeds toward the existing main air flow path. The heat dissipation effect of the heating element, which is the heating source, is maximized while minimizing the resistance loss and the suction rate.

Heat dissipation, flow path, bypass, motor, air, cooling

Description

Apparatus for radiating heat in vacuum cleaner}

1 is a cross-sectional view showing a general vacuum cleaner radiator,

2 is an exploded perspective view of a vacuum cleaner heat dissipation device of the present invention;

3a to 3b is a first embodiment of the flow passage providing housing used in the present invention,

4a to 4b is a second embodiment of the flow passage providing housing used in the present invention,

5 is a cross-sectional view for explaining the principle of operation of the present invention;

6 is a view showing a second embodiment of the vacuum cleaner heat dissipation device of the present invention.

Explanation of symbols on the main parts of the drawings

200: printed circuit board 210: heating element

220: motor 230: heat sink

240: Euro providing housing 250: sealing member

The present invention can maximize the heat dissipation effect of the heat generated from the heating element attached to the printed circuit board to the maximum while minimizing the resistance loss and suction rate for the existing main flow path that proceeds toward the motor along the central axis direction. To a vacuum cleaner heat dissipation device.

In general, a vacuum cleaner uses a predetermined printed circuit board and various heating elements attached thereto to control various kinds of motors and drives to suck out dust present in the indoor floor, filter the dust, and return clean air to the room. As a product for evacuating, heat dissipation of heat generated from such a motor or a heating element attached to a printed circuit board to the outside is an important problem in a vacuum cleaner. FIG. 1 shows a heat dissipation device mainly used in such a vacuum cleaner. to be.

As shown in Figure 1, the conventional vacuum cleaner heat dissipation device, when the motor 100 is rotated, the flow path is generated by the air is sucked toward the motor 100 by the fan, through the flow path generated Air passes through the inlet of the housing 110, through the inlet formed in the center of the heat sink 120 and the motor, and passes through the inside of the impeller and the guide vane to be exhausted to the outside. The element 130 is attached to the printed circuit board 140 and the heat sink 120 closely contacted with the element 130 receives heat generated from the heat generating element 130 according to the driving of the motor to radiate heat.

However, such a conventional heat dissipation device cools the heat generated by the heat generating element only by natural convection since air drawn by the fan and directed through the predetermined flow path does not pass through the heat generating element as the heat generating source. As a result, the heat generated from the heating element is not properly dissipated, resulting in a problem of lowering the thermal reliability of the system.

 Accordingly, the present invention was developed to solve the above-mentioned problems, the vacuum cleaner heat dissipation device is attached to the printed circuit board to increase the heat dissipation effect of the heat generating element that generates heat during operation to improve the thermal reliability of the system, The purpose is to provide.

According to this object, the present invention is to pattern the number of sub-air inlet corresponding to the number of the heating element on the edge of the upper surface of the flow path housing housing to minimize the effect on the existing main flow path that proceeds toward the motor along the central axis direction In this way, by introducing air into the heat dissipation device, a predetermined bypass flow path is formed in addition to the existing main flow path to generate forced convection, thereby minimizing the loss and suction rate of the existing main flow path while generating heat. To maximize the heat dissipation effect of the source heating element.

To this end, the present invention, the through-hole and the receiving port of the predetermined size is formed along the central axis, each of which is bonded to each other through the sealing member, the printed circuit board and the motor portion, the air transfer port is formed in the center and attached to the printed circuit board In the vacuum cleaner heat dissipation device consisting of a heat sink for housing the printed circuit board and the motor unit in close contact with the heat generating element of a predetermined path providing housing for packaging the heat sink;

The flow passage providing housing;

An air inlet is formed in the center of the upper surface to provide a main air passage along the direction of the central axis passing through the through-hole and the receiving opening, and an air inlet pipe is formed at the edge of the upper surface to pass through the heating element to the main air passage. Disclosed is a vacuum cleaner heat dissipation device characterized by providing a predetermined bypass flow path.

In addition, in the present invention, it is preferable that a plurality of bypass flow paths are generated by forming a plurality of hole sizes of the air inlet pipe smaller than that of the main air inlet and the number corresponding to the number of heating elements. It is desirable to limit the number and size of the bypass flow path within a range that minimizes the effect on the main air flow path.

In addition, a flow path providing housing suitable for the heat dissipation device of the present invention, the first housing body having the upper and lower openings; Disclosed is a first aspect of the present invention, which comprises a predetermined first cover which is press-fitted with an outer circumferential surface of the first housing body so as to be rotatable in a circumferential direction so that the air inlet pipe can be positioned at a position corresponding to the position of the heating element.

In addition, a second housing body having a cylindrical shape having an upper end and a lower end opened, and having a circular groove on an upper end thereof; Disclosed is a second aspect of the present invention, wherein the main air inlet part and the sub air inlet part are respectively formed at the center and the edge thereof, and each second cover comprises a predetermined second cover having a circular protrusion along the edge to be press-fitted into the groove formed in the second housing body.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

First, the vacuum cleaner radiator of the present invention will be described with reference to FIG. 2.

2 is an exploded perspective view of the heat dissipation device according to the present invention. As shown in FIG. 2, through-holes and receiving holes having a predetermined size are formed along the central axis, respectively, and are bonded to each other through the sealing member 250 ( 200 and the motor unit 220, the transmission port is formed in the center housing the printed circuit board 200 and the motor unit 220 in close contact with the predetermined heating element 210 attached to the printed circuit board 200. In the vacuum cleaner heat dissipation device consisting of a heat dissipation plate 230 and a predetermined flow path providing housing for packaging the heat sink 230, the flow path providing housing 240; An air inlet is formed in the center of the upper surface to provide a main air flow path along the central axis passing through the through-hole and the receiving port, and an air inlet tube is inserted into the upper surface of the upper surface to pass through the upper portion of the heating element. It has a structure that provides a predetermined bypass flow path directed to the flow path.

In the vacuum cleaner heat dissipation device of the present invention, the receiving motor is formed in the center of the upper end of the impeller cover combined with the predetermined housing that is packaged as a whole of the lower end of the vacuum cleaner, the predetermined sealing member ( A through hole is formed in the center of the circular printed circuit board 200 bonded to the impeller cover through 250, and at least one heat generating element 210, which is a heat source, is attached to an edge thereof.

In addition, the heat dissipation plate 230 has a cylindrical shape with an open lower end, and is closely adhered to the heating element 210 attached to one side of the printed circuit board 200 to connect the printed circuit board 200 and the motor unit 220. The center of the upper surface is formed with a predetermined air transfer port having a size corresponding to the size of the through hole so that air introduced from the outside can be delivered to the through hole of the printed circuit board 200.

On the other hand, the flow path providing housing 240 according to the present invention, the lower surface is opened and bonded or bonded to the heat sink 230 or is housed, the main air flow path of a predetermined size is formed in the center of the upper surface air is introduced from the outside It passes through the through hole of the printed circuit board 200 through the air transfer hole of the heat dissipation plate 230 along a predetermined main air flow path that passes through the central axis, and is transferred to the air receiving hole of the motor unit 200.

In particular, the air inlet pipe is formed at the edge of the upper surface and the air introduced from the outside, the heating element 210 attached to the printed circuit board 200 through the heat sink 230 in accordance with a predetermined bypass flow path After passing through the air delivery port and the through hole of the printed circuit board 200 and toward the receiving port of the motor unit 220, unlike the conventional cooling the heating element only by natural convection, it is forced through the forced By being able to cool by convection it is possible to further improve the heat dissipation effect of the heat generating element 210, a detailed description of the operation principle will be described later.

In addition, the present invention, if possible, to make the hole size of the air inlet pipe used smaller than that of the main air inlet, the number is formed by a number corresponding to the number of the heating element to generate a plurality of bypass flow paths In this case, since the bypass flow path affects the flow of the main air flow path, it is preferable to limit the number and size within the range of minimizing the effect, which does not depart from the technical spirit of the present invention. Many variations are possible.

As described above, the heat dissipation device according to the present invention allows the air introduced into the main air inlet formed in the center of the predetermined flow path providing housing to be delivered to the motor along a predetermined main air flow path running in the direction of the central axis, and at the edge of the flow providing housing. The air introduced into the predetermined air inlet pipe is first delivered to the heating element attached to the printed circuit board according to the bypass flow path, and then proceeds toward the main air flow path. It maximizes the heat dissipation effect with minimal effect on the resistance loss and suction rate for the air channel.

Next, a first preferred embodiment of the flow passage providing housing used in the present invention will be described sequentially with reference to FIGS. 3A and 3B.

First Embodiment

3A is an exploded perspective view of the flow passage providing housing according to the first embodiment, and FIG. 3B is a cross-sectional view of the coupling. As shown in the drawing, the first embodiment of the flow passage providing housing according to the present invention includes an upper surface and a lower portion. A cylindrical first housing body 241 having an open surface, a main air inlet A at the center of the upper surface thereof, and an air inlet tube B at the edge thereof are respectively formed so as to be rotatable in the circumferential direction. It consists of a predetermined first cover 242 is press-fit and coupled to the outer peripheral surface of the 241.

Thus, the flow passage providing housing is configured to manually adjust the position of the first cover 242 so that the air inlet pipe B is positioned toward the heat generating element, and then pressurize the first cover when the adjustment is completed. 242 is press-fitted so as to be coupled to the outer circumferential surface of the first housing body 241, and if fine adjustment is required, the first cover 242 is rotated in the circumferential direction so as to be adjusted to the corresponding position, thereby to the position of the heating element. Accordingly, the air inlet pipe (B) can be variably positioned correspondingly, and more accurate position adjustment is possible.

Subsequently, a second preferred embodiment of the flow path providing housing used in the present invention will be described sequentially with reference to Figs. 4A and 4B.

Second Embodiment

Figure 4a is an exploded perspective view of the flow path providing housing according to the first embodiment, Figure 4b is a coupling diagram, as shown, the second embodiment of the flow path providing housing according to the present invention, the upper surface and the lower surface The open cylindrical shape, the second housing body 243, the circular groove (E) is formed on the upper surface, the main air inlet (C) and the air inlet pipe (D) are formed through the center and the edge, respectively; 2 consists of a predetermined second cover 244 formed with a circular protrusion along the edge to be pressed into the groove (E) formed in the housing body (243).

The flow path providing housing according to the second embodiment of the present invention, the main air inlet portion (A) and the air inlet pipe (B) are respectively formed through the center and the upper surface of the upper surface, and the projections in the circumferential direction along the edge After adjusting the second cover 243 formed for the present invention so that the air inlet pipe (D) is disposed at a position corresponding to the position of the heating element, the upper end of the second housing body 243 with the upper and lower surfaces opened The second housing body 243 and the second cover 244 are coupled to each other by press-fitting into the recess E formed in a circular shape. Hereinafter, the operating principle of the present invention will be described with reference to FIG. 5.

As shown in FIG. 5, when the air is introduced into an air inlet formed at the center of a predetermined flow path providing housing 240, the air introduced therein is driven through the main air path along a central axis. And the air introduced from the outside through the air inlet pipe is delivered to the heating element 210 through the heat dissipation plate 230 according to a predetermined bypass flow path provided according to the present invention. It is transmitted to the inlet side of the motor unit 220 through, the forced convection generated through it to increase the heat transfer coefficient (h) according to the following equation (1) to improve the heat transfer amount (Q) can be expected large heat dissipation effect do.

Q = h × A × △ T

In Equation 1

Q: Heat transfer amount (heat transfer from high temperature object to air)

h: heat transfer coefficient

A: Heat dissipation area (hot object surface area)

ΔT: The temperature difference between the hot object and the ambient air is shown. Wherein the heat transfer coefficient (h) is dependent on the heat transfer passage or flow and flow rate, and the passage or flow is initiated in a suitable form or if the flow rate is large, the heat transfer coefficient (h) is increased to increase the heat transfer amount (Q), the present invention As shown in Equation 1, by increasing the heat transfer path or flow and flow rate through forced convection to increase the heat transfer coefficient (h) to further increase the heat transfer amount (Q) it is possible to improve the heat dissipation effect.

At this time, as much as possible, it is preferable that the hole size of the used air inlet pipe is made smaller than that of the main air inlet port, and the number of the plurality of bypass flow paths is generated by the number corresponding to the number of heating elements. However, at this time, since the bypass flow path affects the flow of the main air flow path, it is desirable to limit the number and size within the range of minimizing the effect.

Finally, a second embodiment of the present invention will be described with reference to FIG.

As shown in FIG. 6, the second embodiment of the present invention allows a plurality of air inlet pipes to be formed in the flow passage providing housing, that is, the flow passage providing housing 240 according to the second embodiment of the present invention is provided from the outside. The main air inlet is formed at the center so that the introduced air is directly transferred to the motor 220, and the heat generating element is indirectly transferred to the heat generating element 210 attached to the printed circuit board 200 through the heat sink 230. To form a plurality of air inlet tube to be inserted into the edge of the upper end in advance so that the air inlet tube is disposed in each of the corresponding region in which the 210 is located, it is variable in various applications according to the number of heating elements 210 In this case, the sub air inlet portion used in the present invention and the number thereof may vary as long as they do not depart from the technical spirit of the present invention. Modifications are possible.

As described above in detail, the vacuum cleaner heat dissipation device according to the present invention is provided with a number of heating elements at the edge of the upper surface of the passage providing housing to minimize the influence on the existing main air flow path proceeding toward the motor along the central axis direction. By forming a corresponding number of air intake pipes to be inserted into the interior, the air introduced from the outside is first delivered to the heating element according to the predetermined bypass flow path and then proceeds toward the existing main air flow path, Forced convection has the effect of maximizing the heat dissipation effect of the heating element, which is the heating source, with minimal effect on the resistance loss and suction rate of the existing main air flow path.

Although the invention has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

Claims (4)

Through-holes and receiving holes of a predetermined size are formed in accordance with the direction of the central axis, the printed circuit board, the motor unit, and the air transfer port are formed in the center and bonded to each other through the sealing member, and the predetermined heating element attached to the printed circuit board; A vacuum cleaner heat dissipation device comprising a heat dissipation plate housing a printed circuit board and a motor unit closely and a predetermined flow path providing housing for packaging the heat dissipation plate, The flow passage providing housing; An air inlet is formed in the center of the upper surface to provide a main air passage along the direction of the central axis passing through the through-hole and the receiving opening, and an air inlet pipe is inserted into the upper surface of the upper surface to pass through the upper portion of the heating element. A vacuum cleaner heat dissipating device, characterized in that it also provides a predetermined bypass flow path to the. According to claim 1, The air suction pipe; A vacuum cleaner radiator, characterized in that a plurality formed in a predetermined number corresponding to the number of heating elements. According to claim 1, The flow path housing is; A first housing body having upper and lower portions opened; Vacuum cleaner heat dissipation, characterized in that consisting of a predetermined first cover to press-fit the outer peripheral surface of the first housing body so as to rotate in the circumferential direction to position the air suction pipe at a position corresponding to the position of the heating element Device. According to claim 1, The flow path housing is; A second housing body having a cylindrical shape having an upper end portion and a lower end portion, the upper end portion having a circular groove; The vacuum cleaner heat dissipation device, characterized in that consisting of a predetermined second cover formed with a circular protrusion along the edge to be pressed into the groove formed in the second housing body.

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