DE102005026423B4 - Heat dissipating device - Google Patents

Abstract

A heat dissipating device comprising: a housing having at least one air inlet (221) and at least one air outlet (212), and a rotor (25) disposed in the housing, the housing having a first frame (21), which houses a drive device (23) for the rotor (25) and a second frame (22) which is connected to the first frame (21), which includes the air inlet (221) and a side wall (222) extending from extends down an inner edge of the air inlet (221) and divides a space into an air collection chamber (26) and a space portion for the rotor (25), the air flow from the chamber of the air collection (26) via the air outlet (212). wherein the second frame (22) has a first extending part (31) formed on an inner side thereof and extending along an axial direction of the first frame (21) of the heat dissipating device to extend axially compressed air passage in the housing, and wherein the height of the axially compressed passage is changed depending on the first extending part without changing an external height of the housing, wherein the axially extending depth of an extending portion (226) gradually from the air outlet ( 212) to a position far from the air outlet (212).

Description

FIELD OF THE INVENTION

The present invention is a continuation-in-part application of parent application serial number 10 / 848,074 filed May 19, 2004. The present invention relates to a heat dissipating device, and more particularly to a high pressure centrifugal fan having an axially compressed air passage.

DESCRIPTION OF THE PRIOR ART

In closes a conventional fan 1 a frame 10 , a motor 11 , an impeller 12 and a cover 13 one. The frame 10 closes an opening 101 as an air outlet and the cover 13 has a circular opening 131 as an air intake. The path from the air inlet to the air outlet is an air flow passage. The engine 11 is on a basic element 102 of the frame 10 arranged to the impeller 12 drive. The fan wheel 12 closes a hub 121 , an annular plate 122 and a variety of blades 123 one on the upper side and the lower side of the annular plate 122 are arranged and around the hub 121 are arranged.

However, this conventional blower employs an array of radially compressed air passages, as in FIG 4, wherein the width of the air flow passage formed in the frame varies from the narrowest width W1 at the location A to the maximum width W2 at the air outlet 101 changes. Therefore, the sucked air flow at location A is compressed and then to the air outlet 101 guided along the direction of the arrow R. However, because the height of the air passage in the axial direction is identical, it is impossible to compress the air flow in the axial direction.

The EP 11 78 215 A2 discloses a centrifugal fan having a plurality of blades comprising a screw chamber. The auger chamber is gradually expanded in cross-section from the extension part of the auger housing to the air outlet point. Part of the kinetic energy imparted to the air drawn from the suction point into the interior of the screw housing by the means of the fan is converted to a static pressure.

The EP 08 46 868 A2 discloses a centrifugal fan having a volute which extends axially asymmetrically with an upper end wall which is flattened to facilitate installation and includes a spiral lower end wall.

The DE 22 23 066 A discloses a blower unit with a blower housing as in the axial direction of the fan worm-shaped widening spiral housing whose air collecting space surrounds the drive motor at least partially.

The US 61 79 561 B1 discloses a heat rejection fan having a housing, a stator seat, an impeller, and a cover plate. The housing has a chamber for receiving the impeller, and a bottom wall defining the chamber has an axle tube formed thereon. The housing further has an air outlet formed at its foot rim and communicating with the chamber. The impeller has a number of vanes and an axle rotatably received in the axle tube.

The US 51 88 508 A discloses a closed radial fan and impeller comprising upper and lower housing halves. The centrifugal fan draws air along a rotor hub containing a motor and then passes the air along a flow channel.

The US 59 82 064 A discloses a DC motor with radiator and housing connected together. The height of the combination is uniform. The air passages are between the housing and a support member to establish an exchange between the exterior and the interior of the housing. The air passages have a uniform height.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a heat dissipating device with an axially compressed air passage, which makes it possible to compress the air flow in the axial direction and thus to increase the performance of the heat dissipating device. This object is achieved by the device in claim 1.

Another object of the present invention is to provide a heat dissipating apparatus which uses an axially compressed air passage to allow the air flow to flow smoothly in the air passage in the frame thereof to increase its performance.

According to the present invention, the heat dissipating device includes a housing having at least one air inlet and at least one air outlet, and a rotor disposed in the housing, the housing having a first extending portion extending along an axial direction the heat dissipating device extends to an axial compressed air flow passage in the housing to form.

Preferably, an axially extending depth of the first extending part is gradually increased from the air outlet to a position far from the air outlet.

The housing further includes a second extending portion extending axially corresponding to the first extending portion to form a two-sided axially compressed air passageway in the housing. An axially extending depth of the second extending part is gradually increased from the air outlet to a position far from the air outlet. Preferably, an axially extending depth of the first or second extending portion is gradually reduced to become near zero near the air outlet.

Alternatively, the first and second extending parts are formed in a mirror-image configuration in the axial direction. Preferably, the housing further comprises a radially compressed air passage within the housing.

On the other hand, the rotor comprises a base member, a hub, a first set of blades and a second set of blades. The first set of blades extends from an edge of the hub to a surface of the base member and the second set of blades is disposed on the base member. The base member, the hub, the first and second sets of blades may be integrally formed as a single unit.

In addition, the housing further includes a first frame for receiving the rotor therein, and a second frame connected to the first frame, provided with the air inlet and having a side wall extending from an edge of the air inlet to one Determine chamber for air collection in the housing. The side wall has a flange extending radially from one end thereof to define an inlet of the chamber for air collection, each of the blades having an end extending to the entrance of the chamber for air collection to the air flow into the chamber for To lead air collection. The air collection chamber partially or completely overlaps an air passage through the rotor along an axis of the heat dissipating device in height.

The second frame further includes a plurality of air guiding elements disposed along the sidewall to increase a fan pressure of airflow passing through the heat dissipating device. In addition, the second frame has a support member mounted in the air inlet, the plurality of air guide members being disposed between the side wall and the support member. The plurality of air guide elements may be configured as strip, plate, curved, inclined or wing structures.

In addition, the first frame has a bearing tube for allowing a first bearing to be disposed therein, wherein the second frame support member receives a second bearing for supporting a shaft of the rotor to connect to the first bearing.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be better understood by reading the following detailed description and examples with reference made to the accompanying drawings, wherein:

1A is an exploded view of a conventional blower,

FIG. 12 is a plan view of the conventional blower after mounting, which is shown in FIG is shown

1 is an exploded view of the heat dissipating device according to an embodiment of the present invention;

a sectional view of the heat dissipating device of after assembly,

a perspective view of the heat-dissipating device of after assembly,

a schematic representation of the heat dissipating device with a two-sided axially compressed air passage according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

It will be nice on the to referenced showing the first embodiment of the invention. The heat dissipating device is exemplified by a centrifugal fan, which is a fan with a suction port. The heat dissipating device includes a housing passing through a first frame 21 and a second frame 22 is formed, a drive device 23 , a metallic bell 24 and a rotor 25 one.

The first frame 21 closes a bearing tube 211 a to the drive device 23 to pick up and hold, bearing the stock 231 inside the bearing tube 211 attached to a rotating shaft 27 of the rotor 25 to keep. The second frame 22 closes an air intake 221 and a side wall 222 a, extending from an inner edge of the air intake 221 extends downwards. If the first frame 21 and the second frame 22 Are mounted together, a space is formed within the heat-dissipating device and can in a chamber for air collection 26 and a space portion for containing the rotor therein 25 to arrange, through the side wall 222 to be shared. An air outlet 212 is also formed at the same time as in shown. A flange 223 extends radially from the bottom of the side wall 222 to an entrance 261 the chamber for air collection 26 set.

The rotor 25 closes a hub 251 , a basic element 252 extending radially from the lower end of the hub 251 extends, a first set of rotor blades 253 and a second set of shovels 254 one and gets in from the hub 251 connected drive device 23 driven. The first and second set of rotor blades 253 . 254 are curved blades, each on the base element 252 are arranged, and each blade has an end that extends to the entrance 261 the chamber for air collection 26 extends, with the first set of blades extending from the edge of the hub 251 down to the surface of the primitive 252 extends. The first and second set of blades are arranged alternately, as in shown. The hub 251 , the basic element 252 and the blades 253 . 254 can be integrally formed by injection molding as one piece of a casting.

The second frame 22 further has a support element 224 mounted in the air inlet, wherein a plurality of air guide elements 225 between the support element 224 and the side wall 222 are arranged to increase the blower pressure of the heat dissipating device. The number, shape and arrangement of the air duct elements can be changed or selected according to the current application. The plurality of air guiding elements may be configured as strip, plate, curved, inclined or wing structures. In addition, when the aspect of the present invention is applied to an upside-down blower, a blower having two suction ports or an axial flow fan, the air guiding elements may be disposed on one of the air inlets or both.

Because the rotor 25 rotates, the air flow in the air intake 221 sucked in, passing through the air ducting elements 225 and the blades 253 . 254 goes, and gets through the entrance 261 into the chamber for air collection 26 guided. In the chamber for air collection 26 the air flow is gradually collected and from there to the outside at high pressure through the air outlet 212 dissipated, which can prevent a sudden change in airflow pressure. Thus, the air flow is successively through the air inlet 221 , the air guide elements 225 , the shovels 253 . 254 and the entrance 261 the chamber for air collection 26 ,

Because the side wall 222 down from the inner edge of the air inlet 221 extends and the chamber for air collection 26 from the rotor 25 separates, taking the size of the air outlet 212 is the time of air flow pressure compensation by the rotor 25 increases, so that the fluctuation of the air flow pressure is stabilized. Furthermore, the claimed space of the centrifugal fan can be kept small, because the height of the chamber for air collection 26 partially or completely in the axial direction that of the flow passage through the rotor 25 and the air guide elements 225 overlaps. The cross-sectional area of the chamber for air collection 26 is essentially the same size as the air outlet 212 , so that the air flow is constant and stable in the chamber for air collection 26 and the air outlet 212 can flow to prevent a loss of performance.

On the other hand, the present invention employs a two-sided fixed motor arrangement as in shown, the bearing 231 in the bearing tube 211 attached and the other camp 232 on the inside of the support element 224 of the second frame 22 attached to the shaft 27 of the rotor 25 connecting support to provide the stabilization of the centrifugal fan in high-speed operation and to suppress the vibration.

As in the or As shown, the second frame has an extending part 226 formed on an inner side thereof and axially toward the first frame 21 extends to form an axially compressed air flow passage in the housing.

The axially extending depth of the extending part 226 is gradually increased from the air outlet to a position far from the air outlet. In other words, as in As shown, the axially extending depth of the extending part decreases 226 is gradually indicated from the location B to the location B 'along the counterclockwise direction and the change in the axially extending depth is indicated by the dotted line C.

In addition to the one-sided axially compressed air flow passage described above, another two-way axially compressed air flow passage may be employed. As in As shown, the first frame, apart from the radially compressed air flow passage as the conventional blower, has a first extending part 31 extending upward in the direction of the second frame, wherein the axially extending depth of the first extending portion 31 is gradually reduced to become near zero near the air outlet, and its changes in the axially extending depth is indicated by the dotted line D. On the other side, the second frame also has a second extending part 32 extending downwardly in the direction of the first frame, the axially extending depth of the second extending portion 32 is gradually decreased to become near zero near the air outlet, and its changes in the axially extending depth are indicated by the dotted line D '. The first and second extending part 31 . 32 are formed in a mirror-image configuration in the axial direction.

Finally, the present invention provides a heat dissipating device that uses a single-sided or double-sided axially compressed air passage to allow the air flow to flow evenly in the air passage in the frame thereof to increase its performance.

While the invention has been described in conjunction with what is presently considered to be the most desirable and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but rather is intended to accommodate various modifications and equivalent arrangements which are included within the spirit and scope of the appended claims.

Claims (21)

A heat dissipating device comprising: a housing having at least one air inlet ( 221 ) and at least one air outlet ( 212 ), and a rotor ( 25 ), which is arranged in the housing, wherein the housing has a first frame ( 21 ) comprising a drive device ( 23 ) for the rotor ( 25 ) and a second frame ( 22 ), with the first frame ( 21 ), which connects the air intake ( 221 ) and a side wall ( 222 ) extending from an inner edge of the air intake ( 221 ) extends down and a space in a chamber for air collection ( 26 ) and a space portion for the rotor ( 25 ), whereby the air flow from the chamber of the air collection ( 26 ) via the air outlet ( 212 ), the second frame ( 22 ) a first extending part ( 31 ) formed on an inner side thereof and along an axial direction of the first frame (FIG. 21 ) of the heat dissipating device to form an axially compressed air passage in the housing, and wherein the height of the axially compressed passage is changed depending on the first extending part without changing an external height of the housing, wherein the axially extending depth of a extending part ( 226 ) gradually from the air outlet ( 212 ) to one far from the air outlet ( 212 ) removed position. A heat dissipating device according to claim 1, wherein an axially extending depth of the first extending part (FIG. 31 ) from the air outlet ( 212 ) to one far from the air outlet ( 212 ) is gradually increased. A heat dissipating device according to claim 1, wherein the housing further comprises a second extending part (Fig. 32 ) extending axially of the first extending part (FIG. 31 ) extends to form a two-sided axially compressed air passage in the housing. A heat dissipating device according to claim 3, wherein an axially extending depth of the second extending part (FIG. 32 ) from the air outlet ( 212 ) to one far from the air outlet ( 212 ) is gradually increased. A heat dissipating device according to claim 3, wherein an axially extending depth of the first or second extending portion (FIG. 31 . 32 ) is gradually reduced to near the air outlet ( 212 ) to be almost zero. A heat dissipating device according to claim 3, wherein the first and second extending parts (FIG. 31 . 32 ) are formed in a mirror-image configuration in the axial direction. The heat dissipating device of claim 1, wherein the housing further comprises a radially compressed air passage within the housing. Heat dissipating device according to claim 1, wherein the rotor ( 25 ) a basic element ( 252 ), a hub ( 251 ), a first set of shovels ( 253 ) and a second set of blades ( 254 ). A heat dissipating device according to claim 8, wherein the first set of blades ( 253 ) from one edge of the hub ( 251 ) to a surface of the primitive ( 252 ) and the second sentence Shovels ( 254 ) on the basic element ( 252 ) is arranged. Heat dissipating device according to claim 8, wherein the basic element ( 252 ), the hub ( 251 ), the first and second set of blades ( 253 . 254 ) are integrally formed as a single unit. Heat dissipating device according to claim 10, wherein the side wall ( 222 ) a flange ( 223 ) extending radially from one end thereof to an entrance ( 261 ) of the Chamber of Air Collection ( 26 ), each of the blades ( 253 . 254 ) has an end leading to the entrance ( 261 ) of the Chamber of Air Collection ( 26 ) to direct the flow of air into the air collection chamber ( 26 ) respectively. Heat dissipating device according to claim 1, wherein the chamber for collecting air ( 26 ) partially or completely through an air passage through the rotor ( 25 ) overlaps along an axis of the heat dissipating device in height. Heat dissipating device according to claim 1, wherein the second frame ( 22 ) a plurality of air guide elements ( 225 ), which along the side wall ( 222 ) are arranged to increase a blower pressure of air flow passing through the heat dissipating device. Heat dissipating device according to claim 1, wherein the second frame ( 22 ) in the air intake ( 221 ) attached support element ( 224 ), and wherein the plurality of air guiding elements ( 225 ) between the side wall ( 222 ) and the support element ( 224 ) is arranged. Heat dissipating device according to claim 14, wherein the plurality of air guiding elements ( 225 ) are designed as strip, plate, curved, inclined or wing structures. A heat dissipating device according to claim 14, wherein the first frame ( 21 ) a bearing tube ( 211 ) in order to allow a first bearing to be arranged therein, and wherein the support element ( 224 ) of the second framework ( 22 ) receives a second bearing around a shaft ( 27 ) of the rotor ( 25 ) connecting with the first bearing. A heat dissipating device comprising: a housing having a first frame ( 21 ), a second framework ( 22 ), at least one air intake ( 221 ) and at least one air outlet ( 212 ), and a rotor ( 25 ), which is arranged in the housing, wherein the first frame ( 21 ) a drive device ( 23 ) for the rotor ( 25 ) and the second frame ( 22 ) with the first frame ( 21 ), which connects the air intake ( 221 ) and a side wall ( 222 ) extending from an inner edge of the air intake ( 221 ) extends down and a space in a chamber for air collection ( 26 ) and a space portion for the rotor ( 25 ), whereby the air flow from the chamber of the air collection ( 26 ) via the air outlet ( 212 ), the second frame ( 22 ) a first extending part ( 31 ) which extends along an axial direction of the first frame (FIG. 21 ) extends the heat dissipating device to form an axially compressed air passage in the housing, wherein the axially extending depth of an extending part ( 226 ) gradually from the air outlet ( 212 ) to one far from the air outlet ( 212 ), and wherein the height of the axially compressed passage is changed depending on the first extending part without changing an external height of the housing. Heat dissipating device according to claim 17, wherein the second frame ( 22 ) further comprises a second extending part ( 32 ) extending axially of the first extending part (FIG. 31 ) to form a two-sided axially compressed air passage in the housing. A heat dissipating device according to claim 18, wherein an axially extending depth of the first or second extending part (Fig. 31 . 32 ) from the air outlet ( 212 ) to one far from the air outlet ( 212 ) is gradually increased. A heat dissipating device according to claim 18, wherein an axially extending depth of the first or second extending part (Fig. 31 . 32 ) is gradually reduced to near the air outlet ( 212 ) to be almost zero. A heat dissipating device according to claim 18, wherein the first and second extending parts (FIG. 31 . 32 ) are formed in a mirror-image configuration in the axial direction.

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