KR20120048173A - Driver for cooling fan of air conditioner and cooling fan using the same - Google Patents

Abstract

PURPOSE: A driving device for a cooling fan of an outdoor unit of an air conditioner and a cooling fan using the same are provided to join a motor and impeller on a same rotary shaft without increasing the number of components and to minimize vibration at the same time with transferring a torque of a motor by using a dust absorption member. CONSTITUTION: A driving device for a cooling fan of an outdoor unit of an air conditioner comprises a rotary shaft(40), a motor(1), a stator support unit(10), a support bracket(20), and first and second bearings. An impeller(51) is supported in a front end portion of the rotary shaft. The motor comprises a rotor(80) in which the rotary shaft is joined to the central part and a stator(30) for rotating the rotor. The stator supporting unit is formed into a reversed cup shape and the stator of the motor is supported in the outer circumference of the stator support unit. The support bracket is formed into a cup shape and the upper part of the stator is joined to the lower part of the stator support unit. The outer circumference of the support bracket is supported to a frame of an outdoor unit of an air conditioner. The first and second bearings are respectively installed in the inner circumferences of the stator support unit and support bracket, thereby supporting the rotary shaft to be rotated.

Description

Cooling fan driving device of air conditioner outdoor unit and cooling fan using the same {Driver for Cooling Fan of Air Conditioner and Cooling Fan Using the Same}

The present invention relates to a cooling fan motor for an outdoor unit of an air conditioner, and provides a perfect waterproof structure while adopting a high efficiency BLDC motor, and provides a cooling structure for the air conditioner outdoor unit that provides a mounting structure in which the cooling fan and the motor shaft are easily coupled. An apparatus and a cooling fan using the same.

In general, an air conditioner uses a cooling cycle to liquefy refrigerant gas compressed at a high temperature and high pressure in a compressor in a condenser. It is based on the air conditioning to maintain the temperature suitable for the activity by supplying the cold air into the enclosed indoor space, such as the office, room or inside the building in hot summer weather in summer.

The air conditioner is divided into an outdoor unit including a compressor and a condenser, and an indoor unit including an expansion valve and an evaporator.

In this case, the condenser disposed in the outdoor unit serves as a heat exchanger for releasing the heat of the room absorbed by the evaporator while releasing it to the outside.

Therefore, the condenser disposed in the outdoor unit is air-cooled by the cooling fan to effectively exchange heat.

The air conditioner installs a thermostat (THERMOSTAT) that senses the outdoor temperature to enable a smooth air conditioner even when the outdoor temperature drops, and operates the cooling fan by adjusting the outdoor unit motor according to the outdoor temperature detected by the thermostat. That is, when the outdoor temperature is detected by a thermostat below a certain temperature, for example, 30 ° C. or less, the outdoor unit microcomputer lowers the motor RPM to 60% higher than the specified ALPM to reduce the outdoor unit heat exchange rate and reduce the air conditioner performance. In addition, smooth air conditioner function is possible even when outdoor temperature drops.

On the contrary, if the cooling fan is operated by raising the motor of the motor, the heat exchange amount of the outdoor unit is increased. As such, the heat exchange amount of the outdoor unit is adjusted according to the operating state of the cooling fan to control the function of the air conditioner according to the outdoor temperature.

Here, the cooling fan motor rotates the cooling fan to air-cool the condenser installed in the air conditioner outdoor unit to perform a function of circulating air.

The motor for driving the cooling fan to the air conditioner outdoor unit generally uses an AC motor, and the motor used for the outdoor unit includes a waterproof structure for protecting the inside of the motor from rainwater and a shaft structure for mounting the cooling fan. Consideration should be given to the efficient power consumption of the outdoor and outdoor units.

 The leak-proof structure for the fan motor disclosed in Korean Patent Laid-Open Publication No. 10-2004-37756 as a related art related to the waterproof structure is formed in the rotary shaft of the cone-shaped waterproof member, but it must be provided with a separate waterproof member cost Rises, and the structure is complicated, resulting in a decrease in productivity.

In addition, the conventional technology for the mounting structure of the cooling fan including the shaft structure for coupling the cooling fan to the rotating shaft is disclosed in Korean Patent Laid-Open Nos. 10-2010-39163, 10-2007-100518, and 10-2009. -97039, 10-2010-27899 and the like.

The patents must be provided with separate components for reducing friction and vibration between the components, thereby increasing the number of components in the axial direction, causing a change in the structure of the shaft around the shaft system, or separately from the rotor. There was a complicated problem in the assembly process because of the formation.

In addition, the need for employing a high-efficiency motor without the existing AC motor has emerged for the efficient power consumption.

A radial core type double rotor type BLDC motor patented by the present applicant for such a high efficiency motor is disclosed in Korean Patent Registration No. 10-663641.

Accordingly, the present inventor proposes the present patent that employs a high efficiency BLDC motor disclosed in the registered patent to a cooling fan drive device.

KR 10-663641 B KR 10-2004-37756 A KR 10-2010-39163 A KR 10-2007-100518 A KR 10-2009-97039 A KR 10-2010-27899 A

Accordingly, an object of the present invention is to provide a cooling system for an outdoor air conditioner that realizes a high efficiency and a perfect waterproof structure by adopting a double rotor type BLDC motor in which the rotor and stator are integrally molded with a resin such as a bulk molding compound (BMC). In providing a fan drive.

In addition, another object of the present invention is to easily combine the motor and the impeller without increasing the number of parts on the same rotation axis in order to transfer the rotational force of the motor to the impeller, and to transfer the rotational force of the motor to the impeller using a suction member At the same time, the vibration caused by the impeller rotation is to provide a cooling fan driving apparatus and a cooling fan using the same of the air conditioner outdoor unit that can minimize the transmission to the motor.

Still another object of the present invention is to design an impeller housing in an inverted cup shape, and to surround a impeller drive motor with an impeller housing, thereby providing a cooling fan driving apparatus for an outdoor unit of an air conditioner that realizes a secondary waterproof structure for the drive motor. In providing a cooling fan.

According to an aspect of the present invention for achieving the above object, the impeller is supported by a rotating shaft; A motor having a stator for rotating the rotor and a rotor coupled to the center of the rotation shaft; A stator support having an inverted cup shape and having a stator of the motor supported on an outer circumference thereof; A support bracket formed in the cup shape and having an upper end coupled to a lower end of the stator support, and having an outer circumferential part supported by a frame of an air conditioner outdoor unit; And first and second bearings respectively installed on the inner circumferential portions of the stator support and the support bracket to rotatably support the rotating shaft.

The rotor forms one of an outer rotor, an inner rotor, and a double rotor.

The outer periphery of the rotor and the stator is molded with resin.

Serration coupling is made between the rotary shaft and the rotor.

According to another aspect of the present invention, an impeller assembly having a plurality of wings coupled to the outer peripheral portion of the inverted cup-shaped impeller housing; A rotating shaft on which the impeller assembly is supported at the distal end portion; A motor having a stator for rotating the rotor and a rotor coupled to the center of the rotation shaft; A stator support having an inverted cup shape and having a stator of the motor supported on an outer circumference thereof; A support bracket formed in the cup shape and having an upper end coupled to a lower end of the stator support, and having an outer circumferential part supported by a frame of an air conditioner outdoor unit; And first and second bearings respectively installed on the inner circumferences of the stator support and the support bracket to rotatably support the rotating shaft.

The motor is preferably arranged inside the impeller housing.

The impeller assembly is formed integrally with the impeller bushing in the center of the impeller housing, the impeller bushing is fixed to the rotating shaft using a pair of fixing bolts.

C-shaped rings are fastened to upper and lower sides of the rotating shaft coupled to the rotor, respectively, and wave washers are fastened to at least one of the C-shaped rings.

According to another aspect of the invention, the rotor; A stator for rotating the rotor; An impeller coupled to a distal end, the rotating shaft being coupled to a central portion of the rotor; First and second bearings rotatably supporting the rotation shaft and disposed at a distance from each other; A stator support part supporting the stator at an outer circumference and provided with the first bearing at an inner circumference; And a support bracket on which the second bearing is installed at an inner circumference of the stator support.

Therefore, the present invention adopts a double rotor type BLDC motor of a molded body integrally molded with a resin such as a bulk molding compound, thereby achieving a high efficiency and a perfect waterproof structure.

In addition, the present invention can be easily coupled to the motor and the impeller without increasing the number of parts on the same rotation axis in order to transfer the rotational force of the motor to the impeller, by using a suction member to transmit the rotational force of the motor to the impeller and vibration Can be minimized.

1 is a cross-sectional view of a cooling fan coupled to an outdoor unit cooling fan driving apparatus according to an embodiment of the present invention;
2 is a perspective view illustrating a cooling fan in which the motor of FIG. 1 is coupled to an impeller;
Figure 3 is a perspective view showing a coupling state of the stator support and the support bracket of Figure 1,
4 is a perspective view of the rotating shaft shown in FIG.
5 is a cross-sectional view of the stator support shown in FIG.
6 is a cross-sectional view of the support bracket shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a cooling fan coupled to an outdoor unit cooling fan driving apparatus according to an embodiment of the present invention, FIG. 2 is a perspective view illustrating a cooling fan coupled to an impeller of FIG. 1, and FIG. 3 is a stator of FIG. 1. A perspective view showing the coupling state of the support and the support bracket. Figure 4 is a perspective view of the rotating shaft shown in Figure 3, Figures 5 and 6 are cross-sectional views of the stator support and the support bracket.

1 to 6, the double rotor type BLDC motor 1 according to the present invention supports a rotating shaft 40 rotatably supported at the center and a lower portion of the rotating shaft 40, and a main body frame 60. ) And the support bracket 20 coupled by the bolt 61, the stator support 10 coupled by the bolt 62 to the top of the support bracket 20, and the bolt to the top of the stator support 10. A stator 30 coupled to the groove 2a by a bolt (not shown) and a double rotor 80 rotatably coupled to the inner and outer circumferential surfaces of the stator 30.

The stator 30 uses a thermosetting resin such as a bulk mold compound (BMC) after a large number of split cores 3 are wound around the bobbin 3a and the coil 3b is wound. Since it is integrally formed by the reduced stator molding body 2 manufactured by insert molding, a perfect waterproof structure can be adopted.

In addition, the rotor 80 has a predetermined magnetic gap in the inner and outer peripheral portions of the stator 30, and a plurality of divided magnets 4a and a ring-shaped inner yoke 4b are disposed in a reducing manner. And an outer rotor 5 in which a plurality of split piece magnets 5a and a ring-shaped outer yoke 5b are arranged.

Here, the rotor 80 is insert-molded with a thermosetting resin in a state in which the rotating shaft fastening key bushing 7 is disposed on an injection molding die so as to be located at approximately the center of gravity of the inner rotor 4 and the outer rotor 5. Manufacture. In the insert molding, the inner rotor 4 and the outer rotor 5 form an annular molding except for the opposite surfaces of the magnets facing each other.

In addition, the rotor 80 may use a ring-shaped permanent magnet in which the N pole and the S pole are separately magnetized in place of the divided piece magnet.

As described above, the BLDC motor 1 has a single rotor and double rotor 80 in which the inner rotor 4 and the outer rotor 5 are supported by the rotor support frame 6, as proposed in Patent Registration No. 10-663641. Since the motor employing the radial rotor composed of the stator 30 is formed, detailed operation description of the motor 1 will be omitted.

In this embodiment, a motor employing the above-described patented radial core type double rotor is disclosed, but both a single rotor type inner rotor and an outer rotor type motor can be employed.

In addition, the stator 30 may use an integral core having a plurality of teeth protruding instead of a plurality of split cores.

Referring to FIG. 4, the rotation shaft 40 includes an intermediate portion 40f having a key 8 coupled to a key bushing 7 integrally formed at the center of the rotor support frame 6 coupled to the key groove 42. And an upper portion 40e to which the cylindrical impeller bushing 53 is coupled to the upper portion of the intermediate portion 40f, and an upper bearing fastening portion for fastening the upper bearing 9a to the lower portion of the intermediate portion 40f. It consists of the lower part 40d in which the lower bearing fastening part 40b for fastening 40a and the lower bearing 9b is formed.

Here, the length of the lower portion 40d of the rotating shaft 40, that is, the distance between the upper bearing 9a and the lower bearing 9b may be determined according to the weight of the impeller 51 and the motor 1. That is, when the weight of the impeller 51 and the motor 1 increases, by setting the length of the lower part 40d in proportion to this, the stable rotation operation | movement of the impeller 51 and the rotor 80 can be maintained.

The key bushing 7 formed integrally with the support frame 6 of the rotor 80 after the key 8 having the serration formed on the outer circumference thereof is coupled to the intermediate portion 40f of the rotary shaft 40. ) Is coupled to the key 80 and serration is combined with the rotor (80).

In addition, a pair of annular grooves 40c are formed at the upper and lower portions of the middle portion 40f of the rotation shaft 40, respectively. Each of the annular grooves 40c has a C-shaped ring (not shown) for blocking the up / down flow of the rotor 80 and a suction member for blocking friction and vibration transmission due to the rotation of the impeller 51. Wave washer 70 is coupled.

At the end of the upper portion 40e, one or more cutting surfaces 41 are formed in the longitudinal direction to fasten the fixing bolt 52 for engaging the impeller bushing 53.

An inverted cup-shaped impeller housing having a plurality of impellers 51 provided along the outer circumferential surface of the rotary shaft 40 and having a hole through which the impeller bushing 53 is coupled to the rotary shaft 40 at the center thereof ( 50) are combined.

A cutting surface 41 for coupling the impeller bushing 53 is formed at the upper portion 40e of the rotating shaft 40 so that the rotating shaft 40 and the impeller bushing 53 are coupled by at least one bolt 52. . Thus, the impeller 51 is fixed to the upper portion of the rotary shaft 40, the rotor 80 has a coupling structure that can effectively transmit the rotational force of the rotary shaft 40 to the impeller 51.

In addition, the ring-shaped wave washer 70 is coupled to the annular groove 40c positioned below the middle portion 40f of the rotating shaft 40 to reduce the transmission of vibration due to the rotation of the impeller 51 to the rotor 80. It adopts structure that we can make.

The impeller 51 and the impeller housing 50 are preferably made of synthetic resin, for example, for weight reduction.

 The impeller housing 50 is fixedly coupled to the rotary shaft 40 by the impeller bushing 53 at the distal end of the rotary shaft 40, and the plurality of impellers 51 formed on the outer circumferential surface of the impeller housing 50 have the rotary shaft 40. In conjunction with the rotation of the rotation is made the cooling fan is operated.

In this case, the double rotor 80 is coupled to the key bushing 7 fixed by the key 8 coupled to the center of gravity of the rotor 80 from the rotor support frame 6 so that the rotational force is rotated by the rotating shaft 40. The rotating shaft 40 is rotatably supported by two bearings 9a and 9b disposed at the center of the stator support 10 and the center of the support bracket 20, respectively.

As shown in FIG. 5, the stator support part 10 has a through hole 11b formed therein for penetrating the rotating shaft 40 in the center of the upper surface, and an upper bearing 9a on the inner circumferential surface formed of the inverted cup shape. It consists of a body (11) having a receiving groove (11a) for accommodating, and an extension portion (13) extending in a direction perpendicular to the outer circumferential surface to the lower portion of the body (11).

The bearing receiving groove 11a for accommodating the upper bearing 9a is formed above the inner circumferential surface of the body 11, and the extension part 13 includes a plurality of bolting holes 13a.

The bolt fastening hole 13a is aligned with the bolt groove 2a formed in the stator molding body 2 and then coupled to the stator molding body 2 upward as the bolt is fastened, one on the bottom of the body 11. As the bolt 62 is fastened to the above bolt fastening hole 14a, it is coupled with the support bracket 20.

As shown in FIG. 6, the support bracket 20 has a cup-shaped body 21 having the same inner diameter as the body 11 of the stator support 10, and is perpendicular to the upper outer circumferential surface of the body 21. The extension part 22 extending in the direction.

The support bracket 20 has a bearing receiving groove 21a for accommodating the lower bearing 9b on the lower surface of the body 21, and the extension portion 22 is bolted to the bolt fastening hole 22a provided at the outer circumference. By fastening the 61, it is fixedly coupled to the body frame 60 of the air conditioner outdoor unit body. In addition, the stator support 10 may be formed by aligning the bolt fastening hole 22b provided at the inner circumference of the bolt fastening hole 22a with the bolt fastening hole 14a of the stator support 10 and then fastening the bolt 62. Is supported on the support bracket (20).

Furthermore, when the stator support 10 and the support bracket 20 are coupled, a space S in which the rotation shaft 40 is accommodated is provided inside by the same inner diameter, and is disposed at a distance above and below the space S. The rotating shaft 40 is stably rotatably supported by the pair of bearings 9a and 9b.

As described above, the present invention can realize a high efficiency and perfect waterproof structure by employing a double rotor type BLDC motor having a structure in which the rotor and the stator are integrally molded with a resin such as a bulk molding compound (BMC). As a result, effective heat exchange of the condenser arranged in the outdoor unit of the air conditioner can be achieved.

In addition, the present invention can be easily coupled to the motor and the impeller without increasing the number of parts on the same rotation axis in order to transfer the rotational force of the motor to the impeller, and at the same time to transfer the rotational force of the motor to the impeller using a suction member Vibration due to rotation can minimize transmission to the motor.

Furthermore, the present invention implements a secondary waterproof structure for the drive motor by designing the impeller housing in the inverted cup shape by surrounding the impeller drive motor with the impeller housing.

The present invention implements a perfect waterproof structure in which the impeller drive motor is firstly sealed by resin molding, and the second sealing is achieved by the impeller housing, and the fan is rotated by a simple configuration using the same shaft to rotate the impeller. Various applications are possible for a motor for driving.

1: Motor 10: Stator Support
20: support bracket 30: stator
40: rotating shaft 50: impeller housing
60: body frame 70: wave washer
9a, 9b: upper and lower bearing 80: rotor
51: impeller 53: impeller bushing

Claims (9)

A rotating shaft on which the impeller is supported at the front end;
A motor having a stator for rotating the rotor and a rotor coupled to the center of the rotation shaft;
A stator support having an inverted cup shape and having a stator of the motor supported on an outer circumference thereof;
A support bracket formed in the cup shape and having an upper end coupled to a lower end of the stator support, and having an outer circumferential part supported by a frame of an air conditioner outdoor unit; And
And a first and a second bearing installed in the inner circumferences of the stator support and the support bracket to rotatably support the rotating shaft. The cooling fan driving apparatus of claim 1, wherein the rotor forms one of an outer rotor, an inner rotor, and a double rotor. The cooling fan drive apparatus according to claim 1, wherein the rotor and the stator are molded with a resin. The cooling fan driving apparatus of claim 1, wherein a serration coupling is performed between the rotation shaft and the rotor. An impeller assembly having a plurality of wings coupled to an inverted cup-shaped impeller housing outer periphery;
A rotating shaft on which the impeller assembly is supported at the distal end portion;
A motor having a stator for rotating the rotor and a rotor coupled to the center of the rotation shaft;
A stator support having an inverted cup shape and having a stator of the motor supported on an outer circumference thereof;
A support bracket formed in the cup shape and having an upper end coupled to a lower end of the stator support, and having an outer circumferential part supported by a frame of an air conditioner outdoor unit; And
And a first bearing and a second bearing installed on the inner circumferential portions of the stator support and the support bracket to rotatably support the rotating shaft. The method of claim 5,
The motor is a cooling fan for an outdoor air conditioner, characterized in that disposed inside the impeller housing. According to claim 5, The impeller assembly is an impeller bushing integrally formed in the center of the impeller housing, the impeller bushing is an air conditioner outdoor fan, characterized in that fixed to the rotating shaft using a pair of fixing bolts. The air conditioner outdoor fan of claim 5, wherein the C-shaped ring is fastened to the upper side and the lower side of the rotating shaft coupled to the rotor, and the wave washer is fastened to at least one of the C-shaped rings. Rotor;
A stator for rotating the rotor;
An impeller coupled to a distal end, the rotating shaft being coupled to a central portion of the rotor;
First and second bearings rotatably supporting the rotation shaft and disposed at a distance from each other;
A stator support part supporting the stator at an outer circumference and provided with the first bearing at an inner circumference; And
And a support bracket provided with the second bearing at an inner circumference thereof while supporting the stator support.

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