KR100747526B1 - Fan - Google Patents

Abstract

The present invention relates to a blower having a new structure that can reduce the noise and increase the blowing efficiency by adopting a BLDC motor that can stably drive the blower fan and increase the blowing amount.

To this end, the present invention is connected to the fan housing of the metal or plastic material, the blowing fan installed inside the fan housing, and the blowing fan installed inside the fan housing to transfer the driving force of the motor to the blowing fan. A rotor comprising a shaft, a supporter fixed to the fan housing, a rotor frame coupled to an end opposite to the fan housing connecting side of the shaft and forming a body, and a magnet provided inside the rotor frame; A blower is provided, which is installed to be located inside the rotor and comprises a stator fixed to maintain concentricity on the supporter.

Blower Fan, Fan Housing, BLDC, Motor, Sirocco Fan, Axial Flow Fan

Description

Blower {FAN}

1 is a perspective view showing a blower of the present invention

2 is a reference perspective view showing a state in which the assembly of the BLDC motor and the supporter is separated from the fan housing and the blower fan;

Figure 3a is a sectional view showing a blower according to the present invention

FIG. 3B is an enlarged view of the motor and the supporter of FIG. 3A

Figure 4a is a perspective view showing the supporter of Figure 3a

4B is a bottom perspective view of FIG. 4A

5 is a partial perspective view showing a state in which the damping member is assembled to the supporter fixing portion of the supporter;

Figure 6 is a perspective view showing another embodiment of the blower of the present invention

FIG. 7A is a cross-sectional view of FIG. 6

7B is an enlarged view illustrating main parts of FIG. 7A;

Figure 8a is a perspective view showing the appearance of the sirocco fan applied to the present invention

8B is a top view of 8A

Figure 9a is a perspective view of a rotor applied to the present invention, a partial cutaway perspective view for showing the internal structure

FIG. 9B is a bottom perspective view of FIG. 9A

10A is a perspective view showing a rotor bushing applied to the present invention.

FIG. 10B is a bottom perspective view of FIG. 10A

11 is a perspective view showing another embodiment of a magnet applied to the rotor

12 is a perspective view showing a stator applied to the present invention

13 is an exploded perspective view of FIG. 12;

FIG. 14 is an enlarged view of the core of FIG. 13, illustrating a spiral core; FIG.

15 is a perspective view showing another example of the stator applicable to the present invention

FIG. 16 illustrates the core structure of FIG. 15 and illustrates a split core. FIG.

17 is a perspective view showing still another example of the stator applicable to the present invention

FIG. 18 is a perspective view illustrating the core core of FIG. 17, illustrating the core structure of FIG. 17.

19 is a perspective view showing another embodiment of the supporter applied to the present invention

20 is a partially cutaway perspective view illustrating an installation state of an outdoor unit for an air conditioner of a front suction method using the blower according to the present invention;

FIG. 21 is an exploded perspective view illustrating an installation state of an outdoor unit for an air conditioner of the front suction method using the blower according to the present invention; FIG.

22 is a front view showing the installation state of the outdoor unit for an air conditioner of the front suction method applied to the blower of the present invention.

23 is a block diagram of a blower according to another embodiment of the present invention.

24 is a block diagram of a blower according to another embodiment of the present invention.

25 is a perspective view showing another structural example of the stator applicable to the present invention;

<Explanation of symbols on main parts of the drawings>

1: Blower 10: Case

11: support bracket 20: outdoor unit side heat exchanger

30: control box 200: Hall sensor

300: tab housing assembly 40: fan housing

410a, 410b: Air intake G: Grill

430: forming part 44: shroud

440a: Fastening surface 440b: Guide surface

46: damping pad 50: sirocco fan

52: blade 54: abacus

56: bushing 560a: base portion

560b: hub part 560c: bolt fastener

58: Rivet 6: BLDC motor

60: rotor 60a: rotor frame

602: bottom 602a: hub portion

602b: Through Hole 602c: Cooling Fin

602d: Through air 602e: Embossing part

602f: Drainage hole 602g: Positioning hole

602h: Fastener 604: side wall surface

604a: bending portion 604b: bending portion

60b: magnet 65: stator

65a: spiral core 652a: base

654a: Teeth 656a: Home

65b: Insulator 650b: Insulator Upper

651b: Insulator lower 655b: Fastening part

656b: Positioning protrusion 657a: Core rivet

65c: coil 65d: metal tube

65 ': Stator 65a': Split core

65 ": Stator 65a": Tong core

68: shaft 680: serration

680a, 680b: Shaft side step 685: Planar section

69a, 69b: bearing 70: rotor bushing

72: fitting part 720: serration

74: fastening part 740: engaging projection for positioning

742: Fastener 76a, 76b: Reinforcement rib

80: supporter 82: bearing housing

822a, 822b: Supporter side step 84: Stator fixing part

842: positioning groove 844: through hole

86: Supporter fixing part 88a, 88b, 88c: Reinforcing rib

90: damping member 920a: main body

920b: head 95: cover bracket

The present invention relates to a blower, and more particularly to a blower that can increase the blowing efficiency and heat exchange efficiency by employing a stable and high efficiency BLDC motor.

In general, the air conditioner is divided into a separate air conditioner installed separately in the indoor and outdoor space by separating the indoor unit and the outdoor unit, and an integrated air conditioner installed through the window or the wall by combining the indoor unit and the outdoor unit as a single device. As the capacity increases, the size of the indoor unit and the outdoor unit increases, and as the vibration generated in the outdoor unit increases as the compressor included in the outdoor unit is operated, a separate air conditioner is frequently used.

Such a separate air conditioner is installed indoors so that the heat exchange action between the low-temperature low-pressure gas refrigerant and the air to provide a hot air or cold air into the air conditioning space, and is installed outdoors to achieve a sufficient heat exchange operation in the indoor unit The outdoor unit is configured to compress, condense, and expand the refrigerant so that the indoor unit and the outdoor unit are installed to be connected to each other by a refrigerant pipe.

Here, the indoor unit is an indoor case formed with an inlet and discharge port for indoor air intake and discharge, and an evaporator is installed inside the interior case to allow a low-temperature low-pressure gas refrigerant to pass through the heat exchange action with the air, the evaporator It is installed on one side and consists of an indoor fan and a motor through which the indoor air passes through the evaporator to discharge the cold air back to the indoor side.

The outdoor unit includes an outdoor case having an inlet and a discharge port through which outdoor air is sucked and discharged, a compressor installed inside the outdoor case to compress the refrigerant passing through the evaporator into a gas refrigerant having a high temperature and high pressure, and through the compressor. A condenser for condensing a refrigerant with medium-temperature high-pressure liquid refrigerant by exchanging heat with outdoor air, an expansion means such as a capillary tube or an electronic expansion valve for reducing the refrigerant passing through the condenser with a low-temperature low-pressure gas refrigerant, and one side of the condenser It is composed of an outdoor fan and a motor which is a kind of axial flow fan to allow the outdoor air to pass through the condenser, the motor is applied to the general single-phase and three-phase induction motor, the induction motor is a shaft and in the middle of the stator installed inside the housing As alternating current is applied to the stator in such a way that the rotor rotates, the rotating magnetic field It is thereby rotate the rotor.

Usually, the outdoor case is formed in the three inlet side in order to increase the blowing efficiency, the discharge port is formed on the upper surface, when the outdoor fan is operated, the air is sucked from the three sides to heat exchange, then to the upper surface The heat exchanged air is discharged.

At this time, the compressor, the condenser, the expansion means, the evaporator is installed to be connected to each other by a refrigerant pipe, the refrigerant is circulated while being sequentially compressed, condensed, expanded, evaporated along the component.

However, such a conventional outdoor unit for an air conditioner has been limited in the installation place due to the high density of the city and the strengthening of environmental management, and has been the subject of complaints around by the noise and heat emission. In particular, common residential facilities, such as large apartment complexes, require outdoor units to be installed inside the veranda due to aesthetics and noise problems.

Therefore, in recent years, the outdoor unit for the air conditioner of the front suction system, which sucks and heats the air only to the front and then discharges the heat exchanged to the front, has been adopted in a common residential facility such as a large-scale apartment complex.

However, the outdoor unit for the air conditioner of the front suction method as described above has a problem in that the blowing efficiency and the heat exchange efficiency are lowered because the suction area less air is sucked than the outdoor unit for the air absorber of the three-side suction method.

In addition, since the single-phase or three-phase induction motor for the air conditioner outdoor unit of the front suction method is applied to drive the blower fan, such an induction motor is not only low in overall efficiency of 40-50% or less, and in particular, The range of the variable range of the torque is limited due to the narrow range of stable torque characteristics, and thus the abnormal noise and efficiency decreases when the rotational speed leaves the stable torque characteristic.

The present invention has been made in order to solve the above problems, by employing a BLDC motor that can increase the blowing amount while driving the blower fan stably, blowing the air to reduce the noise and increase the blowing efficiency and heat exchange efficiency The purpose is to provide a device.

According to one embodiment of the present invention for achieving the above object, the driving force of the motor is axially connected to the metal fan housing, the blowing fan installed inside the fan housing, and the blowing fan installed inside the fan housing. And a shaft for transmitting to the blower fan, a supporter fixed to the fan housing, a rotor frame coupled to an end opposite to the fan housing connecting side of the shaft and forming a body, and a magnet provided inside the rotor frame. And a stator installed to be positioned inside the rotor and fixed to maintain concentricity on the supporter.

On the other hand, according to another aspect of the present invention for achieving the above object, the motor is connected to the fan housing made of plastic material, the blowing fan installed inside the fan housing, and the blowing fan installed inside the fan housing and the motor A shaft for transmitting a driving force to the blower fan, a supporter made of a metal fixed to the outside of the fan housing, a rotor frame coupled to the rear end of the shaft and forming a body, and a magnet provided inside the rotor frame. And a stator that is positioned to be positioned inside the rotor and fixed to maintain concentricity on the supporter.

On the other hand, according to another aspect of the present invention for achieving the above object, it is axially connected to a fan housing made of a plastic material, a blowing fan installed inside the fan housing, and a blowing fan installed inside the fan housing A shaft for transmitting the driving force of the motor to the blower fan, a bearing housing made of a metal material which is inserted and formed during injection molding of the fan housing, and a stator which is formed separately from the bearing housing and is fastened to the fan housing or the bearing housing. A rotor comprising a fixing supporter, a rotor frame coupled to the rear end of the shaft and forming a body, and a magnet provided inside the rotor frame, and installed to be located inside the rotor and being concentric on the supporter. It is provided with a blower, characterized in that it comprises a stator fixed to be maintained.

On the other hand, according to another aspect of the present invention for achieving the above object, at least a surface through which the shaft penetrates, a plastic fan, a blowing fan installed inside the fan housing, and installed inside the fan housing A shaft coupled to the blower fan to transmit the driving force of the motor to the blower fan, a supporter made of metal fixed to the fan housing, a rotor frame coupled to the rear end of the shaft, and forming a body approximately; It is provided with a blower comprising a rotor comprising a magnet provided inside the rotor frame, and a stator installed to be positioned inside the rotor and fixed to maintain concentricity on the supporter.

On the other hand, according to another aspect of the present invention for achieving the above object, a fan housing, an axial fan which is fixed to the inside of the fan housing and is installed to suck air from the side or bottom and discharge to the top, and the axial flow fan A shaft coupled to the shaft to transfer the driving force of the motor to the fan, a bearing for supporting the shaft, a supporter coupled to the lower wall of the fan housing to support the bearing and the stator, and a blower fan connection side of the shaft Including a rotor bushing of an insulating material coupled to the opposite lower end, a rotor frame coupled to the rotor bushing to transfer the driving force to the shaft through the rotor bushing, forming a body approximately, and a magnet provided inside the rotor frame The rotor is configured to be positioned inside the rotor to form a BLDC motor together with the rotor. The fan apparatus characterized in that hayeoseo includes a stator that is fixed so that the concentricity is held on the supporter is provided.

On the other hand, according to another aspect of the present invention for achieving the above object, a fan housing, an axial fan which is fixed to the inside of the fan housing and installed to suck air from the rear to discharge to the front, and the shaft in the axial fan A shaft connected to transfer the driving force of the motor to the fan, a bearing for supporting the shaft, a supporter fastened to the rear wall portion of the fan housing to support the bearing and the stator, and a side opposite to the blower fan connection side of the shaft. Rotor bushing of insulating material coupled to the end, coupled to the rotor bushing to transfer the driving force to the shaft through the rotor bushing, the rotor frame to form an approximately body, and a magnet provided inside the rotor frame A rotor and the rotor and are installed to be located inside the rotor to form a BLDC motor. Provided is a blower, characterized in that it comprises a stator fixed to maintain concentricity on the porter.

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

1 is a perspective view showing a blower of the present invention, Figure 2 is a reference perspective view showing a state in which the assembly of the BLDC motor and the supporter is separated from the fan housing and the blowing fan, Figure 3a is a blower according to the present invention is shown 3B is an enlarged view of the motor and the supporter of FIG. 3A. Here, the sirocco fan of FIG. 3A is shown in half section. That is, the actual bushing is a disk shape symmetrical to both the left and right sides of the shaft as shown in Figure 8b.

On the other hand, Figure 4a is a perspective view of the supporter of Figure 3a, Figure 4b is a bottom perspective view of Figure 4a, Figure 5 is a partial perspective view showing a state in which the damping member is assembled to the supporter fixing portion of the supporter.

Figure 8a is a perspective view showing the appearance of the sirocco fan applied to the present invention, Figure 8b is a plan view of 8a, Figure 9a is a perspective view showing a rotor applied to the present invention, a partial cutaway perspective view for showing the internal structure, Figure 9B is a bottom perspective view of FIG. 9A.

And, Figure 10a is a perspective view showing a rotor bushing applied to the present invention, Figure 10b is a bottom perspective view of Figure 10a, Figure 11 is a perspective view showing another embodiment of a magnet applied to the rotor.

12 is a perspective view illustrating a stator applied to the present invention, FIG. 13 is an exploded perspective view of FIG. 12, and FIG. 14 is an enlarged view of the core of FIG. 13, showing a spiral core.

Blower 1 according to the first embodiment of the present invention, the outer case 10, the air inlet 410a (410b) and fixed in the upper and lower directions respectively formed in the outer case 10 and formed in front A fan housing 40 made of a metal plate having an air discharge port, a sirocco fan 50, which is a centrifugal fan installed inside the fan housing 40, and the sirocco fan 50 are axially connected to the driving force of the motor. The shaft 68 to be transmitted to the sirocco fan 50, the bearings 69a and 69b supporting the shaft 68, and the upper surface of the fan housing 40 are fastened to the bearings 69a and 69b, and The supporter 80 supporting the stator 65, the rotor bushing 70 made of an insulating material coupled to an end opposite to the fan connection part of the shaft 68, and the rotor bushing 70 are coupled to the rotor bushing 70. A rotor 60 which transmits a driving force to the shaft 68 through 70, and together with the rotor 60, constitutes a BLDC motor 6. It is configured to include a stator (65) installed to be located inside the rotor (60) and fixed to maintain concentricity on the supporter (80).

Then, each surface of the outer case 10 corresponding to the air discharge port and the air suction ports 410a and 410b of the fan housing 40 is opened, and the dog corresponding to the air discharge port side of the fan housing 40 is opened. The grille G is installed on the side.

On the other hand, the fan housing 40, the air inlet 410a is formed on the lower surface, the air inlet 410b that can serve as a through hole for the motor installation is formed on the upper surface spaced a predetermined distance from the lower surface, An air outlet is formed at one side of the side wall surface surrounding the sirocco fan 50 while interconnecting the lower surface and the upper surface.

On the other hand, the sirocco fan 50 installed in the fan housing 40 is installed so that its center axis is eccentric with respect to the center line of the upper and lower surfaces of the fan housing 40.

That is, the center line of the upper and lower surfaces of the fan housing 40 and the center axis of the sirocco fan 50 installed therein do not coincide with each other and are spaced apart from each other.

Therefore, as can be seen through Figure 3a, the space size between the fan housing 40 and the sirocco fan 50 is different from each other.

A support bracket 11 is provided between the outer case 10 and the fan housing 40 to support the fan housing to the outer case 10.

The support bracket 11 is preferably integrally extended from the outer case 10 and fastened to the upper surface of the fan housing 40, but may be interposed between the outer case 10 and the fan housing 40 as a separate member. It may be.

1, a forming unit 430 is formed on the upper surface of the fan housing 40 to reinforce strength, and the forming unit 430 formed on the upper surface of the fan housing 40 has a substantially circumferential direction. Formed accordingly.

The forming part 430 formed on the upper surface of the fan housing 40 is formed in a shape in which the width thereof varies in the circumferential direction. That is, the width of the forming unit 430 gradually increases as it comes to a wide portion (outcase front side) of the upper surface of the fan housing 40.

On the other hand, the air inlet 410a of the lower surface of the fan housing 40 and the air inlet 410b, which serves as a through hole for motor installation of the upper surface of the fan housing 40, the shroud 44 for guiding the flow of air introduced therethrough. ) Is provided.

The shroud 44 is a separate member, a guide surface having a predetermined curvature for guiding the fastening surface 440a and the air flow that are fastened around the air inlets 410a and 410b of the upper and lower surfaces of the fan housing 40. Although the case made of 440b is illustrated, the fan housing 40 may be integrally formed with the fan housing 40. In this case, the thickness of the shroud 44 will be thinner than other portions toward the end.

Meanwhile, referring to FIGS. 3A, 3B, and 4, the supporter 80 includes a bearing housing portion 82 in which bearings 69a and 69b for supporting the shaft 68, such as ball bearings, are installed. Is formed so as to extend radially outward of the bearing housing portion 82, between the supporter fixing portion 86 and the supporter fixing portion 86 to fix the supporter 80 to the upper surface of the fan housing 40 It is formed so as to connect and comprises a stator fixing portion 84 that provides a surface for fixing the stator 65, it is preferably a metal material such as aluminum, cast (주조).

That is, the supporter fixing portion 86 of the supporter 80 is triangulated.

The supporter 80 includes a stator fastening end portion of the supporter fixing part 86 such that at least the stator engagement surface of the supporter is located inside the fan housing 40 when the supporter is assembled to the fan housing 40. The fan housing 40 is bent upwardly to be positioned above the surface.

In addition, the supporter 80 is provided with a reinforcing rib 88a for reinforcing the strength of the supporter fixing part 86, and the reinforcing rib 88a is also provided on the outer circumferential surfaces of the stator fixing part 84 and the bearing housing part 82. It is preferred to be connected at the same time.

In addition, the supporter 80 and the stator 65 are provided with corresponding positioning protrusions and positioning grooves 842 that can match concentricity when the stator 65 is fastened to the supporter 80. More specifically, the stator fixing part 84 of the supporter 80 is provided with a positioning groove 842 for determining an assembly position with the stator 65, and positioning projections on the corresponding stator 65. 656b; see FIG. 12. At this time, the positioning projection may be formed in the supporter and the positioning groove may be formed in the insulator of the stator.

On the other hand, a through hole 844 is formed on the surface of the stator fixing portion 84 of the supporter 80 to increase motor cooling performance.

In addition, the step 822a formed at the lower side of the step 822a and 822b formed on the inner circumferential surface of the bearing housing 82 is installed at the lower side of the bearings respectively installed at the upper and lower sides of the outer circumferential surface of the shaft 68. Stepped 822b is formed in the shape of the letter "a" to form a structure for supporting the upper end of the lower bearing (69a), the upper step of the step (822a) 822b formed on the inner peripheral surface of the bearing housing 82 Is formed in a "b" shape to form a structure for supporting the lower end of the upper bearing (69b) is installed on the upper side.

In addition, the lower bearing and the upper part of the outer circumferential surface of the shaft 68, which is located inside the bearing housing 82 and transmits the driving force of the rotor 60 to the fan housing 40, also on the shaft 68. A positioning step can be formed to allow the installation position of the bearing to be determined.

3A, 3B, and 5, it is preferable that a damping pad 46 is provided on the contact surface between the fan housing 40 and the shroud 44.

More specifically, the vibration damping pad 46 is interposed between the fastening surface 440a of the shroud 44 and the peripheral surface of the air inlets 410a and 410b of the fan housing 40 which is in contact therewith. Blocking the transmission to the fan housing (40).

In addition, a damping member 90 is provided between the supporter fixing part 86 and the fan housing 40 of the supporter 80.

Referring to FIG. 5, the vibration damping member 90 is forced through a main body portion 920a contacting the fan housing 40 and a vibration damping member fixing hole 866 formed in the supporter fixing portion 86. The head portion 920b is inserted into and fixed to the supporter fixing portion 86, and a through hole 930 penetrating the body portion 920a and the head portion 920b is provided.

When the supporter 80 is fixed to the fan housing 40 side, the head portion 920b of the vibration damping member 90 is connected to a fastening member such as a bolt 15d passing through the vibration damping member 90. It is preferable that the cover bracket 95 made of metal material such as an iron plate to prevent the damage of the vibration damping member 90 generated by the acting fastening force is overlaid.

The cover bracket 95 refers to an iron piece shaped like a horseshoe so as to wrap the head portion 920b.

That is, the vibration damping member 90 pushes the head portion 920b through the vibration damping member fixing hole 866 formed in the supporter fixing portion 86 to force the body portion 920a and the head portion 920b. The neck portion to be connected is fixed by being caught around the damping member fixing hole 866. In such a state, the cover bracket 95 is put on the head 920b, and then the bolt 15d passes through the through hole 930 of the cover bracket 95 and the vibration damping member 90. The fan housing 40 When it is fastened to the supporter 80 is fixed to the fan housing 40.

3A, 3B, 8A, and 8B, the sirocco fan 50 is provided with a main plate 54 that connects each blade 52 formed along the circumferential direction to the inside of the fan. 54) The central portion includes a bushing 56 for fastening the shaft 68 to the sirocco fan 50.

At this time, the lower portion and the upper portion of the blade 52 is provided with fixing plates 53a and 53b that bind individual blades to each other to prevent blade flow and noise caused by the high speed rotation of the fan.

The bushing 56 has a disc-shaped base portion 560a which is in close contact with the surface of the main plate 54, and protrudes in the axial direction at the center of the base portion 560a, and has a shaft 68 insertion hole at the center thereof. It consists of a hub portion 560b provided.

The bushings 56 are two pieces, which are coupled to each other by riveting or screwing by the rivets 58 in close contact with both sides of the main plate 54.

The main plate 54 is provided at a position close to the motor side from the longitudinal center point of the sirocco fan 50.

The reason for doing this is because a large amount of air flows from the air inlet 410a opposite to the side where the motor is installed among the air inlets 410a and 410b of the fan housing 40.

Here, the position of the main plate 54 is the shorter length from the main plate 54 to the end of the fan and the longer length from the main plate 54 to the end of the fan when the full length of the sirocco fan 50 is divided. Preferably, the length ratio falls within the range of 1: 1.3 to 1: 2.

In addition, at least one bolt fastening hole 560c is provided on the outer circumferential surface of the hub portion 560b of the bushing 56, and on the outer circumferential surface of the end portion of the shaft 68, the bolt fastening hole 560c passes through when assembled. A planar section 685 to which the pressing force of the bolt 15f to be fastened is applied is provided.

Therefore, when the bolting force is applied to the planar section 685 during assembly, the sirocco fan 50 is firmly coupled to the shaft 68 to rotate integrally.

On the outer circumferential surface of the fan connection side end portion of the shaft 68, a protrusion (not shown) or a locking step (not shown) for determining an insertion position of the shaft with respect to the bushing may be provided. That is, when assembling the shaft and the sirocco fan, when the projection of the shaft or the locking jaw of the shaft is no longer inserted, the flat section automatically comes to the bolted position, and the fan housing of the sirocco fan. The position at is also determined.

3A and 3B, the rotor bushing 70 may be coupled to the shaft 68 and the rotor frame 60a in a state located below the rotor frame 60a. However, the rotor bushing 70 may be combined with the shaft bushing 70. ) May be coupled to the shaft 68 and the rotor frame 60a in a state located above the rotor frame 60a.

Meanwhile, referring to FIGS. 10A and 10B, the rotor bushing 70 includes a fitting portion 72 in which a shaft 68 is fitted in the center thereof and engaged with the fitting portion 72 and the fitting portion for fastening with the rotor frame 60a. It comprises a fastening portion 74 extending radially around the 72.

At this time, the coupling portion 74 of the rotor bushing 70 is integrally formed with a plurality of positioning coupling projections 740 inserted into the positioning holes 602g of the rotor frame 60a at the time of assembly. .

In addition, the fastening portion 74 of the rotor bushing 70 is provided with a fastening hole 742 for fastening the bolt with the rotor frame 60a.

Reinforcing ribs 76a and 76b are provided at the engagement portion 72 and the fastening portion 74 of the rotor bushing 70, respectively.

In addition, serrations 680 and 720 for mutual engagement are formed on the outer circumferential surface of the upper end of the shaft 68 and the inner circumferential surface of the center portion of the fitting portion 72 of the rotor bushing 70 corresponding thereto.

That is, the rotor bushing 70 is fastened to the rotor frame 60a by a fastening member such as a bolt 15a penetrating the fastening hole 742 of the fastening portion 74, and inserted through the center of the fitting portion 72. The shaft 68 coupled to the rotor bushing 70 and the serration is fastened to the rotor bushing 70 by a bolt 15b inserted into a fastening hole at an end thereof.

On the other hand, the rotor bushing 70 is made of a resin material that is different from the rotor frame 60a of the steel plate vibration mode.

3A, 3B, and 9A and 9B, the rotor 60 includes a rotor frame 60a and a magnet 60b installed therein, and the rotor frame 60a is In consideration of productivity and formability, it is preferable that the steel sheet is made.

However, the present invention is not limited thereto, and the rotor frame 60a may be made of an injection molding, or may be made of an injection molding of a resin material surrounding the iron plate and its outside.

In addition, the rotor frame 60a includes a bottom surface 602 forming a substantially disk shape and a side wall surface 604 extending in a direction substantially perpendicular to an edge of the bottom surface 602, wherein the side wall surface On the 604, a bent portion 604a having a seating surface for supporting the magnet 60b mounted on the inner surface thereof is formed along the circumferential direction, and the rotor 60 at the center of the bottom surface 602. Hub portion 602a having a through hole 602b through which a fastening member such as a bolt 15b for coupling the shaft 68 to the shaft 68 is provided.

At this time, the fastening hole 602h corresponding to the fastening hole 742 formed in the fastening portion 74 of the rotor bushing 70 is provided on the bottom surface 602 of the rotor frame 60a.

On the other hand, the rotor frame (60a) comprises a bottom surface 602 forming a substantially disk-shaped, side wall surface 604 extending in a direction substantially perpendicular to the edge of the bottom surface 602, iron plate In the case of a material, the bottom surface 602 and the side wall surface 604 are integrally formed by press working.

At this time, the end of the opening of the side wall surface 604 is first bent in the radially outer side, the end is formed in a second bent shape again, the second bending direction of the side wall surface 604 is the bottom surface ( 602).

As described above, the bent portion 604b formed at the opening side end of the side wall surface 604 of the rotor frame 60a increases the rigidity of the rotor side wall surface 604 and thus prevents the distortion of the rotor and the noise caused by the high speed rotation. Will be prevented.

In addition, around the hub portion 602a of the rotor frame 60a, a plurality of air blows air toward the stator 65 when the rotor 60 rotates to cool the heat generated by the stator 65. Cooling fins 602c are formed radially, and the cooling fins 602c are formed to have a predetermined length in the radial direction.

On the other hand, the cooling fin 602c is formed to face the opening side of the rotor 60 by the lancing process, the through hole 602d formed by the lancing process serves as a vent.

The cooling fins 602c are bent at an angle of 90 ° with respect to the bottom surface 602 so as to face the opening side of the rotor 60.

An embossing portion 602e for strength reinforcement of the rotor frame 60a is formed in a region between the cooling fins 602c and the cooling fins 602c of the bottom surface 602 of the rotor frame 60a. On the embossed portion 602e, a drain hole 602f for water discharge is formed.

On the other hand, the magnet (60b) is shown as the individual pieces are arc-shaped as shown in Fig. 9a, or C-shaped (ie, the convex portion is approximately C-shaped as shown in Fig. 11) C-shaped magnet 60b ").

3B, 13, and 14, the stator 65 is an annular shape in which a multi-layer structure is formed while spirally rotating an iron plate formed of a tooth 654a and a base portion 652a from the lowermost layer to the uppermost layer. Spiral core (65a) of the, and wraps the core to be insulated so as to protrude into the core is formed with a fastening hole for fastening the stator 65 to the fan housing 40 by a fastening member such as bolts (15c) And an insulator 65b having a fastening portion 655b, and a coil 65c wound around the teeth 654a of the core.

At this time, the fastening portion 655b of the stator is formed to protrude at least three places inside the core, and the height of the fastening portion 655b forms 20% or more of the total stack height of the core.

This means that, when there is no separate fastening portion in the core as shown in FIG. 13, the fastening portion 655b of the insulator should be formed so that its height is 20% or more of the total core stacking height, so that vibration generated when driving the motor is sufficient. Because it can endure.

On the other hand, the fastening hole of the fastening portion 655b, the metal tube (65d) is press-fitted, or having a cut portion cut along the longitudinal direction instead of the metal tube (65d) spring pins that are elastic in the radial direction (not shown) ) Can be installed.

The spiral core 65a is wound in a spiral form from the bottom layer to the top layer to form a multi-layer structure, and a plurality of teeth radially outward from the base portion 652a of the spiral core 65a. 654a protrudes in a radial direction, and the base portion 652a of the spiral core 65a is provided with a rectangular or trapezoidal recessed groove 656a to reduce stress when the core is wound.

In addition, the spiral core (65a) is riveted by a rivet 657a penetrating through the through hole formed in the base portion 652a, the winding start portion and the winding end portion of the spiral core (65a) are in contact with each other It is welded to a predetermined site and joined.

On the other hand, the insulator (65b) is wrapped in the core as assembled and assembled as a separate upper and lower pieces as shown in FIG.

The insulator 65b in the case of being manufactured by separate upper and lower pieces includes an insulator upper 650b coupled to the upper side of the core and an insulator lower 651b coupled to surround the lower side of the core.

On the other hand, the insulator 65b is not made of a separate upper and lower pieces, but may be made at a time by molding, of course, the core is processed in the state inserted into the resin.

Operation and blowing process of the blower of the present invention configured as described above is made as follows.

When a current flows sequentially through the coil 65c of the stator constituting the BLDC motor 6 through a tap housing assembly 300 for power connection, the rotor 60 rotates, and the rotor 60 is rotated. The rotor bushing 70 coupled to the serration coupled shaft 68 is rotated, so that power is transmitted to the sirocco fan 50 through the shaft 68 to rotate the sirocco fan, the fan housing (10) Air sucked through the upper and lower air inlets 410a and 410b is discharged through the discharge port O on the front of the outer case 10.

Specifically, as the current is applied to the coil 65c of the stator 65 constituting the BLDC motor 6, mutual electromagnetic force is generated between the stator 65 and the magnet 60b, the sensor (60b) ) By detecting the position of the current and sequentially flowing current to the coil 65c of the stator 65 so that mutual electromagnetic force is continuously generated between the stator 65 and the magnet 60b. The rotor 60 fixed to the magnet 60b rotates and the shaft 68 coupled thereto rotates to transmit the rotational force to the sirocco fan 50.

At this time, the BLDC motor 6 can be operated at various rotational speeds because the torque characteristic is stable, and can be operated at a stable speed, thereby reducing noise generation and further reducing power consumption.

Hall sensor 200 is applied as the sensor for controlling the motor in the above.

In other words, the blower 1 of the present invention, when the sirocco fan 50 by the BLDC motor 6 is rotated, the outside air is sucked into the lower air inlet 410a of the fan housing 40 at the same time a part. After being sucked into the upper air inlet 410b of the fan housing 40 and discharged in the circumferential direction, the fan housing 40 is guided by the fan housing 40 and exits through the outlet O of the outer case 10.

On the other hand, the operation and effect of the blower of the present invention is as follows.

First, since the blower 1 according to the present invention is applied to the BLDC motor 6 which is stable at the most rotational speed and maintains high efficiency in order to drive the blowing fan, the BLDC motor is varied while varying the rotational speed. It is possible to reduce the noise and at the same time reduce the power consumption as the stable and high-efficiency operation is made in the entire speed range.

In addition, the blower (1) according to the present invention can effectively install the BLDC motor (6) to the side where the suction air flow rate of the fan housing is small by using a separate supporter 80, and a part of the BLDC motor is the fan By installing to be inserted into the housing 40 there is an advantage that can reduce the size of the overall blower.

In addition, since the blower 1 according to the present invention has a motor direct type structure, noise and failure, power loss is reduced, and the bearing housing part is made of metal, so there is no thermal deformation, thereby increasing reliability of the product.

In addition, the blower (1) of the present invention, the rotor 60 is a steel plate structure can be manufactured by press molding, so the moldability is excellent, the time required for manufacturing is very short, the productivity is improved.

Meanwhile, the blower 1 according to the present invention has a bent portion 604a having a magnet 60b seating surface on a sidewall surface 604 extending vertically from the edge of the bottom surface 602 of the rotor frame 60a. Is formed along the circumferential direction, when the magnet (60b) is attached to the inner surface of the rotor is made stable support of the magnet (60b) by the seating surface, the production of the rotor (60) is made easy.

In addition, a plurality of cooling fins 602c are formed around the hub portion 602a of the rotor frame 60a so as to have a radial length and a predetermined length in a radial direction, so that the cooling fins when the rotor 60 is rotated. 602c blows air toward the stator to cool the heat generated by the stator 65.

The cooling fin 602c is formed to face the opening side of the rotor 60 by a lancing process, and the through hole 602d formed by the lancing process serves as a vent.

In addition, since the iron plate 60 is easily molded at a time by press working, the time required for manufacturing the rotor becomes very short, and productivity can be improved.

In addition, the rotor 60 has a form in which the end of the opening of the side wall surface 604 of the rotor frame 60a is firstly bent radially outward, and the end thereof is secondly bent in the direction of the bottom surface 602, so that the rotor Increasing the rigidity of the frame (60a) serves to prevent the distortion of the rotor (60) generated during high-speed rotation and the resulting noise in advance.

In addition, in the region between each cooling fin 602c and the cooling fin 602c of the bottom surface 602 of the rotor 60, the embossing portion 602e improves the overall strength of the rotor 60, and the embossing The drainage hole 602f formed in the part 602e enables the discharge of water to the outside of the motor.

And, the rotor bushing 70 of the present invention is injection molded as a resin material, the vibration mode is different from the rotor frame (60a) made of iron plate so that the vibration of the rotor 60 is attenuated to be transmitted to the shaft (68). do.

Further, in the present invention, by adopting a spiral core 65a having an easy winding structure, it is possible to prevent waste of the base material and to increase the ease of manufacture, and the rigidity of the stator fixing part 84 of the supporter 80 can be improved. Increase noise, reduce vibration and improve mechanical reliability and extend life.

That is, the recess groove 656a formed in the base portion 652a of the spiral core 65a constituting the stator 65 reduces the stress during winding of the core, thereby helping the winding operation to be easily performed with a smaller force.

12 and 13, since the fastening portion 655b of the resin insulator 65b is formed so that its height is 20% or more of the total core stacking height, the core, which is a metal, is positioned at the fastening portion. Even if it is not, it will have sufficient rigidity, preventing damage to the fastening portion 655b due to the vibration generated when the motor is driven.

In particular, the height of the fastening part 655b is most preferably formed to be the overall height of the stacked cores.

The height of the fastening part 655b may be equal to or greater than the total height of the stacked cores. However, when the height of the fastening part 655b becomes too large, the overall height of the driving part of the blower becomes large, which is disadvantageous in compacting the blower. In consideration of this, the height of the fastening part 655b is preferably not more than twice the height of the entire core stack.

In addition, the positioning protrusions 656b formed on the fastening part 655b are joined to the positioning grooves 842 of the supporter 80 to facilitate the fastening of the stator 65.

That is, in the present invention, the stator 65 is firmly supported by the supporter 80, and the concentricity of the stator is effectively maintained.

In addition, the blower (1) of the present invention is made of a low-cost metal plate while the fan housing 40 is heat-resistant, thereby making it low cost and good manufacturability.

In addition, the blower 1 of the present embodiment is because the BLDC motor 6 is installed on the air inlet 410b of the air inlet 410a, 410b of the fan housing 40 with a relatively small suction flow rate. In addition to minimizing the suction flow resistance, it is possible to increase the blowing efficiency by enabling stable operation with high efficiency.

Hereinafter, a blower according to a second exemplary embodiment of the present invention will be described with reference to FIGS. 6 to 18.

In describing the present embodiment, the same name is used for the same configuration as the first embodiment, and additional descriptions and overlapping descriptions thereof may be omitted below.

The blower according to the second exemplary embodiment of the present invention includes an outer case 10, air inlets 410a and 410b fixed in the outer case 10 and formed in the upper and lower directions, respectively, and an air outlet formed in the front. The plastic housing having a fan housing 40, the sirocco fan 50, which is a centrifugal fan installed in the fan housing 40, and the sirocco fan 50, are axially connected to drive the driving force of the motor. 50 is inserted into the shaft 68, the bearings 69a and 69b supporting the shaft 68, and the upper surface of the fan housing 40, and the bearings 69a and 69b and the stator (50). The supporter (80 ') 80 to support the 65, the rotor bushing 70 of the insulating material coupled to the opposite end of the fan connection portion of the shaft 68, and the rotor bushing 70 is coupled to the rotor A rotor 60 which transmits a driving force to the shaft 68 through the bushing 70, and the BLDC motor 6 together with the rotor 60. It is configured to include a stator (65) which is installed to be located inside the rotor (60) so as to configure a) and is fixed to maintain concentricity on the supporter (80 ').

At this time, the fan housing 40 has at least an upper surface to which the supporter is fixed is formed of a plastic material, of course, may be formed of a plastic material as a whole.

That is, the part surrounding the sirocco fan 50 is made of a metal plate, and the upper surface to which the supporter is fixed is plastic injection molded to a thickness having sufficient strength to form a fan housing. At this time, the metal plate portion surrounding the sirocco fan is inserted into the part forming the supporter fixing surface of the fan housing.

On the other hand, the supporter may be fastened and fixed to the upper surface of the fan housing by a bolt or the like in a separated state without being inserted into the fan housing.

Then, each surface of the outer case 10 corresponding to the air discharge port and the air suction ports 410a and 410b of the fan housing 40 is opened, and the dog corresponding to the air discharge port side of the fan housing 40 is opened. The grille G is installed on the side.

On the other hand, the fan housing 40, the air inlet 410a is formed on the lower surface, the air inlet 410b that can serve as a through hole for the motor installation is formed on the upper surface spaced a predetermined distance from the lower surface, An air outlet is formed at one side of the side wall surface surrounding the sirocco fan 50 while interconnecting the lower surface and the upper surface.

In addition, the sirocco fan 50 installed inside the fan housing 40 is installed so that its center axis is eccentric with respect to the center line of the upper and lower surfaces of the fan housing 40 as in the above-described embodiment.

Therefore, the size of the space between the fan housing 40 and the sirocco fan 50 is different from each other.

A support bracket 11 is provided between the outer case 10 and the fan housing 40 to support the fan housing to the outer case 10.

The support bracket 11 extends integrally from the outer case 10 and is preferably fastened to the upper surface of the fan housing 40. However, the support bracket 11 may be interposed between the outer case 10 and the fan housing 40 as a separate member. It may be.

On the other hand, the air inlet 410a of the lower surface of the fan housing 40 and the air inlet 410b, which serves as a through hole for installing the motor of the upper surface of the fan housing 40, the shroud 44 for guiding the flow of air introduced therethrough. ') Is provided.

In addition, on the upper surface of the fan housing 40, ribs 400 capable of reinforcing strength while reducing the weight of the fan housing are formed in the circumferential direction and the radial direction.

In addition, referring to FIG. 7B, the supporter 80 ′ inserted into the fan housing upper surface includes a bearing housing portion 82 in which bearings 69a and 69b for supporting the shaft 68 such as ball bearings are installed therein. And a stator fixing portion 84 extending radially outward from the bearing housing portion 82 and providing a surface on which the stator 65 can be fixed, and extending from the stator fixing portion 84. It is made to include a support portion 86 which is buried in the peripheral surface of the air inlet, which also serves as a motor housing through hole of the fan housing, it is preferable to be cast as a metal material such as aluminum. That is, the supporter 80 'has a triangular shape when viewed in plan.

In addition, the supporter 80 ′ is a middle portion that connects between the stator fixing portion 84 and the end of the supporter so that the fastening surface of the stator fixing portion 84 does not protrude to the upper surface of the fan housing 40. The housing 40 is bent upwardly.

In addition, at the inlet of the stator fastening hole on the upper surface of the fan housing 40, a protruding boss for preventing direct contact with the stator fixing part of the supporter so that the insulator of the stator 65 is not damaged by the fastening force applied when the stator is fastened ( 800 is formed.

In addition, the supporter 80 ′ is formed with ribs 88a 88c (see FIG. 7B) to reinforce the strength of the supporter and to improve the bonding force with the resin during the injection of the insert.

In addition, the supporter 80 'and the stator 65 have a positioning protrusion and a positioning groove 842 corresponding to the concentricity when the stator 65 is fastened to the supporter 80'. do.

For example, the stator fixing portion 84 of the supporter 80 is provided with a positioning groove 842 for determining an assembly position with the stator 65, and the positioning projection (step) for positioning on the corresponding stator (65) 656b; see FIG. 12).

On the other hand, the stepped (822a) formed at the bottom of the stepped (822a) (822b) formed on the inner peripheral surface of the bearing housing 82 is installed on the lower side of the bearings respectively installed on the upper and lower sides of the outer peripheral surface of the shaft (68) Stepped 822b is formed in the shape of the letter "a" to form a structure for supporting the upper end of the lower bearing (69a), the upper step of the step (822a) 822b formed on the inner peripheral surface of the bearing housing 82 Is formed in a "b" shape to form a structure for supporting the lower end of the upper bearing (69b) is installed on the upper side.

In addition, the lower bearing and the upper part of the outer circumferential surface of the shaft 68, which is located inside the bearing housing 82 and transmits the driving force of the rotor 60 to the fan housing 40, also on the shaft 68. A positioning step can be formed to allow the installation position of the bearing to be determined.

The operation and effect of the blower of the present embodiment configured as described above is almost the same as in the above-described first embodiment, so that the difference is first mentioned as follows.

First, in the blower of the present embodiment, since the fan housing 40 is made of plastic injection molding, the weight of the fan housing can be reduced.

Next, since the supporter 80 'for fixing the stator 65 is insert molded during the injection molding of the plastic housing, the separate supporter assembly process is omitted.

And, since the fan housing is made of a plastic injection molding, unlike the first embodiment, it is possible to omit the damping member and the damping pad.

On the other hand, the blower 1 of this embodiment exhibits the same effects as the blower according to the first embodiment in the following parts.

That is, since the direct-type BLDC motor 6 which is stable at most rotational speeds and maintains high efficiency is applied, noise and power consumption can be reduced by making stable and high efficiency operation.

In addition, by installing a portion of the BLDC motor to be inserted into the fan housing 40, there is an advantage that can reduce the size of the overall blower.

In addition, since the bearing housing is made of metal, there is no thermal deformation, thereby increasing the reliability of the product.

In addition, the blower 1 of the present embodiment has a steel plate structure and can be manufactured by press molding, so the moldability is excellent and productivity is improved.

On the other hand, the blower (1) of the present embodiment is a stable support of the magnet (60b) by the seating surface when the magnet (60b) is attached to the inner surface of the rotor, it is easy to manufacture the rotor (60).

In addition, a plurality of cooling fins 602c formed around the hub portion 602a of the rotor frame 60a by driving the motor blows air toward the stator through the through hole 602d to cool the heat generated by the stator 65. do.

In addition, the rotor 60 of the present embodiment has a form in which the opening end of the side wall surface 604 of the rotor frame 60a is firstly bent radially outward, and the end thereof is secondly bent in the direction of the bottom surface 602. The stiffness of the rotor frame 60a is increased to prevent distortion of the rotor 60 during high speed rotation.

In addition, in the rotor of the present embodiment, the embossed portion 602e is formed in an area between the cooling fins 602c and the cooling fins 602c of the bottom surface 602 of the rotor 60 so that the overall strength of the rotor 60 is increased. In this case, the drainage hole 602f formed in the embossing part 602e enables the discharge of water to the outside of the motor.

In addition, in the blower of the present embodiment, since the rotor bushing 70 is made of a resin material, the vibration mode is different from that of the iron frame 60a made of iron plate, thereby attenuating vibration transmitted to the shaft 68.

In addition, the blower of the present embodiment can increase the ease of manufacture while preventing the waste of the base material by adopting a spiral core (65a) of easy winding structure.

That is, the recess groove 656a formed in the base portion 652a of the spiral core 65a constituting the stator 65 reduces the stress during winding of the core, thereby helping the winding operation to be easily performed with a smaller force.

12 and 13, since the fastening portion 655b of the resin insulator 65b is formed so that its height is 20% or more of the total core stacking height, the core, which is a metal, is positioned at the fastening portion. Even if it is not, it will have sufficient rigidity, preventing damage to the fastening portion 655b due to the vibration generated when the motor is driven.

In addition, the positioning protrusions 656b formed on the fastening part 655b are joined to the positioning grooves 842 of the supporter 80 to facilitate the fastening of the stator 65.

In addition, the blower of the present embodiment can be fixed to the upper surface of the fan housing 40, the stator 65 is a solid resin material, as well as maintaining the concentricity of the stator effectively.

On the other hand, unlike in the above embodiment, instead of inserting the entire portion of the supporter 80 ', the bearing housing portion 82 of the supporter is inserted into the upper surface during the injection molding of the fan housing, the stator fixing portion 84 The injection molding of the fan housing may be molded so as to be exposed to the outside of the upper surface of the fan housing.

19 is a perspective view showing another type of supporter 80 ", which differs slightly from that shown in FIGS. 4A and 4B, but the basic configuration is the same.

In this case, one form of the reinforcing ribs is different from the reinforcing ribs of FIGS. 4A and 4B. As compared with FIG. 4B, it can be seen that the formation position of the reinforcing ribs 88a is different among the reinforcing ribs.

That is, FIGS. 4A and 4B show a case in which only one reinforcing rib 88a is formed at the center position on the stator fixing part 84 surface, but FIG. 19 shows that the reinforcing rib 88a is on the supporter fixing part 86 surface. It shows the case formed in the form facing each other on both sides of the edge.

In addition, although the specific example is not shown, the supporter 80 extends in a radial direction on an outer circumferential surface of the bearing housing 82 and the bearing housing 82 in which the bearing for supporting the shaft 68 is installed therein. It may be made of only a fixed portion that is formed to be able to fix the supporter on the upper surface of the fan housing 40, and to fix the stator on the opposite side.

That is, in this case, the stator fixing part 84 extends to the supporter fixing part 86 in FIG. 4A, and the existing supporter fixing part will have a disc shape instead of the shape of a change in shape.

FIG. 15 is a perspective view showing another example of a stator applicable to the present invention, and FIG. 16 is a perspective view illustrating a split core as an example of the core structure of FIG. 15. In the case of the stator 65 'of FIG. As the core, a split core is applied instead of the spiral core 65a.

The split core 65a 'is made by forming an iron plate composed of a tooth 654a and a base 652a in a divided form along a circumferential direction on a base material, and then welding the divided core pieces by connecting them together. Core.

W in the figure indicates a welded part.

In this case, although the insulator 65b of the assembled type is applied as a separate piece, the core may be insert-molded as shown in FIG. 17 so that the insulator completely surrounds the core.

FIG. 17 is a perspective view showing another example of the stator applicable to the present invention, and FIG. 18 illustrates the core structure of FIG. 17. In the case of the stator 65 ″ shown in FIG. The iron plate composed of the teeth 654a and the base portion 652a instead of the spiral core 65a or the split core shows that a tubular core 65a " that is freely cut along the circumferential direction may be applied. The structure is as shown in FIG.

In FIG. 17, the core is insert-molded so that the insulator completely surrounds the core. However, in this case, the insulator in the form of being assembled together as a separate piece may be applied as in FIG. 16.

On the other hand, in the above embodiment, the sirocco fan 50 is crimped to the flat section 685 formed on the outer peripheral surface of the end portion of the end of the bolt 68 passing through the bolt fastening hole 560c of the bushing 56 As it is fastened rotatably together with the shaft 68, it is not necessarily such a fastening structure can couple the sirocco fan 50 to the shaft 68.

Although not shown, the central portion of the main plate 54 and the shaft 68 of the sirocco fan 50 in the same construction principle that the rotor bushing 70 and the shaft 68 penetrating the center thereof are fastened to each other by bolts 15b. The sirocco fan 50 and the shaft 68 may be fastened to each other by bolts penetrating the end surface of the backplane.

Hereinafter, an example in which the blower 1 having the above-described configuration is applied to an outdoor unit of an air conditioner having a front suction discharge method will be described with reference to FIGS. 20 to 22.

20 to 22 is a partially cutaway perspective view and an exploded perspective view and a front view showing the installation state of the air conditioner outdoor unit of the front suction method according to the present invention, the outdoor unit of the air conditioner of the front suction method according to the present invention, FIG. As shown in FIGS. 20 to 22, various components are installed inside the case 10 ′ formed to open the front surface, and the outdoor unit of the front suction method is an exterior wall 2 of a residential and / or commercial building. It is installed on the inner wall of the rectangular shape formed in the.

Specifically, the outer frame 4 is fixedly installed on the inner wall of the space formed on the outer wall 2 of the building, the inner frame 5 inside the outer frame 4 is fixed to the outer frame 4 ( In some cases, the inner and outer frames 4 and 5 may be integrally formed, and the inner region of the inner frame 5 may be partitioned vertically into the suction region 7a and the discharge region 7b. The intermediate separator 9 is installed to cross the middle, and a plurality of louver blades 8 are installed in each region to allow air to be sucked in or discharged through the gaps between the louver blades 8, and the inner frame (5) An outdoor unit is installed to be in close contact with the inside, and a sealing member S is provided between the inner frame 5 and the outdoor unit to prevent air leakage and to cushion vibration.

The outdoor unit for the air conditioner of the front suction and discharge system installed as described above is formed with a suction port I and a discharge port O so as to be partitioned with each other at the lower side and the upper side of the open front of the case 10a, and inside the suction port I. A compressor (not shown) and a heat exchanger 20 for compressing and condensing a refrigerant are installed. A blower 1 is built in the discharge port O to blow air, and in particular, the blower ( 1) is a blowing fan inside the fan housing 40 fixedly installed inside the discharge port O, a sirocco fan 50, which is a kind of centrifugal fan, is connected to the sirocco fan and rotates the sirocco fan 50. The driving BLDC motor 6 is installed to be fixed to the fan housing 40 by a separate supporter 80.

Here, the case 10a is formed with a suction part 11a and a discharge part 11b inside the suction port I and the discharge port O so as to correspond to the suction area 7a and the discharge area 7b, respectively. In order to prevent invasion of a large sized foreign substance, a bee, an animal, etc., the grille G is preferably provided at each of the suction port I and the discharge port O on the open front surface.

For reference, the case 10a is not only considering the front suction, but also considering the installation of a heat exchanger, etc., so that the structure may be slightly different from the case 10 of the blower described above.

In addition, the case 10a is installed in the suction part 11a and the discharge part 11b such that various components such as the compressor and the heat exchanger 20 are fixed to brackets (not shown) of various shapes. The case 10a is installed such that an open front circumferential portion is in close contact with the sealing member S inside the inner frame 5.

Of course, the compressor and the heat exchanger 20 are installed to be connected by the indoor unit side heat exchanger (not shown) and the refrigerant pipe, and in addition, expansion means (not shown) such as a capillary tube or an electronic expansion valve are also used as the outdoor unit side heat exchanger. The refrigerant is installed between the indoor unit and the indoor unit by a refrigerant pipe, and the refrigerant is circulated along the refrigeration cycle consisting of the compressor, the outdoor unit side heat exchanger 20, the expansion unit, and the indoor unit side heat exchanger. It expands and evaporates to cool the space installed in the indoor unit.

At this time, the outdoor unit side heat exchanger 20 is provided with a plurality of cooling fins 602c in a state in which a plurality of refrigerant pipes are arranged to be bent, and configured to be bent in a 'U' shape to form a suction part of the case ( The control box 30 is installed at 11a), and the compressor is installed at the inside thereof, and the control box 30 for controlling the operation of various components included in the outdoor unit is installed at the rear side of the compressor.

In addition, the blower 1 is fixedly installed above the outdoor unit side heat exchanger 20, and the sirocco fan 50 and the BLDC motor 6 are connected to each other, and then the supporter 80 is used. And fixedly installed so that the sirocco fan 50 and the BLDC motor 6 are embedded in the fan housing 40, and the fan housing 40 is located at the discharge part 11b of the case 10a. It is installed to be fixed by a separate fixing bracket (not shown) on the outdoor unit side heat exchanger 20.

Specifically, the sirocco fan 50 is a kind of centrifugal fan that sucks air in the axial direction and discharges it in the circumferential direction, and the air volume is increased relatively compared to the axial fan.

And, the structure of the sirocco fan 50 follows the structure of the above-described embodiment.

Next, the fan housing 40 has air inlets 410a and 410b on the top and bottom surfaces thereof, respectively, so as to suck air passing through the outdoor unit side heat exchanger 20 in the axial direction of the sirocco fan 50. Is formed, and each air inlet 410a, 410b is preferably provided with a shroud 44 to guide the air sucked into the sirocco fan 50, the circumference of the sirocco fan 50 An air discharge port is formed on the front surface to discharge the air in the direction.

At this time, the air discharge port of the fan housing 40 is in communication with the discharge port (O) of the case (10a).

On the other hand, the BLDC motor 6 uses a drive circuit instead of a brush in converting alternating current into a direct current, and since there is no brush, spark does not occur and there is little risk of gas explosion, and at most rotational speeds. Drives stably while maintaining high efficiency of about 70 to 80%, specifically, the shaft 68 for transmitting power to the sirocco fan 50 and the shaft 68 by generating a rotational force by mutual electromagnetic force to drive the shaft 68 The stator 65 and the rotor 60 and the magnet 60b, and the Hall sensor 200 for controlling the current supplied by detecting the position of the rotor 60.

In particular, the BLDC motor 6 is fixed by the supporter 80 on the air inlet 410b side of the upper surface of the fan housing 40 having a relatively small suction flow rate in order to reduce the suction flow resistance.

In detail, the shaft 68 is installed to be supported by the supporter 80 by bearings 69a and 69b such as ball bearings so as to be rotatable in a state of passing through the supporter 80 and the end thereof is the sirocco. The center of the fan 50 and the upper shaft center of the sirocco fan 50 are connected to each other by a method such as bolting or caulking, and the stator 65 is spaced apart from the outer edge of the shaft 68 by the supporter ( 80) to be fixed.

In addition, the rotor 60 is the outer diameter portion is located on the outer periphery of the stator 65 and the inner diameter portion is fixed to the shaft 68, the bottom surface of the rotor can be reinforced even if a centrifugal force is generated A plurality of ribs or embossing portions are formed in the radial direction so that the plurality of permanent magnets 68 may generate mutual electromagnetic force with the stator 65 in the outer diameter portion of the rotor 60 at predetermined intervals in the circumferential direction. It is fixed so that, and the Hall sensor 200 is installed to be fixed to the core side of the stator (65).

Therefore, when current flows sequentially through the coil 65c of the stator 65, the rotor 60 is rotated by the mutual electromagnetic force of the current flowing through the coil and the magnet 60b, and the The rotational force drives the sirocco fan 50 to rotate by the shaft 68.

Next, the supporter 80 is installed such that the sirocco fan 50 and the BLDC motor 6 are suspended inside the fan housing 40. Specifically, the shaft 68 is the bearing 69a. A cylindrical bearing housing portion 72 which is arranged to be rotatable by a 69b, and a stator fixing portion integrally formed at an upper end of the bearing housing portion 72 and fixedly installed in a state where the stator 65 is raised ( 84) and a plurality of supporter fixing parts 86 formed to protrude in a radial direction at predetermined intervals on the circumference of the stator fixing part 84 and fixed around the air inlet 410b of the upper surface of the fan housing 40. Is done.

At this time, the bearing housing 72 has a cylindrical shape formed shorter than the shaft 68, and the bearings 69a and 69b are installed inside the upper and lower ends to support the shaft 68 so as to be rotatable. The stator fixing part 84 has a plurality of positioning grooves 842 and fastening holes 846 are formed to be screwed in the state in which the stator 65 is inserted into the upper surface.

In addition, the supporter 80 is preferably three supporter fixing portion 86 is formed while maintaining a 120 ° interval around the bearing housing 82 and the stator fixing portion 84 to distribute the load to support In order to reinforce the strength of the supporter fixing part 86, the bearing housing part, the stator fixing part 84, and the supporter fixing part (to support the lower side of the stator fixing part 84 and the supporter fixing part 86) Reinforcing ribs 88a are formed between the 86, and it is more preferable that a plurality of auxiliary reinforcing ribs 88b and 88c are formed on the upper surface of the supporter fixing part 86.

In particular, the supporter fixing portion 86 is formed to protrude radially from the stator fixing portion 84, and the middle portion is formed to be inclined upward toward the radial direction, and the vibration damping member fixing hole in the horizontal portion of the end thereof. 866 is formed, and thus the supporter 80 is installed such that the supporter fixing part 86 is fastened around the upper air inlet 410b of the fan housing 40.

Looking at the assembly process of the blower which is the main part of the present invention configured as described above and the operation of the outdoor unit are as follows.

First, the BLDC motor 6 has the shaft 68 rotatably installed in the bearing housing 82 of the supporter 80 by the bearings 69a and 69b, and the stator 65 is rotatable. The shaft assembly is screwed to the upper surface of the stator fixing portion 84 of the supporter to form a motor assembly. The motor assembly has the shaft 68 positioned with the sirocco fan 50 inside the fan housing 40. It is installed to be connected to the center of the shaft of the sirocco fan 50, the supporter fixing portion 86 of the supporter 80 is assembled and fixed by bolts in a state raised around the air inlet 410b of the upper surface of the fan housing. .

Therefore, the blower 1 in which the BLDC motor 6 is assembled is fixedly installed by a separate bracket in a state of being mounted on the outdoor unit side heat exchanger 20, and the BLDC motor 6 is operated. It is installed to be connected by the control box 30 and the wire to control the.

Looking at the operation of the outdoor unit assembled as described above, the compressor is operated according to the signal of the control box 30, and the refrigerant flows into the indoor unit through the compressor, the outdoor unit side heat exchanger 20, expansion means And circulates along the indoor unit side heat exchanger.

At this time, since the refrigerant is circulated to the outdoor unit side heat exchanger 20 and the sirocco fan 50 is driven by the BLDC motor 6, the air sucked through the inlet I of the case 10a is After passing through the outdoor unit side heat exchanger 20, the refrigerant is heat-exchanged to condense the refrigerant, and then the heat-exchanged air is discharged through the discharge port O of the case 10a through the sirocco fan 50.

Of course, the BLDC motor 6 may be operated at various rotational speeds because the torque characteristic is wide, and thus, the noise may be reduced as it is stably operated, and further, power consumption may be reduced.

Therefore, since the BLDC motor 6 sucks air in the axial direction as the sirocco fan 50, which is a kind of centrifugal fan, is rotated, most of the air passing through the outdoor unit side heat exchanger 20 is in the fan housing. While being sucked into the lower air inlet 410a of the portion 40, a portion thereof is sucked into the upper air inlet 410b of the fan housing, and by the shrouds 44 formed on the respective air inlets 410a and 410b. Guided is introduced in the axial direction of the sirocco fan 50 and discharged in the circumferential direction, guided by the fan housing 40 through the discharge port (O) of the case (10a) communicated to the air outlet of the fan housing Get out.

At this time, since the BLDC motor 6 is installed at the air inlet 410b of the air inlet 410a and 410b of the fan housing 40, the suction flow resistance can be reduced. In addition, the high efficiency and stable driving can increase the blowing efficiency and heat exchange efficiency.

Hereinafter, a blower according to another embodiment of the present invention will be described with reference to FIGS. 23 and 24.

First, FIG. 23 is a configuration diagram of a blower according to another embodiment of the present invention, in which the blower of the present embodiment is fixed to a fan housing and the fan housing, and sucks air from a side or bottom to discharge the upper portion. An axial fan installed therein, a shaft axially connected to the axial fan to transfer the driving force of the motor to the fan, a bearing supporting the shaft, and a supporter coupled to the lower wall of the fan housing to support the bearing and the stator. And a rotor bushing of an insulating material coupled to the lower end of the shaft opposite to the blower fan connection side of the shaft, a rotor coupled to the rotor bushing to transmit a driving force to the shaft through the rotor bushing, and a BLDC motor together with the rotor. And a stator installed to be positioned inside the rotor and fixed to maintain concentricity on the supporter. .

At this time, the blower further includes a water penetration prevention cover to prevent water from flowing into the motor side on the rotor and the stator upper side.

On the other hand, the supporter may be formed to serve as a water-permeable cover.

That is, the blower of the present embodiment has an axial fan, characterized in that the air discharge direction is directed to the upper side, since the air discharge direction is directed to the upper side, if it is installed outdoors, rainwater is expected to flow into the motor side. In order to prevent this, a water-permeable cover may be installed, or the supporter may be configured to serve as a water-permeable cover.

The rest of the stator, the rotor, and the rotor bushing are the same as those of the above-described embodiment, and thus, further description is omitted to avoid duplication.

On the other hand, Figure 24 is a block diagram of a blower according to another embodiment of the present invention, the blower of the present embodiment is fixed to the fan housing and the inside of the fan housing, the air is sucked from the rear or side to discharge to the front An axial fan installed to be connected to the axial fan, a shaft axially connected to the axial fan to transfer a driving force of the motor to the fan, a bearing supporting the shaft, and a rear wall portion of the fan housing to support the bearing and the stator. A supporter, a rotor bushing of an insulating material coupled to the rear end opposite to the blower fan connection side of the shaft, a rotor coupled to the rotor bushing to transfer driving force to the shaft through the rotor bushing, and a BLDC motor together with the rotor. And a stator installed to be located inside the rotor so as to be configured and fixed to maintain concentricity on the supporter. It is.

That is, the blower of the present embodiment has an axial fan, characterized in that the air discharge direction is directed forward, the upper surface of the fan housing is rain water in order to prevent water inflow to the motor side because the air discharge direction is directed forward It is desirable to have a closed structure to prevent penetration of the back.

On the other hand, in the stator of the BLDC motor shown in the embodiment of the present invention, the winding method of the coil is a concentrated zone, but is not necessarily limited thereto, and the winding system of the coil 65c as shown in FIG. 65 ") is also applicable.

The stator 65 " is also provided with a fastening portion 655b on an insulator 65b made of resin, and is fastened to the positioning groove 842 of the supporter 80 around the fastening portion to thereby secure the fastening of the stator 65. Of course, the positioning projections 656b that can be easily made can be formed.

On the other hand, although some embodiments have been described above, it will be apparent to those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope thereof.

Accordingly, the above-described embodiments should be considered illustrative rather than restrictive.

As described above, since the blower of the present invention is applied to the BLDC motor that is stable at the most rotational speed and maintains high efficiency, the rotational speed can be changed in various ways, and stable and high efficiency operation is achieved in the entire rotational speed range. Accordingly, there is an advantage of reducing noise while driving the blower and reducing power consumption.

In addition, the blower of the present invention can effectively install the BLDC motor in the fan housing, as well as install a part or all of the BLDC motor to be inserted into the fan housing to reduce the size of the overall blower has the advantage have.

Claims (56)

Metal fan housing, A blowing fan installed inside the fan housing; A shaft axially connected to a blowing fan installed inside the fan housing and transmitting a driving force of the motor to the blowing fan; A supporter fixed to the fan housing; A rotor coupled to an end opposite to the fan housing connecting side of the shaft, the rotor including a rotor frame forming a body, and a magnet provided inside the rotor frame; And a stator installed to be positioned inside the rotor and fixed to maintain concentricity on the supporter. The method of claim 1, The supporter is a metal material, the blower, characterized in that fixed to the supporter fixing surface of the fan housing. The method of claim 1, The supporter, A bearing housing part in which the bearing for supporting the shaft is installed; And a fixing part extending outward from the bearing housing part to fix the supporter to the supporter fixing surface of the fan housing and to provide a surface for fixing the stator. The method of claim 3, wherein The supporter, The supporter fixing part is characterized in that the blower device is characterized in that the form extending radially extending in at least three directions from the bearing housing. The method of claim 1, The supporter, A bearing housing part in which the bearing for supporting the shaft is installed; A supporter fixing part which extends radially outward of the bearing housing part to fix the supporter to the supporter fixing surface of the fan housing; And a stator fixing part formed to connect between the supporter fixing parts and providing a surface on which the stator can be fixed. Plastic fan housing, A blowing fan installed inside the fan housing; A shaft axially connected to a blowing fan installed inside the fan housing and transmitting a driving force of the motor to the blowing fan; A metal supporter fixed to the outside of the fan housing; A rotor frame coupled to the rear end of the shaft and including a rotor frame forming a body, and a magnet provided inside the rotor frame; And a stator positioned inside the rotor and fixed to maintain concentricity on the supporter. The method of claim 6, The supporter, A bearing housing part in which the bearing for supporting the shaft is installed; The blower device is integrally formed with the bearing housing and extends to the outside thereof, and includes a fixing part for fixing the supporter to an outer surface of the fan housing and providing a surface for fixing the stator. . The method of claim 7, wherein The supporter, The supporter fixing part is characterized in that the blower device is characterized in that the form extending radially extending in at least three directions from the bearing housing. The method of claim 6, The supporter, A bearing housing part in which the bearing for supporting the shaft is installed; A supporter fixing part integrally formed with the bearing housing part and extending radially outward to fix the supporter to an outer surface of the fan housing; And a stator fixing part formed to connect between the supporter fixing parts and providing a surface on which the stator can be fixed. The method according to claim 8 or 9, Blowing device, characterized in that the end of the supporter fixing portion is bent to the rear of the fan housing. The method according to claim 8 or 9, The end portion of the supporter fixing portion is bent back to the fan housing compared to the stator engaging surface, when the supporter is assembled to the fan housing, at least the stator engaging surface of the supporter is located in the fan housing. The method according to any one of claims 6 to 9, The supporter is a blower, characterized in that the fastening is coupled to the supporter fixed surface of the fan housing. The method according to any one of claims 6 to 9, The supporter is a blower, characterized in that the injection molding is inserted into the supporter fixed surface of the fan housing, the injection molding of the fan housing. The method according to claim 7 or 9, The bearing housing part of the supporter is inserted on the supporter fixing surface during injection molding of the fan housing, The supporter fixing part or the stator fixing part of the supporter is blow molding apparatus characterized in that the injection molding so as to be exposed to the outside of the fan housing during the injection molding of the fan housing. The method of claim 6, The supporter, A bearing housing made of metal inserted into the fan housing during injection molding; It is formed separately from the bearing housing, the blower characterized in that made of a stator fixing member fastened to the fan housing or the bearing housing. delete A fan housing made of a plastic material, at least through which the shaft penetrates, A blowing fan installed inside the fan housing; A shaft axially connected to a blowing fan installed inside the fan housing and transmitting a driving force of the motor to the blowing fan; A metal supporter fixed to the fan housing; A rotor frame coupled to the rear end of the shaft and including a rotor frame forming a body, and a magnet provided inside the rotor frame; And a stator installed to be positioned inside the rotor and fixed to maintain concentricity on the supporter. The method of claim 17, The supporter is a blower, characterized in that fastening is coupled to the fan housing. The method of claim 17, The supporter is a blower, characterized in that the insert during the injection molding of the fan housing. The method of claim 17, The supporter, A bearing housing part inserted during injection molding of the fan housing of the supporter; And a supporter fixing part integrally formed with the bearing housing part and exposed to the outside of the fan housing during injection molding of the fan housing. The method of claim 17, The supporter, A bearing housing made of metal inserted into the fan housing during injection molding; It is formed separately from the bearing housing, the blower characterized in that made of a stator fixing member fastened to the fan housing or the bearing housing. The method according to any one of claims 1, 6 and 17, The rotor frame, And a bottom plate forming a substantially disk shape and a side plate surface extending substantially perpendicularly from the edge of the bottom surface. The method according to any one of claims 1, 6 and 17, The rotor frame, And an injection molding comprising a bottom surface forming a substantially disk shape and a side wall surface extending substantially perpendicularly from the bottom edge. The method according to any one of claims 1, 6 and 17, The rotor frame, An air blower, comprising: an iron plate comprising a bottom surface forming a substantially disk shape, a side wall surface extending substantially perpendicularly from the edge of the bottom surface, and an outer surface of the iron plate. The method of claim 22, The rotor frame is a blower, characterized in that formed integrally by pressing. The method of claim 22, The rotor frame, On the sidewall surface extending forward from the bottom edge, a bent portion having a seating surface for supporting a magnet mounted in front of the inner surface thereof is formed along the circumferential direction, And a hub portion having a through hole formed therein, through which a fastening member for coupling the rotor to the shaft is formed at the center of the bottom surface thereof. The method of claim 26, Around the hub portion of the rotor frame, When the rotor is rotated, a plurality of cooling fins are radially formed to blow air into the stator to cool the heat generated in the stator. The cooling fan is a blower, characterized in that formed to have a predetermined length in the radial direction. The method of claim 27, The cooling fin is formed so as to face the opening side of the rotor by the lancing process, the through-holes formed by the lancing process, characterized in that to act as a vent. The method of claim 28, Blowing apparatus, characterized in that the cooling fin is bent at an angle of 90 ° toward the opening side of the rotor. The method of claim 27, In the area between the cooling fins and the cooling fins on the bottom of the rotor frame, Embossing portion for strength reinforcement of the rotor is formed, Blowing device, characterized in that the drainage hole for water discharge is formed on the embossed portion. The method according to any one of claims 1, 6 and 17, And a rotor bushing between the rotor and the shaft for transmitting the driving force of the rotor to the blowing fan. The method of claim 26, At the edge of the through hole formed in the hub portion of the rotor, A blower for fastening a rotor bushing coupled to the outer circumferential surface of the rear end of the shaft coupled to the blower fan and a positioning hole for determining an assembly position of the rotor bushing are formed at a predetermined interval. . The method of claim 26, And a serration for mutual engagement is formed on an inner circumferential surface of the hub of the rotor bushing and an outer circumferential surface of a rear end of the shaft corresponding thereto. The method of claim 32, The rotor bushing, A fastening hole corresponding to the fastening hole formed in the hub portion of the rotor along the circumferential direction is formed in the edge region thereof, And a positioning protrusion integrally formed between the fastening holes so that the fastening holes of the rotor and the rotor bushing are automatically matched as they are inserted into the positioning holes of the rotor. The method of claim 33, wherein Blower device, characterized in that the outer side of the hub of the rotor bushing is provided with a reinforcing rib for reinforcing the strength of the hub. The method of claim 31, wherein Blowing device, characterized in that the rotor bushing is made of a resin material. The method according to any one of claims 1, 6 and 17, The stator is a magnetic body forming a magnetic path, and An insulator surrounding the core to insulate the core; And a coil wound around the tooth portion of the core. The method of claim 37, The core is a blower, characterized in that the iron plate consisting of a tooth and the base portion is a tubular core connected to the tubular without breaking along the circumferential direction. The method of claim 37, The core is a blower, characterized in that the iron plate consisting of a tooth and the base portion is made in a divided form along the circumferential direction on the base material, and then divided core pieces by connecting the divided core pieces into one. The method of claim 37, The core is a blower, characterized in that the spiral spiral core to form a multi-layer structure while rotating the iron plate consisting of a tooth and the base portion from the bottom layer to the top layer spirally. The method of claim 37, The insulator is blown apparatus, characterized in that the insert is formed to surround the core. The method of claim 38, The insulator is, An insulator upper coupled to the upper side of the core, Blower device characterized in that consisting of an insulator lower coupled to surround the lower side of the core. The method according to any one of claims 3, 7, 20, and 21, The stepped step formed at the front of the step formed on the inner peripheral surface of the bearing housing is formed in a "-" shape to form a structure for supporting the rear end of the front bearing installed in the front end of the bearings respectively installed on the outer peripheral surface of the both ends of the shaft , Blower device characterized in that the step formed on the rear of the step formed on the inner surface of the bearing housing is formed in the "b" shape to form a structure for supporting the front end of the rear bearing is installed in the rear end. The method of claim 43, Located in the bearing housing and in front and rear of the outer peripheral surface of the shaft for transmitting the driving force of the rotor to the fan housing, And a positioning step for allowing the installation positions of the front bearing and the rear bearing on the shaft to be determined, respectively. The method of claim 43, The front end of the shaft is blower, characterized in that coupled to the main plate provided in the blowing fan. The method according to any one of claims 1, 6 and 17, The fan housing and the supporter, Blowing apparatus, characterized in that the positioning projection and the positioning groove to be formed to correspond to each other so as to match the assembly position when the supporter is installed in the fan housing. The method according to claim 3 or 7, On the supporter fixing surface of the fan housing and the supporter fixing portion of the supporter, When installing the supporter in the fan housing, Blowing device, characterized in that the positioning projection and the positioning groove to be aligned to correspond to each other. The method according to claim 5 or 9, On the supporter fixing surface of the fan housing and the stator fixing portion of the supporter, Blowing apparatus, characterized in that the positioning projection and the positioning groove to be formed to correspond to each other so as to match the assembly position when the supporter is installed in the fan housing. The method of claim 46, The positioning projection and the positioning groove is a blower, characterized in that to form an arc or a long hole. The method according to any one of claims 1, 6 and 17, In the supporter and stator, Blowing device, characterized in that the positioning projection and the positioning groove that can match the concentricity when the stator is fastened to the supporter is formed to correspond to each other. The method according to claim 3 or 7, In the supporter fixing portion and the stator of the supporter, Blowing device, characterized in that the positioning projection and the positioning groove that can match the concentricity when the stator is fastened to the supporter fixing portion of the supporter is formed to correspond to each other. The method according to claim 5 or 9, In the stator fixing part and the stator of the supporter, Blowing apparatus, characterized in that the positioning projection and the positioning groove for forming a concentricity when the stator is fastened to the supporter fixing portion formed to correspond to each other. 51. The method of claim 50, The positioning projection and the positioning groove is a blower, characterized in that to form an arc or a long hole. Fan Housing, An axial fan fixed inside the fan housing and installed to suck air from the side or the lower part and discharge the air to the upper part; A shaft axially connected to the axial fan to transfer a driving force of the motor to the fan; A bearing supporting the shaft; A supporter fastened to the lower wall of the fan housing to support the bearing and the stator; And the rotor bushing of the insulating material is coupled to the lower end opposite the blowing fan connection side of the shaft; A rotor coupled to the rotor bushing to transmit a driving force to the shaft through the rotor bushing, the rotor frame forming an approximately body, and a magnet provided inside the rotor frame; And a stator installed to be positioned inside the rotor to form a BLDC motor together with the rotor and fixed to maintain concentricity on the supporter. The method of claim 54, wherein Blowing device, characterized in that the water and the water penetration prevention cover is provided on the rotor and the stator upper side to prevent water from flowing into the motor side. Fan Housing, An axial fan fixed inside the fan housing and installed to suck air from the rear and discharge the air forward; A shaft axially connected to the axial fan to transfer a driving force of the motor to the fan; A bearing supporting the shaft; A supporter fastened to the rear wall portion of the fan housing to support the bearing and the stator; An insulator rotor bushing coupled to the rear end of the shaft opposite to the blower fan connection side; A rotor coupled to the rotor bushing to transmit a driving force to the shaft through the rotor bushing, the rotor frame forming an approximately body, and a magnet provided inside the rotor frame; And a stator installed to be positioned inside the rotor to form a BLDC motor together with the rotor and fixed to maintain concentricity on the supporter.

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