KR101078386B1 - BLC motor for radiator cooling fan - Google Patents

Abstract

The present invention relates to a BCD motor for driving a cooling fan for cooling the radiator, and more particularly, a Hall sensor for rotating the cooling fan directly to the motor, and detects the rotation of the rotor is simply mounted and disposed adjacent to the rotor Reduces misdetection and increases the temperature durability of the motor by cooling not only the radiator but also the motor by the wind generated when the cooling fan is driven.The controller that controls the operation of the motor can be installed outside the housing so that the controller malfunctions due to the heat generated by the radiator. The present invention relates to a BCD motor for a radiator, which is prevented or burned out.
The BCD motor for a radiator cooling fan according to the present invention includes a housing; A stator including a fixed body having a plurality of slots radially disposed on an inner surface thereof, and an insulator coupled to the fixed body, the coil wound around the slot surface, and an insulator insulating the slot; A rotor having an upper portion exposed to the outside of the housing and magnets disposed at equal intervals on an outer circumference thereof and rotatably disposed in a hollow formed by the slot of the stator; An impeller coupled to the shaft exposed to the outside of the housing and mounted with a cooling fan for a radiator; A plurality of Hall sensors for sensing the rotation of the rotor by sensing the magnetic force of the magnet, comprising a coil wound around the inner surface of the upper and lower surfaces of the cover portion of the insulator covering the surface of each of the plurality of slots The anti-separation protrusion is formed to prevent the separation of the protrusion, and the anti-separation protrusion is characterized in that the inner groove is formed with a seating groove for seating the hall sensor.

Description

BLC motor for radiator cooling fan {BLDC Motor for radiator cooling fan}

The present invention relates to a BCD motor for driving a cooling fan for cooling the radiator, and more particularly, a Hall sensor for rotating the cooling fan directly to the motor, and detects the rotation of the rotor is simply mounted and disposed adjacent to the rotor Reduces misdetection and increases the temperature durability of the motor by cooling not only the radiator but also the motor due to the wind generated when the cooling fan is driven. The present invention relates to a BCD motor for a radiator, which is prevented or burned out.

As is well known, a radiator is a device that emits a part of heat generated from an internal combustion engine of a vehicle to the atmosphere through cooling water, and a radiator is generally provided with a cooling fan that sends wind to increase cooling efficiency.

The cooling fan for cooling the radiator is conventionally driven by a belt connected to the vehicle engine shaft.

The heat generated from the radiator causes a lot of errors when the Hall sensor of the motor detects the rotation of the rotor, and because the controller is malfunctioning, the temperature durability of the motor is weak. Therefore, the cooling fan is not directly driven by the motor. It is driven by a connected belt.

However, indirectly rotating the cooling fan by using the belt causes wear of the belt and the like, resulting in inefficiency of the cooling fan, and the need to replace the belt. In other words, the cooling fan needs to be driven directly by the motor.

Of course, instead of driving the radiator cooling fan directly with the motor, it is necessary to increase the detection (detection) capability of the hall sensor, prevent malfunction of the controller, and increase durability against heat as described above.

According to the present invention, the cooling fan of the radiator is directly driven by using a motor to increase the efficiency of the cooling fan, and the durability of the motor is weakened by the radiating heat of the radiator, the controller malfunctions, and the hall sensor detection capability is not reduced. It is an object of the present invention to provide a BCD motor for a radiator having a.

In addition, it is an object of the present invention to provide a BCD motor for a radiator that is easy to assemble the components constituting the motor, and to reduce the generation of vibration when driving the motor.

The BCD motor for a radiator cooling fan according to the present invention for achieving the above object is

housing;

A fixed body having a plurality of slots radially disposed on an inner surface thereof,

A stator coupled to the fixed body, the stator including an coil insulator covering the surface of the slot, and an insulator for insulating the slot;

A rotor having an upper portion exposed to the outside of the housing and magnets disposed at equal intervals on an outer circumference thereof and rotatably disposed in a hollow formed by the slot of the stator;

An impeller coupled to the shaft exposed to the outside of the housing and mounted with a cooling fan for a radiator;

A plurality of Hall sensors for sensing the rotation of the rotor by sensing the magnetic force of the magnet;

An anti-separation protrusion is formed at an upper end portion of the insulator covering the surface of each of the slots and an inner end portion of the lower side of the insulator to prevent the coil from being wound.

The release preventing protrusion is characterized in that the inner end is formed with a seating groove in which the hall sensor is seated.

And the upper surface of the impeller is formed in the annular protruding annular projection portion is inserted into the inner surface of the mounting hole of the cooling fan,

The inside of the stepped portion is characterized in that a plurality of passage holes to be a flow path of air generated when the cooling fan is driven through the upper and lower,

The plurality of Hall sensors are mounted, further comprising a PCB bolted to the separation prevention projections,

The seating grooves are formed at both sides of the release preventing protrusions, and the hall sensor is disposed between two adjacent seating recesses and is disposed between two adjacent preventing protrusions.

The rotor is the shaft is formed through the top and bottom, the outer periphery of the rotor and the magnet is arranged at equal intervals,

Further comprising an upper bearing and a lower bearing coupled to the upper and lower portions of the shaft,

The insulator of the stator is composed of an upper insulator and a lower insulator inserted into the upper and lower portions of the stator to cover the slot surface, respectively.

The housing is composed of an upper housing and a lower housing which are assembled and engaged with each other,

Inner surfaces of the upper housing and the lower housing are formed with receiving grooves for accommodating the upper and lower bearings, respectively, and a plurality of heat dissipation fins are formed on the outer periphery in the vertical direction.

Cable holes are formed on the lower edge of the lower housing,

And a controller electrically connected to the coil and the hall sensor to control the coil and the hall sensor, wherein the controller is electrically connected to the coil and the hall sensor through a cable inserted into the cable hole and disposed outside of the housing, thereby providing a It is characterized by less influence of heat generated.

The BCD motor for a radiator cooling fan according to the present invention having such a configuration can directly drive the cooling fan to increase efficiency and driving reliability of the cooling fan.

Hall sensor to detect the rotation of the rotor is placed adjacent to the rotor to reduce the detection error, can be easily mounted on the insulator,

The controller is provided outside the housing, so there is little risk of malfunction or burnout due to heat.

The wind (air) generated during the operation of the cooling fan is sent to the motor as well as the radiator to cool the motor, and the heat radiating fins formed in the housing increase the heat dissipation (cooling) efficiency of the motor to increase the temperature durability of the motor.

The components constituting the motor are assembled quickly and easily, and the rotor is a BCD motor for a radiator cooling fan that rotates smoothly while minimizing the occurrence of vibration, which is a very useful invention for industrial development.

1 is a perspective view of the cooling fan for the radiator is mounted on the BCD motor according to the present invention,
FIG. 2 is an exploded perspective view of FIG. 1;
3 is a cross-sectional view of FIG. 1.

As shown in the figure, the BCD motor for a radiator cooling fan according to the present invention includes a housing 10, a stator 20, a rotor 30, an impeller 50, and a hall sensor 40.

The housing 10 is composed of an upper housing 10A and a lower housing 10B which are engaged with each other and assembled.

The contact surface of the upper housing 10A and the lower housing 10B is formed with a groove 14b and a plurality of protrusions 14a inserted into the groove 14b to be assembled and assembled.

The side wall of the upper housing 10A has a fixing hole 13a penetrating up and down, and the lower housing 10B has a fixing groove 13b formed at a position corresponding to the fixing hole 13a. The bolt is inserted and bolted into the fixing hole 13a and the fixing groove 13b to be assembled to fix the upper housing 10A and the lower housing 10B.

A plurality of heat dissipation fins 11a and 11b are formed on the outer circumference of the upper housing 10A and the housing 10 in the vertical direction. The heat radiating fins 11a and 11b are formed in the vertical direction so that the air flowing in contact with the heat radiating fins 11a and 11b is more maximally utilized by utilizing the wind (flow of air) generated when the cooling fan is driven. Make it high.

And the inner surface of the upper housing (10A) and the lower housing (10B) the receiving groove into which the upper bearing (37a) and the lower bearing (37b), which are respectively coupled to the rotor (30) above and below the shaft (35), is inserted and accommodated ( 12a, 12b) are formed.

In addition, a cable hole 15b through which a cable electrically connecting the controller 60, the coil, and the hall sensor 40 is inserted is formed at the lower edge of the lower housing 10B.

The controller 60 includes various electronic devices, and the electronic devices are weak in heat. Therefore, since the internal temperature of the motor is very high due to the heat generated from the radiator adjacent to the generated heat of the driven motor itself, when the controller 60 is embedded in the motor, the controller 60 is easily malfunctioned by heat and, in the worst case, burns out. This is high.

Therefore, in the present invention, the controller 60 is not embedded in the housing 10 of the motor, and is disposed outside so that the controller 60 is less affected by the self-generating heat of the motor and the radiating heat of the radiator. Instead, the coil and the hall sensor 40 of the motor are replaced. The controller 60 is electrically connected to the controller 60 through a cable inserted into the cable hole 15b so that the controller 60 can supply driving power to the coil and receive a detection signal from the hall sensor 40. .

And although the Hall sensor 40 is a kind of electronic device having a problem that is vulnerable to heat, the Hall sensor 40 must be embedded in the housing 10 because it must detect the magnetic force change of the magnet (33) of the rotor (30). In order to prevent a problem in which the hall sensor 40 malfunctions or burns out due to heat as it is essentially embedded in the housing 10, the present invention uses a motor by the heat radiating fins 11a and 11b and the channel hole 53 to be described below. A structure for cooling was introduced.

The stator 20 is embedded in the housing 10 and includes a fixture 21 and an insulator 23.

The fixing body 21 is formed by stacking a plurality of thin steel sheets of silicon, and each silicon steel sheet is formed with alignment grooves 22 for guiding alignment at the time of lamination.

A plurality of slots in which coils (not shown) are wound are radially disposed on the inner surface of the fixture 21.

The insulator 23 includes an upper insulator coupled to an upper portion of the fixture 21 and a lower insulator 23b coupled to a lower portion of the insulator 23, and the plurality of upper insulators 23a and 23b respectively include the plurality of insulators. A lid 24 is provided that covers the top and bottom surfaces of each slot. The cover part 24 covers the surface of the slot to insulate the coil and the slot wound thereon.

An anti-separation protrusion 25 which protrudes from a coil wound around the upper and lower surfaces of the upper and lower insulators 23a and 23b is formed.

In addition, some of the separation prevention protrusions 25 of the separation prevention protrusions 25 provided in the lower insulator 23b are formed with fastening holes 26 to which the PCB 41 on which the plurality of Hall sensors 40 are mounted is fastened. In addition, the separation preventing protrusion 25 covered by the PCB 41 has a seating groove 27 on which the hall sensor 40 is seated.

In addition, the seating grooves 27 are formed at both sides of the release preventing protrusions 25. That is, two seating grooves 27 formed on the left and right sides of two adjacent anti-separation protrusions 25 form one seating groove 27 having a longer width, and the hall sensor 40 has two seating grooves adjacent to each other. (27) is disposed between the two separation preventing projections 25 are seated in the seating grooves 27 facing each other.

Thus, the hall sensor 40 seated in the seating groove 27 is disposed closer to the rotor 30, and is disposed in the space between the two departure preventing protrusions 25 so as to view the magnetic force change of the rotor 30 rotating. It can be detected accurately.

The rotor 30 is rotatably disposed in the hollow formed by the slots of the stator 20, and includes a rotor 31, a magnet 33, a shaft 35, and upper and lower bearings 37a and 37b. Is done.

The rotor 31 is disposed in the hollow, and the magnet 33 is disposed at equal intervals on the outer periphery of the rotor 31. The magnet 33 may be attached to the outer periphery of the rotor 31, and may magnetize the outer periphery of the rotor 31 at equal intervals.

The shaft 35 is arranged to penetrate vertically through the center of the rotating body 31, the upper portion is exposed to the outside of the housing 10.

The upper and lower bearings 37a and 37b are coupled to the upper and lower portions of the shaft 35 exposed upward and downward of the rotating body 31, respectively, and the upper and lower bearings 37a and 37b are Received in the receiving grooves (12a, 12b) provided in the upper and lower inner surface of the housing 10, respectively, so that the rotor 30 rotates more smoothly without vibration.

The impeller 50 is coupled to the shaft 35 exposed to the outside of the housing 10, and the cooling fan F is fixedly coupled to rotate (drive) the cooling fan coupled as the rotor 30 rotates. Let's do it.

The impeller 50 is fixedly coupled to the shaft 35 through a fixing key 57, and an upper step portion 51 which catches concentric circles of the cooling fan to which the inner surface of the mounting hole of the cooling fan is inserted and contacted. ) Is formed in an annular shape.

In addition, a plurality of bolt holes 55 are formed on the outside of the stepped part 51 of the impeller 50 to fix the mounted cooling fan with bolts, and a plurality of flow path holes 53 are formed on the inner side of the impeller 50. It is.

The flow path 53 is the air generated when driving the cooling fan is sent to the surface of the housing 10 through the flow path hole 53, or through the flow path hole 53 through the surface of the housing 10, More air is forced to contact the surface of the housing 10 to dissipate heat from the housing 10, thereby allowing the housing 10 to dissipate quickly and efficiently.

In the above description of the present invention with reference to the accompanying drawings, a description of the BCD motor for a radiator cooling fan having a specific shape and structure, but the present invention can be variously modified and changed by those skilled in the art, such modifications and changes It should be interpreted as falling within the protection scope of the invention.

10A, 10B: Upper and lower housing 11a, 11b: Heat dissipation fin
12a, 12b: receiving groove 15b: cable hole
20: stator 21: fixed body
23a, 23b: upper and lower insulator 24: cover
25: departure preventing protrusion 27: seating groove
30: rotor 31: rotating body
33: magnet 35: shaft
37a, 37b: Upper and lower bearing 40: Hall sensor
50 impeller 51: stepped portion
53: euro hole 55: bolt hole

Claims (4)

housing;

A fixed body having a plurality of slots radially disposed on an inner surface thereof,
A stator coupled to the fixed body, the stator including an coil insulator covering the surface of the slot, and an insulator for insulating the slot;

A rotor having an upper portion exposed to the outside of the housing and magnets disposed at equal intervals on an outer circumference thereof and rotatably disposed in a hollow formed by the slot of the stator;

An impeller coupled to the shaft exposed to the outside of the housing and mounted with a cooling fan for a radiator;

A plurality of Hall sensors for sensing the rotation of the rotor by sensing the magnetic force of the magnet;

An anti-separation protrusion is formed at an upper end portion of the insulator covering the surface of each of the slots and an inner end portion of the lower side of the insulator to prevent the coil from being wound.
The separation preventing protrusion is characterized in that the inner end is formed with a seating groove for mounting the hall sensor,

On the upper surface of the impeller, a stepped portion into which the inner surface of the mounting hole of the cooling fan is inserted and contacts is formed to protrude in an annular shape.
The inside of the stepped portion of the BCD motor for a radiator cooling fan, characterized in that a plurality of passage holes that are a flow path of air generated when the cooling fan is driven through the upper and lower sides. delete The method of claim 1,
The plurality of Hall sensors are mounted, further comprising a PCB bolted to the separation prevention projections,
The seating groove is formed on both sides of the release preventing protrusion, the Hall sensor is seated in two adjacent seating grooves, the BCD motor for a radiator cooling fan, characterized in that disposed between the two adjacent release preventing projections. The method of claim 3, wherein
The rotor is the shaft is formed through the top and bottom, the outer periphery of the rotor and the magnet is arranged at equal intervals,
Further comprising an upper bearing and a lower bearing coupled to the upper and lower portions of the shaft,

The insulator of the stator is composed of an upper insulator and a lower insulator inserted into the upper and lower portions of the stator to cover the slot surface, respectively.

The housing is composed of an upper housing and a lower housing which are assembled and engaged with each other,
Inner surfaces of the upper housing and the lower housing are formed with receiving grooves for accommodating the upper and lower bearings, respectively, and a plurality of heat dissipation fins are formed on the outer periphery in the vertical direction.
Cable holes are formed on the lower edge of the lower housing,

And a controller electrically connected to the coil and the hall sensor to control the coil and the hall sensor, wherein the controller is electrically connected to the coil and the hall sensor through a cable inserted into the cable hole and disposed outside of the housing, thereby providing a BCD motor for radiator cooling fan, characterized by less influence of heat generated.

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