KR102135734B1 - Inverter built-in brushless direct current motor - Google Patents

Abstract

The present invention relates to an inverter-integrated BLDC motor, one side coupled to the motor 100, the inside is formed to be hollow, the other side is opened, and the inverter housing 200 is provided with a PCB substrate 210 inside the hollow ; A bearing 140 mounted on the bearing mounting portion 220 of the inverter housing 200 and coupled to the rotor 110 rotating shaft 120 of the motor 100 to be rotatable; And coupled to the bearing mounting groove 221 of the bearing mounting portion 220, the bearing 140 is mounted, the opening portion of the bearing mounting groove 221 on the inner bottom surface 201 of the inverter housing 200 ( 222) is formed to block the bearing cover 230; Consisting of, it is possible to dissipate heat by transferring heat through the bearing cover portion, so that a switching element having a large amount of heat is disposed on the PCB substrate provided inside the inverter portion, but the switching element can also be disposed at a position where the bearing cover is formed. It relates to an inverter-integrated BLDC motor for easy sealing.

Description

Inverter built-in brushless direct current motor

The present invention relates to an inverter-integrated BLDC motor, and relates to an inverter-integrated BLDC motor capable of improving heat dissipation performance of an inverter unit provided for control of the motor.

The brushless direct current (BLDC) motor can prevent friction and wear, which are disadvantages of the existing DC motor, and have relatively high efficiency. Recently, in the case of a hybrid vehicle, a BLDC motor is used as a cooling fan rotating motor.

The BLDC motor is a motor that removes brushes and commutators from a DC motor and installs an electronic commutation mechanism.

And in the conventional BLDC motor assembly, the motor unit and the inverter unit are integrally formed to form an inverter-integrated BLDC motor. At this time, as shown in Figure 1, the inverter unit 20 is coupled to one side of the motor unit 10, the inverter unit 20, the cover 22 is coupled to the inverter housing 21, the inverter housing 21 and the cover A PCB substrate is provided in the inner space formed by (22) to form the inverter unit (20).

Here, the inverter housing 21 is formed by extending the motor head portion 12, the motor head portion 12 is rotatably coupled to the rotating shaft 11 of the rotor 16 provided in the motor portion 10 The bearing 13 is mounted so that a sealing member such as an O-ring is assembled for sealing between the bearing disposed on the left side and the motor head in the drawing, an O-ring cover is assembled to fix the O-ring, and the O-ring cover is also an inverter housing. Use a stop ring (snap ring) or the like so as not to deviate from it.

Accordingly, when assembling, the sealing member is pressed and damaged, and there is a problem that moisture may penetrate into the inverter part. As a plurality of parts are used, assembly performance is reduced and manufacturing cost is increased. In addition, a groove into which the bearing is inserted and assembled into the inverter housing is formed. As a result, the inner bottom surface of the inverter housing is not concave and is formed concavely, so it is difficult to dissipate heat by transferring heat through the groove portion. Since a switching element having a large amount of heat is not disposed in a position facing the groove portion on the PCB substrate provided therein, it is difficult to design the PCB substrate.

KR 10-1355253 B1 (2014.01.17)

The present invention has been devised to solve the problems as described above, and the object of the present invention is to combine grooves formed to be assembled by inserting bearings into the inverter housing with a bearing cover and to intervert the housing and bearing cover. By forming a sealing portion therebetween, heat can be radiated by transferring heat through the bearing cover portion, so that a switching element with a large amount of heat is disposed on the PCB substrate provided inside the inverter portion, but the switching element can also be disposed at a position where the bearing cover is formed. It is to provide an inverter-integrated BLDC motor for easy sealing of the inverter.

In order to achieve the above object, the inverter-integrated BLDC motor 1000 of the present invention, one side is coupled to the motor 100, the inside is hollow, the other side is formed to open, and the PCB substrate ( 210) is provided with an inverter housing 200; A bearing 140 mounted on the inverter housing 200 and coupled to the rotor 110 of the motor 100 so that the rotating shaft 120 is rotatable; And coupled to the bearing mounting groove 221 of the inverter housing 200, the bearing 140 is mounted, the opening portion of the bearing mounting groove 221 on the inner bottom surface 201 of the inverter housing 200 ( 222) is formed to block the bearing cover 230; It characterized in that it comprises a.

In addition, the outer bottom surface 231 of the bearing cover 230 is characterized in that formed to match the inner bottom surface 201 of the inverter housing 200.

In addition, some of the switching elements 211 created on the PCB substrate 210 are characterized in that they are disposed at positions opposite to the portion where the bearing cover 230 is located.

In addition, the switching elements 211 are characterized in that they are arranged to contact the inner bottom surface 201 of the inverter housing 200 or the outer bottom surface 231 of the bearing cover 230.

In addition, the outer circumferential surface 232 of the bearing cover 230 is coupled to be in close contact with the inverter housing 200.

In addition, the inverter housing 200 is concave on the inner bottom surface 201 and connected to the bearing mounting groove 221, but an inner groove 223 having a larger inner diameter than the bearing mounting groove 221 is formed to form the inner groove ( 223) is characterized in that the bearing cover 230 is inserted and placed.

In addition, the inverter housing 200 has a sealing groove 224 that is concave on the inner bottom surface 201 and connected to the mounting groove 223 but has a larger inner diameter than the mounting groove 223, so that the sealing groove 224 Characterized in that the sealing member 225 is filled in.

In addition, the sealing member 225 is characterized in that it is formed so as not to protrude from the outer bottom surface 231 of the bearing cover 230 and the inner bottom surface 201 of the inverter housing 200.

In addition, the sealing member 225 is characterized in that it is formed of a thermally conductive material.

In addition, the heat dissipation grease 240 between the inner bottom surface 201 of the inverter housing 200 and the PCB substrate 210 and between the outer bottom surface 231 of the bearing cover 230 and the PCB substrate 210. Characterized in that interposed.

In addition, it is characterized in that the outer diameter of the bearing cover 230 is formed larger than the outer diameter of the bearing 140.

In addition, the bearing cover 230 has a protrusion 233 protrudingly formed on the outer circumferential surface 232, and an engaging groove 226 corresponding to the protrusion 233 is formed on the inverter housing 200, the It is characterized in that the projection 233 is inserted into the coupling groove 226 and coupled.

The inverter-integrated BLDC motor of the present invention can transfer heat through a bearing cover portion to dissipate heat, so that a switching element having a large amount of heat is placed on a PCB substrate provided inside the inverter portion, but a switching element can also be disposed at a position where the bearing cover is formed. There is an advantage of easy sealing of the inverter.

1 is a cross-sectional view showing a conventional inverter-integrated BLDC motor.
2 to 4 is an assembly perspective view, an exploded perspective view and a cross-sectional view showing an inverter-integrated BLDC motor of the present invention.
5 and 6 are partial cross-sectional views showing embodiments in which a switching element is disposed in a portion where a bearing cover according to the present invention is located.
7 is a partial cross-sectional view showing an embodiment in which the heat dissipating grease according to the present invention is interposed between the inverter housing and the PCB substrate and between the bearing cover and the PCB substrate.
8 and 9 is an exploded perspective view and a plan view showing another embodiment of the inverter housing and the bearing cover according to the present invention.

Hereinafter, an inverter-integrated BLDC motor of the present invention having the above-described configuration will be described in detail with reference to the accompanying drawings.

2 to 4 is an assembled perspective view, an exploded perspective view and a cross-sectional view showing an inverter-integrated BLDC motor of the present invention, Figure 5 is a partially enlarged view of FIG.

As shown, the inverter-integrated BLDC motor 1000 of the present invention, one side is coupled to the motor 100, the inside is formed to be hollow, the other side is opened, and the PCB substrate 210 is provided inside the hollow An inverter housing 200; A bearing 140 mounted on the inverter housing 200 and coupled to the rotor 110 of the motor 100 so that the rotating shaft 120 is rotatable; And coupled to the bearing mounting groove 221 of the inverter housing 200, the bearing 140 is mounted, the opening portion of the bearing mounting groove 221 on the inner bottom surface 201 of the inverter housing 200 ( 222) is formed to block the bearing cover 230; It can be made including.

First, the motor 100 may be a brushless direct current motor (BLDC motor). At this time, the rotor is provided on the inner side and the stator is disposed on the outside to be a proton-type BLDC motor in which the inner rotor is rotated, but in the present invention, the stator 150 with the driving coil wound on the inside is provided and the casing form on the outside. The outer rotor type BLDC motor, which is a method in which the rotor 110, which is covered with and is coupled with the permanent magnet 130, is disposed to rotate the outer rotor 110, will be described as an example.

Inverter housing 200, the upper side is coupled to the motor 100, the lower side is formed to be open and the inside is hollow, a PCB substrate 210 for operation of the motor 100 is provided in the hollow PCB The substrate 210 and the motor 100 may be connected. In addition, the PCB substrate 210 may be connected to the outside through a power line and a communication line, and the switching elements 211 for controlling the motor 100 may be mounted on the PCB substrate 210. In addition, the cover 300 is combined with the inverter housing 200 to form an empty space therein, and the PCB substrate 210 may be provided in the space formed therein. And the cover 300 is coupled to the open lower side of the inverter housing 200, the inverter housing 200 and the cover 300 may be coupled to be formed to seal the contact surface. In addition, the inverter housing 200 may be formed with a bearing mounting portion 220 protruding upward from the center portion, and penetrates the upper surface of the bearing mounting portion 220 and the inner bottom surface 201 of the inverter housing 200 vertically. A through hole is formed, and the bearing mounting groove 221 may be formed up and down so as to be stepped inside the pierced inside.

The bearing 140 is inserted and mounted in the bearing mounting groove 221 inside the bearing mounting portion 220 of the inverter housing 200, and the rotor 110 rotation axis 120 of the motor 100 is coupled to the bearing 140 It can be configured to rotate. Here, the bearing mounting portion 220 may be formed to protrude to the outside, which is the opposite side of the inside, on which the PCB substrate 210 is disposed in the inverter housing 200, and the stator of the motor 100 to the protruding bearing mounting portion 220 ( 150) may be fitted and fixed. And the inside of the bearing mounting portion 220 is formed with a through-hole penetrating through the top and bottom, the rotation shaft 120 may be disposed, and the bearing mounting groove 221 is formed concavely larger than the inner diameter of the through-hole so as to step with the through hole. 140) may be coupled to be placed in the bearing mounting groove (221). At this time, as shown, the bearing 140 composed of a pair may be arranged to be spaced up and down to stably support the rotating shaft 120, wherein the bearing mounting groove 221 inserts the bearing 140 To facilitate mounting, one may be formed concavely from the upper side of the bearing mounting portion 220 and the other concavely formed from the inner bottom surface 201 of the inverter housing 200.

The bearing cover 230 may be coupled to the inverter housing 200 on the side of the bearing 140 disposed relatively close to the inner bottom surface 201 side of the inverter housing 200, for example the bearing cover 230 The opposite surface of the bearing 140 is formed in a concave cap shape, and may be inserted into and coupled to the bearing mounting groove 221. Thus, the bearing cover 230 may be coupled to the inverter housing 200 to block the opening 222 formed to be opened by the bearing mounting groove 221 on the inner bottom surface 201 of the inverter housing 200. have. Here, the opening 222 is an opening portion in which the bearing mounting groove 221 is formed in the inner bottom surface 201 of the inverter housing 200, and the bearing cover 230 is provided with an inverter housing ( 200). At this time, the bearing cover 230 is preferably formed of a material having a high thermal conductivity so that the thermal conductivity can be smoothly made with the inverter housing 200, and the bearing cover 230 has a thermal conductivity similar to that of the inverter housing 200 or the inverter housing It may be formed of a material having a higher thermal conductivity than (200).

In this way, the inverter-integrated BLDC motor of the present invention is capable of dissipating heat generated from the PCB board equipped with a switching element to the outside through the bearing cover and dissipating heat, thereby generating heat in the PCB board provided inside the inverter. Although many switching elements are arranged, the switching element can also be arranged in a portion corresponding to a position where the bearing cover is formed, so design freedom can be increased in designing a PCB substrate including the switching element of the inverter.

In addition, the outer bottom surface 231 of the bearing cover 230 may be formed to match the inner bottom surface 201 of the inverter housing 200.

That is, as shown, the outer bottom surface 231 of the bearing cover 230 is formed to coincide with the inner bottom surface 201 of the inverter housing 200, so that the PCB substrate 210 and the inside of the inverter housing 200 are formed. The distance between the bottom surface 201 and the distance between the PCB substrate 210 and the outer bottom surface 231 of the bearing cover 230 may be the same. Accordingly, heat generated from the PCB substrate 210 on which the switching elements 211 are mounted can be uniformly transferred to the inverter housing 200 and the bearing cover 230 to be dissipated to the outside, thereby forming the bearing cover 230 The PCB substrate 210 can be freely designed regardless of the position.

In addition, some of the switching elements 211 created on the PCB substrate 210 may be disposed at positions opposite to the portion where the bearing cover 230 is located.

That is, as shown in FIG. 5, since the switching element 211 is also disposed in the PCB substrate 210 portion of the position corresponding to the bearing cover 230, heat generated from the switching element 211 can be easily dissipated, thereby switching element ( The layout of 211) can be freely designed.

In addition, the switching elements 211 are characterized in that they are arranged to contact the inner bottom surface 201 of the inverter housing 200 or the outer bottom surface 231 of the bearing cover 230.

Here, the PCB substrate 210 may be arranged to be spaced apart from the inverter housing 200 for electrical insulation, so that the gap between the inner bottom surface 201 of the inverter housing 200 and the PCB substrate 210 floats. There will be. At this time, as shown in Figure 6, the switching elements 211 are found on the PCB substrate 210, but the switching elements 211 are disposed between the inner bottom surface 201 of the inverter housing 200 and the PCB substrate 210. , The switching elements 211 may be in contact with the inner bottom surface 201 of the inverter housing 200 or the outer bottom surface 231 of the bearing cover 230.

Thus, the heat generated in the switching element can be directly dissipated and dissipated, thereby advantageously dissipating heat.

In addition, the outer circumferential surface 232 of the bearing cover 230 may be coupled to be in close contact with the inverter housing 200.

That is, the outer circumferential surface 232, which is the outer circumferential surface of the bearing cover 230, is coupled to be in close contact with the inverter housing 200, so that heat transfer from the bearing cover to the inverter housing can occur smoothly. At this time, the thermal conductivity may be improved by bringing the contact surfaces into close contact with a thermal grease or the like so as to reduce thermal resistance at the contact interface between the outer circumferential surface 232 of the bearing cover 230 and the inverter housing 200.

In addition, the inverter housing 200 is concave on the inner bottom surface 201 and connected to the bearing mounting groove 221, but an inner groove 223 having a larger inner diameter than the bearing mounting groove 221 is formed to form the inner groove ( The bearing cover 230 may be inserted into 223 to be placed.

That is, the mounting groove 223 may be concavely formed in the inverter housing 200 so that the bearing cover 230 may be inserted and placed. At this time, the mounting groove 223 may be formed concavely on the inner bottom surface 201 of the inverter housing 200 to be connected to the bearing mounting groove 221, the inner diameter of the mounting groove 223 is the bearing mounting groove 221 ) Can be formed larger than the inner diameter.

Thus, the bearing 140 can be more easily inserted into the bearing mounting groove 221, and the depth into which the bearing cover 230 is inserted is limited, so that the inner bottom surface 201 and the bearing cover 230 of the inverter housing 200 are limited. ) It may be easy to match the height of the outer bottom surface 231 of the same.

In addition, the inverter housing 200 has a sealing groove 224 that is concave on the inner bottom surface 201 and connected to the mounting groove 223 but has a larger inner diameter than the mounting groove 223, so that the sealing groove 224 The sealing member 225 may be filled in.

That is, the sealing member 225 is filled so that the sealing groove 224 is formed in the concave in the inverter housing 200 so that the sealing between the outer circumferential surface 232 of the bearing cover 230 and the inverter housing 200 Can. At this time, the sealing groove 224 may be formed concave on the inner bottom surface 201 of the inverter housing 200 so as to be connected to the mounting groove 223 where the bearing cover 230 is placed, and the sealing groove 224 The inner diameter may be formed larger than the inner diameter of the recess groove 223. In addition, the sealing member 225 may be formed of, for example, silicon, filled with the sealing groove 224, and then cured to be formed of the sealing member 225.

Thus, the bearing cover can be more easily sealed between the inverter housing, and the sealing member can be visually confirmed to improve sealing performance. In addition, the sealing member can be sealed between the bearing cover and the inverter housing, so that moisture can be prevented from entering the inside of the inverter housing where the PCB substrate is disposed on the motor side.

In addition, the sealing member 225 may be formed so as not to protrude from the outer bottom surface 231 of the bearing cover 230 and the inner bottom surface 201 of the inverter housing 200.

That is, since the switching elements 211 mounted on the PCB substrate 210 may be disposed in contact with or adjacent to the outer bottom surface 231 of the bearing cover 230 or the inner bottom surface 201 of the inverter housing 200. , The sealing member 225 is the outer bottom surface 231 of the bearing cover 230 and the inner bottom surface of the inverter housing 200 so that interference does not occur in the arrangement of the switching elements 211 by the sealing member 225 ( 201) and may not be formed.

In addition, the sealing member 225 may be formed of a thermally conductive material.

That is, in order to improve the thermal conductivity, the sealing member 225 may also be formed of a thermally conductive material, and at the same time, it is preferably formed of a material having excellent sealing force.

In addition, the heat dissipation grease 240 between the inner bottom surface 201 of the inverter housing 200 and the PCB substrate 210 and between the outer bottom surface 231 of the bearing cover 230 and the PCB substrate 210. Can be intervened.

That is, the inner bottom surface 201 and the PCB substrate 210 of the inverter housing 200 including the outer bottom surface 231 of the bearing cover 230 which is a surface facing the upper surface of the PCB substrate 210 as shown in FIG. 7. A heat radiating grease 240 such as a thermal grease is interposed between the heat exchanger grease 240 and heat generated from the side of the PCB substrate 210 on which the switching elements 211 are mounted by the heat radiating grease 240, the bearing cover 230 and the inverter housing It can be smoothly transferred to the (200) and radiated. Thus, cooling of the switching elements 211 may be easy.

In addition, the outer diameter of the bearing cover 230 may be formed larger than the outer diameter of the bearing 140.

That is, the outer diameter of the bearing cover 230 is formed to be larger than the outer diameter of the bearing 140, thereby forming an inner groove 223 larger than the inner diameter of the bearing mounting groove 221 of the inverter housing 200 to form a bearing cover 230 It can be coupled by inserting into the recess groove 223, it is possible to limit the depth that is coupled to the bearing cover 230 is inserted into the inverter housing 200. In addition, the contact area between the bearing cover 230 and the inverter housing 200 can be widened to increase the thermal conductivity.

In addition, the bearing cover 230 has a protrusion 233 protrudingly formed on the outer circumferential surface 232, and an engaging groove 226 corresponding to the protrusion 233 is formed on the inverter housing 200, the The protrusion 233 may be inserted into the coupling groove 226 and coupled.

That is, as shown in FIGS. 8 and 9, the bearing cover 230 may be formed with protrusions 233 projecting radially from the outer circumferential surface 232, and the protrusions 233 are spaced along the circumferential direction to form a plurality. Can be. In addition, coupling grooves 226 are formed in the inverter housing 200 to correspond to the projections 233, so that the bearing cover 230 is coupled to the inverter housing 200 so that the projections 233 are inserted into the coupling grooves 226. Can be. Thus, the bearing cover 230 is inserted into the inverter housing 200 by the protrusion 233 and the coupling groove 226 even if there is no recess 223 in the state in which the bearing mounting groove 221 is formed in the inverter housing 200. The depth to be combined may be limited, and the thermal conductivity may be increased by increasing the contact area between the bearing cover 230 and the inverter housing 200.

The present invention is not limited to the above-described embodiments, and of course, the scope of application is various, and anyone who has ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications are possible.

1000: Inverter-integrated BLDC motor
100: motor
110: rotor 120: rotating shaft
130: permanent magnet 140: bearing
150: stator
200: inverter housing 201: inner bottom surface
210: PCB substrate 211: switching element
220: bearing mounting portion
221: bearing mounting groove 222: opening
223: Anchor groove 224: Sealing groove
225: sealing member 226: engaging groove
230: bearing cover 231: outer bottom surface
232: outer peripheral surface 233: projection
240: thermal grease
300: cover

Claims (12)

One side coupled to the motor 100, the inside is formed to be hollow, the other side is formed to open, the inverter housing 200 having a PCB substrate 210 inside the hollow;
A bearing 140 mounted on the inverter housing 200 and coupled to the rotor 110 of the motor 100 so that the rotating shaft 120 is rotatable; And
The bearing 140 is coupled to the bearing mounting groove 221 of the inverter housing 200 is mounted, the opening portion 222 of the bearing mounting groove 221 on the inner bottom surface 201 of the inverter housing 200 ) Is formed to block the bearing cover 230;
Including,
The flat outer bottom surface 231 of the bearing cover 230 is formed to coincide with the flat inner bottom surface 201 of the inverter housing 200,
A heat dissipation grease 240 is interposed between the inner bottom surface 201 of the inverter housing 200 and the PCB substrate 210 and between the outer bottom surface 231 of the bearing cover 230 and the PCB substrate 210. And
Some of the switching elements 211 created on the PCB substrate 210 are disposed at a position overlapping the portion where the bearing cover 230 is located, and the PCB substrate 210 is disposed of the switching element 211 Due to the flat surface on the opposite side of the curved surface is an inverter-integrated BLDC motor, characterized in that disposed to face the bearing cover 230 and the inverter housing 200.
delete delete According to claim 1,
The switching element 211 is an inverter-integrated BLDC motor, characterized in that arranged to contact the inner bottom surface 201 of the inverter housing 200 or the outer bottom surface 231 of the bearing cover 230.
According to claim 1,
The outer circumferential surface 232 of the bearing cover 230 is coupled to the inverter housing 200, characterized in that the inverter-integrated BLDC motor.
According to claim 1,
The inverter housing 200 is concave on the inner bottom surface 201 and connected to the bearing mounting groove 221, but an inner groove 223 having a larger inner diameter than the bearing mounting groove 221 is formed, so that the inner groove 223 Inverter-integrated BLDC motor, characterized in that the bearing cover 230 is inserted and placed in.
The method of claim 6,
The inverter housing 200 has a sealing groove 224 that is concave on the inner bottom surface 201 and connected to the mounting groove 223 but has a larger inner diameter than the mounting groove 223, so that the sealing groove 224 is sealed. Inverter-integrated BLDC motor, characterized in that the member 225 is filled.
The method of claim 7,
The sealing member 225 is an inverter-integrated BLDC motor, characterized in that formed so as not to protrude from the outer bottom surface 231 of the bearing cover 230 and the inner bottom surface 201 of the inverter housing 200.
The method of claim 7,
The sealing member 225 is an inverter-integrated BLDC motor, characterized in that formed of a thermally conductive material.
delete According to claim 1,
Inverter-integrated BLDC motor, characterized in that the outer diameter of the bearing cover 230 is formed larger than the outer diameter of the bearing 140.
According to claim 1,
The bearing cover 230 has a protrusion 233 protrudingly formed on an outer circumferential surface 232, and an engaging groove 226 corresponding to the protrusion 233 is formed on the inverter housing 200, so that the protrusion ( 233) is an inverter-integrated BLDC motor, characterized in that inserted into the coupling groove 226 is coupled.

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