JP2015015804A - Mold motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mold motor allowing attachment of a metallic conductive plate after assembly of a motor.SOLUTION: A mold motor 100 includes: a stator which is formed of mold resin and has a motor shell 20 like a bottomed cylinder formed thereon; a rotor 30 rotatably disposed on the radial inside of the stator; bearings 41 and 42 supporting the output side and the counter output side of an output revolving shaft 31 of the rotor 30; conductive brackets 51 and 52 which have bearing houses 510 and 520 formed therein to store the bearings 41 and 42 and are arranged on both of the output side and the counter output side of the motor shell 20; and a metallic conductive plate 60 for conduction between the bracket 51 on the output side and the bracket 52 on the counter output side. A hole 522 to which a second contact part 62 of the conductive plate 60 is to be inserted is formed in the bracket 52 on the counter output side, and a part of the second contact part 62 is brought into contact with the inner wall surface of the hole 522 to be made electrically conductive.

Description

  The present invention relates to an inner rotor type molded motor.

  The inner rotor type molded motor is applied to, for example, a brushless DC motor for rotationally driving a blower fan mounted on an air conditioner. Since this brushless DC motor is driven by an inverter that converts DC power into AC power by a pulse width modulation method (hereinafter referred to as PWM method), the neutral point potential of the winding does not become zero. For this reason, a potential difference called an axial voltage is generated between the outer ring and the inner ring of the bearing. Since the shaft voltage includes a high frequency component due to switching, when the shaft voltage reaches the dielectric breakdown voltage of the oil film inside the bearing, a minute current flows inside the bearing. For this reason, it is known that electrolytic corrosion occurs inside the bearing (see, for example, Patent Document 1).

  Therefore, as an inner rotor type molded motor that can prevent the occurrence of electrolytic corrosion even if an inverter that converts DC power to AC power by the PWM method is used, the output side bracket and the non-output side bracket are made of metal. There is one that is made to conduct with a conductive plate made of metal (for example, see Patent Document 2). The conduction plate used in the molded motor is positioned between the output-side bracket and the non-output-side bracket, and is disposed along the outer periphery of the motor molded by the mold resin. The output-side bracket and the non-output-side bracket are each formed with a bearing house that accommodates a bearing.

  The conductive plate has a first abutting portion formed so as to abut one side of the bearing house on the side opposite to the output side in a state of warping away from the outer shell of the motor, and the outer side of the motor on the other end side. It consists of a second abutting portion formed so as to abut on the inside of the output-side bracket to be press-fitted, and a conduction band connecting the first abutting portion and the second abutting portion. Thus, in the molded motor according to Patent Document 1, since the bracket on the output side and the bracket on the non-output side are made conductive by the conductive plate, the two brackets have the same potential, so the shaft voltage is reduced and the bearing internal It is possible to prevent electric corrosion from occurring.

  However, since the second contact portion formed on the other end side of the conduction plate is in contact with the inner side of the output side bracket, the conduction plate cannot be attached after the motor assembly. Further, when the output side bracket is press-fitted into the outer shell of the motor, it is necessary to prevent the conductive plate from being detached from the outer shell of the motor.

International Publication No. 2011/43075 JP 2013-81264 A

  In view of the above background art, an object of the present invention is to provide a molded motor capable of attaching a metal conductive plate after motor assembly.

  In order to solve the above-mentioned problems, a molded motor of the present invention includes a stator molded with a mold resin to form a bottomed cylindrical motor outer shell, a rotor rotatably disposed on the inner diameter side of the stator, and a rotor A bearing that supports the output side and the non-output side of the output rotation shaft of the motor, and a conductive bracket that is formed on both the output side and the non-output side of the motor shell, and a bearing house that accommodates the bearing, and the output side And a metal conductive plate that conducts the bracket to the non-output side bracket, and at least one of the output side or the non-output side bracket has a hole into which the leading end of the conductive plate is inserted. A portion is formed, and at least a part of the tip portion is in electrical contact with the inner wall surface of the hole portion.

  According to the molded motor of the present invention, the tip of the metal conductive plate is in contact with the inner wall surface of the hole formed in the bracket on the output side or the counter-output side. After press-fitting into the outer shell, the conduction plate can be attached to the output side or the non-output side bracket. Therefore, the conductive plate can be attached after the motor assembly, and the workability at the time of press-fitting the output-side or counter-output-side bracket into the motor shell can be improved.

It is a front view which shows the mold motor by this invention. It is a side view which shows the mold motor by this invention. It is AA sectional drawing shown in FIG. 2 of the mold motor by this invention. It is a side view which shows the conduction | electrical_connection board with which the mold motor by this invention is equipped. It is explanatory drawing which shows other embodiment of the conduction | electrical_connection board of the mold motor by this invention. It is a fragmentary sectional view which shows the state which the conduction | electrical_connection board shown in FIG. 5 of the mold motor by this invention is inserted in the hole, and is in contact with the inner wall face of the hole. It is a fragmentary sectional view which shows other embodiment of the bracket of the non-output side of the molded motor by this invention.

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. 1 to 6 are views for explaining a molded motor according to the present embodiment. As shown in FIGS. 1 to 3, the molded motor 100 is applied to a brushless DC motor driven by an inverter that converts DC power into AC power by, for example, a PWM method. 20, a rotor 30, an output-side bearing 41 and a counter-output-side bearing 42, an output-side bracket 51 and a counter-output-side bracket 52, a conduction plate 60, and a circuit board 70.

  The stator core 10 is configured by laminating steel plates, and includes an annular yoke portion (not shown) and a plurality of teeth portions extending from the yoke portion toward the inner diameter side. An insulator 11 is formed integrally with the stator core 10, and a winding 12 is wound around the tooth portion via the insulator 11. The stator core 10 around which the winding 12 is wound is molded with a molding resin except for the inner peripheral surface to form a cylindrical motor shell 20 to form a stator. The insulator 11 may be formed separately and attached to the stator core 10 instead of being formed integrally with the stator core 10. On the output side of the motor shell 20, a metal bracket 51 made of aluminum is embedded in the motor shell 20 integrally. The output-side bracket 51 is in a state in which a bearing house 510 in which the output-side bearing 41 is accommodated is exposed from the motor shell 20.

  The rotor 30 includes an output rotation shaft 31 and a permanent magnet having a plurality of magnetic poles (not shown). The magnetic poles of the permanent magnets are arranged around the output rotation shaft 31 so that the N poles and the S poles appear alternately, and the adjacent magnetic poles are integrated with the output rotation shaft 31. The rotor 30 is accommodated oppositely with a predetermined gap (gap) inside the inner periphery of the stator core 10.

  The output rotation shaft 31 is rotatably supported by an output side bearing 41 and a counter output side bearing 42. The output-side bearing 41 and the non-output-side bearing 42 are ball bearings, and include a ball 400 as a rolling element, an inner ring 401, and an outer ring 402.

  In FIG. 3, the non-output side bearing 42 is housed in a non-output side bearing house 520 formed on a metal counter-output side bracket 52 made of aluminum. The non-output side bracket 52 is fitted to the side surface of the motor outer shell 20 on the non-output side.

  In FIG. 1 and FIG. 3, one end side of the conduction plate 60 is brought into contact with the output-side bearing house 510, and the other end side is brought into contact with the non-output-side bracket 52. Hereinafter, the conductive plate 60 will be described in detail. 1, 2 and 3, the conduction plate 60 is made of a strip-shaped metal plate having conductivity, springiness and rigidity, and is made of, for example, stainless steel having these properties. The conductive plate 60 may be formed of iron, steel, brass, phosphor bronze or the like as long as it has conductivity, springiness, and rigidity. The conduction plate 60 includes a first contact portion 61 formed on one end side, a second contact portion 62 as a tip portion formed on the other end side, and the first contact portion 61 and the second contact portion. And a conduction band 63 that couples to 62. As shown in FIG. 3, the conduction band 63 is bent along the shape of the outer surface from the output side of the motor outer shell 20 to the non-output side. A first groove portion 22 in which the conduction plate 60 is accommodated is provided on the outer surface of the motor shell 20. For example, the first groove portion 22 is formed in a groove having a width dimension of 5 mm and a depth dimension of 1 mm.

  1 and 3, the output-side bearing house 510 is formed into a bottomed cylindrical shape by, for example, pressing. The bearing 41 is accommodated inside the bearing house 510 on the output side, and the first abutting portion 61 formed on one end side of the conduction plate 60 is abutted on the outside in a state of warping away from the motor outer casing 20. Has been. On the other hand, the second contact portion 62 formed on the other end side of the conduction plate 60 is in contact with the outer side of the non-output side bracket 52 press-fitted into the side surface on the counter output side of the motor outer shell 20.

  The conductive plate 60 is positioned in the circumferential direction with respect to the motor shell 20 because the first contact portion 61 is in contact with the outer side surface 5101 of the output-side bearing house 510 and the conductive band 63 is accommodated in the first groove portion 22. It can be carried out. Moreover, the thickness dimension of the conduction | electrical_connection board 60 is set to 0.4 mm, for example, and is smaller than the depth dimension of the 1st groove part 22. FIG. For this reason, the conduction band 63 of the conduction plate 60 does not protrude from the outer surface of the motor outer shell 20, and it is possible to prevent the operator's finger or the like from being caught and detached from the first groove portion 22.

  2 and 3, the circuit board 70 is disposed on the non-output side of the motor shell 20 with a distance from the non-output-side bracket 52. The circuit board 70 is electrically connected to a lead wire (not shown) drawn from a lead wire outlet 524 formed on the outer side surface 521 of the bracket 52 on the non-output side. The circuit board 70 is mounted with an inverter driving unit 71 that converts DC power into AC power. Then, DC power supplied from the outside via a lead wire (not shown) is converted into AC power for driving the mold motor 100 by the PWM method and supplied to the stator winding 12.

  In FIG. 3, the conductive plate 60 and the motor outer shell 20 have a first contact portion 61 in contact with the outer side surface 5101 of the output-side bearing house 510. A convex portion 632 formed of a contact portion 61 and an L-shaped bent portion 631 formed on the conduction band 63 continuously on the outer diameter side of the first contact portion 61 is provided. Further, a second groove portion 80 for press-fitting the convex portion 632 of the conduction plate 60 between the outer side surface 5101 of the output side bearing house 510 and the inner diameter side surface 21 formed on the output side outer surface of the motor outer shell 20. It has.

  The second groove portion 80 is formed in an annular shape on the outer diameter side of the output-side bearing house 510, and the inner diameter side surface 21 formed on the outer surface of the motor outer shell 20 on the output-side outer surface is formed at a location continuous to the first groove portion 22. Is formed. Further, the width dimension of the convex portion 632 provided in the conduction plate 60 is set to, for example, 2.8 mm, and extends from the inner diameter side surface 21 of the motor outer shell 20 to the outer side surface 5101 of the output bearing house 510. It is larger than the width dimension.

  Thus, the convex portion 632 is press-fitted into the second groove portion 80, so that the first contact portion 61 is on the outer side surface 5101 of the output-side bearing house 510, and the bent portion 631 is on the inner diameter side surface of the motor outer shell 20. 21 so as to be pressed against each other. Therefore, since the contact state of the first contact portion 61 with the outer side surface 5101 of the output side bearing house 510 is maintained, one end side of the conduction plate 60 is electrically connected to the output side bearing house 510. Can do.

  In FIG. 3, a step portion 23 is formed on the outer surface of the motor outer shell 20 on the side opposite to the output side in order to fit the opposite outer output side bracket 52 to the motor outer shell 20. The non-output side bracket 52 is press-fitted into and fitted into the stepped portion 23. A hole portion 522 that penetrates in the direction of the output rotation shaft 31 is integrally formed at a location continuous with the first groove portion 22 on the outer side surface 521 of the bracket 52 on the counter-output side. The second contact portion 62 is inserted into the hole portion 522.

  The hole 522 is provided in a protruding portion 5211 that protrudes from the outer side surface 521 of the bracket 52 on the counter-output side, and a rectangular hole is formed along the direction of the output rotation shaft 31. The hole 522 is set to a hole having a width dimension of 4 mm and a depth dimension of 1 mm, for example. The width dimension of the conduction plate 60 is set to 4 mm, for example, and the width dimension of the hole 522 is set to a conduction plate. It is equivalent to a width dimension of 60. The second abutting portion 62 has a plurality of concave and convex portions 620 having a sawtooth shape for engaging with the inner wall surface 5221 of the hole 522 on both sides. The tip width dimension of the unevenness 620 due to the sawtooth shape of the second contact part 62 is set to 3 mm, for example, and is smaller than the width dimension of the hole 522.

  Thereby, the conduction plate 60 can be attached along the motor outer shell 20 after press-fitting the non-output side bracket 52 into the motor outer shell 20, that is, after the motor is assembled. When the second contact portion 62 is press-fitted into the hole portion 522, the unevenness 620 due to the sawtooth shape of the second contact portion 62 is fixed so as to bite into the hole portion 522. Therefore, even when a force is applied to the second abutting portion 62 in the pulling direction, the unevenness 620 is caught on the inner wall surface 5221 of the hole portion 522, and the second abutting against the outer side surface 521 of the bracket 52 on the opposite output side. The fixed state of the part 62 is maintained. Further, since the unevenness 620 contacts the inner wall surface 5221 of the hole 522, the other end side of the conduction plate 60 can be electrically connected to the bracket 52 on the counter-output side.

  Next, other embodiments of the conductive plate 60 will be described with reference to FIGS. 5 and 6. In FIG. 5A, the second contact portion 64 of the conduction plate 60 is formed with a folded portion 640 instead of a plurality of unevenness 620 having a sawtooth shape for locking to the inner wall surface 5221 of the hole 522. . The folded portion 640 is folded so as to protrude from the groove portion 22 toward the outer diameter side of the motor outer shell 20. Before the second contact portion 64 is press-fitted into the hole 522, the dimension of the folded portion 640 shown in FIG. 5A is larger than the dimension of the hole 522 shown in FIG. 6A in the XY direction. Is also getting bigger. Accordingly, in FIG. 6A, the folded portion 640 of the second contact portion 64 is press-fitted into the hole 522 so that the dimension in the XY direction becomes smaller than that in FIG. It contacts the wall surface 5221. Therefore, even if a force is applied to the second abutting portion 64 in the pulling direction, the tip of the folded portion 640 is caught by the inner wall surface 5221 of the hole portion 522 and the second side 521 of the bracket 52 on the counter-output side is moved to the outer side surface 521. The contact state of the two contact portions 64 is maintained. Further, since the folded portion 640 contacts the inner wall surface 5221 of the hole 522, the other end side of the conductive plate 60 can be electrically connected to the opposite output side bracket 52.

  5B, the second abutting portion 65 of the conduction plate 60 is formed with a cut-and-raised portion 650 instead of a plurality of irregularities 620 having a sawtooth shape for locking to the inner wall surface 5221 of the hole portion 522. Has been. The cut and raised portion 650 is cut and raised so as to protrude from the groove portion toward the outer diameter side of the motor outer shell 20. Before the second contact portion 65 is press-fitted into the hole portion 522, the dimension in the XY direction of the cut and raised portion 650 shown in FIG. 5B is the same as the dimension in the XY direction of the hole portion 522 shown in FIG. Is bigger than. Accordingly, in FIG. 6B, the cut-and-raised portion 650 of the second contact portion 65 is press-fitted into the hole 522, so that the dimension in the XY direction becomes smaller than that in FIG. It contacts the inner wall surface 5221. Therefore, even if a force is applied to the second contact portion 65 in the pulling direction, the tip of the cut-and-raised portion 650 is caught by the inner wall surface 5221 of the hole portion 522, and the outer side surface 521 of the bracket 52 on the counter-output side is applied. The contact state of the second contact portion 65 is maintained. Further, since the cut-and-raised part 650 contacts the inner wall surface 5221 of the hole 522, the other end side of the conduction plate 60 can be electrically connected to the opposite-output-side bracket 52.

Next, another embodiment of the non-output side bracket 52 will be described with reference to FIG. In FIG.
In order to maintain the state where the second contact portion 66 is in contact with the outer side surface 521 of the non-output side bracket 52, the outer side surface 521 of the counter output side bracket 52 has a groove portion. A hole portion 523 is integrally formed at a location continuous to 22 in a direction orthogonal to the output rotation shaft 31. The hole portion 523 is provided in a protruding portion 5212 protruding from the outer side surface 521 of the non-output side bracket 52, and a rectangular hole is formed along a direction orthogonal to the output rotation shaft 31. Since the second contact portion 66 is bent in the direction of the hole 523 and is locked to the inner wall surface 5231 of the hole 523, a plurality of irregularities (not shown) having a sawtooth shape are formed as in the above-described embodiment. It is formed on both sides. As a result, the second contact portion 66 is press-fitted into the hole portion 523, whereby the unevenness due to the sawtooth shape of the second contact portion 66 is fixed so as to bite into the hole portion 523. Therefore, even when a force is applied to the second contact portion 66 in the pulling direction, the unevenness is caught on the inner wall surface 5231 of the hole portion 523, and the second contact portion to the outer side surface 521 of the bracket 52 on the opposite output side. The fixed state of 66 is maintained. Further, since the unevenness comes into contact with the inner wall surface 5231 of the hole 523, the other end side of the conduction plate 60 can be electrically connected to the bracket 52 on the counter-output side.

  Further, the openings of the holes 522 and 523 according to the present embodiment are formed only in the protrusions 5211 and 5212 that protrude from the outer side surface 521 of the bracket 52 on the counter-output side. For this reason, each of the holes 522 and 523 is not a hole penetrating into the counter-output side bracket 52, so that dust can be prevented from entering the counter-output side bracket 52.

  According to the molded motor 100 according to the embodiment described above, since the output bracket 51 and the non-output bracket 52 are electrically connected by the conductive plate 60, the two brackets 51 and 52 have the same potential. The shaft voltage is reduced, and it is possible to prevent electrolytic corrosion from occurring in the bearings 41 and 42 on the output side and the counter-output side.

  The second contact portions 62, 64, 65 as the tip portions formed on the other end side of the metal conduction plate 60 are the inner wall surfaces of the holes 522 formed in the outer side surface 521 of the bracket 52 on the opposite output side. Since the bracket 52 is locked to the motor outer shell 20, the second contact portions 62, 64, 65 of the conductive plate 60 are attached to the bracket 52 on the counter-output side. be able to. As a result, as shown in the background art, when the opposite output side bracket 52 is press-fitted into the motor outer shell 20, it is not necessary to prevent the conductive plate 60 from being detached from the motor outer shell 20. Therefore, the conductive plate 60 can be attached after the motor assembly, and the workability when the opposite-output-side bracket 52 is press-fitted into the motor shell 20 can be improved. The same applies to the structure in which the second contact portion 66 formed on the other end side of the conduction plate 60 is locked to the inner wall surface 5231 of the hole portion 523 formed in the outer side surface 521 of the bracket 52 on the opposite output side. An effect can be obtained.

  In the molded motor 100 according to the present embodiment, the first contact portion 61 formed on the conduction plate 60 is in contact with the outer side surface 5101 of the output-side bearing house 510. However, the present invention is not limited to this. The first contact portion 61 may be in contact with the outer side surface of the bearing house 520 on the counter-output side. Further, the present invention is not limited to the molded motor 100, and a molded motor in which the structures of the output-side bracket 51 and the counter-output-side bracket 52 are interchanged may be used.

DESCRIPTION OF SYMBOLS 10 Stator core 11 Insulator 12 Winding 20 Motor outer surface 21 Inner diameter side surface 22 1st groove part 23 Step part 30 Rotor 31 Output rotating shaft 400 Ball 401 Inner ring 402 Outer ring 41 Output side bearing 42 Anti-output side bearing 51 Output side bracket 510 Output Side bearing house 5101 Outer side surface 52 Anti-output side bracket 520 Non-output side bearing house 521 Outer side surface 5211, 5212 Protruding portion 522, 523 Hole portion 5221, 5231 Inner wall surface 524 Lead wire outlet 60 Conductive plate 61 First contact Contact portion 62, 64, 65, 66 Second contact portion 620 Concavity and convexity 640 Turn-up portion 650 Cut and raised portion 63 Conductive band 631 Bending portion 632 Convex shape portion 70 Circuit board 71 Inverter drive portion 80 Second groove portion

Claims (4)

A stator molded with a mold resin to form a bottomed cylindrical motor outer shell, a rotor rotatably disposed on the inner diameter side of the stator, an output side and an opposite output side of the output rotation shaft of the rotor; And a conductive bracket formed on both the output side and the non-output side of the motor shell, and an output-side bracket and a non-output-side bracket. A mold motor comprising a metal conductive plate for conducting,
At least one of the output side and the non-output side brackets is formed with a hole into which the leading end of the conduction plate is inserted, and at least a part of the leading end is in contact with the inner wall surface of the hole. A molded motor characterized by being electrically conductive.   The molded motor according to claim 1, wherein the tip portion is locked to the inner wall surface.   The molded motor according to claim 2, wherein the tip portion is formed in a sawtooth shape.   4. The molded motor according to claim 1, wherein the opening of the hole is formed only on an outer side surface of the bracket on the output side or the counter-output side. 5.

Images