JP6015394B2 - Molded motor - Google Patents

Description

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

  Conventionally, there is a molded motor in which an output-side bracket and a counter-output-side bracket are electrically connected by a conductive tape as a conductive member (see, for example, Patent Document 1). The conductive tape used for the mold motor is positioned between the output-side bracket and the non-output-side bracket, and is affixed to the side surface of the outer shell 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.

  In such a molded motor, the output-side bracket and the non-output-side bracket are electrically connected by the conductive tape, so that the potential of the outer ring of the bearing housed in each bearing house becomes the same. For this reason, no current flows through the bearing, and it is possible to prevent the occurrence of electrolytic corrosion of the bearing. In addition, since the conductive tape is affixed to the side surface of the outer shell, it is not necessary to embed a conductive member in the mold resin, so that an advanced technique is not required at the time of molding. However, while conductive tape is easy to apply to the side of the outer shell, it may be cut or peeled off when the mold motor is transported or when the mold motor is mounted on an electrical device such as an air conditioner or deodorizer. is there. In addition, the conductive tape may be peeled off due to aging.

  As a molded motor that solves the problem that the conductive tape is cut or peeled off, there is one in which the output-side bracket and the non-output-side bracket are made to conduct with a metal conductive plate (for example, Patent Document 2). This conductive plate is in contact with the inner side of the annular part formed so as to be fitted to the side surface of the bearing house on the opposite side to the output side on one end side and the bracket on the output side that is press-fitted into the outer shell of the stator on the other side. And a conduction band that connects the annular portion and the contact portion.

  In this molded motor, the conductive plate is held in a state where the output-side bracket and the non-output-side bracket are conductive, so that the conductive plate is not cut or peeled off like the conductive tape. However, since an annular portion is formed on one end side of the conductive plate, there are many scraps discarded when the conductive plate is cut off by press working, resulting in poor material yield.

JP 2007-20348 A JP 2012-210064 A

  In view of the above problems, the present invention prevents the conductive member from being cut or peeled when the output side bracket and the non-output side bracket are connected by the conductive member, and the material yield of the conductive member is reduced. It is an object of the present invention to provide a molded motor capable of maintaining a stable contact between a conducting member and a bearing house while maintaining a state where the conducting member is press-fitted into an outer shell of a stator.

  In order to solve the above-described problems, a molded motor of the present invention includes a stator that is molded with a mold resin to form a bottomed cylindrical outer shell, a rotor that is rotatably disposed on the inner diameter side of the stator, A bearing that supports the output side and the non-output side of the output rotation shaft, a conductive bracket that is formed on both the output side and the non-output side of the outer wall in which a bearing house for housing the bearing is formed, and an output side bracket And a metal conductive plate that conducts the bracket on the non-output side. The conducting plate is press-fitted into the outer shell on the other end side, with a first abutting portion formed so as to abut on the side of the bearing house on the output side or the non-output side on one end side in a state of warping away from the outer shell. A second abutting portion formed so as to abut on the inner side of the output-side or counter-output-side bracket, and a conduction band connecting the first abutting portion and the second abutting portion. The conduction band has an L-shaped bent portion formed continuously with the first contact portion, and the first contact portion and the bent portion are press-fitted between the outer shell and one of the bearing houses. A groove is provided. It has a flat surface formed on the inner diameter side surface of the outer shell constituting the groove portion, and when the first contact portion and the bent portion are press-fitted into the groove portion, the bent portion comes into contact with the flat surface.

  According to the molded motor of the present invention, the first contact portion of the metal conductive plate is in contact with the side of the bearing house on the output side or the non-output side, so that it is prevented from being cut or peeled off like a conductive tape. can do. Further, since the conductive plate is composed of a band-shaped conductive band, there are few scraps discarded when the conductive plate is cut off by press working, and the material yield can be improved. Further, the conduction band includes an L-shaped bent portion formed continuously with the first contact portion, and the first contact portion and the bent portion are press-fitted between the outer shell and one of the bearing houses. Since the first contact portion and the bent portion are press-fitted into the groove portion, the bent portion becomes a flat surface. Therefore, it is possible to maintain a stable contact between the conductive plate and the bearing house while maintaining the state where the conductive plate is press-fitted into the outer shell of the stator.

It is explanatory drawing which shows the mold motor by this invention, (a) is the perspective view seen from the output side, (b) is the perspective view seen from the non-output side. It is a disassembled perspective view which shows the mold motor by this invention. It is AA sectional drawing shown to Fig.1 (a) of the molded motor by this invention. It is an expanded sectional view showing the neighborhood of the 1st contact part and a holding means. FIG. 5 is an enlarged plan view corresponding to FIG. 4. FIG. 6 is an enlarged plan view showing a state before the conductive plate of FIG. 5 is press-fitted into the outer shell of the stator. FIG. 6 is an enlarged perspective view showing a state before the conductive plate of FIG. 5 is press-fitted into the outer shell of the stator. It is an expanded sectional view showing other embodiments near the 1st contact part and a holding means. It is an expansion perspective view which shows other embodiment of the state before press-fitting a conduction | electrical_connection plate to the outer shell of a stator.

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. 1 to 7 are views for explaining a molded motor according to this embodiment. As shown in FIGS. 1 to 3, the molded motor 100 includes a stator core 10, an outer shell 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. A side bracket 52 and a conductive plate 60 are provided.

  The stator core 10 is configured by laminating steel plates, and includes an annular yoke portion and a plurality of teeth portions 11 extending from the yoke portion toward the inner diameter side. An insulator 12 is integrally formed on the stator core 10 by molding, and a winding 13 is wound around the tooth portion 11 via the insulator 12. The stator core 10 around which the windings 13 are wound is molded with a mold resin except for the inner peripheral surface to form a cylindrical outer shell 20, thereby forming a stator. The insulator 12 may be formed separately and attached to the stator core 10 instead of being formed integrally with the stator core 10. A metal bracket 52 made of a galvanized steel plate is integrally embedded on the opposite output side of the outer shell 20. The bracket 52 on the non-output side is in a state where the bearing house 520 in which the bearing 42 on the non-output side is accommodated is exposed from the outer shell 20.

  The rotor 30 includes an output rotating shaft 31 and a permanent magnet 32 having a plurality of magnetic poles. The magnetic poles of the permanent magnet 32 are arranged at an equal interval, and adjacent magnetic poles are arranged around the output rotation shaft 31 so that N poles and S poles appear alternately, and are integrated with the output rotation shaft 31. . The permanent magnet 32 can be formed as a ferrite-bonded magnet by mixing a ferrite magnetic material into a resin material and magnetizing it. The rotor 30 is accommodated oppositely with a predetermined gap (gap) inside the inner periphery of the stator core 10. The permanent magnet 32 is not limited to this, and a rare earth magnet may be used instead of the ferrite magnet, and a sintered magnet may be used instead of the bonded magnet.

  The output rotating shaft 31 is rotatably supported by passing through an output-side bearing 41 and a non-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.

  1, 2, and 3, the output-side bearing 41 is accommodated in an output-side bearing house 510 formed on a metal output-side bracket 51 made of a galvanized steel plate. The output side bracket 51 is fitted to the output side surface of the outer shell 20.

  In FIG. 1, one end side of the conduction plate 60 is in contact with the bearing house 520 on the counter-output side, and the other end side is in contact with the bracket 51 on the output side. Hereinafter, the conductive plate 60 will be described in detail. In FIG. 1, FIG. 2, and FIG. 3, the conduction plate 60 is made of a belt-like metal plate having conductivity, springiness, and rigidity, and is made of a material made of stainless steel having these properties. The conductive plate 60 may be made of a material made of iron, steel, brass, phosphor bronze, or the like as long as it has conductivity, springiness, and rigidity. The conductive plate 60 connects the first contact portion 61 formed on one end side, the second contact portion 62 formed on the other end side, and the first contact portion 61 and the second contact portion 62. And a conduction band 63 is provided. The conduction band 63 is bent halfway and has a substantially L-shape as a whole as shown in FIG. Specifically, the outer wall 20 is bent along the opposite end face of the outer shell 20 and the side surface of the outer shell 20. A groove portion 22 in which the conduction plate 60 is accommodated is provided on the end face of the outer shell 20 on the side opposite to the output side and the side surface of the outer shell 20.

  In FIG. 1 and FIG. 3, the bearing house 520 on the non-output side is formed in a bottomed cylindrical shape by, for example, pressing. The bearing 42 is housed inside the bearing house 520 on the non-output side, and the first contact portion 61 formed on one end side of the conductive plate 60 is in contact with the outside in a state of warping away from the outer shell 20. Has been. On the other hand, the second abutting portion 62 formed on the other end side of the conduction plate 60 contacts the inside of the output side bracket 51 with the output side bracket 51 being press-fitted into the output side surface of the outer shell 20. It is touched.

  4 and 5 show the vicinity of the first contact portion 61 in an enlarged manner. In FIG. 4 and FIG. 5, the conductive plate 60 has the first contact portion 61 in contact with the outer side surface of the bearing house 520 on the non-output side, and the conductive band 63 is accommodated in the groove portion 22. Since the conductive plate 60 is accommodated in the groove portion 22, it can be positioned in the circumferential direction with respect to the outer shell 20. Anti-vibration rubber 70 is attached to the outer periphery of bearing house 520 on the non-output side. For example, when the mold motor 100 is mounted on an air conditioner, the vibration isolating rubber 70 reduces vibration transmitted from the mold motor to the air conditioner. Since the first contact portion 61 is covered with the anti-vibration rubber 70, it is possible to prevent the operator's finger or the like from coming into contact with the first contact portion 61. The anti-vibration rubber 70 is also attached to the outer periphery of the output-side bearing house 510 (not shown).

  The conductive plate 60 and the outer shell 20 are formed with holding means 90 that holds the first contact portion 61 in contact with the outer side surface of the bearing house 520 on the opposite output side. The holding means 90 is configured by combining the first holding portion provided on the conductive plate 60 and the second holding portion provided on the outer shell 20 with each other. 4 and 5, the conductive plate 60 has a first abutment portion 61 as a first holding portion, and an L-shape continuously formed on the conduction band 63 on the outer diameter side of the first abutment portion 61. And a convex portion 632 formed of a bent portion 631. Further, by combining the bearing house 520 on the non-output side and the outer shell 20, a groove portion that press-fits the convex portion 632 between the outer side surface of the bearing house 520 on the non-output side and the stepped portion 27 as the second holding portion. 80.

  The groove 80 is formed in an annular shape on the outer diameter side of the bearing house 520 on the counter-output side by the bearing house 520 on the counter-output side and the stepped portion 27 formed on the inner diameter side surface 21 on the end face on the counter-output side of the outer shell 20. Is formed. 6 and 7, the stepped portion 27 has a flat surface 270 formed as a flat surface continuous to the groove portion 22. On the other hand, the convex portion 632 of the conductive plate 60 is bent so that the bent portion 631 is along the stepped portion 27, and is connected to the first contact portion 61 on the inner diameter side of the bent portion 631. The part 61 is bent in a direction opposite to the bending direction of the bent part 631, thereby forming a substantially convex cross section. As a result, the convex portion 632 is press-fitted into the groove portion 80, so that the contact state of the first contact portion 61 with the outer side surface of the bearing house 520 on the counter-output side is maintained.

  In FIG. 4, the dimension of the thickness t of the conduction plate 60 is, for example, about 0.4 mm, and the dimension of the depth d of the groove 22 is larger than the dimension of the thickness t of the conduction plate 60. It has become. For this reason, since the conduction plate 60 does not protrude from the end face on the opposite side of the outer shell 20 or the side surface of the outer shell 20, even if an operator's finger approaches the groove portion 22, the finger is not caught by the conduction plate 60 and the groove portion 22. It is possible to prevent the conduction plate 60 from coming off. Further, the length dimension L1 from the outer side surface 631a of the bent portion 631 to the tip end portion 610 of the first contact portion 61 in the conductive plate 60 before being press-fitted into the groove portion 80 is a step portion 27 formed in the outer portion 20. The width dimension L2 from the flat surface 270 to the side surface of the bearing house 520 on the non-output side is larger. Furthermore, in FIG. 5, the dimension of the width W of the conduction plate 60 is sufficiently smaller than the dimension of the diameter D of the bearing house 520 on the non-output side, and the tip 610 included in the first contact part 61 is It is formed in an arc shape along the outer side surface of the bearing house 520 on the counter-output side.

  Next, a state where the first contact portion 61 and the bent portion 631 of the conductive plate 60, that is, the convex portion 632 is press-fitted into the groove portion 80 will be described with reference to FIGS. Since the convex portion 632 and the groove portion 80 have a dimensional relationship of L1> L2, when the convex portion 632 is press-fitted into the groove portion 80, the outer side surface 631a of the bent portion 631 becomes the flat surface 270 of the step portion 27. Face contact so that it can be pressed against. Further, the front end portion 610 of the first contact portion 61 comes into contact with the side surface of the bearing house 520 on the non-output side. As a result, the convex portion 632 is unlikely to be removed from the groove 80 due to surface contact between the bent portion 631 and the flat surface 270. Therefore, the state in which the conductive plate 60 is press-fitted into the outer shell 20 of the stator is maintained, and stable contact between the conductive plate 60 and the side surface of the bearing house 520 on the non-output side is ensured.

  Next, the groove part 80 by other embodiment is demonstrated using FIG. 8 and FIG. In addition, the same code | symbol is attached | subjected about the same structure as the above-mentioned embodiment, and the description is abbreviate | omitted. As shown in FIGS. 8 and 9, the stepped portion 27 constituting the groove portion 80 has a flat surface 271 formed as a plane continuous to the groove portion 22, and the flat surface 271 is formed from the upper end to the lower end of the stepped portion 27. It is the surface which inclines so that it may be dented from the internal diameter side surface 21 toward. Accordingly, when the first contact portion 61 and the bent portion 631 are press-fitted into the groove portion 80, the outer side surface 631a of the bent portion 631 is deformed in the direction of the flat surface 271 that is inclined, so that the bent portion 631 is a flat surface. 271 is in surface contact. As a result, since the bent portion 631 is fitted into the recessed flat surface 270, it can be more difficult to be removed from the groove portion 80 as compared with the above-described embodiment.

  According to the molded motor 100 according to the embodiment described above, the output-side bracket 51 and the non-output-side bracket 52 are electrically connected by the conductive plate 60, and the outer ring 402 of the bearing 41 accommodated in the output-side bearing house 510. The potentials of the outer rings 402 of the bearings 42 housed in the bearing house 520 on the opposite output side are the same. For this reason, current does not flow through the output-side bearing 41 and the counter-output-side bearing 42, and the occurrence of electrolytic corrosion of the output-side bearing 41 and the counter-output-side bearing 42 can be prevented. Further, since the first contact portion 61 of the metal conductive plate 60 contacts the outer side surface of the bearing house 520 on the opposite output side, it can be prevented from being cut or peeled off like a conductive tape. . Further, since the conductive plate 60 is formed of the rectangular conductive band 63, there are few scraps discarded when the conductive plate 60 is cut off by press working, and the material yield can be improved. Further, when the first contact portion 61 and the bent portion 631 are press-fitted into the groove portion 80, the bent portion 631 is difficult to come into surface contact with the flat surface 270, so that the conductive plate 60 is press-fitted into the outer shell 20 of the stator. The state can be maintained and stable contact between the conduction plate 60 and the bearing house 520 on the non-output side can be ensured.

  In the molded motor 100 according to the present embodiment, the first contact portion 61 formed on the conductive plate 60 is in contact with the outer side surface of the bearing house 520 on the counter-output side, but the present invention is not limited to this. The first contact portion 61 may be in contact with the outer side surface of the output side bearing house 510. Furthermore, although the tip 610 of the first contact portion 61 is formed in an arc shape, the present invention is not limited to this, and the tip portion 610 of the first contact portion 61 may be formed in a linear shape.

DESCRIPTION OF SYMBOLS 10 Stator core 11 Teeth part 12 Insulator 13 Winding 20 Outer side 21 Inner diameter side surface 22 Groove part 27 Step part 270 Flat surface 30 Rotor 31 Output rotating shaft 32 Permanent magnet 400 Ball 401 Inner ring 402 Outer ring 41 Output side bearing 42 Opposite output side bearing 51 Output-side bracket 510 Output-side bearing house 52 Anti-output-side bracket 520 Non-output-side bearing house 60 Conductive plate 61 First contact portion 610 Tip portion 62 Second contact portion 63 Conductive band 631 Bending portion 631a Side surface 632 Convex-shaped portion 70 Anti-vibration rubber 80 Groove portion 90 Holding means d Depth of groove portion 22 t Thickness of conductive plate 60 D Diameter of bearing house 520 on the non-output side W Width of conductive plate 60 L1 Outline of bent portion 631 The tip 610 of the first contact part 61 from the side surface 631a. L2 Width dimension from the flat surface 270 of the stepped portion 27 to the side surface of the bearing house 520 on the non-output side

Claims (1)

A stator formed with a mold resin to form a bottomed cylindrical outer shell,
A rotor arranged rotatably on the inner diameter side of the stator;
A bearing that supports the output side and the non-output side of the output rotation shaft of the rotor;
A conductive bracket is formed in which a bearing house for accommodating the bearing is formed and arranged on both the output side and the non-output side of the outer shell,
With a metal conduction plate that conducts the output side bracket and the non-output side bracket,
The conductive plate has a first abutting portion formed so as to abut on the side surface of the bearing house on the output side or the non-output side on one end side in a state of warping away from the outer shell,
A second abutting portion formed to abut on the inner side of the bracket on the output side or the counter-output side press-fitted into the outer shell on the other end side;
A conductive band connecting the first contact portion and the second contact portion;
The conduction band includes an L-shaped bent portion formed continuously with the first contact portion,
Between the outer shell and one of the bearing houses, provided with a groove portion for press-fitting the first contact portion and the bent portion,
A flat surface formed on an inner diameter side surface of the outer shell constituting the groove portion, and when the first contact portion and the bent portion are press-fitted into the groove portion, the bent portion contacts the flat surface. Molded motor characterized by contact.

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