KR102280865B1 - electric motor - Google Patents

Abstract

An electric motor having a three-phase winding provided in a stator iron core, and a neutral point accommodating part for accommodating the neutral point of the three-phase winding. Each phase of the three-phase winding includes a first winding portion made of a copper wire and a second winding portion made of an aluminum wire. The neutral point accommodating part accommodates the neutral point of the first winding part of each phase and the neutral point of the second winding part of each phase. Moreover, the neutral point accommodating part has at least 1 contact prevention part which has insulation, and a some accommodating part partitioned by the contact prevention part. The neutral point of the first winding portion and the neutral point of the second winding portion are accommodated in different accommodating portions, respectively.

Description

electric motor

The present invention relates to a three-phase electric motor.

In conventional electric motors, there are those in which the stator windings are made of both copper and aluminum conductors for weight reduction and cost reduction. However, compared with copper, aluminum has a large tendency to ionize, which is a measure of the easiness of becoming a cation in an aqueous solution. For this reason, when aluminum and copper come into direct contact with the neutral point of the Y-connected three-phase winding, aluminum emits ions to the copper and the wire is corroded, leading to an increase in contact resistance, etc., and a high possibility of connection failure. . Corrosion of such an electric wire is called dissimilar metal corrosion or electric corrosion.

In order to avoid this dissimilar metal corrosion, the technique regarding the connection method of a neutral point is conventionally proposed (for example, refer patent document 1). The electric motor of Patent Document 1 adopts a configuration in which an anti-corrosion section made of a material having a greater ionization tendency than aluminum is provided at the neutral point, and the anti-corrosion section is corroded instead of a winding made of a material containing aluminum.

Patent Document 1: Japanese Patent Laid-Open No. 2016-25704

However, in the electric motor of Patent Document 1, it is necessary to form the neutral point connecting portion constituting the neutral point of the Y connection by welding, and to cover the formed neutral point connecting portion with an anti-corrosion portion, and then insulate it again with an insulating member. That is, in the structure of patent document 1, while the number of members increases by providing a corrosion prevention part, the efficiency of the manufacturing operation of an electric motor falls by the effort of providing a corrosion prevention part, and also material cost due to the expansion cost of a corrosion prevention part. There is a challenge to rising.

The present invention has been made in order to solve the above problems, and an object of the present invention is to provide an electric motor which effectively prevents corrosion of dissimilar metals at a neutral point by suppressing the cost with a small number of members.

An electric motor according to the present invention is provided with a three-phase winding provided in a stator iron core, and a neutral point accommodating portion for accommodating the neutral point of the three-phase winding, wherein each phase of the three-phase winding includes a first winding portion made of a copper wire and an aluminum wire a second winding portion, wherein the neutral point accommodating portion accommodates the neutral point of the first winding portion of each phase and the neutral point of the second winding portion of each phase, and is partitioned by at least one contact prevention portion having insulation and the contact prevention portion It has a plurality of accommodating parts, and the neutral point of the first winding part and the neutral point of the second winding part are accommodated in different accommodating parts, respectively.

According to the present invention, since the neutral point of the first winding part and the neutral point of the second winding part are housed in different accommodating parts, contact between dissimilar metals can be prevented only by the insulating member, so that dissimilar metal corrosion at the neutral point can be prevented. , it is possible to provide a three-phase motor with high reliability, which can be effectively prevented by suppressing the cost with a small number of members.

BRIEF DESCRIPTION OF THE DRAWINGS It is the schematic which shows the side surface of the electric motor which concerns on Embodiment 1 of this invention.
Fig. 2 is a connection diagram of a stator winding employing a Y-connection method of an electric motor according to Embodiment 1 of the present invention;
Fig. 3 is a side view showing a neutral point and a neutral point accommodating part of the electric motor according to the first embodiment of the present invention;
Fig. 4 is a connection diagram of a stator winding employing a Y-connection method of an electric motor according to a second embodiment of the present invention;
Fig. 5 is a side view showing a neutral point and a neutral point accommodating part of the electric motor according to the second embodiment of the present invention;
Fig. 6 is a connection diagram of a stator winding employing a Y-connection method of an electric motor according to a third embodiment of the present invention;
Fig. 7 is a side view showing a neutral point and a neutral point accommodating portion of the electric motor according to the third embodiment of the present invention;

Embodiment 1.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the side surface of the electric motor which concerns on Embodiment 1 of this invention. As shown in FIG. 1 , the electric motor 200 is a three-phase electric motor driven by a three-phase AC power supply. The electric motor 200 includes a main body outer shell 210 forming an outer periphery, a stator 220 formed in an annular shape, a rotor 230 rotatably provided on the inner periphery of the stator 220, and a rotor 230 . It has a shaft 240 connected to the. The stator 220 has a stator iron core 220a and a three-phase winding 100 (refer to FIG. 2 ) which is a Y-connected stator winding. The three-phase winding 100 is wound around a stator core 220a and provided.

Fig. 2 is a connection diagram of a stator winding employing the Y-connection method of the electric motor according to the first embodiment of the present invention. As illustrated in FIG. 2 , the electric motor 200 employs a Y-connection method of three windings as a winding method of the three-phase winding 100 .

The three-phase winding 100 is connected to a power supply device or commercial power supply (not shown) for supplying a three-phase AC power, and has an assembly of three independent windings. More specifically, the three-phase winding 100 is an assembly of independent windings, the U-phase winding unit 10 connected to the U-phase of the three-phase AC power supply, and the V-phase connected to the V-phase of the three-phase AC power supply. It has a winding part 20 and a W-phase winding part 30 connected to the W phase of a three-phase AC power supply.

The U-phase winding section 10, the V-phase winding section 20, and the W-phase winding section 30 are three windings made of two copper wires and one aluminum wire, respectively. That is, the U-phase winding portion 10 has a U-phase copper winding portion 11 and a U-phase copper winding portion 12 made of copper wire, and a U-phase aluminum winding portion 13 made of an aluminum wire. The V-phase winding section 20 includes a V-phase copper winding section 21 and a V-phase copper winding section 22 made of copper wire, and a V-phase aluminum winding section 23 made of an aluminum wire. The W-phase winding section 30 includes a W-phase copper winding section 31 and a W-phase copper winding section 32 made of copper wire, and a W-phase aluminum winding section 33 made of an aluminum wire.

U-phase copper winding section 11, U-phase copper winding section 12, V-phase copper winding section 21, V-phase copper winding section 22, W-phase copper winding section 31, and W-phase copper winding section Each of the sections 32 corresponds to the “first winding section” of the present invention. The U-phase aluminum winding part 13, the V-phase aluminum winding part 23, and the W-phase aluminum winding part 33 respectively correspond to the "second winding part" of the present invention. That is, in the three-phase winding 100 , one end of the first winding portion of each phase is connected and Y-connected, while one end of the second winding portion of each phase is connected and Y-connected.

Here, a copper wire shall include the electric wire formed of the material containing copper, such as a copper alloy, for example. In addition, an aluminum wire shall include the electric wire formed with the material containing aluminum, such as an aluminum alloy, for example.

The U-phase copper winding section 11 has a winding 11a, a terminal wire 11b that is one of the terminals, and a terminal wire 11c that is the other of the terminals. The U-phase copper winding section 12 has a winding 12a, a terminal wire 12b that is one of the terminals, and a terminal wire 12c that is the other of the terminals. The U-phase aluminum winding section 13 has a winding 13a, a terminal wire 13b as one of the terminals, and a terminal wire 13c as the other terminal.

The V-phase copper winding unit 21 has a winding 21a, a terminal wire 21b that is one of the terminals, and a terminal wire 21c that is the other of the terminals. The V-phase copper winding portion 22 has a winding 22a, a terminal wire 22b as one of the terminals, and a terminal wire 22c as the other terminal. The V-phase aluminum winding portion 23 has a winding 23a, a terminal wire 23b as one of the terminals, and a terminal wire 23c as the other terminal.

The W-phase copper winding part 31 has a winding 31a, a terminal wire 31b as one of the terminals, and a terminal wire 31c as the other terminal. The W-phase copper winding portion 32 has a winding 32a, a terminal wire 32b that is one of the terminals, and a terminal wire 32c that is the other of the terminals. The W-phase aluminum winding part 33 has a winding 33a, a terminal wire 33b as one of the terminals, and a terminal wire 33c as the other terminal.

In addition, the three-phase winding 100 has a copper neutral point 40 and an aluminum neutral point 50 . The copper neutral point 40 is a neutral point formed by joining a plurality of first winding portions made of a copper wire. More specifically, the copper neutral point 40 is a neutral point formed by joining two sets of first winding portions, that is, two first winding portions of each phase. The aluminum neutral point 50 is a neutral point formed by joining a plurality of second winding parts made of an aluminum wire. More specifically, the aluminum neutral point 50 is a neutral point formed by joining a pair of second winding parts, that is, one second winding part of each phase.

The terminal wire 11b, the terminal wire 12b, the terminal wire 21b, the terminal wire 22b, the terminal wire 31b, and the terminal wire 32b are connected by the copper neutral point 40. As shown in FIG. The terminal wire 13b, the terminal wire 23b, and the terminal wire 33b are connected by the aluminum neutral point 50 . That is, in the three-phase winding 100, the copper neutral point 40 to which six copper wires were connected, and the aluminum neutral point 50 to which three aluminum wires were connected are formed. Here, the copper neutral point 40 corresponds to the "neutral point of the first winding portion" of the present invention, and the aluminum neutral point 50 corresponds to the "neutral point of the second winding portion" of the present invention.

In the first embodiment, the copper neutral point 40 is a terminal wire 11b, a terminal wire 12b, a terminal wire 21b, a terminal wire 22b, a terminal wire 31b, and a terminal wire 32b. It is formed by bundling the wire in a state in which the insulation coating is removed, braiding it along the circumferential direction, and then welding. The aluminum neutral point 50 is also formed by welding the terminal wire 13b, the terminal wire 23b, and the terminal wire 33b similarly to the copper neutral point 40.

However, as a method of forming the copper neutral point 40 and the aluminum neutral point 50, various methods other than the above can be used. For example, as a method of joining electric wires, means such as soldering, Tungsten Inert Gas (TIG) welding, brazing, or connection by crimp terminals can be used. That is, as a joining member of the copper neutral point 40 and the aluminum neutral point 50, various members can be used.

Further, the U-phase winding portion 10 has a U-phase connection terminal 110 connected to the U-phase via a lead wire 300 . The terminal line 11c, the terminal line 12c, and the terminal line 13c are connected by the U-phase connection terminal 110 . The V-phase winding portion 20 has a V-phase connection terminal 120 connected to the V-phase via a lead wire 300 . The terminal line 21c, the terminal line 22c, and the terminal line 23c are connected by the V-phase connection terminal 120 . The W-phase winding section 30 has a W-phase connection terminal 130 connected to the W-phase via a lead wire 300 . The terminal line 31c, the terminal line 32c, and the terminal line 33c are connected by the W-phase connection terminal 130 .

Moreover, the electric motor 200 has the neutral point storage part 60 which accommodates the neutral point of the three-phase winding 100, ie, the copper neutral point 40 and the aluminum neutral point 50. As shown in FIG. In addition, in FIG. 2, the neutral point accommodating part 60 is shown with a broken line for convenience.

Fig. 3 is a side view showing a neutral point and a neutral point accommodating portion of the electric motor according to the first embodiment of the present invention. As shown in FIG. 3 , the copper neutral point 40 and the aluminum neutral point 50 are inserted into the insulating neutral point accommodating part 60 .

The neutral point accommodating portion 60 has a side portion 61 formed by winding a film-shaped insulating paper into a cylindrical shape a plurality of times. In the neutral point accommodating part 60, the end part 62 which closed the one end side of the cylindrical side part 61, and the contact prevention part 64 which has insulation are welded by ultrasonic waves or the like. Moreover, in the neutral point accommodating part 60, the opening 63 is formed in the other end side of the cylindrical side part 61. As shown in FIG. That is, the neutral point accommodating part 60 has the 1st accommodating part 70 and the 2nd accommodating part 80 partitioned by the contact prevention part 64 .

The copper neutral point 40 and the aluminum neutral point 50 are inserted from the opening 63 , the copper neutral point 40 is accommodated in the first accommodating part 70 , and the aluminum neutral point 50 is the second accommodating part 80 . ) is stored in

In the first embodiment, the neutral point accommodating portion 60 is formed of insulating paper. As the insulating paper constituting the neutral point accommodating part 60, for example, a plurality of insulating papers having a thickness of about 100 μm are stacked and formed to have a total thickness of about 500 μm can be suitably used. As a material of the insulating paper constituting the neutral point accommodating part 60 , a weldable material such as NOMEX or PET (polyethylene terephthalate) may be employed.

By the way, aluminum has a large ionization tendency compared with copper. For this reason, when aluminum and copper come into direct contact, dissimilar metal corrosion occurs in which aluminum releases ions to copper by dissimilar metal contact and corrodes aluminum. In this regard, in the electric motor 200 of the first embodiment, the neutral point of copper (40) and the neutral point of aluminum (50) because the contact prevention section (64) in the neutral point accommodating section (60) plays the role of a partition. Since the contact with the copper wire and the aluminum wire can be prevented, corrosion of dissimilar metals at the neutral point can be prevented.

That is, the electric motor 200 is an improved method of connecting the neutral point in the three-phase winding 100, and the copper neutral point 40 and the aluminum neutral point 50 are the first housing part 70 and the second number, respectively. It is stored in the payment (80). Therefore, only by the neutral point accommodating part 60 as an insulating member, since the contact between dissimilar metals can be prevented, the dissimilar metal corrosion at the neutral point is effectively prevented by reducing the cost with a small number of members, A three-phase motor with high reliability can be provided.

Here, the bonding member of the copper neutral point 40 and the bonding member of the aluminum neutral point 50 may be of the same type of metal or different types of metal. For example, the bonding member of the copper neutral point 40 and the bonding member of the aluminum neutral point 50 are dissimilar metals, and the difference in the ionization tendency between the bonding member of the copper neutral point 40 and the bonding member of the aluminum neutral point 50 is large. Also in this case, in the inside of the neutral point accommodating part 60 , the contact preventing part 64 is interposed between the copper neutral point 40 and the aluminum neutral point 50 . Therefore, since the bonding member of the copper neutral point 40 and the bonding member of the aluminum neutral point 50 do not contact each other, corrosion of dissimilar metals can be prevented.

Embodiment 2.

Since the overall configuration of the electric motor of the second embodiment is the same as that of the electric motor 200 described with reference to FIG. 1 , the same reference numerals are used below. In addition, about the structural member equivalent to Embodiment 1 mentioned above, description is abbreviate|omitted using the same code|symbol.

Fig. 4 is a connection diagram of the stator windings employing the Y-connection method of the electric motor 200 according to the second embodiment of the present invention. An electric motor 200 according to the second embodiment is Y-connected and has a three-phase winding 100A provided in a stator iron core 220a. The three-phase winding 100A has a copper neutral point 40a, a copper neutral point 40b, and an aluminum neutral point 50, as shown in FIG. The copper neutral point 40a and the copper neutral point 40b are, respectively, a neutral point formed by joining a pair of first winding parts, ie, one first winding part of each phase.

The terminal wire 11b, the terminal wire 21b, and the terminal wire 31b are connected by the copper neutral point 40a. The terminal wire 12b, the terminal wire 22b, and the terminal wire 32b are connected by the copper neutral point 40b. That is, in the three-phase winding 100A, a copper neutral point 40a to which three copper wires are connected, a copper neutral point 40b to which three copper wires are connected, and an aluminum neutral point 50 to which three aluminum wires are connected are formed. The copper neutral point 40a and the copper neutral point 40b are formed similarly to the copper neutral point 40 in Embodiment 1. FIG.

Here, the copper neutral point 40a and the copper neutral point 40b respectively correspond to the "neutral point of the first winding portion" of the present invention, and the aluminum neutral point 50 corresponds to the "neutral point of the second winding portion" of the present invention. do.

As described above, in the three-phase winding 100A, the number of wires connected to the neutral point of the copper wire is three, and since the number of wires connected to the neutral point of the copper wire is reduced from six in the three-phase winding 100 of the first embodiment, the connection difficulty can be reduced, and connection failure can be more reliably prevented.

In addition, the electric motor 200 in the second embodiment has a neutral point of the three-phase winding 100A, that is, a neutral point accommodating part ( 60A). In addition, in FIG. 4, the neutral point accommodating part 60A is shown with a broken line for convenience.

5 : is a side view which shows the neutral point of the electric motor which concerns on Embodiment 2 of this invention, and a neutral point accommodating part. The neutral point accommodating portion 60A has a side portion 61 formed by winding a film-shaped insulating paper into a cylindrical shape a plurality of times. In the neutral point accommodating portion 60A, the end portion 62 having one end of the cylindrical side portion 61 closed, and the insulating contact preventing portion 64a and the contact preventing portion 64b are welded by ultrasonic waves or the like. there is. Further, in the neutral point accommodating portion 60A, an opening 63 is formed at the other end of the cylindrical side portion 61 . That is, the neutral point accommodating part 60A includes the first accommodating part 70a partitioned by the contact preventing part 64a and the contact preventing part 64b, the second accommodating part 80, and the third accommodating part ( 70b).

The copper neutral point 40a, the copper neutral point 40b, and the aluminum neutral point 50 are inserted from the opening 63, the copper neutral point 40a is accommodated in the first accommodating part 70a, and the copper neutral point 40b Silver is accommodated in the third accommodating part 70b, and the aluminum neutral point 50 is accommodated in the second accommodating part 80 .

As described above, the number of accommodating parts included in the neutral point accommodating part 60A is equal to the sum of the number of neutral points of the first winding part and the number of neutral points of the second winding part. And, in the electric motor 200 of this Embodiment 2, the copper neutral point 40a, the copper neutral point 40b, and the aluminum neutral point 50 are respectively the 1st accommodating part 70a and the 3rd accommodating part 70b. and the second accommodating part 80 . Therefore, since the contact of dissimilar metals can be prevented by only the neutral point accommodating part 60A as an insulating member, the dissimilar metal corrosion at the neutral point can be efficiently prevented by reducing the cost with a small number of members, and 3 with high reliability A phase motor may be provided.

That is, in the neutral point accommodating part 60A, the contact prevention part 64b is a partition between the copper neutral point 40a and copper neutral point 40b as a neutral point of a copper winding part, and the aluminum neutral point 50 as a neutral point of an aluminum winding part. function Therefore, since the contact between the copper wire and the aluminum wire can be prevented, corrosion of the dissimilar metal at the neutral point can be prevented.

Moreover, since the neutral point accommodating part 60A has the contact prevention part 64a interposed between the copper neutral point 40a and the copper neutral point 40b, the copper neutral point 40a and the aluminum neutral point 50 contact. can be prevented more reliably. And, for example, the bonding member of the copper neutral point 40a and the bonding member of the copper neutral point 40b are dissimilar metals, and the bonding member of the copper neutral point 40 and the bonding member of the aluminum neutral point 50 are ionized, for example. Even when the difference in tendency is large, dissimilar metal corrosion can be effectively prevented.

In addition, in the three-phase winding 100A, since the number of copper wires connected at each neutral point is smaller than that of the three-phase winding 100, the copper wires can be better connected, and poor connection can be avoided more reliably. . The other effects are the same as those of the first embodiment.

Embodiment 3.

Since the overall configuration of the electric motor of the third embodiment is the same as that of the electric motor 200 of the first embodiment described with reference to FIG. 1 , the same reference numerals are used below. In addition, about the structural member equivalent to Embodiment 1 and 2, description is abbreviate|omitted using the same code|symbol.

Fig. 6 is a connection diagram of the stator windings employing the Y-connection method of the electric motor according to the third embodiment of the present invention. The electric motor 200 according to the third embodiment is Y-connected and has a three-phase winding 100B provided in a stator iron core 220a. In addition, the electric motor 200 has not the neutral point storage part 60A in Embodiment 2, but the neutral point storage part 60B which accommodates the neutral point of the three-phase winding 100B. That is, the neutral point accommodating part 60B accommodates the copper neutral point 40a, the copper neutral point 40b, and the aluminum neutral point 50. As shown in FIG. The other configuration of the three-phase winding 100B is the same as that of the three-phase winding 100A in the second embodiment.

Fig. 7 is a side view showing a neutral point and a neutral point accommodating portion of the electric motor according to the third embodiment of the present invention. The neutral point accommodating portion 60B has a side portion 61 formed by winding a film-shaped insulating paper into a cylindrical shape a plurality of times. In the neutral point accommodating part 60B, the end 62 which closed the one end side of the cylindrical side part 61, and the contact prevention part 64c which have insulation are welded by ultrasonic waves or the like. Further, in the neutral point accommodating portion 60B, an opening 63 is formed at the other end of the cylindrical side portion 61 . That is, the neutral point accommodating part 60B has the 1st accommodating part 70c and the 2nd accommodating part 80 partitioned by the contact prevention part 64c.

The copper neutral point 40a, the copper neutral point 40b, and the aluminum neutral point 50 are inserted from the opening 63, and the copper neutral point 40a and the copper neutral point 40b are accommodated in the first accommodating part 70c, , the aluminum neutral point 50 is accommodated in the second accommodating part 80 . That is, two of the neutral point of the first winding portion and the neutral point of the second winding portion are accommodated in one housing portion.

As described above, the number of accommodating parts included in the neutral point accommodating part 60B is smaller than the sum of the number of neutral points of the first winding part and the number of neutral points of the second winding part. And, in the electric motor 200 of this Embodiment 3, the copper neutral point 40a and the copper neutral point 40b are accommodated in the 1st accommodating part 70a, and the aluminum neutral point 50 is the 2nd accommodating part 80. is stored in Therefore, since the contact of dissimilar metals can be prevented by only the neutral point accommodating portion 60B as an insulating member, corrosion of dissimilar metals at the neutral point can be efficiently prevented by reducing the cost with a small number of members, and having high reliability A phase motor may be provided.

Moreover, although the neutral point storage part 60A of Embodiment 2 mentioned above has two contact prevention parts, the neutral point storage part 60B of this Embodiment 3 has one contact prevention part. Therefore, in the neutral point accommodating part 60B, compared with the neutral point accommodating part 60A, since a welding part decreases and the number of labor decreases, the improvement of productivity can be aimed at. In addition, since it is not necessary to accommodate the copper neutral point 40a and the copper neutral point 40b in another storage unit, the copper neutral point 40a and the copper neutral point 40b can be easily accommodated, thereby improving work efficiency. can do. The other effects are the same as in the first and second embodiments.

Here, each embodiment mentioned above is a suitable specific example in an electric motor, and the technical scope of this invention is not limited to these aspects. For example, in Embodiment 1 - 3, although the case where the electric motor 200 has three windings of stator windings was illustrated, it is not limited to this. That is, in Embodiments 1 to 3, the U-phase winding section 10, the V-phase winding section 20, and the W-phase winding section 30 were three windings made of two copper wires and one aluminum wire, Three volumes with one copper wire and two aluminum wires may be sufficient. In this case, the three-phase winding 100, 100A, or 100B may have a neutral point formed by joining two sets of second winding parts, and may have two neutral points formed by joining a pair of second winding parts.

In addition, the number of windings which the U-phase winding part 10, the V-phase winding part 20, and the W-phase winding part 30 have is not limited to three, If a copper wire and an aluminum wire are mixed, it is two. Any number is fine, and 4 or more is fine. When the number of windings of each phase winding portion is four or more, the ratio of the number of copper winding portions to the number of aluminum winding portions in the winding portion of each phase can be arbitrarily changed. In addition, the number of neutral points of a 1st winding part and the number of neutral points of a 2nd winding part can be changed arbitrarily. In addition, the number of neutral points accommodated in each accommodating part is not limited to one or two, and may be three or more. That is, the neutral point accommodating portion may have at least one contact preventing portion having insulation and a plurality of accommodating portions partitioned by the contact preventing portion.

That is, in the electric motor 200 of Embodiments 1 - 3, the neutral point of a 1st winding part and the neutral point of a 2nd winding part should just be accommodated in different storage parts, respectively. Further, in the electric motor 200 of the second and third embodiments, each phase of the three-phase windings 100A and 100B may have one or more first winding portions and one or more second winding portions. And at least one of the neutral point of a 1st winding part and the neutral point of a 2nd winding part should just be provided in multiple numbers.

In addition, in the electric motor 200 in Embodiment 2, at least two of the neutral point of a 1st winding part and the neutral point of a 2nd winding part should just be accommodated in one accommodating part. Here, the number of accommodating parts may be greater than the sum of the number of neutral points of the first winding part and the number of neutral points of the second winding part. Therefore, in the neutral point accommodating portion, the number of accommodating portions may be equal to the sum of the number of neutral points in the first winding portion and the number of neutral points in the second winding portion.

Further, in the electric motor 200 according to the third embodiment, at least two of the plurality of neutral points of the first winding portion and the second winding portion may be accommodated in one housing portion. Here, for example, the neutral point accommodating part 60A of Embodiment 2 is applied to the electric motor 200 of Embodiment 3, and the neutral point accommodating part which has many accommodating parts in the state in which one of each accommodating part is emptied is applied. It may be used and rotated, but if there is a accommodating part in which the neutral point is not accommodated, that much effort and cost is required. Accordingly, the neutral point accommodating section may have the necessary number of accommodating sections such that the number of accommodating sections is smaller than the sum of the number of neutral points of the first winding section and the number of neutral points of the second winding section.

In other words, the U-phase winding portion 10, the V-phase winding portion 20, and the W-phase winding portion 30 may each have at least one copper winding portion and at least one aluminum winding portion, respectively. . In addition, one or a plurality of copper neutral points and one or a plurality of aluminum neutral points may be accommodated in different accommodating units, respectively. When the electric motor 200 contains a plurality of at least one of a copper neutral point and an aluminum neutral point, the number of accommodating portions and the number of neutral points may be the same, and the plurality of neutral points may be accommodated in different accommodating portions. Alternatively, the number of accommodating parts may be made smaller than the number of neutral points, and at least two of the plurality of neutral points may be accommodated in one accommodating part.

In addition, FIG. 3, FIG. 5, and FIG. 7 describe each structural member typically, The size, shape, etc. of each structural member are not limited to description of each figure. For example, the welding position of the contact prevention portion 64 in Fig. 2 is not limited to the central portion in the side view of the end portion 62, and is appropriately changed according to the size of the copper neutral point 40 and the aluminum neutral point 50, etc. can That is, each of the accommodating portions included in the neutral point accommodating portions 60, 60A, and 60B may not have an equal size or may not have an equal shape.

10: U-phase winding part
11, 12: U-phase copper winding part
11a, 12a, 13a, 21a, 22a, 23a, 31a, 32a, 33a winding
11b, 11c, 12b, 12c, 13b, 13c, 21b, 21c, 22b, 22c, 23b, 23c, 31b, 31c, 32b, 32c, 33b, 33c: terminal line
13: U-phase aluminum winding part
20: V-phase winding part
21, 22: V-phase copper winding part
23: V-phase aluminum winding part
30: W phase winding part
31, 32: W-phase copper winding part
33: W-phase aluminum winding part
40, 40a, 40b: copper neutral point
50: aluminum neutral point
60, 60A, 60B : Neutral point storage part
61: side
62: end
63: opening
64, 64a, 64b, 64c: contact prevention part
70, 70a, 70c: first receiving part
70b: third accommodating part
80: second storage unit
100, 100A, 100B: 3-phase winding
110: U-phase connection terminal
120: V phase connection terminal
130: W phase connection terminal
200: electric motor
210: body outer shell
220: stator
220a: stator iron core
230: rotor
240: shaft
300: lead wire

Claims (5)

a three-phase winding provided on the stator iron core;
and a neutral point accommodating part for accommodating the neutral point of the three-phase winding,
Each phase of the three-phase winding is
a first winding portion made of a copper wire;
It includes a second winding part made of an aluminum wire,
The neutral point receiving unit,
accommodating the neutral point of the first winding part of each phase and the neutral point of the second winding part of each phase,
at least one contact preventing part having insulating properties;
It has a plurality of accommodating parts partitioned by the contact prevention part,
The neutral point of the first winding part and the neutral point of the second winding part are accommodated in the different accommodating parts,
Each phase of the three-phase winding is
Having one or a plurality of sets of the first winding portion, and one or a plurality of sets of the second winding portion,
At least one of the neutral point of the first winding portion and the neutral point of the second winding portion is provided in plurality;
At least two of the neutral point of the first winding part and the neutral point of the second winding part are accommodated in one of the housing parts. According to claim 1,
The number of the accommodating parts is smaller than the sum of the number of neutral points of the first winding part and the number of neutral points of the second winding part. delete delete delete

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