JP7013560B2 - Motors and motor equipment - Google Patents

Description

The present invention relates to motors and motor devices.

Patent Document 1 discloses a motor having two windings. In the motor, the first system winding and the second system winding composed of distributed windings are alternately arranged in the slots of the stator.

International Publication No. 2016/0633668

In the above-mentioned distributed winding motor, since the first system winding and the second system winding are alternately arranged at the coil end portion, the windings having different systems are easily mechanically contacted with each other, and the two systems are easily contacted with each other. Short circuits between windings are likely to occur.

According to one aspect of the invention, the motor is distributed around the stator core and is provided with a plurality of independent system windings individually connected to the plurality of inverters and different system windings provided in the slots of the stator core. An in-slot insulating member arranged between the coil end insulating members and a coil end insulating member arranged at the coil end portion of the plurality of system windings are provided, and the plurality of system windings are formed in a slot formed in the stator core. It is composed of a system winding arranged on the inner peripheral side and a system winding arranged on the outer peripheral side of the slot than the system winding arranged on the inner peripheral side, and is arranged on the outer peripheral side. The coil end portion of the wire is arranged with a gap with respect to the coil end portion of the system winding arranged on the inner peripheral side, and the coil end insulating member is arranged on the inner peripheral side. The system winding is inserted between the coil end portion of the winding and the coil end portion of the system winding arranged on the outer peripheral side, and the system winding arranged on the inner peripheral side and the system arranged on the outer peripheral side. Each of the windings has a crossover wire arranged at the coil end portion so as to straddle between different slots, and the coil end insulating member has a flange portion sandwiched between the crossover wire and the coil end portion. Has .
According to another aspect of the present invention, a plurality of independent system windings arranged in a distributed winding on the stator core and individually connected to a plurality of inverters and between different system windings provided in the slot of the stator core. The plurality of system windings are distributed windings of wave windings, and are arranged in order from the inner peripheral side to the outer peripheral side of the slot. The n system windings formed by separating the 4 series orbital coils arranged on the inner peripheral side of the slot into n pieces, and the 4 series orbiting coils arranged on the outer peripheral side of the slot into m pieces. There are m system windings formed separately.
According to another aspect of the present invention, the motor device is provided for each of the motor of the above aspect, a plurality of inverters individually connected to the plurality of system windings of the motor, and the plurality of system windings. A switching unit provided and connected to each neutral point of the phase winding of the system winding to connect and disconnect the neutral points, and a connection by the switching unit according to a short circuit between different system windings. And a control unit for controlling the disconnection.
According to another aspect of the present invention, the motor device is individually connected to the motor of the above aspect and the plurality of system windings of the motor, and a plurality of drives for supplying electric power to the plurality of system windings. A circuit and a plurality of inverters connected in parallel to the system winding are provided in the drive circuit.

According to the present invention, in a motor having a plurality of system windings, it is possible to improve the insulation between different system windings.

FIG. 1 is a diagram showing an embodiment of the motor of the present invention. FIG. 2 is a cross-sectional view of the motor. FIG. 3 is a perspective view of a stator in which two system windings are arranged. FIG. 4 is a diagram illustrating the arrangement of conductors in the slot. FIG. 5 is a diagram schematically showing two orbiting coils arranged in the slot. FIG. 6 is an enlarged view of a part of the stator shown in FIG. FIG. 7 is a diagram illustrating the shape of the coil end insulating member. FIG. 8 is a diagram showing an example of an installation method of the coil end insulating member. FIG. 9 is a diagram showing a modified example of the coil end insulating member. FIG. 10 is a diagram in which the coil end insulating member of FIG. 9 is arranged at the coil end portion. FIG. 11 is a diagram showing another example of the shape of the coil end portion. FIG. 12 is a diagram showing the shape of the insulating member in the slot. FIG. 13 is a diagram showing another example of the insulating member in the slot. FIG. 14 is a diagram showing a comparative example. FIG. 15 is a diagram showing an example of an in-slot insulating member in a comparative example. FIG. 16 is a diagram showing a coil connection circuit of the two-system winding shown in FIG. FIG. 17 is a slot layout diagram in the case where the second system winding is arranged with the second system winding deviated by one slot from the first system winding. FIG. 18 is a diagram showing a coil connection circuit in the case of the slot layout diagram shown in FIG. FIG. 19 is a diagram illustrating a torque waveform when configured as shown in FIGS. 17 and 18. FIG. 20 is a circuit block diagram showing an example of a drive device for driving a two-system winding motor. FIG. 21 is a diagram showing another example of a drive device for driving a two-system winding motor. FIG. 22 is a diagram showing still another example of a drive device for driving a two-system winding motor. FIG. 23 is a slot layout diagram in the case of three-system winding. FIG. 24 is a coil connection circuit of the first to third system windings shown in FIG. 23. FIG. 25 is a diagram illustrating the torque of the motor configured by the first to third system windings shown in FIG. 24. FIG. 26 is a coil layout diagram in the case of four systems. FIG. 27 is a coil arrangement diagram in the case of 6 systems. FIG. 28 is a schematic diagram showing a coil arrangement when four system windings over the entire circumference are arranged concentrically. FIG. 29 is a schematic diagram showing a coil arrangement when one circumference is divided into two and different system windings are arranged in each. FIG. 30 is a diagram illustrating the torque of the motor configured by the first to fourth system windings shown in FIG. 29. FIG. 31 is a diagram illustrating a case where the torque of the second system winding of FIG. 29 is stopped. FIG. 32 is a diagram showing a coil arrangement when the two system windings shown in FIG. 14 are arranged on the inner peripheral side and the outer peripheral side to form a four system winding. FIG. 33 is a perspective view of the stator in which the two-system winding of the lap winding is arranged. FIG. 34 is a diagram showing an example of an in-slot insulating member in the case of the arrangement shown in FIG. 32. FIG. 35 is a perspective view of the steering device. FIG. 36 is a flow chart illustrating the operation of the steering device. FIG. 37 is a diagram showing a switching unit provided in the drive circuit.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing an embodiment of the motor of the present invention, and shows an external view of an auxiliary motor for a vehicle, for example, a motor 100 used for electric power steering. The motor 100 has a drive circuit (not shown) arranged on the opposite side of the shaft 3. The motor 100 includes a housing 1 and a bracket 2, and a shaft 3 which is an output shaft protrudes from the bracket 2. A plurality of coil lead wires 50 extend from the opposite side of the housing 1 (that is, the side opposite to the bracket mounting side).

FIG. 2 is a cross-sectional view of the motor 100. An O-ring 6 is provided between the housing 1 and the bracket 2. A front bearing 5 that supports one end side of the shaft 3 is fixed to the bracket 2 by a bevel type retaining ring 4. On the other hand, the housing 1 is provided with a rear bearing 10 that supports the other end side of the shaft 3. The shaft 3 is rotatably supported by these bearings 5 and 10. The rotor 16 provided on the shaft 3 has an embedded structure in which a permanent magnet 7 is provided in the rotor core 8.

A stator core 9 is provided on the inner peripheral side of the housing 1, and an electrically independent three-phase first system winding 20 and a second system winding 21 are arranged in the slot of the stator core 9. As will be described later, in the present embodiment, the first system winding 20 is arranged on the inner peripheral side of the slot, and the second system winding 21 is arranged on the outer peripheral side of the first system winding 20. A cylindrical coil end insulating member is provided between the coil end portion of the first system winding 20 on the inner peripheral side and the coil end portion of the second system winding 21 on the outer peripheral side for the purpose of preventing a short circuit between the systems. 11 is provided. The coil end insulating member 11 is provided at both coil end portions on the output shaft side (bracket 2 side) and the non-output side (coil lead wire 50 side). The plurality of coil lead wires 50 are drawn out to the coil end portion on the non-output side, and project from the housing 1 to the control circuit side on the right side in the drawing.

FIG. 3 is a perspective view of the stator in which the first system winding 20 and the second system winding 21 are arranged. A plurality of coil lead wires 50 (50a, 50b) are drawn out from the coil end portions arranged on the upper side in the axial direction of the stator core 9. A cylindrical coil end insulating member 11 is arranged between the coil end portion of the first system winding 20 arranged on the upper side in the axial direction of the stator core 9 and the coil end portion of the second system winding 21. .. Although not shown, also between the coil end portion of the first system winding 20 and the coil end portion of the second system winding 21 arranged on the opposite side (that is, the lower side in the axial direction) of the stator core 9. The coil end insulating member 11 is arranged. On the opposite side of the stator core 9, a connecting portion 17 of a segment coil constituting the winding is provided.

Twelve coil lead wires 50 are provided, and six coil lead wires 50a relating to the UVW input wire and the neutral wire of the first system winding 20 and the UVW input wire and the neutral wire of the second system winding 21 are provided. It is composed of the six coil lead wires 50b of the above. Further, a crossover wire 18a of the first system winding 20 and a crossover wire 18b of the second system winding 21 are arranged on the coil end portion side where the coil lead wire 50 is drawn out.

Each of the first system winding 20 and the second system winding 21 shown in FIG. 3 is a distributed winding three-phase winding in which a plurality of segment coils are connected by a wave winding. Although the details will be described later, the first and second system windings 20 and 21 of the wave winding structure are formed by a circumferential coil formed by connecting a plurality of segment coils in series. Each segment coil is inserted into the slot from the upper side in the axial direction of the stator core 9, and the end of the inserted segment coil protrudes from the opposite side (lower side in the axial direction) of the slot. The end of the segment coil protruding from the opposite side (lower side in the axial direction) of the slot is connected by soldering, Tig welding, laser welding, or the like to form the connecting portion 17.

FIG. 4 is a diagram illustrating the arrangement of conductors in the slot. Hereinafter, the conductor portion arranged in the slot in the system winding will be referred to as an in-slot conductor. FIG. 4 shows the arrangement of conductors in the slots in the case of 10 poles and 60 slots. In one slot, four conductors in the slot are inserted from the inner peripheral side to the outer peripheral side.

In FIG. 4, the upper figure shows slot numbers 1 to 24, the middle figure shows slot numbers 25 to 48, and the lower figure shows slot numbers 49 to 60. The numbers shown at the bottom of the figure in each row indicate the slot numbers. In the figure of each stage, the upper side in the drawing is the outer peripheral side of the slot, and the lower side in the drawing is the inner peripheral side. Four in-slot conductors are arranged in the slot, and hereinafter, the positions of the in-slot conductors in the slot will be referred to as layer 1, layer 2, layer 3, and layer 4 from the inner peripheral side. Each of the first system winding 20 and the second system winding 21 has a configuration in which four circumferential coils formed by connecting a plurality of segment coils in the circumferential direction of the stator core 9 are connected in series.

Of the four circumferential coils constituting the U-phase winding of the first system winding 20, the first circumferential coil having the coil lead wire 50a on the input side (circular coil indicated by reference numeral 1U14 in FIG. 16 to be described later) is The ten in-slot conductors shown by reference numerals 1U14, 1u12, 1U24, 1u22, 1U34, 1u32, 1U44, 1u42, 1U54, 1u52 in FIG. 4 are connected in order, and are drawn out of the slot from the in-slot conductor 1U14. The winding constitutes the coil lead wire 50a. The numbers in parentheses shown in FIG. 4 indicate the connection order.

The second orbital coil connected to the orbiting coil 1U14 (the orbiting coil indicated by reference numeral 1U13 in FIG. 16 to be described later) is indicated by reference numerals 1U13, 1u11, 1U23, 1u21, 1U33, 1u31, 1U43, 1u41, 1U53, 1u51 10 The conductors in the slots of the book are connected in order, and the conductors 1U13 in the slots are connected to the conductors 1u52 in the slots of the circumferential coil 1U14.

The third orbital coil connected to the orbiting coil 1U13 (the orbiting coil indicated by reference numeral 1U11 in FIG. 16 to be described later) is indicated by reference numerals 1U11, 1u53, 1U51, 1u43, 1U41, 1u33, 1U31, 1u23, 1U21, 1u13 10 The conductors in the slots of the book are connected in order, and the conductors 1U11 in the slots are connected to the conductors 1u51 in the slots of the circumferential coil 1U13.

The fourth orbital coil connected to the orbiting coil 1U11 (the orbiting coil indicated by reference numeral 1U12 in FIG. 16 to be described later) is indicated by reference numerals 1U12, 1u54, 1U52, 1u44, 1U42, 1u34, 1U32, 1u24, 1U22, 1u14. The conductors in the slots of the book are connected in order, and the conductors 1U12 in the slots are connected to the conductors 1u13 in the slots of the circumferential coil 1U11.

Regarding the V-phase winding and the W-phase winding of the first system winding 20, the reference numerals U and u in the U-phase winding are replaced with the reference numerals V and v in the case of the V phase, and the reference numerals W and v in the case of the W phase. It will be replaced with w. Further, although the description is omitted, the second system winding 21 has the same configuration. In the configuration shown in FIG. 4, since the in-slot conductor is arranged in the same slot number in the U phase of the first system winding 20 and the U phase of the second system winding 21, the U of the first system winding 20 There is no electrical phase difference between the phase and the U phase of the second system winding 21. The same applies to the V phase and the W phase.

As can be seen from FIG. 4, the first system winding 20 is arranged on the inner peripheral side layer 1 and layer 2, and the second system winding 21 is arranged on the outer peripheral side layer 3 and layer 4. Therefore, the coil end portion of the first system winding 20 and the coil end portion of the second system winding 21 are separated into an inner peripheral side and an outer peripheral side, and a cylindrical coil end (see FIG. 3) is formed in the gap between them. The insulating member 11 can be arranged. That is, one coil end insulating member 11 can be configured to prevent contact between the first system winding 20 and the second system winding 21 at one coil end portion.

FIG. 5 is a diagram schematically showing the orbiting coils 1U14 and 1U13 arranged in the slot. The number surrounded by a circle indicates the slot number. For example, the segment coil of the circumferential coil 1U14 designated by the reference numeral SC is inserted into the slot of slot number 8 and the slot of slot number 14 from the upper side of the drawing. Then, the conductor portion protruding on the opposite side of the slot is bent in the direction of the adjacent segment coil, and the connecting portion 17 of each of the bent conductors is connected to the connecting portion 17 of the adjacent segment coil. Among the conductors in the slot inserted into the slot, those arranged in layer 1 are shown by solid lines, and those arranged in layer 2 are shown by broken lines. The segment coil SC comprises two in-slot conductors 1u12 and 1U24, the in-slot conductor 1u12 is located in layer 1 of the slot number 8 and the in-slot conductor 1U24 is located in layer 2 of the slot number 14. Has been done.

The circumferential coil 1U14 is wound around the slot number 2 in the direction of the slot number 56, and the circumferential coil 1U13 is wound around the slot number 1 in the direction of the slot number 55. The 20 inner-slot conductors 1U14 to 1u51 of the circumferential coils 1U14 and 1U13 are alternately arranged in layers 2 and 1.

The first in-slot conductor 1U11 of the third orbiting coil 1U11 is arranged in layer 1 of slot number 1, and the crossover wire 18a connecting the in-slot conductor 1u51 of the orbiting coil 1U13 and the in-slot conductor 1U11 of the orbiting coil 1U11. Is provided so as to extend from layer 1 of slot number 55 to layer 1 of slot number 1. The ten inner conductors 1U11 to 1u13 of the orbiting coil 1U11 are alternately arranged in layers 1 and 2, and the orbiting coil 1U11 is wound so as to orbit in the direction opposite to that of the orbiting coils 1U14 and 1U13. The fourth orbiting coil 1U12 is also wound so as to orbit in the opposite direction in the same manner as the orbiting coil 1U11.

In the configuration shown in FIGS. 3 and 4, the U-phase, V-phase, and W-phase windings of the first system winding 20 and the second system winding 21 each crossover two circumferential coils connected in series. It is configured to be connected by 18a and 18b. Here, the n system windings formed by separating the four series orbital coils arranged on the inner peripheral side of the slot into n pieces and the four series orbiting coils arranged on the outer peripheral side of the slot are m. The number of systems can be increased by using m system windings that are separated and formed. Here, n and m are integers of 2 to 4. For example, by disconnecting the four series orbital coils at the crossover wires 18a and 18b and connecting the two separated coils (two series orbital coils) in parallel or making them independent, the first system winding 20 and the first system winding 20 and the first Each of the two-system winding 21 can be newly made into two systems. That is, the structure of the conductor in the slot shown in FIG. 4 can be four systems. Further, if the connection portion of the two series circumferential coils is separated, a maximum of eight winding systems can be obtained.

As shown in FIG. 4, the in-slot conductor of the first system winding 20 is arranged in the layers 1 and 2 on the inner peripheral side of the slot, and the in-slot conductor of the second system winding 21 is arranged in the layer 3 on the outer peripheral side of the slot. By arranging them at, 4, different system windings 20, 21 can be separately arranged on the inner peripheral side and the outer peripheral side of the stator core 9. Then, the coil end portion of the first system winding 20 and the coil end portion of the second system winding 21 can be separated and arranged on the inner peripheral side and the outer peripheral side via a gap. As a result, it is possible to prevent different system windings from coming into contact with each other at the coil end portion, and it is possible to improve the insulation performance between the different system windings.

(Explanation of coil end insulating member 11)
FIG. 6 is an enlarged view of a part of the stator shown in FIG. A slot 9b into which a conductor in the slot of the segment coil is inserted is formed between the teeth 9a of the stator core 9 and the teeth 9a adjacent thereto. As described above, the two inner-slot conductors on the inner peripheral side of each slot 9b are the inner-slot conductors of the segment coil constituting the first system winding 20. Further, the two in-slot conductors on the outer peripheral side of each slot 9b are the in-slot conductors of the segment coil constituting the second system winding 21.

In the slot 9b, an in-slot insulating member 15 is provided in order to improve the insulation between the inserted in-slot conductor and the stator core 9. As will be described later, in the present embodiment, the in-slot insulating member 15 also functions as a member for improving the insulation between the in-slot conductor of the first system winding 20 and the in-slot conductor of the second system winding 21. There is. Further, as described above, the coil end portions of the first system winding 20 and the second system winding 21 protruding from both ends in the axial direction of the stator core 9 have the first system winding 20 and the second system winding 21. A coil end insulating member 11 (see also FIG. 2) is provided so that the coil ends do not come into contact with each other mechanically or electrically.

The coil lead wire 50a of the first system winding 20 is drawn from the inner peripheral side of the coil end insulating member 11, and the coil lead wire 50b of the second system winding 21 is drawn from the outer peripheral side of the coil end insulating member 11. In this embodiment, the two system windings (first system winding 20 and second system winding 21) have a coil lead wire 50a and a coil lead wire as shown in FIG. 3 in order to avoid mechanical contact. It is designed to take out 50b from the opposite side of the left and right. Further, the crossover wire 18a of the first system winding 20 is located on the inner peripheral side of the coil end insulating member 11, and the crossover wire 18b of the second system winding 21 is located on the outer peripheral side of the coil end insulating member 11. ing. The crossover wire 18a connects the conductors in the slot of the layer 1 to each other, and the crossover wire 18b connects the conductors in the slot of the layer 3 to each other.

7A and 7B are views for explaining the shape of the coil end insulating member 11, FIG. 7A is a plan view, FIG. 7B is a sectional view taken along the line AA, and FIG. 7C is a modified example of the folded-back portion 111. Is shown. The coil end insulating member 11 includes a cylindrical portion 110 on the inner peripheral side and a folded portion 111 formed at the lower end portion (that is, the end portion on the stator core side) of the cylindrical portion 110. Although the folded portion 111 is folded into a V shape in FIGS. 7 (a) and 7 (b), it may be folded into a substantially circular shape as shown in FIG. 7 (c). The radial dimension L1 of the folded portion 111 is preferably set to be larger than the radial clearance dimension of the first system winding 20 and the second system winding 21.

The coil end insulating member 11 is formed of, for example, insulating paper. First, one long side portion of the strip-shaped insulating paper is folded back to form the folded portion 111. After that, the strip-shaped insulating paper on which the folded-back portion 111 is formed is rolled into a cylindrical shape so that the insulating paper end portions 114 are abutted as shown in FIG. 7A.

FIG. 8 is a diagram showing an example of a method of installing the coil end insulating member 11 in the gaps between the first and second system windings 20 and 21. When inserting the coil end insulating member 11 into the gap between different system windings, a thin plate-shaped jig 170 as shown in FIG. 8A is inserted into the recess of the folded-back portion 111 to insert the coil end insulating member 11. Push 11 into the gap. At that time, the folded-back portion 111 is deformed to the inner peripheral side as shown by an arrow, and the folded-back portion 111 is in contact with the inner peripheral side of the second system winding 21 as shown in FIG. 8 (b). When the folded-back portion 111 has a shape as shown in FIG. 7 (c), the cross-sectional shape is deformed so as to be crushed in the radial direction from a substantially circular shape and comes into contact with the inner peripheral side of the second system winding 21. It becomes a state.

By forming the folded-back portion 111 on the insertion side of the coil end insulating member 11 in this way, the folded-back portion 111 comes into contact with the inner peripheral side of the second system winding 21 and is caught, and the coil end insulating member 11 becomes the first. It becomes difficult to come off from the gap between the system winding 20 and the second system winding 21. Further, by pushing the coil end insulating member 11 with the jig 170 as shown in FIG. 8A using the folded-back portion 111, the coil end insulating member 11 can be easily inserted into the gap between the first system winding 20 and the second system winding 21. Can be inserted.

As described above, by arranging the coil end insulating member 11 between the coil end portion of the first system winding 20 and the coil end portion of the second system winding 21 separated on the inner peripheral side and the outer peripheral side. It is possible to completely prevent contact between different system windings at the coil end portion, and further improve the insulation performance between the system windings at the coil end portion.

FIGS. 9 and 10 are diagrams showing a modified example of the coil end insulating member arranged at the coil end portion on the coil lead wire lead-out side. Here, the coil end insulating member on the coil lead-out side is represented by reference numeral 11R. 9A and 9B are views showing the shape of the coil end insulating member 11R, where FIG. 9A is a plan view and FIG. 9B is a cross-sectional view taken along the line BB. Further, FIG. 10 is a diagram in which the coil end insulating member 11R is arranged at the coil end portion on the coil lead wire lead-out side. As shown in FIG. 9, the coil end insulating member 11R has a plurality of collars at the upper end of the cylindrical portion 110, that is, the end portion of the cylindrical portion 110 opposite to the folded portion 111, in addition to the cylindrical portion 110 and the folded portion 111. The portions 115a and 115b are provided. The flange portion 115a is bent toward the inner peripheral side, and the flange portion 115b is bent toward the outer peripheral side.

As shown in FIG. 10, the coil end insulating member 11R is inserted from the folded-back portion 111 into the gap between the first system winding 20 and the second system winding 21 as in the case of the coil end insulating member 11. Then, the flange portion 115a bent to the inner peripheral side is placed on the lower side of the crossover wire 18a of the first system winding 20 arranged on the inner peripheral side (that is, the coil end portion of the crossover wire 18a and the first system winding 20). Insert into the gap). The flange portion 115b bent toward the outer peripheral side is below the crossover wire 18b of the second system winding 21 arranged on the outer peripheral side (that is, the gap between the crossover wire 18b and the coil end portion of the second system winding 21). Insert into. By inserting the flange portions 115a and 115b below the crossover wires 18a and 18b in this way, it is possible to prevent the coil end insulating member 11R from coming off from the gap between the first system winding 20 and the second system winding 21. is doing.

In the example shown in FIGS. 6 and 10, the case where the winding crawling shape of the first system winding 20 and the winding crawling shape of the second system winding 21 at the coil end portion have the same form is an example. It was shown to. On the other hand, as shown in FIG. 11, the winding crawling shape of the first system winding 20 and the winding crawling shape of the second system winding 21 are the positions of the coil end insulating member 11R (boundary between system windings). The winding crawling shape of the first system winding 20 may be changed so as to have a symmetrical shape with respect to the wind.

For example, in the layout diagram of FIG. 4, by exchanging the conductor in the slot of layer 1 of the first system winding 20 and the conductor in the slot of layer 2, the coil end portion having a symmetrical shape as shown in FIG. 11 is obtained. Although not shown, in the replaced arrangement drawing, the in-slot conductor 2U14 arranged in the layer 4 of the slot number 2 of the second system winding 21 on the outer peripheral side is arranged in the layer 3 of the slot number 8. It is connected to the in-slot conductor 2u12, while the in-slot conductor 1U14 of the layer 1 of the slot number 2 of the first system winding 20 on the inner peripheral side is connected to the in-slot conductor 1u12 of the layer 2 of the slot number 8. Become. As a result, the arrangement shape of the windings connecting the conductors in the slot is symmetrical with respect to the coil end insulating members 11 and 11R, and the coil end insulating members 11 and 11R can be easily inserted into the gap of the coil end portion.

(Explanation of Insulating Member 15 in Slot)
FIG. 12 is a diagram illustrating insulation in the slot 9b, and is a schematic view when a portion of the slot 9b is cross-sectionald perpendicular to the slot core axial direction. In addition, in FIG. 12, the slot of the slot number 1 of FIG. 4 is shown. Two conductors in the slot of the first system winding 20 are arranged on the inner peripheral side of the slot 9b, and two conductors in the slot of the second system winding 21 are arranged on the outer peripheral side of the slot 9b. .. The in-slot insulating member 15 is slotted so as to surround the two inner-slot conductors 1U11, 1U13 of the first system winding 20 and the two inner-slot conductors 2U11, 2U13 of the second system winding 21, respectively. It is arranged in 9b. For the insulating member 15 in the slot, for example, an insulating paper obtained by bending an insulating paper as shown in the shape of FIG. 12 is used.

In the configuration shown in FIG. 12, both ends of the in-slot insulating member 15 are inserted between the in-slot conductor 1U13 of the first system winding 20 and the in-slot conductor 2U11 of the second system winding 21, and the in-slot insulating member 15 is inserted. Are arranged so that two sheets overlap. Here, this insertion portion will be referred to as an insulating member insertion portion 15a. That is, in the configuration of FIG. 12, two insulating member insertion portions 15a are arranged between the first system winding 20 and the second system winding 21. Of course, only one of the upper and lower insulating member insertion portions 15a may be provided, but by arranging the insulating member insertion portions 15a in duplicate, the electrical insulation between the systems in the slot 9b can be further improved. Can be planned.

Further, when the thickness dimension of the coil end insulating members 11 and 11R arranged between the systems of the coil end portion is Tz2 and the thickness dimension of the in-slot insulating member 15 arranged in the slot 9b is Tz1. The thickness dimension 2Tz1 of the portion of the in-slot insulating member 15 between the system windings 20 and 21 and the overall thickness dimension 2Tz2 of the portion where the folded portion 111 of the coil end insulating members 11 and 11R are provided are 2Tz1 <2Tz2. By setting as follows, that is, by setting Tz1 <Tz2, the distance between the conductors of different system windings in the slot 9b can be made wider, and short-circuit prevention between different system windings can be prevented. It is effective for. In FIG. 12, an insulating member insertion portion 15a on the system winding distance 20 side and an insulating member insertion portion 15a on the system winding distance 21 side are provided between the system windings 20 and 21, and the insulating member is divided into two layers. However, in the case of a single-layer configuration in which the insulating member insertion portion 15a is provided on only one side (not shown), by setting Tz1 <2Tz2, the conductors in the slots of different system windings in the slot 9b The distance between them can be increased.

FIG. 13 is a diagram showing another example of the in-slot insulating member 15. In FIG. 13, the folded-back 150 is formed in the insulating member inserting portion 15a so that the number of layers of the insulating member of the insulating member inserting portion 15a is two, so that the conductors 1U13 in the slots and the conductors 2U11 in the slots having different systems are used. The structure is such that four insulating members (four layers) are arranged in the same space. In this way, by folding back the insulating paper at the boundary between the different system windings, a larger gap between the conductors in the slot can be secured, and the slots of the different system windings on the inner peripheral side and the outer peripheral side of the slot 9b. In the motor in which the inner conductor is arranged, there is an effect that the insulation between the system windings can be further improved. Further, since it is possible to secure a larger gap in the coil end portions of the system windings 20 and 21, it is possible to omit the coil end insulating members 11 and 11R.

(Comparative example)
FIG. 14 is a diagram showing a comparative example, and shows a case where conductors in slots of the same system winding are arranged in all layers from layer 1 to layer 4 of the slot as in the conventional case. In-slot conductors 1U11, 1U12, 1U13, 1U14 of the first system winding 20 are arranged in the slot of slot number 1, and in-slot conductors 2U11, 2U12, 2U13 of the second system winding 21 are arranged in the slot of slot number 2. , 2U14 are arranged.

FIG. 15 is a diagram showing an example of the in-slot insulating member 25 in the comparative example. In FIG. 15, the slot 9b of the slot number 1 is shown. As shown in FIG. 14, the in-slot conductors of the same system winding are arranged in the slot 9b, and the in-slot conductors 1U11, 1U12, 1U13, 1U14 of the first system winding 20 are arranged in the slot number 1. There is. Therefore, as shown in FIG. 15, an insulating paper that integrally surrounds the four in-slot conductors 1U11 to 1U14 is used for the in-slot insulating member 25 arranged in the slot 9b.

As described above, in the case of the comparative examples shown in FIGS. 14 and 15, since the in-slot conductors of the same system winding are arranged in the slots, it is not necessary to consider the insulation between the systems with respect to the in-slot conductors. As shown in FIG. 15, the shape could be made in consideration of only the insulation between the conductor in the slot and the stator core 9. However, in the coil end portion, since the first system winding and the second system winding cannot be separately arranged on the inner peripheral side and the outer peripheral side as in the present embodiment, it is difficult to insulate by the insulating member. Met. Therefore, the first system winding 20 and the second system winding 21 are likely to come into contact with each other at the coil end portion, and if the coils of different systems rub against each other due to vibration or the like, a short circuit may occur.

FIG. 16 is a diagram showing a coil connection circuit of the two-system winding shown in FIG. As described in FIG. 4, for the U-phase circumferential coils 1U11 and 1U13 of the first system winding 20, since the conductors 1U11 and 1U13 in the slot at the start of winding (that is, the input side) are arranged in the slot number 1. There is no electrical phase difference between the orbiting coil 1U11 and the orbiting coil 1U13. However, the conductors 1U12 and 1U14 in the slots at the start of winding of the circumferential coils 1U12 and 1U14 are arranged in slot number 2, and in the case of 10 poles and 60 slots, the electric angle of 360 degrees for 2 poles corresponds to 6 slots. The electric angle for one slot is 30 degrees. Therefore, the phase of the U-phase coil (U1 phase in FIG. 16) is 15 degrees in electrical angle as shown in FIG. 16 with respect to slot number 1.

Similarly, since the U-phase in-slot conductor of the second system winding 21 is arranged in the same slot as the U-phase in-slot conductor of the first system winding 20, the first system winding is shown in the winding diagram. The phase shift is 15 degrees, which is the same as the U phase of 20. As a result, there is no electrical phase difference between the first system winding 20 and the second system winding 21. The phases other than the U phase are electrically out of phase by 120 degrees, and detailed description thereof will be omitted.

FIG. 17 shows a slot arrangement diagram when the second system winding 21 is arranged in a state of being displaced by one slot from the first system winding 20. Regarding the first system winding 20, the conductors 1U11 and 1U13 in the slots of the circumferential coils 1U11 and 1U13 are arranged in the layers 1 and 2 of the slot number 1, and the slots of the circumferential coils 1U12 and 1U14 are arranged in the layers 1 and 2 of the slot number 2. Inner conductors 1U12 and 1U14 are arranged. On the other hand, regarding the second system winding 21, the in-slot conductors 2U11, 2U13 of the circumferential coils 2U11, 2U13 are arranged in the layers 3 and 4 of the slot number 2, and the circumferential coils 2U12 and 2U14 are arranged in the layers 3 and 4 of the slot number 3. In-slot conductors 2U12 and 2U14 are arranged.

FIG. 18 is a diagram showing a coil connection circuit in the case of the slot layout diagram shown in FIG. The first system winding 20 is the same as that shown in FIG. 16, but as shown in FIG. 17, the second system winding 21 is arranged so as to be offset by one slot from the first system winding 20. As a result, an electrical phase difference of 30 degrees is provided. The phases other than the U phase are electrically displaced by 120 degrees, and detailed description thereof will be omitted.

FIG. 19 shows a torque waveform (torque of the first system) when a current is supplied to the first and second system windings 20 and 21 configured as shown in FIGS. 17 and 18 at a current phase angle at which the maximum torque can be generated. It is a figure which shows T1, the torque T2) of the 2nd system, and the waveform of the combined torque Tout which superposed the torque T1 and the torque T2. Since the torque ripple of the three-phase motor is the sixth component of the fundamental wave, the period of the torque ripple is 60 degrees in the electric angle.

Since the second system winding 21 has a phase difference of an electric angle of 30 degrees with respect to the first system winding 20 (see FIG. 18), the second system winding has a phase difference with respect to the torque T1 generated by the first system winding 20. The torque T2 generated by the wire 21 is electrically out of phase by 30 degrees. As a result, when the torque T1 and the torque T2 that repeat in a cycle of 60 degrees are added and combined, they are combined so that the mutual torque ripples cancel each other, and the waveform of the combined torque Tout becomes a waveform with a small torque ripple. Therefore, when applied to a motor for electric power steering, very good performance can be obtained.

(Explanation of drive unit)
FIG. 20 is a circuit block diagram showing an example of a drive device that drives a motor with two windings. Hereinafter, a structure in which a phase difference capable of reducing torque ripple is provided between the first system winding 20 and the second system winding 21 (for example, the structure shown in FIGS. 17 and 18) will be described as an example. A drive circuit 40 is connected to the first system winding 20, and a drive circuit 41 is connected to the second system winding 21 configured to have a phase difference of 30 degrees in electrical angle with respect to the first system winding 20. Be connected.

The drive circuit 40 includes an inverter 61 and a control ECU (Electronic Control Unit) 81 that generates a gate signal 71 of the inverter 61. Similarly, the drive circuit 41 includes an inverter 64 and an ECU 82 that generates a gate signal 74 of the inverter 64. Further, the drive circuits 40 and 41 each have phase current detection units CtU1 to CtW2 so that the current of each phase can be fed back, and two systems are obtained by measuring the current actually flowing in response to the current command. The imbalance between them is corrected. Since the drive circuits 40 and 41 are basically energized with a phase difference of 30 degrees as described above, the torque ripple is minimized. However, if there is reluctance torque generated in the embedded magnet rotor structure, it may be better to make the phase slightly larger than 30 degrees. In that case, torque ripple is performed by adjusting the current phase of the second system winding. Can be minimized.

The battery Bat1 is connected to the drive circuit 40, and the battery Bat2 is connected to the drive circuit 41. Further, the generator 42 for charging the batteries Bat1 and Bat2 has an independent system terminal. That is, the drive circuits 40 and 41 are configured to be able to independently supply electric power to the system windings 20 and 21. In FIG. 20, the generator 42 has a structure in which a power generation voltage independent of one housing is supplied, but two generators may be provided so that the two systems can be completely separated.

Further, a communication means 43 is provided between the drive circuit 40 and the drive circuit 41, and the drive circuits 40 and 41 can grasp each other's situation by the communication means 43. Then, the drive circuits 40 and 41 can operate so as to help the decrease in the motor drive on the defective side when an abnormality occurs.

FIG. 21 is a diagram showing another example of a drive device for driving a two-system winding motor, and shows a circuit configuration when a means capable of boosting the motor output is built-in. The difference from the configuration shown in FIG. 20 is that the two independent batteries Bat1 and Bat2 are unified into one battery Bat1, and the power generation command voltage Vref can be output from the drive circuit 40 to the generator 42. ing.

Next, the operation will be described. Normally, the generator 42 generates electricity at a voltage slightly higher than the nominal voltage of the battery Bat1 used. For example, for a 12V battery, the generator generates electricity at about 14V. If it is known that a mode in which the output is desired to be increased occurs in the middle of driving the motor, the power generation voltage command Vref of the generator 42 is raised before the mode is generated, and the battery voltage is charged higher. By increasing the voltage that can be used by the motor in this way, it is possible to power up in a short time.

In FIG. 21, the configuration is such that the power is charged only by the battery Bat1, but since it takes time to increase the charging voltage when charging by the battery Bat1, it is possible to connect a capacitor or a capacitor in parallel and disconnect it from the battery once. It may be configured to raise the voltage in a short time.

FIG. 22 is a diagram showing still another example of a drive device for driving a two-system winding motor. The motor is composed of two winding structures including a first system winding 20 and a second system winding 21 having a phase difference in electrical angle. In the drive circuit 40 connected to the first system winding 20, three inverters 61 to 63 connected in parallel to the first system winding 20 and an ECU 81 for generating gate signals 71 to 73 of the inverters 61 to 63 are generated. Is provided. Similarly, in the drive circuit 41 connected to the second system winding 21, three inverters 64, 65, 66 connected in parallel to the second system winding 21 and the gate signals 74 to the inverters 64 to 66 An ECU 82 that generates 76 is provided. The ECUs 81 and 82 individually output gate signals to the plurality of inverters. Similar to the case of FIG. 20, a communication means 43 is provided between the drive circuit 40 and the drive circuit 41.

Since a plurality of inverters 61 to 63 are connected in parallel to the first system winding 20, even if a failure occurs in any of the inverters 61 to 63, the motor operation can be continued by disconnecting only the failed inverter. It is possible. However, since the torque is reduced by the amount of the failed inverter, the effect of the torque reduction can be reduced as the number of built-in inverters increases. Further, it is possible to increase the current of the remaining inverters for a short time when the inverter fails to generate the torque before the failure.

As described above, when the inverter fails, the torque drops, but in the case of windings over the entire circumference as shown in FIGS. 4 and 5, the torque drop occurs over the entire circumference, so the centralized winding partially Compared to the split type winding that created the system, it has the effect of suppressing vibration, and is a structure suitable for application to electric power steering motors.

In the above-described embodiment, the case of the two-system winding has been described, but the case of the three-system winding is shown in FIGS. 23 to 25. FIG. 23 is a slot layout diagram in the case of a three-system winding. In the case of a three-system winding, in order to cancel the torque ripple, it is canceled by a phase difference of 1/3 of one cycle when the electric angle of the order to be canceled is one cycle. Since the torque ripple of the three-phase motor is the sixth-order component of the fundamental wave, one cycle has an electric angle of 60 degrees. In this case, the phase difference for canceling the torque ripple is 20 degrees in the electric angle. In order to obtain a phase difference of 20 degrees in one slot, the electric angle of 360 degrees for two poles is 18 slots, so the number of slots in the case of a 10-pole motor is 90 slots. Moreover, since it is a three-system winding, the number of layers in the slot is six.

As shown in FIG. 23, the in-slot conductors of the first system winding 20 are arranged in layers 1 and 2, and the in-slot conductors of the second system winding 21 are arranged in layers 3 and 4, and the third system winding The 22 in-slot conductors are arranged on layers 5 and 6. The 1U + phase of the first system winding 20 is arranged in the layers 1 and 2 of the slot numbers 1 and 2, and the 2U + phase of the second system winding 21 is the layers 3 and 4 of the slot numbers 2, 3 and 4. The 3U + phase of the third system winding 22 is arranged in layers 5 and 6 of slot numbers 3, 4 and 5. That is, with respect to the first system winding 20, the second system winding 21 is arranged shifted to the right by one slot, and the third system winding 22 is arranged shifted to the right by two slots.

FIG. 24 is a diagram showing a coil connection circuit of the first to third system windings 20 to 22 shown in FIG. 23. Six circumferential coils 1U11 to 1U16 are connected in series in the 1U phase of the first system winding 20. The orbiting coils 1U12 and 1U15 are electrically deviated by 20 degrees with respect to the orbiting coils 1U11 and 1U14, and the orbiting coils 1U13 and 1U16 are displaced by 40 degrees. Therefore, when viewed as a whole U1 phase, the phase is 20 degrees in electrical angle on average with respect to slot number 1. Since the second system winding 21 is the result of electrically adding 20 degrees to the first system winding 20, the U2 phase winding has a phase of 40 degrees electrically. Similarly, in the case of the third system winding 22, the U3 phase winding has a phase difference of 60 degrees by adding another 20 degrees. The phases other than the U phase are electrically displaced by 120 degrees, and detailed description thereof will be omitted.

FIG. 25 shows the torque generated by each phase winding of the motor composed of the first to third system windings 20 to 22 shown in FIG. 24 (torque T1 of the first system, torque T2 of the second system, first). It is a figure which shows the waveform of the torque T3) of 3 systems and the combined torque Tout which is the total torque of all system windings. By providing a phase difference of an electric angle of 20 degrees between the system windings as shown in FIG. 24, the torque ripple of the combined torque Tout can be reduced. If the torque balance of the three systems is lost, the combined torque ripple will increase. Therefore, reducing the torque ripple in each system as a winding method that spans multiple slots as in this embodiment is effective in reducing torque ripple. be.

As described in FIGS. 19 and 25, the torque ripple is performed with a phase difference of 30 degrees in the electric angle (see FIG. 19) in the case of the two-system winding and 20 degrees in the electric angle (see FIG. 25) in the case of the three-system winding. It is important to consider the phase as it can be minimized. As for the relationship between the number of systems and the phase, since the period of torque ripple is an electric angle of 60 degrees, the value obtained by dividing the value by the number of systems is the appropriate phase difference. That is, it is 15 degrees in the case of 4 systems, 12 degrees in the case of 5 systems, and 10 degrees in the case of 6 systems. By setting the phase difference in this way, the torque ripple can be minimized.

Further, in the case of four systems, the same phase difference (electrical angle of 30 degrees) as in the case of two systems can be obtained by arranging as shown in FIG. In the case of 6 systems, by arranging as shown in FIG. 27, the same phase difference (electrical angle of 20 degrees) as in the case of 3 systems can be obtained.

In the above-described embodiment, as shown in FIGS. 4, 17, 23, 26 and 27, a plurality of system windings are sequentially arranged from the inner peripheral side of the stator core 9 toward the outer peripheral side. FIG. 28 schematically shows the coil arrangement in the case of four-system winding. In this case, the first system winding 20, the second system winding 21, the third system winding 22, and the fourth system winding 23 are provided over the entire circumference of the stator core 9, and the gap between them and the adjacent system windings is provided. A cylindrical coil end insulating member 11 is arranged in the coil end insulating member 11.

On the other hand, as shown in FIG. 29, one circumference may be divided into two and different system windings may be arranged in each. The example shown in FIG. 29 is a case of four system windings, in which the first system winding 20 and the second system winding 21 are separately arranged vertically on the inner peripheral side, and the third system winding 22 and the third system winding 22 are arranged on the outer peripheral side. The fourth system winding 23 and the winding 23 are arranged separately on the left and right.

By arranging the windings of a plurality of systems over one circumference in this way, the number of layers of the system windings in the radial direction can be reduced. For example, in the configuration of FIGS. 28 and 29 in the case of four systems, in the case of FIG. 28 in which one system winding is arranged over the entire circumference, there are four layers, but in the case of FIG. 28, two systems are arranged in one circumference. In the configuration, the number of layers can be reduced to two. Further, by shifting the switching portion on the inner peripheral side and the switching portion on the outer peripheral side as shown in FIG. 29, the torque imbalance generated in the first system winding 20 and the second system winding 21 can be reduced by the third system winding. The torque imbalance generated in the wire 22 and the fourth system winding 23 can be alleviated.

FIG. 30 shows the torque T12 generated by the first system winding 20 and the second system winding 21 and the third system in the motor composed of the first to fourth system windings 20 to 23 shown in FIG. 29. It is a figure which shows the waveform of the torque T34 generated by the winding 22 and the 4th system winding 23, and the combined torque Tout which is the total torque of all system windings. By shifting the third system winding 22 and the fourth system winding 23 in the phase of 1/2 cycle of the electric angle of 60 degrees with respect to the first system winding 20 and the second system winding 21, the combined torque Tout can be obtained. The torque ripple can be reduced.

Further, when an abnormality occurs in the drive circuit connected to the second system winding 21 in the configuration of FIG. 29 and operation becomes impossible, the remaining first system winding 20 and the third system winding 22 And it will be operated by three systems of the fourth system winding 23. In that case, the torque T12 in FIG. 30 is the torque T1 only for the first system winding as shown by the solid line in FIG. 31. The period of the waveform of the torque T1 is the same as that of the torque T12, but the level of the amplitude and the average value is reduced to half of the torque T12. Therefore, the torque T34 generated by the third system winding 22 and the fourth system winding 23 is the same as in the case of FIG. 29, but the combined torque changes as in Tout1 and the torque ripple is higher than the combined torque Tout in FIG. Becomes larger.

Therefore, if an abnormality occurs in the drive circuit connected to the second system winding 21, the current of the first system winding 20 arranged on the same circumference is increased to change the torque T1 in FIG. 31 to the torque T10. By increasing the torque ripple as described above, the torque ripple can be reduced as in the combined torque Tout2.

In the above description, the plurality of system windings are separated from each other and the insulating member is arranged in the separated gap. However, a part of the plurality of system windings is separated and the insulating member is arranged in the gap. You may do so. For example, in the case of a four-system winding, when the two system windings shown in FIG. 14 are arranged on the inner peripheral side and the outer peripheral side to form a four-system winding, the four-system winding having the configuration as shown in FIG. 32 Will be.

As shown in FIG. 32, in layers 1 to 4 on the inner peripheral side of each slot, the in-slot conductor of the first system winding 20 and the in-slot conductor of the second system winding 21 are arranged so as to be offset by one slot. ing. In layers 5 to 8 on the outer peripheral side of each slot, the in-slot conductor of the third system winding 22 and the in-slot conductor of the fourth system winding 23 are arranged so as to be offset by one slot. In this case, the windings arranged on the stator core include the inner peripheral side where the first system winding 20 and the second system winding 21 are arranged, and the third system winding 22 and the fourth system winding 23. It is separated from the outer peripheral side to be arranged. Therefore, the coil end insulating members 11 and 11R can be arranged between the separated system gaps. As a result, by arranging the coil end insulating members 11 and 11R, the insulation performance between the first and second system windings 20 and 21 and the third and fourth system windings 22 and 23 can be improved.

The layout of the conductors in the slot shown in FIG. 14 is shown for the conventional two-system winding of the wave winding, but the arrangement of the conductors in the slot is also shown in FIG. 14 in the case of the two-system winding of the lap winding. It will be the same as the one. In the case of lap winding, the shape of the coil end portion of the first system winding 20 and the second system winding 21 is as shown in FIG. 33, and the coil end portion of the first system winding 20 and the second system winding are formed. The coil end portions of 21 are alternately arranged in the circumferential direction. As described above, in the case of the lap winding shown in FIG. 33 and the case of the wave winding of the present embodiment shown in FIG. 3, the crawling of the winding at the coil end portion is different. As in the case, the two systems cannot be arranged separately on the inner peripheral side and the outer peripheral side. However, as shown in FIG. 32, by arranging the two system windings shown in FIGS. 14 and 33 on the inner peripheral side and the outer peripheral side to form a four system winding, the two system windings on the inner peripheral side and the outer peripheral side are formed. It is possible to arrange them separately from the two windings on the side.

FIG. 34 is a diagram showing an example of the in-slot insulating member 15 in the case of the arrangement shown in FIG. 32. In slot 9b of slot number 1, conductors 1U11 to 1U14 in the slot of the first system winding 20 on the inner peripheral side are integrally surrounded, and conductors 3U11 to 3U14 in the slot of the third system winding 22 on the outer peripheral side are integrally surrounded. An insulating member 15 in the slot is provided so as to integrally surround the periphery. Similarly, in the slot 9b of the slot number 2, the inner conductors 2U11 to 2U14 of the second system winding 21 on the inner peripheral side are integrally surrounded, and the inner conductor 4U11 of the fourth system winding 23 on the outer peripheral side is integrally surrounded. The in-slot insulating member 15 is provided so as to integrally surround the 4U14. Two insulating member insertion portions 15a of the in-slot insulating member 15 are arranged between the in-slot conductor 1U14 and the in-slot conductor 3U11 and between the in-slot conductor 2U14 and the in-slot conductor 4U11 having different systems.

The arrangement of the in-slot insulating member 15 in FIG. 34 has the same form as in the case of FIG. 12, but in the case of FIG. 12, the number of conductors in the slot enclosed integrally is two, and in the case of FIG. 34, four. It has become. Two insulating member insertion portions 15a of the in-slot insulating member 15 are arranged between the in-slot conductor 1U14 and the in-slot conductor 3U11 having different systems. The in-slot insulating member 15 shown in FIG. 13 may be similarly applied.

FIG. 35 is a perspective view of the steering device 200 using the motor 100 (see FIGS. 1 and 2) of the present embodiment. A pinion (not shown) is provided at the lower end of the steering shaft 202 connected to the steering wheel 201, and this pinion meshes with a rack (not shown) that is long in the left-right direction of the vehicle body. Tie rods 203 for steering the front wheels in the left-right direction are connected to both ends of the rack, and the rack is covered with a rack housing 204. A rubber boot 205 is provided between the rack housing 204 and the tie rod 203.

An electric power steering device 206 is provided to assist the torque when rotating the steering wheel 201. That is, a motor 100 is provided with a sensor 207 that detects the rotation direction and the rotation torque of the steering shaft 202, and a motor 100 that applies steering assist force to the rack via the gear 210 based on the detection value of the sensor 207, and the motor 100. A control ECU 209 for controlling the above is provided.

In such a structure, the control ECU 209 detects the steering start from the rate of change of the steering angle detected by the sensor 207, and controls to use the motor output of the inner peripheral side system as the steering assist force at the steering start. can do.

FIG. 36 is an example of a flow chart illustrating the operation of the steering device 200. When the control ECU 209 detects the steering start from the rate of change of the steering angle detected by the sensor 207 (S301), the control ECU 209 is set to use the motor output of the inner peripheral side system as the steering assist force at the steering start (S302). ). The inner peripheral side system is, for example, the first system winding 20. This utilizes the characteristic that the inner peripheral side system has a lower electrical time constant and better responsiveness, and normal control is performed after an arbitrary time has elapsed from the start of steering.

On the other hand, when the steering start is not detected from the rate of change of the steering angle detected by the sensor 207, the control ECU 209 is set to use the motor output of the outer peripheral side system as the steering assist force at the steering start (S301). (S303). The outer peripheral side system is, for example, the second system winding 21. If the start of steering is not detected, it may be controlled to use not only the outer peripheral side system but also the inner peripheral side system.

By doing so, the responsiveness of applying the steering assist force immediately after the start of steering is improved, and the steering performance can be improved. The above is particularly suitable for steep steering and high-speed operation.

According to the above-described embodiment, the effects described below can be achieved. As shown in FIGS. 3, 4 and 6, the motors are arranged in distributed windings in the stator core 9 and are connected to a plurality of independent system windings 20 and 21 individually connected to a plurality of inverters and in slots 9b of the stator core 9. The in-slot insulating member 15 provided and arranged between the different system windings 20 and 21 is provided, and the plurality of system windings 20 and 21 are arranged on the inner peripheral side of the slot 9b formed in the stator core 9. It is composed of a first system winding 20 and a second system winding 21 arranged on the outer peripheral side of the slot 9b with respect to the first system winding 20 arranged on the inner peripheral side.

By arranging the different system windings 20 and 21 on the inner peripheral side and the outer peripheral side of the slot 9b formed in the stator core 9 in this way, the first system winding 20 and the coil end portion can be used both in the slot and on the outer peripheral side. It can be arranged separately from the second system winding 21. Since the in-slot insulating member 15 is arranged between the system windings 20 and 21 in the slot, the system windings 20 and 21 are separated by the thickness of the in-slot insulating member 15 and the system is separated at the coil end portion. It is possible to form a gap between the windings 20 and 21. As a result, the insulation performance between the system windings 20 and 21 at the coil end portion can be improved.

Further, as shown in FIG. 13, the insulating member 15 in the slot is formed of insulating paper, and the folded-back 150 is formed in the insulating member insertion portion 15a between the different system windings 20 and 21, so that the different system windings 20 are formed. , 21 the insulating paper will form a plurality of layers. As a result, the insulation performance between the system windings 20 and 21 in the slot can be further improved, the distance between the system windings 20 and 21 in the slot becomes larger, and the system winding 20 at the coil end portion is increased. , The gap size between 21 can be made larger.

Further, as shown in FIG. 3, it is inserted between the coil end portion of the first system winding 20 arranged on the inner peripheral side and the coil end portion of the second system winding 21 arranged on the outer peripheral side. By providing the coil end insulating member 11, it is possible to completely prevent contact between the different system windings 20 and 21 at the coil end portion.

As shown in FIGS. 7 and 8, by forming the folded-back portion 111 at the end portion of the coil end insulating member 11 on the stator core side, the folded-back portion 111 comes into contact with the inner peripheral side of the second system winding 21 and is easily caught. .. As a result, the coil end insulating member 11 has an effect that it is difficult for the coil end insulating member 11 to come off from the gap between the first system winding 20 and the second system winding 21.

Further, as shown in FIGS. 9 and 10, each of the first system winding 20 arranged on the inner peripheral side and the second system winding 21 arranged on the outer peripheral side has coil ends so as to straddle between different slots. The coil end insulating member 11R has a flange portion 115a, 115b sandwiched between the crossover wire 18a, 18b and the coil end portion. By sandwiching the flange portions 115a and 115b between the crossover wires 18a and 18b and the coil end portion in this way, the coil end insulating member 11R is disengaged from the gap between the first system winding 20 and the second system winding 21. It has the effect of making it difficult.

Further, by setting the thickness dimension Tz2 of the coil end insulating members 11 and 11R to be larger than the thickness dimension Tz1 of the insulating member 15 in the slot, the distance between the conductors in the slots of different system windings 20 and 21 in the slot is set. Can be made wider.

As shown in FIG. 11, the first system winding 20 adjacent to the inner peripheral side of the coil end insulating member 11R and the second system winding 21 adjacent to the outer peripheral side have a winding crawling shape at the coil end portion. It has a symmetrical shape with respect to the boundary between system windings. As a result, the coil end insulating members 11 and 11R can be easily inserted into the gap between the coil ends.

As shown in FIGS. 26 to 28, by making each of the plurality of system windings into a wave winding distribution winding, each system winding arranged in order from the inner peripheral side to the outer peripheral side of the slot is radially oriented. Can be placed separately.

As shown in FIGS. 17, 23, 26, 27, at least one of the plurality of system windings is arranged so as to be displaced by one slot or more so as to cause an electrical phase difference, for example, in FIG. 26. In the example shown, the torque ripple can be reduced by shifting the second system winding 21 and the fourth system winding 23 by one slot.

Further, as shown in FIG. 29, the system windings 20 and 21 of the distributed winding of the wave winding are arranged separately on the same circumference on the inner peripheral side in 180 degree phase, and the system winding 22 of the distributed winding of the wave winding is arranged. , 23 may be arranged separately on the same circumference on the outer peripheral side in 180 degree phase. With such a configuration, the number of layers of the system winding in the radial direction can be reduced.

Further, as shown in FIG. 20, the motor device includes a motor including a plurality of system windings 20 and 21, a drive circuit 40 having an inverter 61 connected to the first system winding 20, and a second system winding 21. A drive circuit 41 having an inverter 64 connected to is provided. Then, as shown in FIG. 37, the drive circuit 40 is connected to the neutral points of the phase windings U1, V1 and W1 of the first system winding 20 to connect and disconnect the neutral points, respectively. A unit 400 and an ECU 81 that controls connection and disconnection by the switching unit 400 according to a short circuit between different system windings may be provided. The drive circuit 41 has the same configuration.

When driving the motor, the neutral points are connected to each other by the switching unit 400. Further, if a short circuit occurs between the phase windings, the drive of the system winding is stopped, but in that case, the neutral point of the phase winding that is short-circuited by controlling the switching unit 400 is controlled. Separate each other. If the neutral points of the short-circuited system windings are connected to each other, there arises a problem that a current due to the induced voltage always flows and a brake torque is generated for the normal system windings. Therefore, by separating the neutral points from each other by the switching unit 400, it is possible to prevent the generation of such a break torque.

Further, as shown in FIG. 22, a plurality of drive circuits 40, 41, which are individually connected to the first system winding 20 and the second system winding 21 and supply power to the first system winding 20, are provided. The drive circuit 40 may be provided with a plurality of inverters 61, 62, 63 connected in parallel to the first system winding 20. The drive circuit 41 has the same configuration. With such a configuration, even if any of the inverters 61 to 63 connected in parallel to the first system winding 20 fails, the motor operation can be continued by disconnecting only the failed inverter. Will be.

Although various embodiments and modifications have been described above, the present invention is not limited to these contents. Other aspects considered within the scope of the technical idea of the present invention are also included within the scope of the present invention. For example, the case where a segment coil is used for the winding has been described, but the present invention can be applied to a motor composed of distributed winding windings even in the case of a configuration in which continuous wires are used instead of the segment coil. ..

1 ... Housing, 2 ... Bracket, 3 ... Shaft, 8 ... Rotor core, 9 ... Stator core, 9a ... Teeth, 9b ... Slot, 11, 11R ... Coil end insulating member, 15, 25 ... Slot insulating member, 15a ... Insulating member Insert, 17 ... Connection, 18a, 18b ... Cross wire, 20 ... 1st system winding, 21 ... 2nd system winding, 22 ... 3rd system winding, 23 ... 4th system winding, 40 ... Drive Circuit, 41 ... Drive circuit, 50 (50a, 50b) ... Coil lead wire, 61-66 ... Inverter, 81, 82 ... ECU, 100 ... Motor, 111 ... Folded part, 115a, 115b ... Collar part, 200 ... Steering device

Claims (13)

With multiple independent system windings arranged in distributed windings on the stator core and individually connected to multiple inverters,
Insulation members in the slots provided in the slots of the stator core and arranged between different system windings.
A coil end insulating member arranged at the coil end portion of the plurality of system windings is provided.
The plurality of system windings are a system winding arranged on the inner peripheral side of the slot formed in the stator core and a system arranged on the outer peripheral side of the slot with respect to the system winding arranged on the inner peripheral side. Consists of windings,
The coil end portion of the system winding arranged on the outer peripheral side is arranged via a gap with respect to the coil end portion of the system winding arranged on the inner peripheral side.
The coil end insulating member is inserted between the coil end portion of the system winding arranged on the inner peripheral side and the coil end portion of the system winding arranged on the outer peripheral side.
Each of the system winding arranged on the inner peripheral side and the system winding arranged on the outer peripheral side has a crossover wire arranged at the coil end portion so as to straddle between different slots.
The coil end insulating member is a motor having a flange portion sandwiched between the crossover wire and the coil end portion . In the motor according to claim 1,
A motor in which the insulating member in the slot is made of insulating paper, and the insulating paper is folded back to form a plurality of layers between the different system windings. In the motor according to claim 1 or 2 .
A motor in which a folded portion is formed at an end portion of the coil end insulating member on the stator core side. The motor according to any one of claims 1 to 3 .
A motor in which the thickness dimension of the coil end insulating member is set to be larger than the thickness dimension of the insulating member in the slot. The motor according to any one of claims 1 to 4 .
The system winding adjacent to the inner peripheral side and the system winding adjacent to the outer peripheral side of the coil end insulating member are motors in which the winding crawling shape at the coil end portion is symmetrical with respect to the boundary between system windings. .. The motor according to any one of claims 1 to 5 .
The plurality of system windings are distributed windings of wave windings, and motors are arranged in order from the inner peripheral side to the outer peripheral side of the slot. In the motor according to claim 6 ,
A motor in which at least one of the plurality of system windings is staggered by one slot or more so as to cause an electrical phase difference. The motor according to any one of claims 1 to 5 .
The plurality of system windings are all distributed windings of wave windings, and two system windings are separated and arranged on the same circumference on the inner peripheral side in 180 degree phase, and 180 on the same circumference on the outer peripheral side. A motor in which two system windings are separated and arranged in a degree phase. In the motor according to claim 6 ,
The stator core is provided with first and second system windings arranged on the inner peripheral side of the slot and third and fourth system windings arranged on the outer peripheral side of the slot.
Each of the first and second system windings is composed of two series of orbital coils formed by separating four series of orbital coils arranged on the inner peripheral side of the slot into two.
Each of the third and fourth system windings is a motor composed of two series of orbital coils formed by separating four series of orbital coils arranged on the outer peripheral side of the slot into two. In the motor according to claim 6 ,
The stator core has n system windings formed by separating four series-series orbiting coils arranged on the inner peripheral side of the slot into n pieces, and four series-series arranged on the outer peripheral side of the slot. A motor provided with m system windings formed by separating the orbiting coil into m pieces. With multiple independent system windings arranged in distributed windings on the stator core and individually connected to multiple inverters,
An in-slot insulating member provided in the slot of the stator core and arranged between different system windings.
The plurality of system windings are distributed windings of wave windings, and are arranged in order from the inner peripheral side to the outer peripheral side of the slot.
The stator core has n system windings formed by separating four series-series orbiting coils arranged on the inner peripheral side of the slot into n pieces, and four series-series arranged on the outer peripheral side of the slot. A motor provided with m system windings formed by separating the orbiting coil into m pieces. The motor according to any one of claims 1 to 11 .
A plurality of inverters individually connected to the plurality of system windings of the motor, and
A switching unit provided in each of the plurality of system windings and connected to the neutral points of the phase windings of the system windings to connect and disconnect the neutral points.
A motor device including a control unit that controls connection and disconnection by the switching unit in response to a short circuit between different system windings. The motor according to any one of claims 1 to 11 .
A plurality of drive circuits that are individually connected to the plurality of system windings of the motor and supply power to the plurality of system windings.
A motor device in which a plurality of inverters connected in parallel to the system winding are provided in the drive circuit.

Images