CN215897414U - Multilayer flat wire winding stator module and motor - Google Patents

Abstract

The utility model provides a multilayer flat wire winding stator module, includes stator core, the position of the initiating terminal of winding sets up to initial layer and initial slot, winds along stator core circumferencial direction according to pitch y, after 1 circle of coiling along stator core circumferencial direction, is connected to the inslot flat wire of another polar group on the same layer according to span k with the mode of crossing the line on the same layer, then winds the circle along stator core circumferencial direction according to pitch y equally, and the leading-out terminal and the initiating terminal of last winding are located the same layer. The bus bar does not have the condition of multilayer overline, the outgoing lines are arranged clearly, so that the purposes of reducing the size, the number and the circumferential angle of the bus bar, optimizing the structure of the bus bar, reducing the volume of the bus bar or canceling the bus bar are achieved, meanwhile, the twisting heads of every two layers of the welding ends are completely consistent with the welding form, the simplification of the processes of twisting heads, welding, insulating treatment and the like of the welding ends is realized, the manufacturing process of the motor is simplified, the cost is reduced, and the product flexibility is improved.

Description

Multilayer flat wire winding stator module and motor

Technical Field

The utility model relates to the field of electricity, in particular to a motor, and especially relates to a multilayer flat wire winding stator assembly and a motor.

Background

With the increasing requirements of the driving motor of the new energy automobile on torque density and power density, the driving motor also shows a tendency of flattening. The motor stator winding adopts a flat wire mode, so that the slot filling rate is greatly increased, and meanwhile, good heat dissipation of the winding in the slot is realized. The flat wire winding of the motor usually adopts a wave winding form, and can simultaneously adopt different pitches to meet the arrangement, insulation and the like of winding. The common flat wire forms of the stator winding comprise a Hairpin structure, an I-pin structure and a continuous wave winding structure, and the two types are mature at present. The number of the common stator winding flat wires is also 2, 4, 5, 6, 7, 8, 10, 12 and more according to the complexity of the manufacturing process. In the existing common flat wire scheme, one end or both ends of the flat wire are connected by adopting a welding mode, and in order to form Y-shaped or delta-shaped connection of a three-phase winding and connection between branches, the winding end part usually adopts a plurality of cross-wire modes, a plurality of groups of cross-wire structures form a common bus bar, the bus bar mainly has the functions of realizing cross-wire connection of the same branch, series or parallel connection of different branches, neutral point connection and three-phase outgoing line connection, and plays a very critical role in a winding formed by a flat wire motor, in the prior art, the cross-wire structure for forming the bus bar is complex, so that the bus bar at the end part of the flat wire winding has larger envelope size, more layers and larger circumferential angle, the processing process difficulty is high, the copper consumption is high, the processing cost and the material cost are both higher, the application flexibility is lower, and the local temperature of the bus bar end is overhigh, the winding performance is not stable.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a multilayer flat wire winding stator assembly and a motor, and aims to solve the technical problems that the structure of a flat wire motor stator winding in the prior art is complex, the processing technology difficulty is high, and the winding performance is unstable.

The utility model relates to a multilayer flat wire winding stator component, which comprises a stator core, wherein the stator core comprises a stator slot, the stator is characterized in that a flat wire winding is embedded in the stator slot, the flat wire winding adopts a wave winding structure, a U phase, a V phase and a W phase are arranged in the winding, at least one branch is arranged in any phase, any branch is formed by a coil, the number of layers of any coil is an even number with more than two layers, a starting end of the winding is arranged as a starting layer starting slot and is wound along the circumferential direction of the stator core according to a pitch y, after 1 turn of winding is carried out along the circumferential direction of the stator core, the stator core is connected to the flat wire in the slot of the other polar group in the same layer in a same layer cross wire mode according to the span k, and then, winding a circle along the circumferential direction of the stator core according to the pitch y, wherein the wire outlet end and the starting end of the final winding are positioned in the same layer, and both y and k are positive integers.

Furthermore, any phase is provided with two or more branches, and the branches are connected in series or in parallel.

Further, k = y +1 or k = y-1.

Furthermore, each phase of the wave winding comprises 2 parallel branches, the number of layers of coils in any one stator slot is 6, the outgoing line end in any layer of coils is connected with a three-phase outgoing line, the three-phase outgoing line end in each phase of branch is connected in parallel, and the tail ends of the three-phase branches are connected together to form a star point line end to form star connection or form triangular connection through head-to-tail connection.

The motor comprises the multilayer flat wire winding stator assembly.

Compared with the prior art, the utility model has positive and obvious effect. The bus bar does not have the condition of multilayer overline, the outgoing lines are arranged clearly, so that the purposes of reducing the size, the number and the circumferential angle of the bus bar, optimizing the structure of the bus bar, reducing the volume of the bus bar or canceling the bus bar are achieved, meanwhile, the twisting heads of every two layers of the welding ends are completely consistent with the welding form, the simplification of the processes of twisting heads, welding, insulating treatment and the like of the welding ends is realized, the manufacturing process of the motor is simplified, the cost is reduced, and the product flexibility is improved. The overline of the utility model has simple structure, less bending, less bus bar welding spots, less layers and small radial size, improves the structural performance stability of the winding and simplifies the process.

Drawings

Fig. 1 is a schematic view of a winding unwinding structure of a multi-layer flat wire winding stator assembly and an embodiment of an electric machine according to the present invention.

Fig. 2 is a schematic structural diagram of a stator assembly of an embodiment of a multi-layer flat wire winding stator assembly and an electric machine according to the present invention.

Fig. 3 is a schematic structural diagram of a U-shaped wire of a stator assembly according to an embodiment of the utility model.

Fig. 4 is a schematic structural diagram of a U-shaped wire with cross wires on the same layer according to an embodiment of the multi-layer flat wire winding stator assembly and the motor of the present invention.

Fig. 5 is a schematic structural diagram of a stator assembly welding end of an embodiment of a multi-layer flat wire winding stator assembly and an electric machine according to the present invention.

Illustration of the drawings: the stator comprises a stator iron core 1, a stator winding crown (U-shaped) end 2, a stator winding welding end 3, a busbar or copper bar 4, a conventional U-shaped wire 5 and a U-shaped wire 6 below the busbar.

Detailed Description

The present invention will be further described with reference to the drawings and examples, but the present invention is not limited to the examples, and all similar structures and similar variations using the present invention shall fall within the scope of the present invention. The use of the directions of up, down, front, rear, left, right, etc. in the present invention is only for convenience of description and does not limit the technical solution of the present invention.

As shown in fig. 1-5, the multilayer flat wire winding stator assembly of the present invention comprises a stator core 1, the stator core 1 includes a stator slot, the flat wire winding is embedded in the stator slot, the flat wire winding adopts a wave winding structure, the winding is provided with a U phase, a V phase and a W phase, any phase is provided with 2 branches, the 2 branches are connected in parallel, any branch is formed by a coil, the number of layers of any coil is an even number of two or more layers, in any branch, the position of the starting end of the winding is set as a starting layer starting groove, the winding is performed along the circumferential direction of the stator core 1 according to a pitch y, after 1 turn is performed along the circumferential direction of the stator core 1, the winding is connected to a flat wire in a slot of another polar phase group on the same layer according to a span k in the same layer overline manner, and then the winding is performed along the circumferential direction of the stator core 1 according to the pitch y, and the wire outlet end and the starting end of the last winding are positioned on the same layer, and y and k are positive integers.

Further, k = y +1 or k = y-1.

Furthermore, the wave winding comprises 2 parallel branches, the number of layers of coils in any one stator slot is 6, the outgoing line end in any layer of coil is connected with a three-phase outgoing line, the three-phase outgoing line end in each phase of branch is connected in parallel, the tail ends of the three-phase branches are connected together to form a star point line end to form star connection, or the three-phase branches are connected end to form triangular connection.

The motor comprises the multilayer flat wire winding stator assembly.

Specifically, each phase winding of the same polarity is defined as a polar phase group.

Specifically, the flat wire winding, the wave winding, the winding wound 1 turn along the circumferential direction of the stator core 1 and the like in this embodiment all adopt the known schemes in the prior art, and those skilled in the art are well aware of this and will not be described herein again.

If a plurality of parallel branches exist, any other parallel branch is also connected by windings according to the method, each branch has a same-layer overline, and the same-layer overlines among different branches form concentric symmetrical overlines. Therefore, no matter the branches are connected in series or in parallel in the winding process of the motor winding, the multi-layer overline cannot be led out, and the starting ends and the wire outlet ends of different branches are all arranged on the same layer, so that the arrangement of the lead wires is very clear.

In order to ensure the current distribution in each branch is balanced, the winding in each branch comprises the winding of each layer, and the circulating current between the winding branches can be effectively reduced.

The bus 4 of the utility model does not have the condition of multilayer overline, and the lead wires are arranged clearly, thereby achieving the purposes of reducing the size, the number of layers and the circumferential angle of the bus 4, optimizing the structure of the bus 4, reducing the volume of the bus 4 or canceling the bus 4, simultaneously, the twisting heads of each two layers of the welding end are completely consistent with the welding form, realizing the simplification of the processes of twisting heads, welding, insulating treatment and the like of the welding end, simplifying the manufacturing process of a motor, reducing the cost and improving the product flexibility.

The overline of the utility model has simple structure, less bending, less bus bar welding spots, less layers and small radial size, improves the structural performance stability of the winding and simplifies the process.

The stator assembly of the winding connection structure and the motor with the stator assembly have the advantages that the number of winding layers, the number of parallel branches, the number of stator slots, the set pitch, the same-layer cross-line span, the winding direction (clockwise/counterclockwise) and higher flexibility are not limited.

Example 1

As shown in fig. 1 to 5, taking an 8-pole 48-slot motor as an example, a U phase, a V phase and a W phase are arranged in a winding, any phase is provided with 2 branches, the 2 branches are connected in parallel, and any branch is formed by a coil.

Taking the U-phase as an example,

the starting end of the U1 branch starts from the 1 st layer of the 1 st groove, the pitch y =6 is set, after a U-shaped wire is connected from the 2 nd layer of the 7 th groove, the wire is wound along the circumferential direction of the stator and wound to the 6 th layer of the 43 th groove, then the wire is connected to the 6 th layer of the 2 nd groove through the same-layer overline according to the span k1, the span k1=7 is set, then the wire is wound along the circumferential direction according to the pitch y, and finally the wire outlet end returns to the 1 st layer of the 8 th groove;

the U2 branch is also wound according to the mode of U1, the same layer overline span k2=5, the starting end position of the U2 branch is the 1 st layer of the 2 nd groove, the outgoing end position is the 1 st layer of the 7 th groove,

therefore, the starting end and the outlet end of each of the U1 branch and the U2 branch are on the 1 st layer, and the same-layer overlines on the two branches are concentrically symmetrical.

The connection of the V phase and the W phase is the same as that of the U phase.

Finally, the bus bars 4 are welded through adjacent lines, or the bus bars 4 are directly replaced by copper bars for connection, and the overlines are formed in the same layer connection mode.

Claims (5)

1. A multilayer flat wire winding stator assembly characterized in that: the winding comprises a stator core, wherein a stator slot is arranged in the stator core, a flat wire winding is embedded in the stator slot, the flat wire winding adopts a wave winding structure, a U phase, a V phase and a W phase are arranged in the winding, at least one branch is arranged in any phase, any branch is formed by a coil, the number of layers of any coil is an even number more than two, the position of the starting end of the winding is set as a starting layer starting slot, the winding is wound along the circumferential direction of the stator core according to a pitch y, after 1 coil is wound along the circumferential direction of the stator core, the winding is connected to an in-slot flat wire of another polar group on the same layer according to a span k in a mode of crossing the same layer, then the winding is wound for a circle along the circumferential direction of the stator core according to the pitch y, the wire outlet end and the starting end of the winding are positioned on the same layer, and y and k are positive integers.

2. The multi-layer flat wire winding stator assembly of claim 1, wherein: any phase is provided with two or more branches, and the branches are connected in series or in parallel.

3. The multi-layer flat wire winding stator assembly of claim 1, wherein: k = y +1 or k = y-1.

4. The multi-layer flat wire winding stator assembly of claim 1, wherein: each phase of the wave winding comprises 2 parallel branches, the number of layers of coils in any one stator slot is 6, the outgoing line end in any layer of coil is connected with a three-phase outgoing line, the three-phase outgoing end in each phase of branch is connected in parallel, and the tail ends of the three-phase branches are connected together to form a star point line end to form star connection or form triangular connection through end-to-end connection.

5. An electric machine characterized by: a multi-layer flat wire winding stator assembly comprising any of claims 1-4.

Images