KR102515571B1 - Stator assembly, motor and washer - Google Patents

Abstract

A stator assembly, motor and washer are provided. The stator assembly includes a first framework and a second framework. the first framework includes a first annular portion; the second framework includes a second annular portion; the first inner end face is attached and fitted to the second inner end face; The first annular portion is provided with a first mounting hole penetrating the first annular portion in an axial direction of the first annular portion; the second annular portion is provided with a second mounting hole penetrating the second annular portion in an axial direction of the second annular portion; the second mounting holes are respectively disposed coaxially with the respective first mounting holes; A groove is disposed on the outer end of each first mounting hole, and a wire groove is disposed on the outer end face of the second annular portion.

Description

Stator assembly, motor and washer

This application claims priority from Chinese Patent Application No. 201811062700.8 dated Sep. 12, 2018, entitled “Stator Assembly, Motor and Washing Machine”, the entire content of which is hereby incorporated in its entirety.

The present application relates to the technical field of motor devices, and more particularly, to a stator assembly, a motor with a stator assembly, and a washing machine with a motor.

The drum-type washing machine has a beautiful appearance and a more delicate and compact structure than a pulsator-type washing machine. Generally, the volume of the body of the drum type washing machine is half that of the pulsator type washing machine, and the drum type washing machine occupies a small space and is safe and convenient. Accordingly, the drum type washing machine is preferred by consumers.

The structure of the motor directly affects the overall size of the drum type washing machine. 1 and 2, the motor 11 of the conventional drum-type washing machine 1 is located on the rear side of the washing machine 1 (the opening and closing door of the drum is located on the front side). The motor 11 is connected to the water cylinder 12 of the washing machine 1 through a mounting flange 111 of the motor 11, and the rotation shaft 112 of the motor 11 is connected to the washing machine It is connected to the drum (not shown) of (1). Since the wires of the coil windings of the stator 113 of the conventional motor are drawn from one end close to the mounting flange 111, there is a gap between the stator 113 and the mounting flange 111 of the motor in the axial direction. More space needs to be provided for facilitating the wire drawing, thereby increasing the thickness of the motor 11 in the axial direction and making the overall size of the drum type washing machine 1 too large. In addition, a space-saving groove is not disposed between the conventional motor stator 113 and the connecting column 114 of the mounting flange 111, which causes an increase in the thickness of the motor 11 in the axial direction. do.

In order to achieve the first object of the present application, a stator assembly that makes the thickness of a motor very thin in an axial direction is provided.

In order to achieve the second object of the present application, an ultrathin motor having the above-mentioned stator assembly is provided.

In order to achieve the third object of the present application, a washing machine having the above-mentioned ultra-thin motor is provided.

In order to achieve the first object of the present application, a stator assembly is provided and includes a first framework and a second framework. the first framework includes a first annular portion; the second framework includes a second annular portion; the first annular portion includes a first inner end face opposite the second annular portion in an axial direction of the first annular portion; the second annular portion includes a second inner end face opposite the first annular portion in an axial direction of the second annular portion; The first inner end face is attached and fitted to the second inner end face. The first annular portion is provided with a first mounting hole penetrating the first annular portion in an axial direction of the first annular portion; the second annular portion is provided with a second mounting hole penetrating the second annular portion in an axial direction of the second annular portion; The second mounting holes are arranged coaxially with each of the first mounting holes. the groove is disposed at the outer end of each first mounting hole and is in a direction away from the second annular portion; The groove is recessed in a direction toward the second annular portion. The wire groove is disposed on the outer end face of each second mounting hole and is away from the first annular portion in the axial direction of the second annular portion; Each wire groove includes an opening in the axial direction of the second annular portion.

As can be seen from the above-mentioned technical solutions, the grooves are respectively disposed at the respective outer ends of the first mounting holes provided in the first annular portion of the first prom work, and are in a direction away from the second annular portion, The groove is recessed toward the direction of the second annular portion. On the other hand, the wire groove is disposed on the outer end face of the second annular portion of the second framework, and is away from the first annular portion in the axial direction of the second annular portion, thereby greatly reducing the axial thickness of the motor, thereby reducing the ultra-thin shape. implement the motor. Therefore, the overall volume of the motor is small and its weight is light.

In an embodiment, the first mounting holes are each disposed adjacent to the inner annular wall of the first annular portion.

In an embodiment, the number of first mounting holes is at least two; The number of the second mounting holes is at least two; The second mounting holes are disposed coaxially with each of the first mounting holes.

In an embodiment, at least two grooves corresponding to the at least two first mounting holes communicate in a circumferential direction of the first annular portion.

In an embodiment, the groove is disposed through the outer annular wall of the first annular portion.

In an embodiment, the stator assembly further includes an iron core including an annular yoke portion; The first annular portion and the second annular portion respectively cover and fit the two ends of the annular yoke portion in the axial direction; The bottom face of each groove is adjacent to the first inner end face and is flush with the end face of the iron core, and the end face of the iron core is away from the second annular portion.

In the embodiment, the iron core further includes a toothed portion, and the toothed portion is respectively disposed on the outer annular wall of the annular yoke portion and extends in the radial direction of the annular yoke portion; The first framework further includes first protruding pawls, the first protruding pawls are respectively disposed on the outer annular wall of the first annular portion and extend in the radial direction of the first annular portion; the second framework further includes second protruding pawls, the second protruding pawls are respectively disposed on the outer annular wall of the second annular portion and extend in the radial direction of the second annular portion; The first protruding pawl and the second protruding pawl overlap the two ends of the respective teeth in the axial direction of the annular yoke portion.

In the embodiment, the iron core further includes a boot portion, each boot portion being connected to an end of a corresponding tooth portion and extending in an axial direction of the annular yoke portion; The end of the corresponding tooth part is away from the annular yoke part; The first framework further includes a first position limiting plate; each first position limiting plate is connected to an end of a corresponding first protruding pawl and extends in an axial direction of the first annular portion; The end of the corresponding first protruding pawl is away from the first annular portion; the second framework further includes second position limiting plates, each second position limiting plate being connected to an end of a corresponding second projecting pawl and extending in the axial direction of the second annular portion; The end of the corresponding second protruding pawl is away from the second annular portion; Each of the first position limiting plates and each of the second position limiting plates are adjacent to the side of the corresponding boot portion, and the side of the corresponding boot portion is adjacent to the annular yoke portion.

To achieve the second object of the present application, a motor is provided, which includes a stator assembly and a rotor. The stator assembly includes a first framework and a second framework. the first framework includes a first annular portion; the second framework includes a second annular portion; the first annular portion includes a first inner end face opposite the second annular portion in an axial direction of the first annular portion; the second annular portion includes a second inner end face opposite the first annular portion in an axial direction of the second annular portion; The first inner end face is attached to and fitted to the second inner end face. The first annular portion is provided with a first mounting hole penetrating the first annular portion in an axial direction of the first annular portion; the second annular portion is provided with a second mounting hole penetrating the second annular portion in an axial direction of the second annular portion; The second mounting holes are disposed coaxially with each of the first mounting holes. the groove is disposed at the outer end of each first mounting hole and is in a direction away from the second annular portion; The groove is recessed in a direction toward the second annular portion. The wire groove is disposed on the outer end face of the second annular portion and is away from the first annular portion in the axial direction of the second annular portion; Each wire groove includes an opening in the axial direction of the second annular portion.

As can be seen from the above-mentioned technical solutions, the grooves are respectively disposed at respective outer ends of the first mounting holes provided in the first annular portion of the first framework, and are in a direction away from the second annular portion, and is recessed toward the direction of the second annular portion. On the other hand, the wire groove is disposed on the outer end face of the second annular portion of the second framework, and is away from the first annular portion in the axial direction of the second annular portion, thereby greatly reducing the axial thickness of the motor, and making the ultra-thin motor achieve Therefore, the overall volume of the motor is small and its weight is light.

In an embodiment, the motor further includes a rotating shaft; The mounting flange is provided with a through hole; a rotating shaft is rotatably inserted into the through hole about an axis of the rotating shaft, and one end of the rotating shaft is connected to the rotor; The rotor is fitted to the stator assembly.

In an embodiment, the motor further includes a rotating shaft. The mounting flange is provided with a through hole; a rotating shaft is rotatably inserted into the through hole about an axis of the rotating shaft, and one end of the rotating shaft is connected to the rotor; The rotor is fitted to the stator assembly.

To achieve the third object of the present application, a washing machine is provided, which includes a stator assembly and a motor including a rotor. The stator assembly includes a first framework and a second framework. the first framework includes a first annular portion; the second framework includes a second annular portion; the first annular portion includes a first inner end surface facing the second annular portion in an axial direction of the first annular portion; the second annular portion includes a second inner end face opposite the first annular portion in an axial direction of the second annular portion; The first inner end face is attached to and fitted to the second inner end face. The first annular portion is provided with a first mounting hole penetrating the first annular portion in an axial direction of the first annular portion; the second annular portion is provided with a second mounting hole penetrating the second annular portion in an axial direction of the second annular portion; The second mounting holes are disposed coaxially with each of the first mounting holes. the groove is disposed at the outer end of each first mounting hole and is in a direction away from the second annular portion; The groove is recessed in a direction toward the second annular portion. The wire groove is disposed on the outer end face of the second annular portion and is away from the first annular portion in the axial direction of the second annular portion; Each wire groove includes an opening in the axial direction of the second annular portion.

As can be seen from the above-mentioned technical solutions, the grooves are respectively disposed at the outer ends of the first mounting holes provided in the first annular portion of the first framework of the stator assembly of the motor, and are located away from the second annular portion. direction, and the groove is recessed toward the direction of the second annular portion. On the other hand, the wire groove is disposed on the outer end face of the second annular portion of the second framework, and is away from the first annular portion in the axial direction of the second annular portion, so that the axial thickness of the motor is greatly reduced, and the ultra-thin motor is achieve Therefore, the overall volume of the motor is small and its weight is light, so the thickness of the washing machine in the axial direction of the motor is greatly reduced, the overall size of the product is reduced, and the product is more competitive in the market.

1 is a partial cross-sectional view of a conventional washing machine.
FIG. 2 is an enlarged view of part “A” shown in FIG. 1 .
3 is a partial cross-sectional view of a washing machine according to an embodiment of the present application.
4 is a cross-sectional view of a motor of a washing machine in an embodiment of the present application.
5 is an exploded view of a stator assembly of a motor of a washing machine in an embodiment of the present application.
6 is a structural diagram of a stator assembly of a motor of a washing machine in an embodiment of the present application.
FIG. 7 is an enlarged view of part “B” shown in FIG. 6 .
The present application is described below with reference to the drawings and examples.

Yarae's embodiment aims at applying the motor of the present application to a washing machine, but is not limited to the washing machine. Other household appliances that require ultra-thin motors can also choose to use the motors of this application to reduce overall size.

Referring to FIGS. 3 and 4 , the washing machine 2 includes a water tank 21 , a drum (not shown) and a motor 22 . The drum is placed in the water bath (21). The motor 22 is disposed on the rear wall of the water tank 21. The water tank 21 is arranged fixedly, and the drum is arranged to rotate around the axis of the drum. The motor 22 includes a rotating shaft 222 , a rotor 224 , a mounting flange 221 and a stator assembly 226 . One end of the mounting flange 221 in its axial direction is provided with a plurality of fixed columns 2211 extending in the axial direction. The other end of the mounting flange 221 in the axial direction is connected to the water tank 21 . A through hole 2212 is disposed at an axial position of the mounting flange 221 and penetrates the mounting flange 221 , and a bearing 223 is provided inside the through hole 212 . The stator assembly 226 is mounted on the stationary column 2211. The rotor 224 fits outside the stator assembly 226. The rotating shaft 222 passes through the bearing 223, and the two ends of the rotating shaft 222 are connected to the drum and the rotor 224, respectively.

5 to 7 , the stator assembly 226 includes a first framework 227, a second framework 229, an iron core 228, and coil windings (not shown). The first framework 227 and the second framework 229 cover and fit two ends of the iron core 228 in the axial direction of the iron core 228, respectively. The iron core 228 includes an annular yoke portion 2281, a sawtooth portion 2282, and a boot portion 2283. Each tooth portion 2282 is disposed on the outer annular wall of the annular yoke portion 2281 and extends in the radial direction of the annular yoke portion 2281 . Each boot portion 2283 is connected to an end of a corresponding toothed portion 2282, away from the annular yoke portion 2281, and extending in the axial direction of the annular yoke portion 2281.

The first framework 227 includes a first annular portion 2271 , a first protruding pole 2274 , and a first position limiting plate 2275 . The first annular portion 2271 includes a first inner end face opposite to the second annular portion 2291 of the second framework 229 in the axial direction of the first annular portion 2271 . The first annular portion 2271 is provided with a plurality of first mounting holes 2272 communicating through the first annular portion 2271 in the axial direction of the first annular portion 2271 . The plurality of first mounting holes 2272 are coaxially arranged in each of the plurality of fixed columns 2211 . A groove 2273 is disposed at the outer end of each first mounting hole 2272, which is recessed toward the second annular portion 2291 of the second framework 229. Grooves 2273 each fit into each fixed column 2211. The bottom surface of each groove 2273, which is close to the first inner end surface of the first annular portion 2271, is adjacent to the top surface of the corresponding fixing column 2211. Each first protruding pawl 2274 is disposed on an outer annular wall of the first annular portion 2271 and extends in a radial direction of the first annular portion 2271 . Each first position limiting plate 2275 is connected to an end of a corresponding first protruding pole 2274, away from the first annular portion 2271, and extends in the axial direction of the first annular portion 2271. .

The second framework 229 includes a second annular portion 2291 , a second protruding pawl 2293 and a second position limiting plate 2295 . The second annular portion 2291 includes a second inner end surface opposing the first annular portion 2271 in the axial direction of the second annular portion 2291 . The plurality of second mounting holes 2292 are disposed in the second annular portion 2291 and pass through the second annular portion 2291 in the axial direction of the second annular portion 2291 . The plurality of second mounting holes 2292 are arranged coaxially with each of the plurality of first mounting holes 2272 . Each second protrusion pool 2293 is disposed on the outer annular wall of the second annular portion 2291 and extends in the radial direction of the second annular portion 2291 . Each second position limiting plate 2295 is connected to an end of a corresponding second protrusion pool 2293, away from the second annular portion 2291, and extends in the axial direction of the second annular portion 2291. .

The first annular portion 2271 and the second annular portion 2291 overlap the two ends of the annular yoke portion 2281 in the axial direction of the annular yoke portion 2281 , respectively. The first inner end face of the first annular portion 2271 is attached to and fits the second inner end face of the second annular portion 2291 . On the other hand, the first protruding pawl 2274 and the second protruding pawl 2293 respectively overlap and fit the two ends of each tooth portion 2282 in the axial direction of the annular yoke portion 2281 . The first position limiting plate 2275 and the second position limiting plate 2295 are each adjacent to the side of the boot portion 2283 adjacent to the annular yoke portion 2281, and the iron core 228 is the first framework 227 and the second framework 229 . In this embodiment, the bottom surface of each groove 2273 adjacent to the first inner end surface of the first annular portion 2271 is flush with the end surface of the iron core 228, and the second annular portion 2291 ) away from A groove 2273 is arranged through the outer annular wall of the first annular portion 2271 .

In this embodiment, the first mounting hole 2272 is disposed adjacent to the inner annular wall of the first annular portion 2271, and correspondingly, the second mounting hole 2292 is the inner annular portion of the second annular portion 2291. It is placed adjacent to the annular wall. In this embodiment, three sets of fixed columns are arranged side by side on the mounting flange 221 in its circumferential direction, and each set of fixed columns includes three fixed columns 2211. The circumferential distance between any two adjacent fixed columns in each set of fixed columns is equal. The number of first mounting holes 2272 is equal to the number of fixed columns 2211 , and the number of second mounting holes 2292 is equal to the number of fixed columns 2211 . The first mounting holes 2272 are coaxially arranged with each of the second mounting holes 2292 and each of the fixed columns 2211 . On the other hand, in the circumferential direction of the first annular portion 2271, the plurality of grooves 2273 corresponding to the plurality of first mounting holes 2272 communicate with each other.

The wire groove 2294 is disposed on the outer end face of the second annular portion 2291 and is away from the first annular portion 2271 in the axial direction of the second annular portion 2291 . Each wire groove 2294 includes an opening in the axial direction of the second annular portion 2291 . The coil winding is wound on the outer wall of the first protruding pole 2274 and the outer wall of the second protruding pole 2293. The wires of two adjacent coil windings may enter one wire groove 2294 through the corresponding open ends. The rotor 224 of the motor 22 is provided in the form of a U-shaped thin housing. The rotor 224 is fitted to the stator assembly 226. The rotor 224 includes a disk portion 2241 and an annular portion 2242. The disk unit 2241 is disposed outside the second framework 229 . The annular portion 2242 is fitted to the outside of the boot portion 2283 of the iron core 228. The plurality of permanent magnets 225 are evenly distributed on the inner wall of the annular portion 2242 in the circumferential direction of the annular portion. One end of the rotating shaft 222 is connected to the axis of the disk unit 2241.

The motor 22 of this embodiment has a simple structure and low manufacturing cost. The grooves 2273 are respectively disposed at outer ends of the first mounting holes 2272 provided in the first annular portion 2271 of the first framework 227, and the outer ends of the first mounting holes 2272 is in a direction away from the second annular portion 2291. Grooves 2273 fit into fixing columns 2211 of mounting flange 221, respectively. The bottom surface of each groove 2273, adjacent to the first inner end surface, is adjacent to the top surface of each stationary column 2211. On the other hand, the wire groove 2294 is disposed on the outer end surface of the second annular portion 2291 of the second framework 229, and the outer end surface of the second annular portion 2291 is the second annular portion 2291. away from the first annular portion 2271 in the axial direction of , and the axial thickness of the motor 22 is greatly reduced, realizing the ultra-thin motor 22. Therefore, the overall volume of the motor 22 is small and the weight is light. The motor 22 mentioned above is applied to the washing machine 2, greatly reducing the thickness of the washing machine 2 in the axial direction of the motor 22, reducing the overall size of the product, and making the product higher on the market. can make you competitive.

The above embodiments are only preferred embodiments of the present application, and are not intended to limit the implementation scope of the present application, so all equivalent variations or modifications made in accordance with the structure, features, and principles of the present application should be included within the scope of the present application. do.

Claims (12)

It includes a first framework 227 and a second framework 229,
the first framework 227 includes a first annular portion 2271; the second framework 229 includes a second annular portion 2291; the first annular portion 2271 includes a first inner end face opposite to the second annular portion 2291 in the axial direction of the first annular portion; the second annular portion 2291 includes a second inner end surface opposing the first annular portion 2271 in the axial direction of the second annular portion 2291; the first inner end face adheres to and mates with the second inner end face;
the first annular portion 2271 is provided with a first mounting hole 2272 penetrating the first annular portion 2271 in an axial direction of the first annular portion 2271; the second annular portion 2291 is provided with a second mounting hole 2292 penetrating the second annular portion 2291 in an axial direction of the second annular portion 2291; the second mounting holes 2292 are arranged coaxially with each of the first mounting holes 2272;
a groove 2273 is disposed at an outer end of each of the first mounting holes 2272, and is in a direction away from the second annular portion 2291; the groove 2273 is recessed in a direction toward the second annular portion 2291;
a wire groove 2294 is disposed on the outer end face of the second annular portion 2291, and is away from the first annular portion 2271 in the axial direction of the second annular portion 2291; Each of the wire grooves 2294 includes an opening in the axial direction of the second annular portion 2291. According to claim 1,
The first mounting hole 2272,
Stator assemblies each disposed proximate to the inner annular wall of the first annular portion 2271. According to claim 1 or 2,
The number of the first mounting holes 2272 is at least two;
the number of the second mounting holes 2292 is at least two;
The second mounting holes 2292 are arranged coaxially with the respective first mounting holes 2272, respectively. According to claim 3,
At least two grooves (2273) corresponding to the at least two first mounting holes (2272) communicate with the first annular portion (2271) in a circumferential direction. According to claim 1 or 2,
The groove 2273,
A stator assembly arranged through the outer annular wall of the first annular portion (2271). According to claim 1 or 2,
The stator assembly 226,
further comprising an iron core 228 including an annular yoke portion 2281;
the first annular portion 2271 and the second annular portion 2291 each overlap the two ends of the annular yoke portion 2281 in the axial direction;
The bottom face of each groove 2273 is close to the first inner end face and is flush with the end face of the iron core 228, and the end face of the iron core 228 is away from the second annular portion 2291. stator assembly. According to claim 6,
The iron core 228 further includes a toothed portion 2282,
the sawtooth portions are respectively disposed on the outer annular wall of the annular yoke portion 2281 and extend in the radial direction of the annular yoke portion 2281;
The first framework 227 further includes first protruding pawls 2274, the first protruding pawls are respectively disposed on the outer annular wall of the first annular portion 2271, and the first annular portion 2271 ) extends in the radial direction of;
The second framework 229 further includes second protruding pawls 2293, the second protruding pawls 2293 are respectively disposed on the outer annular wall of the second annular portion 2291, and the second annular pawl 2293 extends in the radial direction of portion 2291;
The first protruding pawl 2274 and the second protruding pawl 2293 cover and fit two ends of each of the toothed portions 2282 in the axial direction of the annular yoke portion 2281. According to claim 7,
The iron core 228 further includes boot portions 2283, each boot portion 2283 being connected to an end of a corresponding tooth portion 2282 and extending in the axial direction of the annular yoke portion 2281, ; The end of the corresponding tooth portion 2282 is away from the annular yoke portion 2281;
The first framework 227 further includes first position limiting plates 2275, and each of the first position limiting plates 2275 is connected to an end of a corresponding first protruding pawl 2274 and 1 extends in the axial direction of the annular portion 2271; an end of the corresponding first protruding pole is away from the first annular portion 2271;
The second framework 229 further includes second position limiting plates 2295, and each of the second position limiting plates 2295 is connected to an end of a corresponding second protruding pawl 2293, 2 extends in the axial direction of the annular portion 2291; an end of the corresponding second protruding pawl 2293 is away from the second annular portion 2291;
Each of the first position limiting plate 2275 and each of the second position limiting plate 2295 are adjacent to the side surface of the corresponding boot portion 2283, and the side surface of the corresponding boot portion 2283 is the annular shape. A stator assembly adjacent to the yoke portion 2281. a stator assembly 226 and a rotor 224;
The motor (22) wherein the stator assembly (226) is a stator assembly (226) according to claim 1 or 2. According to claim 9,
It further includes a mounting flange 221, one end of which is provided with a fixed column 2211;
The groove 2273 is fitted to each of the fixed columns 2211;
The first mounting hole 2272 is a motor 22 arranged coaxially with each fixed column 2211, respectively. According to claim 10,
further comprising a rotating shaft 222; The mounting flange 221 is provided with a through hole 2212; The rotating shaft 222 is rotatably inserted into the through hole 2212 about the axis of the rotating shaft 222, and one end of the rotating shaft 222 is connected to the rotor 224; The rotor 224 is a motor 22 that fits the stator assembly. including a motor 22;
The motor (22) is the motor (22) according to claim 9 washing machine.

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