RU2327269C2 - Stator of the motor with outer rotor and the method of its production - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering and may by used in washing machines with a direct connection to the drum. The invention allows a lower consumption of materials and simplification of production process. The said motor features the stator design allowing its stable arrangement on the tank attachment side or on the bearing housing. To this effect, the stator incorporates a steel core produced by faggoting and coiling the steel plate. The stator has teeth and a basic element. The upper insulator is shaped as a spiral-like core and envelopes the upper part of the spiral core. The lower insulator has an identical form and envelopes the lower part of the spiral core in assembly with the upper insulator. The lower insulator is made from an insulating material. The connector is made from a steel plate forming a spiral core so as to prevent uncoiling the steel plate in direction opposite to that of the steel plate coiling in faggoting and coiling the steel plate and to prevent shifting of separate layers relative to each other in the steel plate package. There is cut is provided in the steel plate basic element to reduce strain in coiling the core.

EFFECT: materials savings and simpler production process.

35 cl, 12 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to an external rotor motor, and more particularly, to a stator structure of an external rotor motor used in a direct link drum washing machine.

BACKGROUND OF THE INVENTION

Basically, the drum washing method is a washing method in which washing is carried out using the frictional force between the rotating drum and the laundry, the drum rotating, sensing the driving force from the engine, when detergent, washing water and laundry are placed in the drum. The washing method in the drum prevents damage to the laundry and its tangling with each other when the friction washing effect is obtained.

Conventional washing machines with a drum are divided into units with indirect transmission of the engine driving force to the drum through the engine pulley and belt wrapped around the drum pulley, and units with a direct connection, transmitting the engine driving force directly to the drum by using a rotor of a brushless DC motor directly connected with a drum.

In this case, the method of transmitting the driving force of the engine to the drum not directly, but through the engine pulley and belt wrapped around the belt pulley, has the disadvantages of large energy losses and strong noise during the transmission of the driving force. Accordingly, to solve the problems associated with a conventional washing machine, the tendency to use a washing method with a drum with a direct connection is increasing.

Next, with reference to FIG. 1, a structure of a conventional direct coupled washing machine will be briefly described. Figure 1 shows a longitudinal section, which shows the design of a conventional washing machine with a drum, including a tank 2 located in the housing 1, and a drum 3, located in the center of the tank 2.

The engine is mounted on the rear side of the tank 2, the stator 6 is mounted on the rear wall of the tank, and the rotor 5 passes through the tank and covers the stator 6 so as to be axially connected to the drum 3 through the tank.

At the same time, there is a door 21 in front of the housing 1, and a gasket 22 is installed between the door 21 and the tank 2.

A suspension spring 23, designed to support the tank 2, is installed between the upper inner side of the housing 1 and the upper outer peripheral surface of the tank 2. The friction damper 24, designed to reduce the vibration of the tank 2 that occurs during the spin cycle, is made between the inner lower surface of the housing 1 and the lower outer peripheral surface of the tank 2.

At the same time, FIG. 2 is a perspective view illustrating an outside view of the stator of FIG. 1, and FIG. 3 is a perspective view of a composite core applied to the stator 2. A conventional method for manufacturing the stator core involves stamping a steel sheet for manufacturing a plurality of individual cores, each of which has a plurality of teeth 151 and a base element 150 on one side of each of the plurality of teeth 151, and a protrusion 500, made on the second side, opposite the side of each of the teeth 151, stacking separate rdechnikov for assembly and connection of the individual cores each other circumferentially for the assembly of the stator core, called the composite core.

In this case, the protrusion forms a connecting hole 500a, necessary for connecting the stator 6 with the rear wall of the tank, and playing the role of perceiving the connecting force of the bolt.

A method of manufacturing a stator 6 using a composite core (SC) is very complex and leads to excessive consumption of materials. Accordingly, in order to reduce the consumption of materials and simplify the production process, it is convenient to use the so-called spiral core, made by packing and spiraling a steel plate, including teeth and a base element. However, the drawback of the spiral core is the difficulty of obtaining a protrusion on it for connecting the stator to the inner part of the core, since a pack of steel plates, stamped in the shape of a chain, needs to be bent in the manufacture of the spiral core.

This is due to the fact that the core becomes too wide for bending, when a protrusion 500 is formed inside the core during the manufacture of a spiral core (HC).

Accordingly, in order to be able to use a spiral core (HC), an improved design stator is required that allows the same protrusion of the composite core to be performed in a different place, not on the core itself.

It should be noted that the reason why it is so important to give sufficient rigidity to the protrusion is that the protrusion has a connecting hole for connecting the stator to the side of the tank.

A washing machine that rotates the drum directly using a brushless DC motor includes a stator directly connected to the attachment side behind the tub. As for the engine for a high-power drum washing machine, an engine having a stator that weighs 1.5 kg and rotates at a maximum spin speed of 600-2000 rpm, damages the connecting part due to the weight of the stator, vibration during rotation engine with high speed and shaking rotor 5.

In particular, in the case of a drum washing machine using a brushless DC motor with a stator 6 connected to the rear wall of the tank, the connecting part of the stator 6 and the rear wall of the tank are more seriously damaged due to vibration that occurs during washing, since the directivity of the stator diameter 6 is basically parallel to the floor.

Accordingly, it is very important to give sufficient rigidity to the protrusion of the stator 6 having a connecting hole fastened to the sidewall of the tank.

At the same time, in the manufacture of a conventional composite core, there is a problem of material consumption and the complexity of the manufacturing process.

In other words, in the manufacture of a composite core (SC), the assembly is made by stamping a separate core from a separate steel plate and stacking them, after which the cores are connected around each other in a circle.

Accordingly, there is a waste of a large amount of materials, since after stamping the core a significant part of the steel plate remains, a large number of plates are used in the production of single cores and, in addition, the manufacturing process is complicated due to the protrusion 500, performed on the opposite side of the teeth 151.

Therefore, there is a need to create a stator core that can reduce material consumption and simplify the production process, but perform the same functions as a composite core.

SUMMARY OF THE INVENTION

Technical problem

The aim of the present invention is to provide an engine with an external rotor, which has a stator that can reduce material consumption and simplify the production process, and which can be stably placed on the mounting side, such as a tank or bearing housing.

Another objective of the present invention is to provide a stator of a new design, which allows the stator to be stably placed on the mounting side, such as a tank or bearing housing, similar to the application of a composite core so that a stator weighing at least 1.5 kg can be applied to a brushless washing DC motor machines with a drum having a rotational speed of more than 2000 rpm

TECHNICAL SOLUTION

To achieve these goals and other advantages, and according to the purpose of the invention, which is implemented and described in detail here, an engine stator with an external rotor is created, comprising a spiral core obtained by packaging and coiling of a steel plate, including teeth and a base element; an upper insulator having a shape corresponding to the shape of a spiral core, and covering the upper part of the spiral core, a lower insulator having a shape corresponding to the shape of a spiral core, and covering the lower part of the spiral core during mutual assembly with the upper insulator, and the lower insulator is made of electrical insulating material, connecting means made on a steel plate forming a spiral core (HC) in such a way as to prevent the deployment of the steel plate in systematic way opposite to coagulation of the steel plate when the steel plate is stacked and rolled up in a spiral, and in order to prevent shifting relative to each other of the individual layers in the package of the steel plate; and a cutout formed in a base member of a steel plate forming a spiral core (HC) in order to reduce stress during core rolling.

Additionally, an engine stator with an outer rotor of a washing machine with a drum was created, comprising: a spiral core with a multilayer structure obtained by packaging a steel plate having a base in the form of a tape and T-shaped teeth protruding from the base when rolling the steel plate into a spiral, starting from the bottom layer to the top layer; a top insulator of electrical insulating material covering the upper side of the spiral core in a form complementary to the shape of the spiral core; and a lower insulator of electrically insulating material covering the lower side of the spiral core when assembling with the upper insulator in a shape complementary to the shape of the spiral core, the steel plate forming the spiral core including a groove having a shape complementary to the spiral core on the upper or lower surface steel plate to prevent the deployment of the steel plate in a direction opposite to the direction of the spiral when applying steel plates by rolling steel plates in the direction of the spiral, and to prevent loosening of the package of steel plates, and a mounting portion having protrusions facing the mounting groove and pressed into the upper or lower surface of the steel plate, and the base of the spiral core includes an incision to reduce stresses in the rolling of the core.

In addition, a motor stator with an external rotor has been created, containing an annular spiral core with a multilayer structure, obtained by stacking a steel plate having a base in the form of a tape and T-shaped teeth protruding from the base when the steel plate is rolled into a spiral, starting from the bottom layer and to the top layer; a top insulator of electrical insulating material covering the upper side of the spiral core in a form complementary to the shape of the spiral core; and a lower insulator of electrically insulating material having a shape complementary to the shape of the spiral core in order to cover the lower side of the spiral core during assembly with the upper insulator, the spiral core comprising: a mounting pin on the upper and lower surfaces of each of the T-shaped teeth of the steel core plate and a hole complementary to the mounting pin, designed to prevent the deployment of the core from the steel plate in a direction opposite to the direction of rotation of the spiral whether, as well as the shift of the lower or upper layer of the core from the steel plate when packing the core from the steel plate when rolling the core from the steel plate into a spiral; an incision in the base between each of the adjacent T-shaped teeth of the core from the steel plate to reduce stresses in the coagulation of the core; and essentially the C-shaped end of each of the T-shaped teeth to reduce noise arising from the moment of the induction motor when it starts.

Additionally, a method has been created for the production of an engine stator with an external rotor, in which: they use an electrically conductive sheet, which is the base material; cut off the base material for the formation of two rows of cores from a steel plate having one pair of base parts in the form of a tape, opposite in width, and T-shaped teeth protruding alternately to the opposite base part; forming a multilayer annular spiral core by stacking the core from the steel plate while rolling the core from the steel plate into a spiral from the lower layer to the upper layer; and placing the spiral core in an insulator of electrically insulating material having a shape complementary to the spiral core.

Advantages of the Invention

The consumption and weight of the materials needed to make the stator of the brushless DC motor are reduced, the production process is simplified, and the stator is stably attached to the side of the mount, such as the tank of a washing machine with a drum.

The consumption of materials for the manufacture of a spiral core (HC) is reduced and the core manufacturing process is simplified.

In particular, the stator can be stably placed on the mounting side, such as a tank or bearing housing, as in the case of using a composite core, so that a stator weighing at least 1.5 kg is applicable to a washing machine engine with a drum with a speed of more than 2000 rpm min

If the present invention is used to manufacture a washing machine with a drum, the installation of a stator on a tank is facilitated, which facilitates the work of a specialist in maintenance and repair during further operation.

The present invention prevents the deployment of steel plates and prevents the formation of gaps between two adjacent layers of stacked steel plates.

The present invention helps to prevent the deployment of adjacent stacked steel plates, the formation of gaps between adjacent layers of stacked steel plates, and manufacture by using a spiral core to perform coagulation work to facilitate core formation, and increases mechanical reliability and strength by increasing the stiffness of the stator mounting portion to reduce noise and vibration.

The profile of the teeth of the spiral core (HC) is formed having an approximately C-shape in order to reduce the consumption of materials for the manufacture of the spiral core (HC) and effectively reduce noise and vibration.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included here to improve understanding of the invention and are part of this application, illustrate embodiments of the invention, and together with the description serve to explain the principle of the invention. In the drawings:

figure 1 is a longitudinal section schematically illustrating an example of the structure of a conventional washing machine with a drum;

figure 2 is a perspective view of the design of a standard stator;

figure 3 is a perspective view of the composite core of figure 2;

4 is a perspective view of the exterior of the stator according to the present invention;

5 is a perspective view of figure 4 with exploded parts;

Fig.6 is a one-level plan of section "A" of Fig.5;

Fig.7 is a longitudinal section of the main part of the spiral core, made along the line I-I of Fig.6, which is an illustration of the packetized state of the spiral core;

FIG. 8 is a rear perspective view of a portion of the upper insulator of FIG. 5;

Fig.9 is a one-level plan of the main part of the stator of Fig.4;

figure 10 and 11 is a reference view designed to describe the open application of the insulator; and

12 is an approximate diagram of a spiral core manufacturing process of FIG. 5.

BEST MODE FOR CARRYING OUT THE INVENTION

Next, preferred embodiments of the present invention will be described in detail, examples of which are illustrated in the accompanying drawings. If possible, the same reference numbers in the drawings will be used to refer to the same or similar parts.

Next, an embodiment of the present invention will be described with reference to FIGS. 4-12. Figure 4 illustrates a perspective view of the appearance of a stator according to the present invention. Figure 5 illustrates a perspective view of figure 4 with exploded parts. Figure 6 illustrates a single-level plan of section "A" of figure 5, and figure 7 illustrates a longitudinal section of the main part of the spiral core, made along the line I-I of figure 6, which is a diagram of the packetized state of the spiral core.

Meanwhile, Fig. 8 illustrates a rear perspective view of a portion of the upper insulator of Fig. 5, Fig. 9 illustrates a single-level plan of the main part of the stator of Fig. 4, Figs. 10 and 11 illustrate a reference view for describing the open use of the insulator. ; and FIG. 12 illustrates an approximate diagram of a spiral core manufacturing process of FIG. 5.

As shown in the drawings, the stator 6 of the outer rotor motor according to the first embodiment of the present invention includes a spiral core (HC) made in the form of a ring and with a multilayer structure obtained by packaging and coiling of a steel plate starting from the bottom layer and up to the uppermost layer, the upper insulator 60a, including an electrically insulating material and corresponding to the shape of the spiral core in order to cover the upper part of the spiral core (HC), lower the th insulator 60b, which is an electrical insulator and corresponding to the shape of the spiral core in order to cover the lower part of the spiral core (HC), and the connecting element 500 (see Fig.5), integrated into the upper and lower insulators 60a and 60b and protruding from at least three parts inside the spiral core (HC) to the center of the stator 6.

In this case, in the base member 150 of the steel plate forming the spiral core (HC), a cutout 152 is formed so as to reduce stress during core rolling. The cutout 152 has a maximum depth (H) in the central part 152a, which becomes smaller towards both ends of the base of the central part 152a, and is made in a multilateral form connected to the end of the base element 150.

On the steel plate forming the spiral core (NS), there is a connecting means designed to prevent the phenomenon of springing, i.e. in order to prevent the deployment of the steel plate in a direction opposite to the direction of folding of the steel plate when the steel plate is packaged and coiled in a spiral, and also to prevent the layers of the stacked steel plate from shifting relative to each other.

In this case, as shown in FIGS. 6 and 7, the connecting means includes a connecting protrusion 154a protruding from the upper surface of each of the plurality of teeth of the steel plate 151, and a connecting recess 154b formed on the lower surface of each of the teeth of the steel plate 151.

At the same time, in contrast to the shape mentioned above, the connecting protrusion can, of course, be made on the lower surface of the teeth 151 of the steel plate, and the connecting recess - on the upper surface of the teeth 151 of the steel plate.

As shown in FIG. 6, the end of the teeth 151 of the spiral core (HC) is C-shaped to reduce vibration and noise caused by the torque of the induction motor in the spiral core (HC).

In other words, the end of the teeth 151 of the spiral core (HC) is generally C-shaped by bevelling the corner portion 151c of each of its both ends based on the central portion 151b.

In this case, the corner portion 151c is mowed in a straight line, as shown, or, although not shown, in a curved line.

For reference, it should be noted that in this case there is a synchronous moment or reactive moment, which is generated by a change in magnetic resistance in the lumen between the rotor and the stator, and the lumen is formed due to a change in the position of the rotor during rotation of the rotor. The synchronous moment cannot be the actual beginning of the motor moment, and therefore it is desirable to reduce it.

The core 11 of a steel plate is stamped in two rows from a conductive steel plate 10, i.e. from one plate 10 of electrically conductive steel, so that an incision 150a is formed on the base member 150 opposite to the teeth 151, the shape of which corresponds to the shape of the end portion of the teeth 151.

At the same time, when stamping the core 11 of the steel plate in two rows on the teeth 151 of the core 11 of the steel plate, an ejector groove 151d is formed in order to smoothly separate the core 11 of the steel plate from the teeth 151, and thereby facilitate the separation of the core 11 of steel a plate stamped in two rows from a plate 10 of conductive steel.

In other words, when separating the core from the steel plate, the ejector comes into contact with the concavity for the ejector groove 151d, and exerts a compressive force to ensure separation of the core.

In the connecting member 600 (see FIG. 5), a connecting hole 620a (see FIG. 5) is formed to secure the stator to the attachment side, such as a tank, using the connecting means, and the connecting hole 620a is formed by the bulge 620 of the connecting element 600.

The supporting rib 650, designed to support the inner surface of the core, is made along the circumference of the supporting rib 650 from the inside to the closed surface, which comes into contact with the upper and lower surfaces of the spiral core (HC) between the upper and lower insulators 60a and 60b.

At the same time, on the inner circumference of the connecting element 600 of each of the upper and lower insulators 60a and 60b, an additional rib 670 is formed in the direction of the closed surface, and at least one connecting rib is inserted between the additional rib 670 and the supporting rib 650, which supports inside the core and creates a support force.

On both side walls of the teeth 610 of the upper and lower insulators 60a and 60b, which are combined during assembly, step surfaces 610a and 610b are formed.

In this case, if one of the stepped surfaces 610a and 610b on both side walls of each of the teeth 610 is shaped “┐”, then the other is shaped “└”.

The stepped surfaces 610a and 610b are also combined together on both end surfaces located at right angles to both side walls of each of the teeth 610 of the upper and lower insulators 60a and 60b.

At the end of each of the teeth 610 of the upper and lower insulators 60a and 60b, a loading surface 611a is stably located, with a shoe 151a of the core of the spiral core (HC) (see FIG. 5).

In addition, on the side of the tank mounting, a positioning protrusion 630 is made, or a positioning protrusion 630 in combination with a positioning hole (not shown) is made around a connecting hole 620a formed in the connecting element 600 of the upper insulator.

The sleeve 800 has a cylindrical shape, and a hollow pin is provided in the connecting hole 620a, which can be pressed into the connecting hole 620a, or a spring pin having elasticity due to the cut part and playing the role of the sleeve.

In the base element 150 of the spiral core (HC), a cutout 152 is made to reduce stress so as to facilitate coagulation when shaping the core, and the spiral core (HC) is riveted with a rivet 153 passing through a through hole made in the base element 150 and connected to him.

The starting clotting point and the ending clotting point of the spiral core are respectively welded to predetermined parts of the base member 150.

As shown in FIG. 9, the stator according to the present invention is inserted into the upper and lower insulators 60a and 60b and includes a connecting member 600 protruding inward in the radial direction from at least three places of the inner circular surface of the core. When the length of each of the teeth 151 extending from the outer surface of the spiral core (HC) is "a" and the distance from the inner surface of the spiral core (HC) to the center of the connecting hole made in the connecting element 600 is "b", the connecting element is formed such that a = b.

At the same time, reference numeral 8 in FIG. 5 denotes a hole sensor assembly for controlling the motor, and 9 denotes a tap housing assembly for connecting power to supply electric power to the stator.

Next, the operation of the present invention will be described. Firstly, according to the present invention, the so-called spiral core (HC) is used as the core 15 included in the stator, the spiral core being obtained by stacking and coiling the steel plate, which includes many teeth and the base element. Accordingly, unlike a composite core (SC), there is no process for assembling and welding composite cores, which simplifies the manufacturing process.

Unlike a composite core, the spiral core according to the present invention does not have a protrusion, which reduces material consumption. In other words, the stator manufacturing method of the present invention is simple and reduces material consumption.

The connecting means includes a connecting protrusion 154a and a connecting recess 154b, placed on each of the teeth 151 of the steel plate, which forms a spiral core (HC). Accordingly, when a spiral core is made by stacking and coiling a steel plate, the connecting means facilitates and increases the accuracy of core production by preventing springing, i.e. preventing the deployment of the steel plate in the opposite direction to the folding direction of the steel plate, and also preventing the layers of the stacked steel plate from shifting relative to each other.

In the base member 150 of the steel plate forming a spiral core (HC), a cutout 152 is made in a multilateral shape, designed to prevent the deployment of the steel plate in the opposite direction to the rolling direction of the steel plate by reducing the voltage when rolling the core, and also to facilitate coagulation of the steel plate.

At the same time, the change in magnetic resistance depending on the change in the position of the rotor and stator is reduced due to the fact that the end of the teeth 151 of the spiral core (HC) is C-shaped, and thus the synchronous moment of the spiral core (HC) is also reduced. Therefore, there is an effective reduction in vibration and noise that generate a synchronous moment.

According to the present invention, due to the fact that the core 11 of the steel plate is pressed in two rows from the plate 10 of conductive steel, two cores of steel plates are made of one steel plate during one stamping operation. Therefore, compared with the conventional method of manufacturing one steel plate from one steel sheet, the consumption of the steel sheet required for core production is sharply reduced, and the production process is noticeably simplified.

In addition, with the improved structure of the upper and lower insulators 60a and 60b, the stator 6 according to the present invention is strong enough to withstand the force of the bolted joint.

In other words, in the present invention, the connecting element 600 of the upper and lower insulators 60a and 60b is designed in the same way as the protrusion of the composite core (SC), and a stator 6 can be applied to which a spiral core (HC) is applicable.

The space 640 among the plurality of ribs 650, 660, 670 and 680, which is provided on the closed surface of the connecting element 600, is designed to absorb and reduce vibration that occurs when the engine is running, and thus increases the reliability of the stator mechanism 6, and also reduces the consumption of insulating material.

At the same time, there is a support rib 650 extending in a circumferential direction relative to the inner radial part of the closed surfaces of the upper and lower insulators 60a and 60b in contact with the top and bottom of the spiral core (HC), respectively designed to support the inner side of the core.

The supporting rib 660, made on the connecting element 600 of the upper and lower insulators 60a and 60b for coupling the protrusion 620 with the supporting rib 650, dissipates the connection force acting on the protrusion 620, and increases the strength of the connecting element 600.

Accordingly, the stator 6 according to the present invention can effectively prevent damage to the connecting part of the stator 6 in a washing machine with a high power drum, when the stator 6 weighs more than 1.5 kg and rotates in the spin mode at a speed of 600-2000 rpm.

The position-determining protrusion 630, which is formed around the connecting hole 620a of the connecting element 600, is connected to the connection-determining hole (not shown) of the tank in such a way as to help the stator 6 to be fixed.

When the stator 6 according to the present invention is attached to the tank 2, the stator 6 is more easily connected to the tank 2 due to the position-determining protrusion. Therefore, with subsequent servicing, maintenance and repair work is facilitated.

In this case, the position-determining protrusion 630 is formed on the tank 2, and the position-determining hole can be made on the connecting element 600.

At the same time, FIGS. 10 and 11 show a reference view illustrating the open use of the insulator, and the upper and lower insulators 60a and 60b according to the present invention can be used in a predetermined range even at a different height of the stacked spiral core (HC).

In other words, the height (h1) of the core in the case of FIG. 10 is the height at which the stepped surfaces 610a and 610b of the upper and lower insulators 60a and 60b are fully mated, and in the case of FIG. 11, the core height exceeds that shown in FIG. 10, and the stepped surfaces 610a and 610b of the upper and lower insulators 60a and 60b are not completely mated, but there is a gap between them.

In the case shown in FIG. 11, the height (h2) of the core exceeds the height of the upper and lower insulators 60a and 60b when the stepped surfaces 610a and 610b (see FIGS. 5 and 8) of the upper and lower insulators 60a and 60b are not fully mated between themselves, and there is a gap between them.

In the case shown in FIG. 11, the step surfaces 610a and 610b are separated by a gap, since the height (h2) of the stacked core exceeds its height when the step surfaces 610a and 610b of the upper and lower insulators 60a and 60b are completely interconnected. However, it is suitable for use, since the teeth of the core 151 are isolated.

Accordingly, regardless of the height of the core, the insulator, which is divided into the upper and lower parts, can be used for general purposes and thus the efficiency of the assembly line is increased.

Next, with reference to FIG. 12, a manufacturing process of a spiral core (HC) according to the present invention will be described. Positions (I), (II), (III) in FIG. 12 show the production process of the spiral core in order, and (I) in FIG. 12 indicates the position immediately after stamping of the plate 10 of the conductive steel is completed, before extrusion of the core 11 from the steel plate formed in two rows.

Position (II) in FIG. 12 shows a portion of a single core of a steel plate extruded from a sheet of conductive steel, and position (III) shows the shape of a separate rolled steel core [109].

It should be noted that the connecting protrusion 154a, the connecting recess 154b and the ejector groove 151d shown in Fig.6, Fig.12 are omitted in order to simplify the circuit.

As shown in FIG. 12, the manufacturing process of a spiral core (HC) according to the present invention includes a process of stamping opposing base elements 150 in the form of a strip in width, stamping in two rows of a separate core 11 of a steel plate from a plate 10 of conductive steel, so that many of the teeth 151 extending from the base element 150 intersect with each other, and the coagulation process to form a multilayer structure by spiraling a separate core 11 from a steel plate from the lowest layer to the uppermost layer, and a separate core of a steel plate went through a stamping process.

During stamping, two rows of a steel plate core 11 facing inwardly to each other are stamped and molded in two rows on one conductive steel plate 10 so as to form an incision 151s having the same shape as the end of each of the teeth 151 on the base element 150 on the opposite side of the teeth 151.

In this case, there is an ejector groove on each of the teeth 151 so that it is easy to separate the core 11 of the steel plate from the plate 10 of the electrical conductive steel, the cores of the steel plate being stamped when they are facing each other.

The core 11 of a steel plate connected to the other from the inside is stamped with a press (not shown) along the entire length of the plate of conductive steel, and cut after stamping into the lengths necessary for the manufacture of one spiral core (HC).

At the same time, as mentioned above, the core 11 of the steel plate, cut into pieces of the desired length, has a certain diameter, is automatically coiled [wound] and packaged by a winding device (not shown), so that the teeth 151 protrude outward, and so way gets the shape of a ring.

The rolled and packaged core 11 of the steel plate is riveted with a rivet 153, passed through a through hole made in the base element 150.

The core 11 of a steel plate riveted as described above is welded and adhered to the parts of the base member 150, each of which is adjacent to the initial part (not shown) and the final part so as to complete one spiral core (HC).

It should be noted that the finished spiral core (HC) is assembled together with the upper and lower insulators 60a and 60b (see drawings 60a and 60b), and the stator 6 (see figure 4) is completed when around the teeth 151 of the spiral core (HC) assembled with upper and lower insulators 60a and 60b, coil 142 will be wound.

Specialists in the art should be obvious the possibility of making the present invention of various modifications and changes without deviating from the essence or scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

INDUSTRIAL APPLICABILITY

When using the present invention, the loss of materials required for the production of the stator of the brushless DC motor is reduced, the production process is simplified, and the stator is firmly mounted on the attachment side, such as a washing machine tub with a drum.

In particular, the stator can be stably mounted on the mounting side, such as a tank or bearing housing, as in the case of using a composite core, so that it is possible to use a stator weighing at least 1.5 kg on a brushless DC motor of a washing machine with a drum with a frequency of rotation of more than 2000 rpm.

When applying the present invention to the manufacture of a washing machine with a drum, the installation of a stator on the tank is facilitated, so that subsequent servicing facilitates the maintenance and repair.

The present invention prevents the deployment of steel plates and prevents the formation of gaps between two adjacent layers of stacked steel plates.

The present invention facilitates the prevention of deployment of stacked steel plates and the formation of gaps between adjacent layers of stacked steel plates, and also facilitates the rolling work for forming a core during assembly for applying a spiral core, and also improves mechanical reliability and durability by increasing the stiffness of the stator mounting portion with The goal is to reduce noise and vibration.

The profile of the teeth of the spiral core (NS) is given a C-shape in order to reduce the consumption of material for the manufacture of the spiral core (NS) and effectively reduce noise and vibration.

The present invention has the advantage of reducing the consumption of materials for the manufacture of a spiral core (HC) and simplifying the manufacturing process of the core. Due to this, the present invention can find wide application in industry.

Claims (35)

1. The stator of the motor with an external rotor, containing: a spiral core obtained by stacking and spiraling a steel plate, including teeth and a base element; an upper insulator having a shape corresponding to the shape of the spiral core, and covering the upper part of the spiral core; a lower insulator having a shape corresponding to the shape of the spiral core, and covering the lower part of the spiral core during mutual assembly with the upper insulator, and the lower insulator is made of electrically insulating material; connecting means made on a steel plate forming a spiral core in such a way as to prevent the steel plate from expanding in a direction opposite to the direction of folding of the steel plate when the steel plate is wrapped and coiled in a spiral, and also to prevent individual shear relative to each other layers in a steel plate package; and a cut formed in the base member of a steel plate forming a spiral core in order to reduce stress during core rolling. 2. The stator according to claim 1, in which the connecting means includes a connecting protrusion extending from the upper or lower surface of the steel plate, and a connecting recess made on the lower or upper surface of the steel plate. 3. The stator according to claim 1, in which the connecting means is made on the teeth of a steel plate. 4. The stator according to claim 1, in which the upper and lower insulators are combined in the upper and lower insulators, and contains a connecting element protruding from the inside of the spiral core towards the center of the stator. 5. The stator according to claim 4, in which the connecting element contains a connecting hole that allows you to attach the stator to the fastening side of the tank using the connecting means. 6. The stator according to claim 5, in which the connecting hole is formed by the convexity of the connecting element, and the bulge protrudes in the direction of the closed surface. 7. The stator according to claim 1, in which there is a support rib extending in a circumferential direction to the inner radial part of the closed surfaces of the upper and lower insulators in contact with the top and bottom of the spiral core, respectively, designed to support the inner side of the core. 8. The stator according to claim 4, in which at least one supporting rib is made for the connecting part of the upper and lower insulators for connecting the bulge forming the connecting hole with the supporting rib, thereby distributing the connecting force concentrated on the bulge, and increasing rigidity of the connecting part. 9. The stator according to claim 1, in which on both side walls of the T-shaped teeth of the lower and upper insulators are made steps along which the lower and upper insulators are interconnected. 10. The stator according to claim 9, in which the steps are made on both side walls of the T-shaped teeth, and if one side of the T-shaped teeth of the lower and upper insulators is made in the form

the other side is shaped

11. The stator according to claim 9, in which both end sides of the side walls, made perpendicular to each other on both side walls of the T-shaped teeth of the lower and upper insulators, have a complementary shape, forming a step in one plane. 12. The stator according to claim 9, in which the protruding locking surface is made on the outer side of both end faces of the T-shaped teeth of the lower and upper insulators and is designed to fix the shoe of the core of the spiral core. 13. The stator according to claim 5, in which around the connecting hole made in the connecting part of the upper insulator, the position-determining protrusion is made, and the position-determining protrusion has an additional shape to the position-determining recess or hole made on the fixed side of the tank attachment. 14. The stator according to claim 5, in which a cylindrical sleeve is made inside the connecting hole. 15. The stator of claim 14, wherein the cylindrical sleeve is a spring pin having resilience due to a longitudinally cut portion of the outer circumferential surface. 16. The stator according to 14, in which the cylindrical sleeve, which does not have a cut-off part, has a hollow shape for installation with force in the connecting hole. 17. The stator according to claim 1, in which the spiral core is riveted with a rivet passing through a through hole made in the base. 18. The stator according to claim 1, in which the initial clotting point and the final clotting point of the spiral core are welded to predetermined parts of the base. 19. The stator according to claim 1, in which "a" is the length of the T-shaped teeth extending from the outer surface of the spiral core is equal to or greater than "b" is the distance between the inner surface of the spiral core and the center point of the connecting hole made in the connecting part , i.e. "A≥b". 20. The stator according to claim 1, in which the recess for the insertion of the core has a semi-cylindrical or oval shape. 21. The stator according to claim 20, in which the recess for the tab has a symmetrical design relative to its Central part, and the Central part of the recess for the tab is deeper than both sides of the recess for the tab. 22. The stator according to claim 20 or 21, in which the recess for the tab is made at the base of the spiral core and is located between the T-shaped teeth of the spiral core and the T-shaped teeth. 23. The stator according to claim 9, in which the end of the T-shaped teeth is C-shaped to reduce vibration and noise arising from the moment of the spiral core. 24. The stator according to claim 23, in which the edge part of the T-shaped teeth of the spiral core is C-shaped by beveling the corner parts at the ends of each side. 25. The stator according to paragraph 24, in which the mowing is performed in a straight line or along a curved line. 26. The stator according to claim 9, in which the core of the steel plate is formed by punching two lines on the conductive sheet, and an incision is formed on the base part facing the T-shaped teeth, the shape of which is identical to the edge part of the T-shaped teeth. 27. The stator according to claim 26, wherein an ejector groove is formed on the tooth of the core from the steel plate to facilitate the process of separating the core from the steel plate. 28. A motor stator with an outer rotor of a washing machine with a drum, comprising: a spiral core with a multilayer structure obtained by packaging a steel plate having a base in the form of a tape and T-shaped teeth protruding from the base when rolling the steel plate into a spiral, starting from the lower layer to the upper layer; a top insulator of electrical insulating material covering the upper side of the spiral core in a form complementary to the shape of the spiral core; and a lower insulator of electrically insulating material covering the lower side of the spiral core during assembly with the upper insulator in a form complementary to the shape of the spiral core; moreover, the steel plate forming the spiral core includes a groove having a shape complementary to the spiral core on the upper or lower surface of the steel plate to prevent the steel plate from expanding in a direction opposite to the direction of the spiral when applying steel plates by rolling the steel plates in the spiral direction , and to prevent loosening of the package of steel plates, and the mounting section having protrusions facing the mounting groove and pressed into the upper or lower steel plate surface, and the base of the spiral core includes an incision to reduce stresses in the coagulation of the core. 29. A motor stator with an external rotor, comprising: an annular spiral core with a multilayer structure, obtained by packaging a steel plate having a base in the form of a tape and T-shaped teeth protruding from the base when rolling the steel plate into a spiral, starting from the lower layer to the upper layer; a top insulator of electrical insulating material covering the upper side of the spiral core in a form complementary to the shape of the spiral core; and a lower insulator of electrically insulating material having a shape complementary to the shape of the spiral core in order to cover the lower side of the spiral core during assembly with the upper insulator, the spiral core comprising: a mounting pin on the upper and lower surfaces of each of the T-shaped teeth of the steel plate of the core and a hole complementary to the mounting pin designed to prevent the core from expanding from the steel plate in the direction opposite to the direction of rotation of the spiral, as well as the shift of the lower or upper layer of the core from the steel plate when packaging the core from a steel plate when rolling the core from a steel plate into a spiral; an incision in the base between each of the adjacent T-shaped teeth of the core from the steel plate to reduce stresses in the coagulation of the core; and essentially the C-shaped end of each of the T-shaped teeth, to reduce the noise arising from the moment of the induction motor when it starts. 30. A method of manufacturing a motor stator with an external rotor, wherein: using a conductive sheet, which is a base material; cut off the base material for the formation of two rows of cores from a steel plate having one pair of base parts in the form of a tape, opposite in width, and T-shaped teeth protruding alternately to the opposite base part; forming a multilayer annular spiral core by stacking the core from the steel plate while rolling the core from the steel plate into a spiral from the lower layer to the upper layer; and the spiral core is placed in an insulator of electrically insulating material having a shape complementary to the spiral core. 31. The method according to item 30, in which the base material is cut in two rows, so that in the base part opposite to one side of the T-shaped teeth, an incision is formed having a shape identical to the shape of the end of one side of the T-shaped teeth. 32. The method according to clause 30, in which the T-shaped teeth of the core of the steel plate have a concavity made in them for pushing, designed for smooth separation of the core from steel plates. 33. The method according to clause 30, in which the end of the T-shaped teeth of the core of the steel plate give a C-shape to significantly reduce vibration and noise arising from the moment of the spiral core. 34. The method according to clause 30, wherein when placing the spiral core, cover the upper side of the spiral core with an upper insulator of electrically insulating material having a shape that complements the shape of the upper part of the spiral core; and covering the lower side of the spiral core with a lower insulator of electrically insulating material having a shape complementary to that of the lower part of the spiral core. 35. The method according to clause 30, in which the base part of the core of the steel plate has a notch to reduce stresses that occur during coagulation of the core.

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