KR20050087275A - Structure for stator of outer rotor-type motor for drum-type washing machine - Google Patents

Abstract

The present invention is a stator structure of a motor for a direct drum washing machine having a structure that can be stably mounted on a fixed side such as a tub or a bearing housing while reducing the weight of the material and the stator after manufacturing and simplifying the manufacturing process. In order to provide a, in particular in the winding operation of the spiral core constituting the stator to prevent the loosening in the opposite direction of rotation of the iron plate constituting the spiral core and the lifting between the iron plate and the iron plate to be laminated.

To this end, the present invention is an annular spiral core and a spiral core of a spiral structure stacked by rotating the iron plate consisting of a strip-shaped base portion and the teeth protruding from the base from the bottom layer to the top layer in a spiral manner. A phase insulator made of an electrically insulating material covering the upper side of the spiral core in a shape corresponding to the shape, and an electrical portion wrapping in the lower side of the spiral core when mutually assembled with the phase insulator in a shape corresponding to the shape of the spiral core. Made of insulating material; The iron plate forming the spiral core is provided with a molding means for preventing loosening in the opposite direction of rotation of the iron plate and lifting between the stacked iron plate and the iron plate when the iron plate is spirally rotated and stacked. Provide a stator structure.

Description

Stator structure of outer rotor type motor for drum washing machine {structure for stator of outer rotor-type motor for drum-type washing machine}

The present invention relates to a drum washing machine, and more particularly, to a stator structure of an outer rotor type BLDC motor applied to a direct drum washing machine.

In general, the drum washing method is a method in which the laundry is performed using the friction force of the rotating drum and the laundry by receiving the driving force of the motor while the detergent, the washing water, and the laundry are put in the drum. These don't get tangled with each other, and can be washed and pounded.

The conventional drum washing machine has an indirect connection method in which the driving force of the motor is indirectly transmitted to the drum through a belt wound around the motor pulley and the drum pulley, and the rotor of the BLDC motor is directly connected to the drum, depending on the driving method. It is divided into direct type that transmits driving force.

Here, the driving force of the motor is transmitted directly through the belt wound around the motor pulley and the drum pulley, instead of being directly transmitted to the drum, energy loss occurs in the driving force transmission process, and a lot of noise is generated in the power transmission process.

Therefore, in order to solve such problems of the conventional drum washing machine, the use of a direct drum washing machine using a BLDC motor is increasing.

Referring to Figure 1 briefly look at the structure of the conventional direct-type drum washing machine as follows.

1 is a vertical cross-sectional view illustrating a conventional drum washing machine, in which a tub 2 is installed inside a cabinet 1 and a drum 3 is rotatably installed in the center of the tub 2.

In addition, a motor is installed at the rear side of the tub (2). The stator (6) is fixed to the rear wall of the tub, and the rotor (5) is axially connected to the drum (3) through the tub while surrounding the stator (6). It is installed as possible.

In addition, between the tub rear wall and the stator is substantially the same shape as the outer shape of the rear wall portion of the tub (2) is fixed to the tub rear wall when the stator is fastened to support the load of the stator and the concentricity of the stator The metal tub supporter which keeps) is interposed.

Meanwhile, a door 21 is installed in front of the cabinet 1, and a gasket 22 is installed between the door 21 and the tub 2.

In addition, a hanging spring 23 for supporting the tub 2 is installed between the inside of the upper surface of the cabinet 1 and the upper side of the outer peripheral surface of the tub 2, and the inside of the lower surface of the cabinet 1 and the tub. (2) A friction damper 24 is provided between the lower side of the outer circumferential surface to damp the vibration of the tub 2 generated during dehydration.

On the other hand, Figure 2 is a perspective view of the stator appearance of Figure 1, Figure 3 is a perspective view showing a split core (DC) to be applied to the stator of Figure 2, the conventional stator core manufacturing method by pressing a metal iron plate teeth (151) And the base 150 and at the same side of the tooth 151 on the opposite side of the manufacturing unit cores having a protrusion 500 for forming the fastening hole (500a), and then laminated them to make an assembly, again in the circumferential direction The interconnects complete the stator cores, called split cores.

At this time, the protrusion provides a fastening hole 500a necessary for fastening the stator 6 to the rear wall of the tub and serves to withstand the fastening force of the bolt.

However, the manufacturing method of the stator 6 by such a split core DC is not only complicated in process but also causes a lot of material loss.

Therefore, in order to reduce the loss of materials and simplify the manufacturing process, a so-called spiral core that spirally rotates the iron plate composed of the teeth 151 and the base 150 is useful, but the spiral core (SC) is useful. Since the iron plate punched out in the form of a strip should be bent in a spiral shape when manufacturing the, there is a disadvantage in that it is impossible to form a protrusion for coupling the stator to the tub inside the core.

This is because, when the spiral core (SC) is manufactured, if the protrusion 500 is formed inside the core, the core width becomes too large at the portion where the protrusion exists, making it impossible to bend the core.

Therefore, there is a need for a stator structure to which the spiral core SC can be applied by performing the same role as the protrusion of the split core DC instead of performing the same role in the core itself.

For reference, it is important that the rigidity of the protrusion part having the fastening hole for fastening the stator to the tub side is sufficiently secured as follows.

In the washing machine that directly rotates the drum using a BLDC motor, the stator is directly mounted on the fixed side behind the tub. However, in a large drum washing machine motor having a stator weight of more than 1.5 kg and having a dewatering rotation speed of about 600 to 2,000 RPM, the stator is stably due to the stator weight, vibration during high-speed rotation, and shaking and deformation of the rotor 5. The fastening part of (6) is broken.

In particular, in the case of a drum washing machine which fastens the stator 6 to the tub rear wall while using a BLDC motor, since the radial direction of the stator 6 is substantially parallel to the ground, the stator 6 may be caused by vibration generated during the washing machine operation. ), Damage to the fastening portion with the rear wall of the tub is more severe.

Therefore, it is very important that the rigidity of the protrusion part having the fastening hole for fastening the stator 6 to the tub side should be sufficiently secured.

The present invention is to solve the above-mentioned problems, to reduce the material and weight required during manufacturing, manufacturing process is also simple, for a drum washing machine having a stator that can be stably mounted on a fixed side, such as a tub or bearing housing The purpose is to provide an outer rotor type motor.

In addition, the present invention can stably mount the stator on a fixed side such as a tub or a bearing housing while reducing the material as described above, while applying a split core, so that only the weight of the stator becomes 1.5 kg or more, and the rotation The aim is to provide a new stator structure suitable for BLDC motors for drum washing machines whose speed varies from 0 to 2,000 RPM or more.

In particular, the present invention is to provide a stator structure that can prevent unwinding in the opposite direction of rotation of the iron plate constituting the spiral core and lifting between the iron plate and the iron plate laminated during the winding operation of the spiral core constituting the stator have.

In order to achieve the above object, the present invention is an annular spiral core to form a multi-layer structure by spirally rotating the iron plate consisting of a strip-shaped base portion and the teeth protruding from the base portion from the lowermost layer to the uppermost layer And a phase insulator made of an electrically insulating material covering the upper side of the spiral core as a shape corresponding to the shape of the spiral core, and a shape corresponding to the shape of the spiral core. Consists of a lower insulator that is an electrical insulation material surrounding the lower side; The iron plate forming the spiral core is provided with a molding means for preventing loosening in the opposite direction of rotation of the iron plate and lifting between the stacked iron plate and the iron plate when the iron plate is spirally rotated and stacked. Provide a stator structure.

Here, the forming means is characterized by consisting of a forming projection protruding on the upper surface of the teeth of the iron plate, and the forming groove formed on the lower surface of the teeth of the iron plate to correspond to the forming projection when the iron plate is laminated.

In addition, integrally formed in the upper insulator and the lower insulator and includes a fastening portion protruding at least three places from the inside of the spiral core toward the center of the stator so as to fix the stator on the fixed side of the tub, the fastening portion of the tub The fixing side is characterized in that the fastening hole for fixing the stator to the fastening member is formed.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings, FIGS. 4 to 9.

First, an embodiment of the present invention will be described with reference to FIGS. 4 to 7.

Figure 4 is a perspective view of the stator appearance of the present invention, Figure 5 is an exploded perspective view of Figure 4, Figure 6 is a longitudinal sectional view of the main portion of the spiral core along the line II of Figure 5, Figure 7 is the top insulator of Figure 5 As a rear perspective view showing a part of the stator 6 of the outer rotor type motor according to an embodiment of the present invention, the belt-shaped base portion 150 and the teeth 151 protruding from the base portion 150. A spiral spiral core (SC) having a multi-layered structure formed by spirally rotating the constructed iron plate from the lowermost layer to the uppermost layer and an upper portion of the spiral core (SC) in a form corresponding to the shape of the spiral core (SC). The upper insulator 60a of the electrically insulating material surrounding the side and a shape corresponding to the shape of the spiral core SC, and the lower side of the spiral core SC when mutually assembled with the upper insulator 60a. Wrap around The lower insulator 60b is an electrical insulator, which is formed integrally with the upper insulator 60a and the lower insulator 60b, and has a spiral core (SC) to fix the stator 6 to the fixed side of the tub. It includes a fastening portion 600 protruding at least three places from the inside toward the center of the stator (6).

Here, the iron plate forming the spiral core (SC) to prevent the loosening (spring back phenomenon) in the opposite direction of rotation of the iron plate while laminating while rotating the iron plate in a spiral, while lifting between the iron plate and the iron plate to be laminated Forming means for preventing is provided.

At this time, the forming means is a mold formed on the lower surface of the teeth 151 of the iron plate to correspond to the forming projections 154a protruding on the upper surface of the teeth 151 of the iron plate and the forming projections 154a when the iron plates are stacked. It is made up of a groove 154b.

Meanwhile, a forming protrusion may be formed on the lower surface of the tooth 151 of the iron plate, and a forming groove may be formed on the upper surface of the tooth 151 of the iron plate.

In addition, the fastening part 600 (see FIG. 5) is provided with a fastening hole 620a (see FIG. 5) which is formed to fix the stator 6 as a fastening member on a fixed side such as a tub, and the fastening hole 620a. ) Is formed by the boss 620 protruding toward the non-exposed surface side of the fastening part 600.

In addition, a support rib 650 supporting the inner surface of the core is disposed along the circumferential direction on the inner side of the non-exposed surface which is in contact with the upper and lower surfaces of the spiral core SC of the upper insulator 60a and the lower insulator 60b, respectively. Is formed.

In addition, the fastening part 600 of the upper insulator 60a and the lower insulator 60b is connected to the boss 620 constituting the fastening hole 620a and the support rib 650 to be concentrated on the boss 620. At least one reinforcing rib 660 is provided to disperse the fastening force and reinforce the strength of the fastening part 600.

On the other hand, reinforcing ribs 670 are formed on the inner peripheral surface of each of the fastening parts 600 of the upper and lower insulators 60a and 60b in the non-exposed surface direction, and the inner ribs of the reinforcing ribs 670 and the core are supported. At least one connection rib 680 is also radially connected between the support ribs 650 to provide mutual support.

In addition, step surfaces 610a and 610b are formed on both sidewalls of each tooth 610 of the upper insulator 60a and the lower insulator 60b.

At this time, the stepped surfaces 610a and 610b formed on both side wall surfaces of the teeth 610 are formed to form a “b” shape when the other is “a” shape.

In addition, stepped surfaces 610a and 610b are formed on both end surfaces substantially orthogonal to both wall surfaces of the teeth 610 of the upper insulator 60a and the lower insulator 60b.

In addition, a seating surface 611a is formed at the ends of the teeth 610 of the upper insulator 60a and the lower insulator 60b on which a core shoe 151a of the spiral core SC is mounted.

In addition, a positioning protrusion (not shown) formed in a positioning groove or a positioning hole (not shown) formed on a fixed side such as a tub is formed around the fastening hole 620a formed in the fastening portion 600 of the merchant insulator 60a. 630 is formed.

In addition, the cylindrical sleeve (sleeve) 800 installed in the fastening hole 620a serves as a bushing as a spring pin having elasticity or a hollow pin that can be forced into the fastening hole 620a by the cut portion. do.

In addition, the base portion 150 of the spiral core SC is provided with a recessed groove 152 for reducing stress so that a winding operation for forming the core is easily performed. The spiral core SC has a base portion. Riveted by the rivet 153 penetrating the through-hole formed in the 150 is coupled.

In addition, the winding start portion and the winding end portion of the spiral core (SC) may be welded and joined to a predetermined portion of the base portion 150 in contact with each other.

8, the stator 6 of the present invention is integrally formed with the upper insulator 60a and the lower insulator 60b, and has a fastening part 600 protruding at least three places radially inward from the inner circumferential surface of the core. The length of each tooth 151 protruding from the outer surface of the spiral core (SC) is referred to as "a", the center of the fastening hole formed in the fastening portion 600 from the inner surface of the spiral core (SC) When the distance to "b" is called, the fastening part 600 is formed so that it may be defined as a≥b.

Meanwhile, reference numeral 8 in FIG. 5 denotes a hall sensor assembly for controlling a motor, and reference numeral 9 denotes a tap housing assembly for power connection for supplying power to the stator side.

The operation of the present invention configured as described above is as follows.

First, in the present invention, the core 15 constituting the stator is a so-called spiral core (SC; Spiral Core) which is laminated while rotating the iron plate composed of the teeth 151 and the base portion 150 in a spiral manner. Unlike in DC), the process of combining and welding the divided cores together is omitted, thereby simplifying the manufacturing process.

In addition, unlike the split core, the spiral core SC of the present invention does not have protrusions, thereby reducing material loss.

That is, the stator manufacturing method of the present invention is not only a simple process, but also can reduce the loss of material.

In addition, the teeth 151 of the iron plate forming the spiral core (SC) is provided with a forming means consisting of a fitting protrusion 154a and a fitting groove 154b, and is laminated while rotating the iron plate in a spiral manner. When manufacturing SC) to prevent loosening in the opposite direction of rotation of the iron plate and at the same time to prevent the lifting phenomenon between the iron plate and the iron plate to be laminated to make the core manufacturing process easy and accurate.

In addition, the stator 6 of the present invention improves the structure of the upper and lower insulators 60a and 60b so that the core itself does not form protrusions that can withstand the clamping force when fixing the stator 6 to the tub side. It does not have sufficient rigidity against the bolt fastening force.

That is, according to the present invention, a structure that performs the same role as the protrusion of the split core DC is placed on the fastening part 600 of the upper and lower insulators 60a and 60b so that the spiral core SC can be applied. (6) can be provided.

In addition, the space 640 between each of the ribs 650, 660, 670, and 680 provided on the non-exposed surface of the fastening part 600 performs buffering and attenuation for vibration generated when the motor is driven. Therefore, the mechanical reliability of the stator 6 is improved, and the space 640 also contributes to the material saving of the insulator.

On the other hand, the support ribs 650 formed along the circumferential direction inside the non-exposed surface which are in contact with the upper and lower surfaces of the spiral core SC of the upper insulator 60a and the lower insulator 60b, respectively, Support the inner side.

In addition, the reinforcing rib 660 formed at the fastening part 600 of the upper insulator 60a and the lower insulator 60b and connecting between the boss 620 and the support rib 650 forming the fastening hole 620a is In addition to dispersing the fastening force concentrated in the boss 620 serves to reinforce the strength of the fastening portion 600.

Therefore, the stator 6 of the present invention has the weight of only the stator of 1.5 kg or more, and even in a large-scale drum washing machine having a dehydration rotation speed of about 600 to 2,000 RPM, the vibration and the shaking and deformation of the rotor 5 at high speed rotation. The damage of the fastening portion of the stator 6 due to this is effectively prevented.

In addition, the positioning protrusions 630 formed around the fastening hole 620a of the fastening part 600 are joined to the positioning grooves (not shown) of the tub 2 to facilitate the fastening of the stator 6. do.

Therefore, the stator 6 according to the present invention has a positioning protrusion when it is coupled to the tub 2, so that it can be easily assembled, and thus the maintenance work of the serviceman can be made more easily even during after-sales service.

At this time, the positioning projection 630 is formed on the tub 2, the positioning groove may be formed in the fastening portion 600, of course.

9A and 9B are reference diagrams showing common use of the insulator, and the upper and lower insulators 60a and 60b of the present invention can be applied within a certain range even if the stack height of the spiral core SC is changed. .

That is, in the case of FIG. 9A, the stack height h1 of the core is a height at which the stepped surfaces 610a and 610b of the upper and lower insulators 60a and 60b are completely matched, and in the case of FIG. 9b. 9A is higher than that of FIG. 9A to show a case where the stepped surfaces 610a and 610b (see FIGS. 5 and 7) of the upper and lower insulators 60a and 60b are not fully joined and open.

In the case of FIG. 9B, the stack height h2 of the core is greater than the height at which the stepped surfaces 610a and 610b of the upper and lower insulators 60a and 60b are completely matched. Although it is to be opened, the insulation to the core tooth 151 is made so that it is applicable.

Accordingly, the vertically insulated insulator of the present invention can contribute to improving the workability in the assembly line by allowing it to be used universally regardless of the stack height of the core within a certain range.

Meanwhile, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made to various forms without departing from the scope of the technical idea of the present invention.

The effects of the present invention configured as described above are as follows.

First, the present invention can reduce the material and weight required for the stator production of the BLDC motor for the drum washing machine, while simplifying the manufacturing process, it can be stably mounted on a fixed side such as a tub.

In particular, while the present invention reduces the material of the stator core and the insulator, the stator can be stably mounted on a fixed side such as a tub or a bearing housing as in the case of applying a split core, so that the weight of the stator becomes 1.5 kg or more. It is more suitable for BLDC motors for drum washing machines whose rotation speed varies from 0 to 2,000 RPM or more.

In addition, the drum washing machine according to the present invention can be easily assembled when the stator is coupled to the tub in the assembly line, and thus the maintenance work can be more easily performed even during service.

In addition, in the drum washing machine of the present invention, it is easy to manufacture by adopting a spiral core (SC) having a structure that prevents loosening in the opposite direction of rotation during winding and lifting during stacking, and increases the rigidity of the fastening part of the stator to increase noise. By reducing the vibration and vibration can be improved mechanical reliability and life.

1 is a longitudinal sectional view schematically showing the structure of a conventional direct type washing machine;

2 is a perspective view showing a conventional stator structure

3 is a perspective view illustrating a split core of FIG. 2;

Figure 4 is a perspective view of the stator appearance of the present invention

5 is an exploded perspective view of FIG.

FIG. 6 is a longitudinal sectional view of the main portion of the spiral core along the line I-I of FIG. 5; FIG.

FIG. 7 is a rear perspective view of a portion of the upper insulator of FIG. 5. FIG.

8 is a top view of the stator main portion of FIG.

9 is a reference diagram showing the common use of the insulator

Explanation of symbols on main parts of drawing

6: Stator 60a: phase insulator

60b: high insulator 150: base

151: Teeth 152: Indentation groove

153: rivet 154a: shaped bumper

154b: mating groove 600: fastening part

SC: spiral core

Claims (20)

An annular spiral core which is formed by stacking a steel plate consisting of a strip-shaped base portion and teeth protruding from the base portion while rotating spirally from the bottom layer to the top layer to form a multilayer structure, A phase insulator made of an electrically insulating material covering the upper side of the spiral core in a form corresponding to the shape of the spiral core; A shape corresponding to the shape of the spiral core, wherein the spiral insulator is electrically insulated from the lower side of the spiral core when assembled with the phase insulator; The iron plate forming the spiral core is provided with a drum washing means for preventing the loosening in the opposite direction of rotation of the iron plate and lifting between the stacked iron plate and the iron plate when laminating the iron plate in a spiral rotation. Stator structure of the outer rotor type motor. The method of claim 1, The matching means, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that it consists of a forming projection protruding on the upper surface or the lower surface of the iron plate, and a forming groove formed on the lower surface or the upper surface of the iron plate so as to correspond to the forming projection when the iron plate is laminated. The method according to claim 1 or 2, The molding means is a stator structure of the outer rotor type motor for a drum washing machine, characterized in that formed on the teeth of the iron plate. The method of claim 1, The rotor washing machine is formed integrally with the upper insulator and the lower insulator, and has a fastening part protruding from the inside of the spiral core toward the center of the stator so as to fix the stator on the fixed side of the tub. Stator structure of the motor. The method of claim 4, wherein Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the fastening portion is formed on the fixing side of the tub for fastening the stator to the fastening member. The method of claim 5, The fastening hole of the fastening portion is a stator structure of the outer rotor type motor for a drum washing machine, characterized in that formed by a boss projecting to the non-exposed surface of the fastening portion. The method of claim 1, Inside the non-exposed surface which is in contact with the upper and lower surfaces of the spiral core of the upper insulator and the lower insulator, respectively. Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the support rib for supporting the inner surface of the spiral core is formed along the circumferential direction. The method of claim 7, wherein In the fastening portion of the upper insulator and the lower insulator, The stator structure of the outer rotor type motor for a drum washing machine, characterized in that at least one reinforcing rib is formed to connect the boss forming the fastening hole and the support rib to disperse the fastening force concentrated on the boss and to reinforce the strength of the fastening part. The method of claim 1, On both side walls of the teeth of the upper and lower insulators, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the stepped surface forming the same plane is formed as the upper and lower insulators are assembled together. The method of claim 9, The stepped surface formed on each side wall of each tooth, The stator structure of the outer rotor type motor for a drum washing machine, wherein the upper and lower insulators are formed such that the tooth side of the one side has a "b" shape, and the other has a "b" shape. The method of claim 1, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the stepped surface forming the same plane is formed on both end wall surfaces formed to be substantially orthogonal to both side wall surfaces of each of the upper insulator and the lower insulator. The method of claim 1, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the mounting surface on which the core shoe portion of the spiral core is projected is formed outside the both end wall surfaces of the upper and lower insulators. The method of claim 1, Around the fastening hole formed in the fastening portion of the merchant insulator, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the positioning projection formed in the positioning groove or the positioning hole formed on the fixed side of the tub or the like. The method of claim 1, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that a cylindrical sleeve (sleeve) is installed inside the fastening hole. The method of claim 14, The cylindrical sleeve, the stator structure of the outer rotor type motor for a drum washing machine, characterized in that the spring pin having elasticity by a portion cut along the longitudinal direction on the outer peripheral surface. The method of claim 14, The cylindrical sleeve is a stator structure of an outer rotor type motor for a drum washing machine, characterized in that the hollow pin is forcibly pressed into the fastening hole without having a cutout. The method of claim 1, Stator structure of the outer rotor type motor for a drum washing machine, characterized in that the base portion of the spiral core is formed with a recess groove to reduce the stress when the core is wound. The method of claim 1, The spiral core is stator structure of the outer rotor type motor for a drum washing machine, characterized in that the rivet is coupled by a rivet penetrating through the through-hole formed in the base portion. The method of claim 1, The winding start portion and the winding end portion of the spiral core are stator structure of the outer rotor type motor for a drum washing machine, characterized in that the welding is bonded to a predetermined portion of the base in contact with each other. The method of claim 1, When the length of the teeth protruding from the outer surface of the spiral core is "a", and the distance from the inner surface of the spiral core to the center of the fastening hole formed in the fastening portion is "b", a≥b is Stator structure of the outer rotor type motor for a drum washing machine.