KR20080076056A - Drum type washing machine - Google Patents

Abstract

A frontload washer is provided to reduce a manufacturing cost of a motor by forming a coil with other materials but with copper. A frontload washer comprises a tub, a drum, a motor, and weight compensating members(250,260). The drum rotates in the tub. The motor has a stator composed of a stator core(210) and insulators(220,230), and a rotor, and rotates the drum. The insulators, assembled to the stator core, on which a coil which is not made of copper is wound. The rotor electromagnetically rotates with the stator. The weight compensating members are installed at the stator to compensate an unbalance generated when a material of the coil is changed.

Description

Drum Washing Machine {Drum Type Washing Machine}

1 is a cross-sectional view of a drum washing machine according to the present invention.

Figure 2 is an exploded perspective view of the motor stator mounted on the drum washing machine shown in FIG. And a perspective view of a weight compensation structure according to the first embodiment formed on the stator.

3 is a cross-sectional view of the weight compensation structure according to the first embodiment shown in FIG.

4 is a perspective view of a weight compensation structure according to a second embodiment installed in the stator shown in FIG.

5 is a perspective view of a weight compensation structure according to a third embodiment installed in the stator shown in FIG.

<Explanation of symbols for the main parts of the drawings>

120: Tub 130: Drum

140: motor 200: stator

210: stator core 220,230: insulator

250: pocket 260: weight compensator

270: fixed hook 280: ring shaped weight compensator

The present invention relates to a drum washing machine, and more particularly, to a drum washing machine that can easily solve the unbalance problem of the drum washing machine generated as the material of the coil wound on the stator is changed.

In general, the drum washing machine is a device for washing by using a friction force of the rotating drum and the laundry by receiving the driving force of the motor in a state in which detergent, washing water and laundry into the drum. Such a drum washing machine has an advantage that the laundry is hardly damaged and the laundry is not entangled with each other.

The 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 BLDC motor is directly connected to the tub so that the driving force of the motor is directly transmitted to the drum. It is divided into direct connection method.

A motor for driving a drum washing machine includes a stator and a rotor, which are rotated by electromagnetic interaction with the stator.

As such, the laundry inside the drum rotated by the motor is biased toward one side in the drum as the drum rotates, and the tub has a weight balancer to reduce the vibration generated by the bias of the laundry. The same vibration reducing devices are installed. Such vibration reducing devices are designed to minimize vibration in consideration of the weight of the tub, drum, and motor.

Meanwhile, a coil is wound around the stator, and as the current is applied to the coil, the rotor rotates with respect to the stator.

The stator is usually wound with a coil of copper material. This is because copper has excellent electrical conductivity and excellent ductility, so that damage to the stator during winding is small.

However, copper generally has a very high cost and accordingly, a manufacturing cost of the motor increases. In addition, the demand for copper is soaring internationally that the supply and demand of raw materials is not stable.

Therefore, efforts have been made to reduce manufacturing costs of motors by using coils other than copper coils.

However, a coil of a material other than copper is wound around the stator, and the weight of the motor is changed. As the weight of the motor is changed, vibration reduction devices such as a weight balancer installed in the tub must be redesigned.

However, since the vibration reduction devices have different design values depending on various variables, a problem that requires a lot of time and cost to design the vibration reduction devices so as to minimize vibration of the drum washing machine occurs.

The present invention has been made to solve the above problems, and provides a drum washing machine that can easily solve the unbalance problem of the drum washing machine, which may occur when the coil of a material other than copper is wound on the stator, without changing the design of other devices. do.

Drum washing machine according to the present invention for achieving the above object and tub; A drum rotating inside the tub; A stator having a stator core and an insulator coupled to the stator core to which coils other than copper are wound, and a rotor rotating electromagnetically with the stator; It includes a weight compensation structure installed in the stator to reduce the vibration generated in the drum due to the material change of the coil.

The weight compensation structure may include a plurality of pocket parts formed on the insulator, and a plurality of weight compensators mounted on the plurality of pocket parts.

In addition, each pocket part has a plurality of pocket holes into which the weight compensator is inserted and fixed.

In addition, a support protrusion may be formed inside the pocket hole to support the weight compensator so that the weight compensator is not separated.

The stator includes a plurality of fastening parts projecting to the center of the stator so as to be coupled to the rear surface of the tub, and each pocket part is formed between the fastening parts adjacent to each other.

The weight compensation structure may include a plurality of fixed hooks formed on the insulator, and a ring-shaped weight compensator fixed by the plurality of fixed hooks.

Alternatively, the weight compensation structure may be formed as a ring-shaped weight compensator having a boss portion formed at a position corresponding to the plurality of fastening portions formed on the stator.

In addition, the coil is preferably formed of an aluminum material.

Hereinafter, with reference to the accompanying drawings, a drum washing machine according to a preferred embodiment of the present invention will be described in detail.

1 is a cross-sectional view of a drum washing machine according to the present invention. The drum washing machine according to the present invention includes a case 110 forming an appearance, a tub 120 installed inside the case 110 to store wash water, and A drum 130 rotatably installed inside the tub 120 and a motor 140 for driving the drum 130 are provided.

An inlet 111 is formed on the front surface of the case 110 to inject laundry, and the inlet 111 is opened and closed by a door 112 installed to rotate in the case 110.

The upper portion of the tub 120 is supported on the upper portion of the case 110 by a hanging spring 121, the lower portion of the tub 120 is supported by the friction damper 122 to the high speed of the drum 130 The vibration generated in the drum washing machine during rotation is reduced. In addition, the front of the tub 120 is provided with a weight balancer 123 for reducing the vibration generated in the tub 120 during the high-speed rotation of the drum (130).

Such a hanging spring 121, friction damper 122, the weight balancer 123 is designed to reduce the vibration as possible in consideration of the weight of the tub 120, drum 130 and the motor 140, respectively After it is installed.

On the other hand, the inner circumferential surface of the drum 130 is provided with a lifter 131 for raising the laundry put into the drum 130 to a predetermined position, so that the washing water is discharged from the drum 130 in a washing operation such as dehydration. A plurality of through holes 132 are formed.

A water supply hose 140 and a water supply valve 141 installed on the water supply hose 140 to supply water from the external water source to the tub 120 in an upper side of the tub 120 are controlled. ), And a detergent supply device 142 to which detergent is input so that the water supplied through the water supply hose 140 is introduced into the tub 120 together with the detergent, and the laundry is disposed below the tub 120. And a drain hose 150 and a drain pump 151 may be installed to discharge the wash water used for rinsing to the outside.

The motor 140 mounted at the rear of the tub 120 is coupled to the drum 130 through the rotation shaft 160 to rotate the drum 130.

The motor 140 includes a stator 200 mounted on the rear surface of the tub 120, and a rotor 300 rotating by electromagnetic interaction with the stator 200.

2 is an exploded perspective view showing the stator 200 of the motor 140 installed in the drum washing machine according to the present invention.

The stator 200 again includes a stator core 210, an upper insulator 220, and a lower insulator 230.

The stator core 210 includes an annular base 211 and teeth 212 protruding radially outward along the outer circumference of the base 211. 2 illustrates an outer rotor type motor in which the rotor 300 is disposed outside the stator core 210 to rotate. However, on the contrary, the teeth 212 may protrude radially inward along the inner circumference of the base 211. In this case, the stator will be the stator of the inner rotor type motor.

The stator core 210 may be formed by punching a steel sheet, but is formed in a band-shaped base 211 and the base 211 as shown in FIG. The vertically protruding teeth 212 are bent while being spirally stacked to form a spiral core.

The caulking portion 213 is formed in the annular base 211 stacked in this manner so that each layer is integrally formed with each other.

A coil (not shown) is wound around the tooth 212 protruding radially outward of the base 211. However, since the teeth 212 are generally conductor materials, there are generally insulators 220 and 230 for insulation between the teeth 212 and the coil. In FIG. 2, the upper and lower insulators 220 and the lower insulator 230 are coupled to the upper and lower portions of the stator core 210, respectively, to form a stator. However, unlike one illustrated in FIG. It may be formed integrally with the stator core 210 by the method.

Winding parts 221 and 231 are formed in the upper insulator 220 and the lower insulator 230, respectively. When the upper insulator 220 and the lower insulator 230 are combined, one winding part is formed and the winding parts 221 and 231 are formed. The coil is wound.

On the other hand, the coil having one phase is wound around the winding portion 221 of the upper insulator 220 and the winding portion 231 of the lower insulator 230 is wound in one winding formed to prevent the upper insulator Coil winding ribs 222 are formed at 220.

In addition, an insulator rib 223 is formed in the circumferential direction of the coil winding rib 222 in the radially inner side. The insulator rib 223 is formed not only on the upper insulator 220 but also on the lower insulator 230. The insulator ribs 223 are formed at a predetermined height or more, so that moisture inside the insulators 220 and 230 is transferred to the winding parts 221 and 231. It blocks the flow.

Meanwhile, fastening portions 225 and 235 protruding in the radial direction are formed inside the insulator rib 223, and fastening holes for fastening the stator 200 to the rear surface of the tub 120 are provided in the fastening portions 225 and 235. (226,236) are formed.

The fastening hole 226 of the upper insulator 220 and the fastening hole 236 of the lower insulator 230 are combined to form one fastening hole, and a fastening member such as a bolt (not shown) is fastened to the single fastening hole. After passing through the hole, the stator 200 is mounted to the tub 120 by being fastened to a groove (not shown) formed at the rear surface of the tub 120.

In addition, in the vicinity of the fastening hole 226 of the upper insulator 220, a groove (not shown) and the fastening hole formed in the tub 120 or the like when the stator 200 is mounted on the rear surface of the tub 120. Positioning protrusions 227 may be formed such that the positions of 226 coincide with each other.

Meanwhile, the coils 221 and 231 of the stator 200 according to the present invention are wound with a coil of metal material which is cheaper than copper rather than a coil of copper material. Various materials may be used as the coils wound on the winding parts 221 and 231, but an aluminum coil may be used. This is because aluminum is inexpensive compared to copper, and electrical conductivity is not much behind that of copper.

However, since the specific gravity of copper is 8.92, while the specific gravity of aluminum is 2.7, when the coil is wound around the stator 200 with the same number of turns, the weight of the stator 200 having the aluminum coil is the stator 200 having the copper coil. It will be much lighter than its weight. As described above, the weight of the stator 200 having the aluminum coil becomes lighter than that of the stator having the conventional copper coil, so that the vibration is minimized in consideration of the weight of the motor 140. (122), the vibration reduction device such as the weight balancer 123 has to be designed again.

Drum washing machine according to the invention the motor 140 so that even if the material of the coil wound on the stator 200 is changed, the hanging spring 121, friction damper 122, the weight balancer 123, etc. do not have to be designed again. It has a weight compensation structure that can compensate for the weight change.

As shown in FIG. 2, the weight compensation structure according to the first embodiment of the present invention includes a plurality of pockets 250 formed in the insulators 220 and 230 and a plurality of pockets 250 mounted in the plurality of pockets 250. Weight compensators 260.

Each pocket part 250 is formed between the fastening parts 225 and 235 which are adjacent to each other. In the present exemplary embodiment, since six fastening parts 225 and 235 formed on the insulators 220 and 300 are formed, six pocket parts 250 are also formed. However, even when the fastening parts 225 and 235 are six, the pocket part 250 may not be formed in six but three or other numbers. When the three pocket portion 250 is formed, it is preferable that the distance between the pocket portions 250 is the same.

Each pocket part 250 includes a plurality of pocket holes 251 into which the weight compensator 260 is inserted and fixed.

The pocket part 250 may include a first rib 255 connecting the fastening parts 225 and 235 adjacent to each other, and a plurality of second radially extending from the first rib 255 in the radial direction of the insulators 220 and 230. Formed by ribs 256. When forming the plurality of pockets 250 as described above, it is preferable to be formed integrally with the insulators 220 and 230 using a method such as injection molding.

3 is a cross-sectional view taken along line I-I in the state in which the stator core 210 and the insulators 220 and 230 are coupled to each other in FIG. 2.

Meanwhile, as illustrated in FIG. 3, the weight compensator 260 is inserted into the pocket hole 251 in the inside of each pocket hole 251 by pressing the side of the weight compensator 260. By supporting, the support protrusion 252 is formed so that the weight compensator 260 does not fall out of the pocket hole 251. Therefore, the weight compensator 260 once inserted into the pocket hole 251 is not separated from the pocket hole 251 unless an artificial force is applied.

As described above, a plurality of pockets 250 are formed in the insulators 220 and 230, and the pockets 250 are inserted into and fitted with the weight compensator 260 to use an aluminum coil instead of a copper coil. Accordingly, the weight of the stator 200 can be compensated for. In this case, when the weight to be compensated by using an aluminum coil is divided by the weight of one weight compensator 260, the number of weight compensators 260 to be mounted in the pocket part 250 is calculated.

On the other hand, when the weight compensator 260 is mounted to each pocket portion 250, it is preferable that the position on which the weight compensator 260 is mounted is distributed to each other. For example, if six weight compensators 260 are fitted to compensate for the weight of the stator 200, one weight compensator 260 is mounted to each pocket part 250.

This is to prevent the problem that the weight compensator 260 is distributed to be installed so that the center of gravity of the stator 200 is directed to one side.

4 shows a weight compensation structure according to a second embodiment of the present invention.

As shown in FIG. 4, the weight compensation structure according to the second embodiment of the present invention includes a plurality of fixing hooks 270 formed on the insulators 220 and 230, and a ring shape fixed by the plurality of fixing hooks 270. The weight compensator 280 of the.

The plurality of fixing hooks 270 are formed inside the insulator rib 223 so that the ring-shaped weight compensator 280 is fixed to the stator 200.

Each of the fixing hooks 270 is installed to have a predetermined distance from the insulator rib 223, and the interval is such that the ring-shaped weight compensator 280 has the insulator rib 223 and the fixing hook 270. It is preferable that it is formed so that it may fit in between.

Meanwhile, the fixing hook 270 is formed of an elastic member so that the ring shaped weight compensator 280 can be easily fixed to the stator 200, and the insulator rib 223 and the fixing member are formed at an end thereof. The separation prevention jaw 271 is formed so that the ring-shaped weight compensator 280 fitted in the space between the hooks 270 is not separated.

In addition, the plurality of fixing hooks 270 may be formed to have a constant distance from each other in the circumferential direction so that the ring-shaped weight compensator 280 can be stably fixed to the stator 200. In addition, the plurality of fixed hooks 270 is preferably formed integrally with the insulators 220 and 230 in the same manner as injection molding.

5 shows a weight compensation structure according to a third embodiment of the present invention.

As shown in FIG. 5, the weight compensation structure according to the third embodiment of the present invention includes a plurality of bosses 291 formed at positions corresponding to the plurality of fastening parts 225 and 235 formed on the insulators 220 and 230. It is formed of a ring shaped weight compensator 290.

In addition, each of the bosses 291 has coupling holes 292 having the same size as that of the fastening holes 226 and 236 formed in the fastening parts 225 and 235 of the insulators 220 and 230.

As such, the boss portion 291 having a shape corresponding to the fastening portions 225 and 235 of the insulators 220 and 230 is formed in the ring-shaped weight compensator 290 so that the ring-shaped weight compensator 291 is formed on the insulators 220 and 230. ) And overlap the ring-shaped weight compensator 290 by allowing the fastening member such as a bolt to pass through the insulators 220 and 230 and the ring-shaped weight compensator 290 at the same time and to be fastened to the tub 120. It can be easily mounted on the stator 200.

The weight compensator described in various embodiments described above may be formed of various materials. For example, heavy metal materials, concrete or rubber materials are also possible.

As such, since the weight compensator can be easily mounted on the stator, it is possible to easily solve the unbalance problem of the drum washing machine, which may occur as the material of the coil wound on the stator is changed.

As described in detail above, according to the drum washing machine according to the present invention, by changing the coil wound on the stator to a coil of a material other than copper, it is possible to reduce the manufacturing cost of the motor used in the drum washing machine.

In addition, the unbalance problem of the drum washing machine, which may occur as the coil of a material other than copper is wound on the stator, may be easily solved without changing the design of other devices.

Claims (8)

Tub; A drum rotating inside the tub; A stator having a stator core and an insulator coupled to the stator core to which coils other than copper are wound, and a rotor rotating electromagnetically with the stator; And a weight compensating structure installed on the stator to compensate for the unbalance caused by the material change of the coil. The method of claim 1, And the weight compensating structure includes a plurality of pocket parts formed in the insulator, and a plurality of weight compensators mounted on the plurality of pocket parts. The method of claim 2, And each of the pockets includes a plurality of pocket holes into which the weight compensator is inserted and fixed. The method of claim 3, wherein And a support protrusion for supporting the weight compensator so that the weight compensator is not separated from the inside of the pocket hole. The method of claim 2, The stator has a plurality of fastening portions protruding toward the center of the stator for coupling to the back of the tub, wherein each pocket portion is formed between the adjacent fastening portion drum. The method of claim 1, The weight compensating structure includes a plurality of fixed hooks formed on the insulator, and a ring shaped weight compensator fixed by the plurality of fixed hooks. The method of claim 1, The stator has a plurality of fastening portions protruding toward the center of the stator for coupling to the back of the tub, the weight compensation structure has a ring shape having a boss portion formed at a position corresponding to the plurality of fastening portions formed on the stator Drum washing machine, characterized in that the weight compensator. The method of claim 1, The coil washing machine, characterized in that the coil is formed of an aluminum material.

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