KR101949359B1 - Apparatus for treating laundry - Google Patents

Abstract

According to the present invention, an apparatus for treating laundry includes: an inner tub for accommodating wash water and laundry inside; a pulsator rotatably provided about a predetermined central axis inside the inner tub; a driving unit allowing the plusator to be rotated; a blade rotatably provided about the central axis and provided to pump wash water; and an elasticity member connecting the blade to the pulsator to transfer rotatory force of the pulsator to the blade, transforming and restoring elasticity, and allowing the blade to be relatively rotated about the pulsator.

Description

Apparatus for treating laundry [0001]

The present invention relates to a laundry processing apparatus having a washing function.

Top Loading In general, a washing machine refers to a washing machine that puts laundry in and out of the inner tub. The most common form of top loading washing machine is a pulsator type washing machine. The pulsator-type washing machine is characterized in that the washing water flow generated by forcibly flowing the washing water by the mechanical force of the pulsator installed on the lower part of the inner tub in a state where the detergent, the washing water and the laundry are put in the inner tub, The laundry is washed by friction and emulsifying action of the detergent.

The washing machine includes an outer tub for receiving the washing water and an inner tub for receiving the laundry. Further, the washing machine includes a pulsator that forms various water streams inside the inner tub through forward and reverse rotation. A driving unit is provided to rotate the pulsator and the inner tub.

Conventionally, a washing machine, which is capable of easily washing laundry even with a small amount of water, by pumping washing water in the lower part of the inner tub through a circulation pump other than the driving part and spraying the laundry from the upper part of the inner tub Developed.

However, if the pump is provided separately from the driving unit, the cost of the pump is further increased, the manufacturing cost of the washing machine is increased, and the operation of the pump is further controlled.

The prior art (Korean Patent Laid-Open Publication No. 2013-0049094) discloses a washing machine including a water flow forming means provided at a lower portion of a pulsator to form a water flow jetted into the inner tub. The water flow forming means includes a centrifugal blade portion which forms a jetting pressure by centrifugal force by rotation. The centrifugal blade portion and the pulsator are rotated together.

Korean Patent Publication No. 2013-0049094 (Feb.

A first object of the present invention is to provide a structure for forming a water stream in addition to a pulsator, so that the detergent dissolving and spreading can be effectively performed while using a relatively small amount of water.

A second object of the present invention is to improve the washing performance by doubling the water hammer effect of washing water falling into laundry.

A third object of the present invention is to more effectively remove the lint in the wash water.

In the prior art, the centrifugal blade portion rotates integrally with the pulsator, so that the pumping performance is exhibited only when the pulsator is rotating, and the degree of pumping is instantaneously changed according to the rotational speed of the pulsator. Accordingly, in the prior art, there is a problem that the pulsator agitation and the pumping of the blade necessarily coincide with each other in time, and there is a problem that the performance of the washing performance is further limited. A fourth object of the present invention is to solve such a problem.

A fifth object of the present invention is to provide a product which solves the above problems with a minimum structure and which is remarkably improved in the washing performance against the manufacturing cost.

According to an aspect of the present invention, there is provided a laundry processing apparatus comprising: an inner tub for receiving washing water and laundry therein; A pulsator provided rotatably about a predetermined central axis in the inner tub; A driving unit for rotating the pulsator; A blade rotatably disposed about the central axis and pumped with wash water; And an elastic member connecting the pulsator and the blade to transmit rotational force of the pulsator to the blade, elastically deforming and elastically restoring the relative rotation of the blade with respect to the pulsator.

The elastic member may be provided such that the blade is elastically deformed in a relative rotation with respect to the pulsator in one direction, and the blade is elastically restored relative to the pulsator in a direction opposite to the one direction.

The elastic member may be elastically deformed by a load of washing water applied to the blade when the pulsator rotates.

The elastic member may be provided to store torsional elastic energy of the blade relative to the pulsator.

The laundry processing apparatus may further include: an outer tub for accommodating the inner tub; And a washing water circulating module for guiding and spraying the washing water pumped by the blade to the upper side of the inner tub. Wherein the driving unit includes: a washing shaft disposed through the outer tub, the inner tub, and the blade, the washing tub being rotated with the pulsator fixed; And a dewatering shaft disposed through the outer tub and rotating with the inner tub fixed.

Through the above-described solution, a more complex water flow can be formed by using the power of the conventional driving unit, so that the detergent dissolution, the spraying depth and the washing function can be improved. Furthermore, it is possible to provide an apparatus capable of performing lint filtering more effectively.

With the above-described solving means, there is an effect that the driving unit can rotate the pulsator separately from the pulsator to the pulsator by merely transmitting the rotational force to the pulsator.

With the above-mentioned solution, the pulsator, the blade and the inner tub can be separately rotated using only the double shaft structure of the washing shaft and the dewatering shaft.

The rotation force is transmitted to the blade by the elastic member, so that it is possible to obtain an effect of watering the laundry with rotation and time difference of the pulsator. Particularly, as the pumping performance of the blade is enhanced in the process of decelerating the rotation of the pulsator in either direction, the intensity pattern of the agitated washing performance by the pulsator and the intensity pattern of the washing performance by the blade are shifted in time, It is possible to exhibit continuous washing performance in terms of time.

The elastic deformation and the elastic restoration of the elastic member can further diversify the rotational motion of the blade.

And the elastic member is elastically deformed by the load of the washing water applied to the blade when the pulsator rotates. Accordingly, a new washing method in which the washing water is stirred after the pulsator stirs the laundry is easily achieved.

FIG. 1 is a side view of a laundry processing apparatus according to an embodiment of the present invention, and an arrow shown by a dotted line shows a flow direction of the washing water by the blade 150.
FIG. 2 is a perspective view illustrating a pulsator 140 and a circulation duct provided in the inner tub 120 of FIG.
FIG. 3 is an exploded perspective view of FIG. 2. FIG.
4 is a disassembled sectional view of the washing shaft 132, the blade 150, the elastic member 160 and the pulsator 140 of FIG. 2 cut vertically along the lines S1-S1 '.
5 is a perspective view of the engaging member 157 and the elastic member 160 of Fig.
6 is a partial cross-sectional view showing the blade 150, the elastic member 160, the bearing 171, and the bearing stopper 172 of FIG.
7 is a partial cross-sectional view showing the pulser 140 and wash shaft 132 further coupled to the assembly of FIG.

The terms 'upper' and 'lower', which are referred to below, are defined on the basis of the top loading laundry processing apparatus of FIG. 1, but are for the purpose of clarifying the present invention. It goes without saying that the directions can be defined differently depending on where the reference is placed.

Hereinafter, the 'center axis' refers to a straight line in which the rotation axis of the inner tub 120 is disposed. The 'centrifugal direction' mentioned below means a direction away from the central axis, and the 'centrifugal direction' means a direction approaching the central axis. In addition, 'circumferential direction' means a direction rotating about the central axis. The 'outer circumference' of a component means the 'centrifugal direction portion' of the component and the 'inner circumference' means the 'centrifugal opposite portion' of the component.

When viewed from the upper side to the lower side, either the clockwise direction or the counterclockwise direction is defined as a 'first direction' and the other is defined as a 'second direction'.

The use of terms such as "first, second, third, etc." in front of the constituent elements mentioned below is intended only to avoid confusion of the constituent elements referred to above, and is not limited to the order, importance, . For example, an invention including only the second component without the first component is also feasible.

The fact that the first component is 'fixed' to the second component, which will be mentioned below, means that not only when the first component is directly coupled to the second component, but also when the first component is coupled to the third component And the third component is coupled to the second component so that the relative position of the first component with respect to the second component is maintained.

Hereinafter, the first component rotates 'integrally with the second component' means that the first component rotates at the same rotational speed and the same rotational direction as the second component, In addition to the case where the component is coupled to and rotated together with the second component, the first component is coupled to the third component and the third component is coupled to the second component such that the first component is coupled to the second component And the case of rotating as shown in Fig.

As used herein, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

1 to 3, the laundry processing apparatus includes a cabinet 100 forming an external shape. The laundry processing apparatus includes an outer tub 110 for receiving wash water. The laundry processing apparatus includes an inner tub 120 for receiving wash water and laundry therein. The inner tub 120 is disposed inside the outer tub 110. The laundry processing apparatus includes a pulsator 140 rotatably installed in the inner tub 120. The pulsator (140) is disposed at a lower portion in the inner tub (120). The laundry processing apparatus includes a driving unit 130 that rotates the pulsator 140. The driving unit 130 can rotate the inner tub 120. [ The laundry processing apparatus includes a blade 150 rotatably provided. The blade 150 is provided to pump washing water. The laundry processing apparatus includes an elastic member 160 connecting the pulsator 140 and the blade 150 to transmit the rotating force of the pulsator 140 to the blade 150. The laundry processing apparatus may include a bearing 171 for rotating the blade 150. The laundry processing apparatus may include a bearing stopper 172 for guiding the position of the bearing 171.

The cabinet 100 forms the appearance of the laundry processing apparatus. The cabinet 100 includes a base cabinet forming a lower side surface, a side cabinet forming front, rear, left, and right side surfaces, and an upper surface having a laundry access hole so that laundry can enter and exit the laundry processing apparatus Includes top cover cabinets.

A door 101 is provided on the upper part of the cabinet 100 to allow laundry to be introduced or withdrawn from the top cover cabinet 100. The door 101 opens and closes the laundry access hole.

The outer tub 110 is disposed inside the cabinet 100. The outer tub 110 receives the inner tub 120 therein. The outer tub 110 may have a cylindrical shape whose upper side is opened. The outer tub 110 is suspended and supported by a suspension bar 111 inside the cabinet 100. The outer tub 110 stores the supplied wash water therein. The outer tub 110 is provided to dissolve and mix the supplied detergent into the washing water. A drain port is provided on the bottom surface of the outer tub 110.

The outer tub 110 includes a support member 115 fastened to the lower side of the outer tub 110. [ The support member 115 supports the driving unit 130. The stator 130b of the driving unit 130 is fixed to the supporting member 115. [ The dehydrating shafts 131 are arranged to pass through the center of the support member 115. The washing shaft 132 is disposed so as to pass through the center of the supporting member 115.

The support member 115 includes a first fixing part (not shown) fixed to the lower side of the outer tub 110. The first fixing part may be formed entirely of a circular plate.

The support member 115 includes a second fastening part (not shown) fastened to the lower side of the first fastening part. The second fixing part supports the driving part 130. And the stator 130b is fixed to the second fixed part. The second fixing part is formed in a cylindrical shape whose central portion is entirely recessed from the upper side to the lower side.

The inner tub 120 is rotatably installed inside the outer tub 110 to perform washing. The inner tub 120 receives power from the driving unit 130 and rotates. The inner tub 120 can selectively receive power from the driving unit 130 by intermittent operation of a clutch (not shown). The inner tub 120 may be fixed to the outer tub 110 at the time of washing and rinsing and may be provided to rotate relative to the outer tub 110 at the time of dewatering. The inner tub 120 includes a side wall portion 120a having a plurality of dewatering holes, a balancer 125 mounted on the upper portion of the side wall portion 120a, a base 121 coupled to a lower portion of the side wall portion 120a, And a hub 124 coupled to a lower portion of the base 121. The wash water stored in the outer tub 110 flows into the lower portion of the inner tub 120 through the laundry suction feeding hole 124a of the hub.

The inner tub 120 is fixed to the dewaxing shaft 131. The inner tub 120 is provided to rotate integrally with the dew condensation shaft 131. When the dehydrating shafts 131 are stopped, the inner tub 120 is also stopped. When the dehydrating shafts 131 are rotated, the inner tub 120 is also rotated integrally.

The inner tub 120 includes a side wall portion 120a that forms a side surface of the inner tub 120 in the centrifugal direction. The side wall portion 120a has a plurality of dewatering holes. The wash water in the outer tub 110 flows into the side wall part 120a through the plurality of dewatering holes.

The inner tub 120 includes a balancer 125 mounted on an upper portion of the side wall portion 120a. The balancer 125 may extend along the circumference of the side wall portion 120a.

The inner tub 120 may include a base 121 coupled to a lower portion of the side wall portion 120a. The base 121 is disposed below the inner tub 120 to form at least a part of the lower surface of the inner tub 120.

The base 121 forms the bottom surface of the inner tub 120. The upper portion of the base 121 is engaged with the lower end of the side wall portion 120a.

The base 121 is formed downward as a whole. The blade 150 is disposed in a space formed by being recessed downward of the base 121. The base 121 is recessed downward to form a space between the bottom surface of the base 121 and the lower surface of the pulsator 140. The blade 150 is disposed in a space between the bottom surface of the base 121 and the lower surface of the pulsator 140.

The base 121 forms step portions 121c and 121d at a lower portion thereof. The base 121 forms a first step 121c at the bottom. The base 121 forms a second step 121d at the bottom.

When the base 121 is viewed from the upper side to the lower side, the center portion (the portion near the central axis) forms the lowest phase side. The second step portion 121d and the first step portion 121c are sequentially arranged in the direction of the edge from the center portion of the base 121. [ The upper surface of the base 121 is raised by the second stepped portion 121d when the upper surface of the base 121 follows the upper surface of the base 121 in the centrifugal direction in the central portion of the base 121. [ The upper surface of the base 121 is raised by the first stepped portion 121c when the second stepped portion 121d of the base 121 follows the upper surface of the base 121 in the edge direction. The first stepped portion 121c is formed to extend in the circumferential direction. The second stepped portion 121d is formed to extend in the circumferential direction.

The base 121 has a round portion 121a formed at an upper portion thereof so as to be rounded downward. When the base 121 is viewed from the upper side to the lower side, the round portion 121a is disposed at the edge of the base 121. The round portion 121a is formed to extend in the circumferential direction. When the base 121 is viewed from the upper side to the lower side, the round portion 121a is inclined so that the height gradually decreases from the edge of the base 121 to the central axis direction. The edge of the round portion 121a is connected to the lower end of the side wall portion 120a.

The protrusion 121b is protruded upward in the round portion 121a. A plurality of semicircular protrusions 121b are spaced apart from one another in the circumferential direction.

The first stepped portion 121c is formed so as to surround the outer peripheral portion of the pulsator 140. The first step portion 121c includes a vertical surface formed to face the outer peripheral portion of the pulsator 140 vertically. The first stepped portion 121c is connected to the lower portion of the round portion 121a. The upper portion of the first stepped portion 121c is connected to the inner peripheral portion of the round portion 121a (distal end portion in the direction close to the rotation axis).

The second stepped portion 121d is formed so as to surround the outer periphery of the blade 150. The periphery of the second stepped portion 121d is disposed on the inner side of the pulsator 140 when viewed from the upper side to the lower side. The second stepped portion 121d includes a vertical surface formed to face the outer peripheral portion of the blade 150 vertically. The second stepped portion 121d is connected to the bottom surface of the base 121. The central portion of the base 121 forms the lowest surface. The lower portion of the second stepped portion 121d is connected to the outer peripheral portion of the central portion of the base 121. [

An opening is formed in the bottom surface of the base 121. The base 121 forms the opening at the center. Water may be introduced into the base 121 from the outside of the base 121 through the opening of the base 121.

The inner tub 120 includes a hub 124 coupled to the lower portion of the base 121. The hub 124 is disposed below the inner tub 120. The hub 124 forms at least a part of the lower surface of the inner tub 120. The hub 124 is formed of a circular member having a relatively thicker thickness than the side wall portion 120a and the base 121. [ The hub 124 receives the rotational force of the driving unit 130 and transmits the rotational force to the base 121 and the side wall 120a. The hub 124 may have a plurality of washable milk feed openings 124a. A plurality of the washing and feeding holes 124a may be disposed apart from each other in the circumferential direction. The washing water stored in the outer tub 110 may be introduced into the inner portion of the inner tub 120 through the washing and feeding holes of the hub 124. The washing and feeding nipple 124a may be formed in a fan shape.

The hub 124 is fixed to the dewaxing shaft 131. The hub 124 receives rotational force from the dewaxing shaft 131.

The hub 124 is fixed to the lower surface of the base 121. The hub 124 is disposed at a central portion of the base 121. The center hub of the hub 124 is provided with a central engaging portion 124b that engages with the dewaxing shaft 131. The central engaging portion 124b forms a hole penetrating in the vertical direction. And the upper portion of the dewaxing shaft 131 is fixed to the central engaging portion 124b. The washing shaft 132 is disposed so as to pass vertically through the hole of the central engaging portion 124b.

The washing water circulation modules 126, 127 and 128 guide the washing water pumped by the blade 150 to the upper side of the inner tub 120 and inject it. The washing water circulation modules 126, 127 and 128 may be provided in plural. In this embodiment, two wash water circulation modules 126, 127 and 128 are provided. The two wash water circulation modules 126, 127, 128 are arranged symmetrically about the central axis to face each other.

The washing water circulation modules 126, 127 and 128 are fixed to the inner tub 120. The washing water circulation modules 126, 127, and 128 rotate integrally with the inner tub 120.

The washing water circulating modules 126, 127 and 128 include a washing water inflow part 127 which is connected to the base 121 and into which the washing water flowing by the blades 150 flows. The washing water circulating modules 126, 127 and 128 are provided on the inner surface of the side wall part 120a and include a circulating duct 126 for guiding the washing water flowing into the washing water inflow part 127 to the upper end of the side wall part 120a ). The washing water circulation modules 126, 127 and 128 include a filter part 128 for spraying the washing water guided through the circulation duct 126.

The circulation duct 126 is connected to the inner tub 120 to circulate the wash water in the lower portion of the inner tub 120 to the upper portion of the inner tub 120, And provides a flow path 126a.

The circulating duct 126 may be mounted on the inner circumferential surface of the inner tub 120 in the form of a cover. The back surface of the circulating duct 126 may be opened and the side end of the circulating duct 126 may be formed to be bent. The circulating duct 126 can be fastened to the inner circumferential surface of the inner tub 120. A slit formed to be long in the vertical direction is formed on the inner circumferential surface of the side wall part 120a and the fastening protrusion of the circulating duct 126 can be inserted into the slit and fastened. A circulation flow path 126a capable of raising the washing water is formed in the circulation duct 126.

The washing water inflow part 127 is connected to the lower part of the circulating duct 126. The washing water inflow portion 127 is a passage for receiving the washing water discharged by the blade 150 and moving the washing water to the circulating duct 126.

The washing water inflow portion 127 is disposed at the lower outer side of the base 121. The washing water inflow section 127 includes an inflow port formed at the lower portion and an outflow port formed at the upper portion.

The inlet of the washing water inflow part 127 is connected to the space between the pulsator 140 and the base 121 through the communication hole 121h1 of the base 121. [ The inlet of the washing water inflow portion 127 is disposed to face the outer peripheral portion of the blade 150. The washing water pumped from the blade 150 flows into the washing water inflow part 127 through the inlet of the washing water inflow part 127 and the communication hole 121h1.

The upper portion of the washing water inflow portion 127 is coupled to the circulation duct 126 through the duct communication hole 121 h 1 of the base 121. The washing water in the washing water inflow part 127 moves into the circulating duct 126 through the outlet of the washing water inflow part 127 and the duct communication hole 121h2.

The filter portion 128 is disposed at the upper end of the side wall portion 120a. The filter unit 128 is installed at the upper end of the circulating duct 126. The filter unit 128 includes a filter housing 128a and a filter provided in the filter housing 128a. The filter may be disposed within the filter housing 128a. The filter filters foreign matter in the washing water passing through the washing water circulating modules 126, 127 and 128.

The lower side of the filter housing 128a is connected to the upper end of the circulating duct 126. One side of the filter housing 128a faces the inside of the side wall portion 120a. A jet port 128h is formed on one side of the filter housing 128a. The jet port 128h may have a narrow width in the vertical direction and a longer width in the horizontal direction. The washing water passing through the air outlet 128h is injected into the side wall portion 120a.

The driving unit 130 is provided at an outer lower portion of the outer tub 110. The driving unit 130 includes a motor that provides power for driving the pulsator 140 and the inner tub 120. [ The driving unit 130 includes a washing shaft 132 for transmitting rotational force of the motor to the pulsator 140. The driving unit 130 includes a dehydrating shaft 131 for transmitting the rotating force of the motor to the inner tub 120.

The driving unit 130 is supported by the outer tub 110. The driving unit 130 is supported by the supporting member 115 of the outer tub 110. [ The stator 130b is fixedly supported on the support member 115. [ The rotor 130a is fixedly supported on a washing shaft 132 on which the supporting member 115 is rotatably supported. The dehydrating shafts 131 support the support member 115 in a rotatable manner.

The motor of the driving unit 130 is disposed below the outer tub 110. The motor of the driving unit 130 includes a stator 130b fixed to the outer tub 110 and a rotor 130a rotating with respect to the stator 130b. The stator 130b is fixed to the outer tub 110 by the supporting member 115. [ The stator 130b is disposed inside the centrifugal direction of the rotor 130a. The outer peripheral portion of the stator 130b and the inner peripheral portion of the rotor 130a may be provided facing each other. The rotor 130a is rotated by electromagnetic interaction with the stator 130b.

The washing shaft 132 is located on the central axis. And the washing shaft 132 is fixed to the rotor 130a. The washing shaft 132 is rotated integrally with the rotor 130a. The pulsator 140 is fixed to the washing shaft 132 and rotated. The pulsator 140 is rotated integrally with the washing shaft 132. The washing shaft 132 is formed to extend in the vertical direction. The lower end of the washing shaft 132 is fixed to the rotor 130a. The upper end of the washing shaft 132 is fixed to the pulsator 140. The washing shaft 132 is coupled to the pulsator bushing 145 and rotated. The washing shaft 132 is disposed through the outer tub 110. The washing shaft 132 is arranged to pass through the inner tub 120. The washing shaft 132 is disposed through the blade 150. The washing shaft 132 may be disposed through the dew condensation shaft 131.

The dehydrating shafts 131 are located on the central axis. The dehydrating shafts 131 are rotatably provided. The dehydrating shafts 131 are provided so as to be changeable by the driving unit 130. The dehydrating shafts 131 are disposed apart from the rotor 130a. The lower end of the dew condensation shaft 131 is disposed above the rotor 130a. Depending on whether or not the clutch is interrupted, the dew condensation shaft 131 can rotate integrally with the rotor 130a. The inner tub 120 is fixed to the dehydrating shafts 131 and rotated. The inner tub 120 is rotated integrally with the dew condensation shaft 131. The dehydrating shafts 131 are formed extending in the vertical direction. The upper end of the dew condensation shaft 131 is fixed to the inner tub 120. The dehydrating shafts 131 are disposed around the circumference of the washing shaft 132. The dehydrating shafts 131 are coaxially rotatable with the washing shaft 132. The washing shaft 132 and the dewatering shaft 131 are provided in a double shaft structure. A bearing B is disposed between the descaling shaft 131 and the washing shaft 132. The dehydrating shafts 131 are disposed through the outer tub 110.

Referring to Figs. 3, 4 and 7, the pulsator 140 is provided in the lower part of the inner tub 120. Fig. The pulsator (140) is rotatably provided around a predetermined central axis. The pulsator (140) is provided to rotate by the rotation of the washing shaft (132). The pulsator (140) is provided so as to be rotatable relative to the inner tub (120). The pulsator (140) receives power from the driving unit (130). The pulsator 140 may be fixed to the upper portion of the washing shaft 132. The pulsator (140) receives rotational force from the washing shaft (132). The pulsator 140 can rotate in both forward and reverse directions. The pulsator 140 is used to scrub laundry to obtain an effect of being washed.

The pulsator 140 includes pulsator bodies 141, 142, and 143 which are provided to pressurize laundry and wash water. The laundry is agitated by the pulsator bodies 141, 142 and 143 to be washed. The pulsator bodies 141, 142, and 143 form an upper surface that looks inside the inner tub 120. The pulsator (140) is formed with a depressed concaved groove at the center of its lower side.

The pulsator body 141, 142, 143 includes a rotary plate 141 which forms a circular plate. The pulsator bodies 141, 142, and 143 include a plurality of protrusions 143 protruding upward from the upper surface of the rotating plate 141. The pulsator bodies 141, 142, and 143 include a central projection 142 protruding upward from the central portion of the rotary plate 141.

The pulsator 140 may form a plurality of through holes 141a. A plurality of through holes 141a are formed in the rotary plate 141. The through hole 141a allows the wash water to pass through the fluxer 140 in the vertical direction. The wash water can flow to the lower portion of the inner tub 120 through the through hole 141a.

The plurality of protruding portions 143 are formed to extend in the center protruding portion 142 in the centrifugal direction. The plurality of protrusions 143 are disposed apart from each other along the circumferential direction. The protruding portion 143 may be formed with a curved upper surface. The plurality of protruding portions 143 can rotate the washing water in the inner tub 120 in the forward and reverse directions to form a water stream.

The center protruding portion 142 may be formed as a separate member and fastened to a central portion of the rotary plate 141. The center protrusion 142 can be fastened to the center protrusion 142g provided at the center of the upper side of the rotary plate 141. The center protruding portion 142 may be formed so as to protrude further upward than the plurality of protruding portions 143.

The pulsator 140 includes a pulsator bushing 145 that is fixed to the pulsator body 141, 142, The pulsator bushing 145 is fastened to the lower central portion of the pulsator body 141, 142, 143. The pulsator bushing 145 can be fastened to the rotary plate 141. The upper portion 145b of the pulsator bushing 145 may be formed to protrude upward. The upper side portion 145b is inserted into the groove of the lower central portion of the pulsator body 141, 142,

The washing shaft 132 is fixed to the pulsator bushing 145. The pulsator bushing 145 is fastened to the washing shaft 132 and rotated. The rotational force of the washing shaft 132 is transmitted to the pulsator body 141, 142, 143 through the pulsator bushing 145. The upper end of the washing shaft 132 is inserted into the recess depressed upward from the lower side of the pulsator bushing 145. A serration is formed along the circumferential direction at the outer peripheral portion of the upper end of the washing shaft 132 and a wrinkle is formed in the inner peripheral portion of the pulsator bushing 145 to engage with the serration of the washing shaft 132 So that the rotational force of the washing shaft can be effectively transmitted to the pulsator bushing 145.

The pulsator (140) includes a pulsator engagement portion (145a) to which one end of the elastic member (160) is engaged. The pulsator engagement portion 145a is disposed below the pulsator 140. And the first end portion 161 is fixed to the pulsator engagement portion 145a. The pulsator fastening portion 145a can form a groove into which the first end portion 161 is inserted. The first end portion 161 may be formed in a hook shape and the first end portion 161 may be hooked to the pulsator engagement portion 145a.

The first end 161 of the elastic member 160 may be fixed to the pulsator bushing 145. [ The pulsator fastening portion 145a may be provided on the pulsator bushing 145. [ Thus, the pulsator bushing 145 directly connected to the washing shaft 132 can transmit the rotational force to the elastic member 160 directly.

The pulsator bushing 145 may include a circumferentially extending base portion 145d protruding in the centrifugal direction. The pulsator engagement portion 145a may be formed in the receiving portion 145d. The upper surface of the receiving portion 145d can contact the lower surface of the rotating plate 141. [ The receiving portion 145d can support the rotary plate 141. [ The receiving portion 145d protrudes in the centrifugal direction from the upper side portion 145b. The receiving portion 145d protrudes in the centrifugal direction from the lower portion 145c.

The pulsator bushing 145 includes an upper portion 145b projecting upward from the receiving portion 145d. The upper side portion 145b is inserted into the lower central groove of the rotary plate 141. [ The fastening member 148 penetrates the upper side of the upper side portion 145b up and down.

The pulsator bushing 145 includes a lower portion 145c protruding downward from the receiving portion 145d. The lower portion 145c is inserted into the inner peripheral portion of the bearing 171. [ The upper end of the washing shaft 132 is inserted into a groove formed in the lower side of the lower portion 145c. The groove into which the washing shaft 132 of the pulsator bushing 145 is inserted penetrates the inside of the lower portion 145c and extends to the inside of the upper portion 145b.

The pulsator 140 may include a fastening member 148 such as a screw for fastening the pulsator body 141, 142, 143 to the washing shaft 132. The fastening member 148 is vertically penetrated through the center of the rotary plate 141 and is fastened to the upper end of the washing shaft 132. At the upper end of the washing shaft 132, a groove into which the lower end of the fastening member 148 is inserted is formed. The fastening member 148 penetrates the upper center of the pulsator bushing 145 up and down. The fastening member 148 is disposed on the central axis. The rotary plate 141, the pulsator bushing 145 and the washing shaft 132 can be triple-fastened in the vertical direction by the fastening member 148.

Referring to Figs. 3 to 7, the blade 150 is provided in the lower part of the inner tub 120. Fig. The blade 150 is disposed below the pulsator 140. The blade 150 is disposed between the pulsator 140 and the hub 124.

The rotational force of the pulsator 140 is transmitted to the blade 150 by the elastic member 160. The blade 150 pressurizes the wash water. The blade 150 serves to lift the wash water to the upper portion of the inner tub 120 using a centrifugal force.

The blade 150 is rotatably provided about the central axis. That is, the virtual rotation axis of the blade 150 coincides with the virtual rotation axis of the pulsator 140.

The blade 150 does not rotate integrally with the pulsator 140. The blade 150 is provided so as to be rotatable relative to the pulsator 140. The blade 150 temporarily rotates the pulsator 140 at the same rotational direction and at the same rotational speed in accordance with the driving pattern of the washing shaft 132 and the water load (load of the washing water) At some point, however, the blade 150 is provided to rotate relative to the pulsator 140.

The blade includes blade bodies (151, 152) provided with pressurized wash water. The blade bodies 151 and 152 are formed in a circular shape when viewed from above. The central portions of the blade bodies 151 and 152 form holes that penetrate vertically. The washing shaft 132 is disposed so as to pass through the central portions of the blade bodies 151 and 152 up and down. And the engaging members 157 can be engaged with the blade bodies 151 and 152. The blade bushing 155 can be coupled to the blade bodies 151 and 152. [

The blade bodies 151 and 152 include a circular rotary plate 151. The rotary plate 151 may have a thickness up and down. A blade bushing 155 is coupled to the center of the rotary plate 151. And the engaging member 157 is engaged with the central portion of the rotary plate 151.

The blade bodies 151 and 152 include a plurality of pumping wings 152 protruding downward from the lower surface of the rotating plate 151. [ The pumping wing 152 is a part for rotating the washing water filled in the lower part of the rotating plate 151 and pumping it by centrifugal force. The pumping wing 152 may extend in the centrifugal direction. The plurality of pumping wings 152 may be spaced apart from each other in the circumferential direction. The plurality of pumping wings 152 may be arranged radially.

The blade 150 includes a blade bushing 155 that is fixed to the blade bodies 151 and 152. The blade bushing 155 is fastened to the center of the blade bodies 151 and 152. The blade bushing 155 can be inserted from the lower side to the upper side of the central portion of the rotary plate 151 and fastened. The upper protrusion 155a of the blade bushing 155 is inserted into the hole in the center of the blade bodies 151 and 152. [

The blade 150 is rotatably supported by the pulsator 140. The blade bushing 155 is rotatably supported by the pulsator bushing 145. The blade bushing 155 is rotatably supported by the pulsator bushing 145 by a bearing 171.

The blade bushing 155 is formed with a hole vertically passing through the center thereof. And the washing shaft 132 passes through the hole of the blade bushing 155. A bearing (171) is disposed in the inner periphery of the hole of the blade bushing (155). The inner peripheral portion of the blade bushing 155 faces at least a part of the outer peripheral portion of the pulsator bushing 145. The lower portion 145c of the pulsator bushing 145 is inserted into the hole of the blade bushing 155. [ The bearing 171 is disposed between the inner peripheral portion of the blade bushing 155 and the outer peripheral portion of the pulsator bushing 145. [

The blade bushing 155 may include a circumferentially extending support portion 155b projecting in the centrifugal direction. The upper surface of the support portion 155b can contact the lower surface of the rotary plate 151. [ The support portion 155b can support the rotary plate 151. [ The supporting portion 155b protrudes in the centrifugal direction from the upper protruding portion 155a. The supporting portion 155b protrudes in the centrifugal direction from the lower protruding portion 155c.

The blade bushing 155 includes an upper protruding portion 155a projecting upward from the support portion 155b. The upper projecting portion 155a is inserted into the center hole of the blade bodies 151 and 152. [ The lower portion 145c of the pulsator bushing 145 penetrates the upper side of the upper projection 155a up and down. The bearing 171 is inserted into the inner peripheral portion of the upper projecting portion 155a.

The blade bushing 155 includes a lower protruding portion 155c protruding obliquely from the support portion 155b. The center hole of the blade bushing 155 penetrates the lower protrusion 155c and the upper protrusion 155a up and down. The outer peripheral portion of the lower side projecting portion 155c can be arranged in the centrifugal direction with respect to the outer peripheral portion of the upper side projecting portion 155a. The inner peripheral portion of the lower projecting portion 155c may be located in the centrifugal direction than the inner peripheral portion of the upper projecting portion 155a.

The blade 150 includes a blade engaging portion 157a at which the other end of the elastic member 160 is engaged. The blade engaging portion 157a is disposed on the upper side of the blade 150. [ And the second end portion 162 is fixed to the blade engaging portion 157a. The blade catching portion 157a can form a projection to which the second end portion 162 is caught. The second end portion 162 may be formed in a hook shape and the second end portion 162 may be hooked to the blade engagement portion 157a.

The blade 150 includes a latching member 157 to which the second end 162 is fixed. The blade engaging portion 157a may be provided on the engaging member 157. [

The engaging member 157 is fixed to the blade bodies 151 and 152. The engaging member 157 rotates integrally with the blade bodies 151 and 152 and the blade bushing 155. [ The latching member 157 is made of a separate member and can be fastened to the blade bodies 151 and 152 or the blade bushing 155. The latching member 157 can be fastened to the upper end of the blade bushing 155. The engaging member 157 can be fastened to the upper end of the central portion of the rotary plate 151. The engaging member 157 is disposed at the center of the blade 150.

The engaging member 157 can function to guide the position of the elastic member 160. [ The engaging member 157 can receive the elastic member 160.

The engaging member 157 may include a base portion 157b that forms an upper side to guide the position of the lower side of the elastic member 160. [ The base portion 157b may be formed in a plate shape having an upper and a lower thickness. The base portion 157b may be formed in a ring shape. A center hole 157h is formed at the center of the base portion 157b so as to pass through the top and bottom. A part of the upper projecting portion 155a of the blade bushing 155 may be inserted into the center hole 157h of the engaging member 157. [ The lower surface of the base portion 157b can be in contact with the blade bushing 155. [ The lower surface of the base portion 157b can contact the rotating plate 151. [ The elastic member 160 is disposed above the base portion 157b.

The engaging member 157 may include a guide portion 157c that forms an inner peripheral surface to guide the position of the outer peripheral portion of the elastic member 160. [ The guide portion 157c may extend in the circumferential direction. A plurality of guide portions 157c may be disposed apart from each other along the circumferential direction. The guide portion 157c may protrude upward from the base portion 157b. The guide portion 157c can be disposed at the edge of the base portion 157b. The elastic member 160 is disposed in the direction opposite to the centrifugal direction of the guide portion 157c.

The blade engaging portion 157a may protrude upward from the base portion 157b. The blade engagement portion 157a may be disposed at the edge of the base portion 157b. The elastic member 160 is disposed in the direction opposite to the centrifugal direction of the blade engaging portion 157a. The blade engaging portion 157a may be disposed apart from the guide portion 157b. The blade engaging portion 157a may be formed in the same shape as the guide portion 157b.

For example, a plurality of protrusions having the same shape protruding upward from the edge of the base portion 157b may be formed. In the manufacturing process, any one of the plurality of protrusions becomes the blade catching portion 157a, (157b). The plurality of projections are disposed at the edge of the base portion 157b. The plurality of protrusions may each be formed in a rib shape extending in a circumferential direction. The plurality of projections may be spaced apart from one another along the circumferential direction.

3 to 7, the elastic member 160 connects the pulsator 140 and the blade 150 to transmit the rotational force of the pulsator 140 to the blade 150, and elastically deforms and elastically restores The blade 150 is rotated relative to the pulsator 140.

The elastic member 160 rotates the blade 150. The elastic member 160 can rotate the blade 150 by repeating the elastic deformation and the elastic restoration. When the pulsator 140 rotates agitating in the first direction and the second direction, the elastic member 160 can repeat the elastic deformation and the elastic restoration.

The elastic member 160 receives rotational force from the pulsator 140. When the rotational force is applied to the elastic member 160, the elastic member 160 can be subjected to torsional elastic deformation by the water load applied to the blade 150. [

The elastic member 160 is elastically deformed when the blade 150 elastically deforms relative to the pulsator 140 in one direction relative to the pulsator 140 and the blade 150 rotates relative to the pulsator 140 in the opposite direction It can be provided to restore elasticity.

For example, the elastic member 160 may be elastically deformable in a torsional manner only in the first direction. In this case, the elastic member 160 is provided to be elastically restored only in the second direction.

As another example, the elastic member 160 may be provided in a torsional elastic deformation manner in both the first direction and the second direction. When the elastic member 160 is torsionally elastically deformed in the first direction, the elastic member 160 is elastically restored in the second direction. When the elastic member 160 is elastically deformed in the second direction, the elastic member 160 is elastically restored in the first direction.

The elastic member 160 is provided to be able to store the torsional elastic energy of the pulsator 140 of the blade 150. The elastic member 160 is configured such that the blade 150 stores the torsional elastic energy in relative rotation with respect to the pulsator 140 in the first direction and the blade 150 discharges the torsional elastic energy, It is possible to accelerate the rotor 140 in the second direction.

The elastic member 160 may be elastically deformed by a load (water load) of washing water caught on the blade 150 when the pulsator 140 rotates. When the elastic member 160 elastically deforms to such an extent that the elastic member 160 hangs over the load applied to the blade 150, the elastic member 160 elastically restores and the blade 150 accelerates and rotates. Even when the pulsator 140 is decelerated or stopped, the elastic force of the elastic member 160 can pump the washing water while the blade 150 accelerates and rotates.

For example, when the pulsator 140 rotates in the first direction, the elastic member 160 is elastically deformed due to the water load of the blade 150 and is elastically deformed in the first direction of the pulsator 140 In the first direction. When the pulsator 140 continuously rotates in the first direction, the amount of elastic deformation of the elastic member 160 gradually increases, and the elastic force proportional to the amount of elastic deformation becomes equal to the number of loads of the blade 150. When the pulsator 140 continues to rotate in the first direction in a state where the elastic force of the elastic member 160 is equal to the number of loads of the blade 150, the blade 150 is rotated at the same rotational speed as the pulsator 140 Thereby rotating in one direction. The elastic force of the elastic member 160 is transmitted to the blade 150 and the elastic force of the elastic member 160 is transmitted to the blade 150. In this case, The blade 150 accelerates in the first direction. Thus, in a time period during which the pulsator 140 decelerates the rotation in the first direction, the washing water can be pumped by the blade 150 with a stronger force.

The elastic member 160 can be arranged to be wound around the central axis. The elastic member 160 may be disposed around a portion of the pulsator 140. The elastic member 160 may be disposed around the pulsator bushing 145. The elastic member 160 may be disposed in a first direction or a second direction from the first end 161 fixed to the pulsator 140 to the second end 162 fixed to the blade 150. In this embodiment, the elastic member 160 extends from the first end 161 to the second end in a first direction of rotation, in which case the blade 150 is positioned relative to the pulsator 140 in a first direction The elastic member 160 can be elastically deformed while being stretched.

For example, the elastic member 160 may be a spring-loaded spring or a torsion spring. In this embodiment, the elastic member 160 includes a spring 150 having both ends thereof engaged with the pulsator 140 and the blade 150, respectively.

The elastic member 160 is disposed between the pulsator 140 and the blade 150. The elastic member 160 is disposed at the outer periphery of the pulsator bushing 145. [ The elastic member 160 is disposed below the rotary plate 141. The elastic member 160 is disposed on the upper side of the rotary plate 151. The elastic member 160 is disposed between the base 157b and the rotary plate 141. [ The inner peripheral portion and the upper portion of the elastic member 160 may be covered by the pulsator 140. The outer peripheral portion and the lower side of the elastic member 160 may cover the blade 150.

The elastic member 160 includes a first end 161 fixed to the pulsator 140. The first end 161 may be formed by bending. The first end portion 161 is engaged with the pulsator engagement portion 145a.

The elastic member 160 includes a second end 162 that is fixed to the blade 150. The second end 162 may be formed by bending. And the second end portion 162 is engaged with the blade engagement portion 157a.

The resilient member 160 includes an extension portion 164 that extends and connects the first end 161 and the second end 162. [ The extension portion 164 is elastically deformable. The extension portion 164 can undergo elongate elastic deformation. When the second end 162 rotates in the first direction relative to the first end 161, the extension 164 is elastically deformed elastically. When the extension 164 is resiliently restored, the second end 162 rotates in a second direction relative to the first end.

The bearing 171 is disposed between the pulsator 140 and the blade 150. And the blade 150 is rotatably supported by the bearing 171. The bearing 171 is disposed between the pulsator bushing 145 and the blade bushing 155. The outer peripheral portion of the bearing 171 is coupled to the inner peripheral portion of the blade bushing 155. The inner peripheral portion of the bearing 171 is engaged with the outer peripheral portion of the pulsator bushing 145. The bearing 171 is formed in a ring shape as a whole, and the washing shaft 132 is disposed through the bearing 171.

The bearing 171 is seated on the bearing stopper 172. The bearing stopper 172 supports the lower portion of the bearing 171. The bearing stopper 172 can be disposed on the lower side of the bearing 171. The bearing stopper 172 may be formed in a ring shape. The washing shaft 132 is disposed through the bearing stopper 172. The bearing stopper 172 may be disposed within the blade bushing 155. The outer peripheral portion of the bearing stopper 172 can contact the inner peripheral portion of the blade bushing 155. The bearing stopper 172 may be disposed below the pulsator bushing 145. The bearing stopper 172 can contact the lower end of the pulsator bushing 145.

100: cabinet 101: door
110: outer tub 111: suspension bar
115: support member 120: inner tub
120a: Side wall part 121: Base
124: Hub 125: Balancer
130: driving part 130a: rotor
130b: stator 131: deformation shrinkage
132: washing shaft 140: pulsator
141, 142, 143: pulsator body 141: spindle
142: central protrusion 143: protrusion
145: pulsator bushing 145a: pulsator engagement portion
148: fastening member 150: blade
151, 152: blade body 151: spindle
152: pumping wing 155: blade bushing
157: engaging member 157a: blade engaging portion
157b: base portion 157c: guide portion
157h: center hole 160: elastic member
161: first end 162: second end
164: extension part 171: bearing
172: Bearing stopper B: Bearing

Claims (14)

An inner tub for receiving laundry water and laundry therein;
A pulsator provided rotatably about a predetermined central axis in the inner tub;
A driving unit for rotating the pulsator;
A blade rotatably disposed about the central axis and pumped with wash water; And
And an elastic member connecting the pulsator and the blade to transmit rotational force of the pulsator to the blade, elastically deforming and restoring the elasticity, and rotating the blade relative to the pulsator,
Wherein the driving unit includes a washing shaft to which the pulsator is fixed and rotates,
The elastic member
And arranged to be wound around the central axis,
Wherein both ends of the spring and the spring are engaged with the pulsator and the blade, respectively. The method according to claim 1,
The elastic member
Wherein the blade is resiliently deformed in a relative rotation with respect to the pulsator in one direction and the blade is elastically restored to the pulsator in a relative rotation in the opposite direction to the pulsator. The method according to claim 1,
The elastic member
And is elastically deformed by a load of washing water caught on the blade when the pulsator rotates. The method according to claim 1,
Wherein the elastic member is configured to store torsional elastic energy of the blade relative to the pulsator. delete The method according to claim 1,
The blade
A base portion forming an upper side surface to guide a position of a lower side of the elastic member; And
And a guiding part forming an inner circumferential surface to guide the position of the outer peripheral part of the elastic member.
delete The method according to claim 1,
The elastic member
A first end fixed to the pulsator;
A second end fixed to the blade; And
And an extension part connected to the first end part and the second end part and being elastically deformable. 9. The method of claim 8,
Wherein the pulsator is disposed below the pulsator, the first end is fixed and includes a pulsator engagement portion,
Wherein the blade includes a blade engaging portion disposed on an upper side of the blade and having the second end fixed thereto. 9. The method of claim 8,
The blade
A blade body provided to pressurize washing water; And
And a locking member fixed to the blade body and fixing the second end. 9. The method of claim 8,
The pearl-
A pulsator body provided to pressurize laundry and wash water; And
And a pulsator bushing fixed to the pulsator body and fixing the first end. 12. The method of claim 11,
The driving unit includes:
Wherein the pulsator bushing includes a washing shaft coupled to the pulsator bushing. 12. The method of claim 11,
The blade
A blade body provided to pressurize washing water; And
And a blade bush fixed to the blade body and forming an inner peripheral portion facing at least a part of an outer peripheral portion of the pulsator bushing,
And a bearing disposed between the pulsator bushing and the blade bushing. The method according to claim 1,
An outer tub for accommodating the inner tub therein; And
And a washing water circulating module for guiding the washing water pumped by the blade to the upper side of the inner tub and spraying the washing water,
Wherein the washing shaft is disposed through the outer tub, the inner tub, and the blade,
Wherein the driving unit comprises: a dehydrating shrinking unit disposed to penetrate through the outer tub and rotating with the inner tub fixed.

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