JP2008055135A - Washing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve in drying performance of the laundly while minimizing washing/drying capacity and the amount of water used as much as possible, and minimizing a load on a motor for driving a pulsator. <P>SOLUTION: The washing machine has the pulsator 4 as a rotary body disposed at the bottom of a washing tub 5. The pulsator 4 has a base part 4a formed with a slant surface 4A having one lower end side of an upper face and the other higher end side facing the one end side and a vane part 4b raised on the slant surface 4A of the base part 4a and follow its slant direction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a washing machine, and more particularly to a pulsator type washing machine.

In general, washing machines are roughly classified into a drum type and a pulsator type. In the drum type, a drum (corresponding to a washing tub) having a horizontal rotating shaft is rotated, and the mechanical action and the chemical action by the detergent when the laundry falls in the drum by the rotation are used. In order to dehydrate the washed laundry, the drum is rotated and centrifugal force is used. Furthermore, drying of the laundry after dehydration rotates the drum while blowing warm air into the drum.
On the other hand, the pulsator method rotates a pulsator arranged at the bottom of a washing tub (or a washing and dewatering tub) and generates a “circulating water flow” by the rotation, thereby causing mechanical action such as friction or vibration. Dirt is removed by chemical action with detergents. In addition, for washing the laundry that has been washed, the washing tub is rotated and centrifugal force is utilized. Further, the laundry after dehydration is dried by blowing warm air into the washing tub while rotating the pulsator to stir the laundry.

A pulsator that performs the above-described action greatly affects its drying performance. Therefore, conventionally, attempts have been made to improve the drying performance by forming the upper surface of the pulsator on a slope and thereby moving the laundry up and down (for example, Patent Documents 1 and 2).
Japanese Patent Laying-Open No. 2005-81102 (FIGS. 2, 6, etc.) Japanese Utility Model Publication No. 56-44676 (FIGS. 2 and 3)

  However, in the conventional pulsator structure, when an inclined surface for moving the laundry up and down is secured, there is a problem in that the volume of the pulsator itself increases, and the washing / drying capacity is reduced and the amount of water that can be used is reduced. In addition, there is a problem that the load on the motor that drives the pulsator becomes large.

  The present invention has been made in view of the above problems, and it is possible to dry laundry while minimizing a decrease in washing / drying capacity and the amount of water that can be used and reducing an increase in load of a motor that drives the pulsator as much as possible. The purpose is to propose a pulsator-type washing machine capable of improving performance.

The washing machine according to the present invention is a washing machine in which a pulsator that is a rotating body is arranged at the bottom of a washing tub, wherein the pulsator has a lower end on the upper surface and the other end on the upper surface facing the lower side. It has a base portion whose surface is formed into an inclined surface by increasing the height, and a wing portion standing on the inclined surface of the base portion and extending along the inclination direction of the inclined surface.
In addition, because of the shape of such a pulsator, it is preferable that a measure for balancing the pulsator is taken.

In the washing machine of the present invention, the upper surface of the pulsator is inclined by the two-stage configuration of the base portion having the inclined surface and the wing portion protruding from the inclined surface, so that the washing volume can be maintained while keeping the volume of the pulsator small. A sufficient inclined surface can be secured to move the object up and down. As a result, it is possible to improve the drying performance of the laundry while decreasing the washing / drying capacity and the amount of water that can be used as much as possible and also reducing the load of the motor that drives the pulsator as much as possible.
In addition, since the pulsator is treated to balance the pulsator when it is rotated, the rotation is smoothly performed regardless of the shape of the pulsator.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, in the figure, since each structural member is shown typically, the dimension is not exact. In particular, for members formed of thin plates, the thickness is exaggerated for clarity. Moreover, the same code | symbol is attached | subjected to the same part in each figure, and the overlapping description is abbreviate | omitted.

  FIG. 1 is a side sectional view of a washing machine according to an embodiment of the present invention. This washing machine performs a series of washing processes, a rinsing process, a dehydrating process, and a drying process. The washing process and the rinsing process may be collectively referred to as a “washing process”.

(Casing)
The casing 1 has a cylindrical shape with a rectangular cross section (same as a substantially rectangular parallelepiped), and a top cover 10 is installed on the top surface. The top cover 10 is formed with a top surface opening connected to the front surface (the left side surface in FIG. 1), a front surface opening is formed near the top surface of the front surface, and the top surface opening is connected to the front surface opening. The section serves as an inlet for taking in and out the laundry. A transparent outer lid 9 is installed at the inlet so as to be freely opened and closed. Moreover, the corner | angular part where each surface of the housing | casing 1 and the top cover 10 cross | intersects is formed in circular arc shape.
Further, the casing 1 is provided with an upper end portion of the hanging rod 3 near the upper end portion of the four corners, and a horizontal table 19 and a tilting table 20 are installed at the lower end portion of the hanging rod 3. The horizontal table 19 is provided with a tilting fulcrum 20a that rotatably supports the tilting table 20 near the front surface thereof. For the sake of convenience, the rotation of the tilting table 20 is referred to as “tilting” in order to distinguish it from the rotation of the washing tub 5.

(Aquarium)
A water tank 2 is accommodated in the housing 1. The water tank 2 has a cylindrical shape with the top surface opened and the bottom surface closed, and is fixed to the tilting table 20. On the upper end surface of the water tank 2 (same as the periphery of the top surface opening), a water tank cover 7 whose inside is an opening is installed. In addition, an inner lid 8 that closes or opens an opening of the water tank cover 7 is tiltably installed in the water tank cover 7. In this example, an inner lid 8 is disposed below the outer lid 9.

The opening / closing operation of the outer lid 9 is transmitted to the inner lid 8 by an interlocking mechanism (not shown). When the outer lid 9 is opened, the inner lid 8 is also opened, and when the outer lid 9 is closed, the inner lid 8 is also closed.
Furthermore, a lid locking mechanism (not shown) is provided for locking the outer lid 9 (or the inner lid 8) so that it cannot be opened. Such a lid locking mechanism may be mechanically performed using an electromagnetic pin that moves forward and backward, or when the outer lid 9 (or inner lid 8) is opened and closed by an electric lid opening / closing drive mechanism. The opening / closing drive mechanism may not be electrically driven.

(Laundry tub)
Since the washing tub 5 is used for washing, rinsing, dehydrating and drying of the inputted laundry, it is also called a washing / dehydrating tub or a washing / dehydrating / drying tub. The washing tub 5 is rotatably arranged in the water tub 2. That is, since the water tank 2 is fixed to the tilting table 20 and the tilting table 20 tilts, the washing tank 5 tilts together with the water tank 2. The washing tub 5 has a cylindrical shape with the top surface opened and the bottom surface closed, and a plurality of water passage holes for dehydration are formed on the side surface.
A balancer 6 is installed around the top opening of the washing tub 5. A range surrounded by the inner periphery of the balancer 6 is provided for loading and unloading laundry as an opening. In addition, since the water tank cover 7 is installed in the water tank 2 that stores the washing tub 5, the upper end surface of the balancer 6 is covered with the water tank cover 7.

(Pulsator)
At the bottom of the washing tub 5, a pulsator 4 for agitating the thrown-in laundry and poured water (hereinafter referred to as "washing water") is rotatably arranged. Hereinafter, for the sake of convenience, the rotation of the pulsator 4 is referred to as “turning” in order to distinguish it from the rotation of the washing tub 5.
FIG. 2 is a perspective view showing the pulsator 4 used in this embodiment, and FIG. 3 is a side view of the pulsator 4 seen from the direction of arrow X in FIG. The pulsator 4 has a disk-like base portion 4a having an inclined surface formed on the surface (upper surface) 4A by lowering one end side of the upper surface and raising the other end opposite thereto, A wing portion 4b that protrudes from the inclined surface and extends along the inclination direction of the inclined surface and traverses the central portion of the base portion 4a, and the protrusion height of the wing portion 4b from the inclined surface of the base portion 4a The height of the portion 4a is made higher from the lower side toward the higher side. In addition, the code | symbol 4B in a figure has shown the back surface (bottom surface) of the pulsator.
By setting the pulsator 4 to such a structure, it is possible to secure an inclined surface sufficient to move the laundry up and down while keeping the volume of the pulsator small. As a result, it is possible to improve the drying performance of the laundry while decreasing the washing / drying capacity and the amount of water that can be used as much as possible and also reducing the load of the motor that drives the pulsator as much as possible.
Moreover, many drain holes 4c provided in the pulsator 4 are provided in the region on the lower side than the side on which the height of the base portion 4a is higher. As a result, the amount of drainage from the low-height portion where water tends to collect increases, so that drainage efficiency from the washing tub 5 is improved.

  FIG. 4 shows a modification of the pulsator 4, and is a cross-sectional view taken along a line orthogonal to the longitudinal direction of the wing 4 b of the pulsator 4. In the pulsator 4 of FIG. 4, both side surfaces of the base portion 4a separated by the wing portion 4b are also formed on inclined surfaces that become higher from the edge toward the wing portion 4b. Thereby, when the pulsator 4 rotates, the laundry jumps up along the inclined surface toward the top of the wing part 4b, and the vertical movement of the laundry is further promoted, and the drying performance of the laundry is further improved.

  In the wing portion 4b of the pulsator 4 described so far, the left and right wall surfaces in the longitudinal direction of the wing portion 4b along the inclination direction of the inclined surface of the base portion 4a are formed with the same inclination (for example, see FIG. 4). The inclination of the left and right wall surfaces may be different. In that case, it is preferable to form one wall surface on a steep slope that applies a circumferential force to the laundry, and the other wall surface on a gentle slope that applies a vertical force to the laundry. FIG. 5 is an operation explanatory diagram for explaining the operation of the wing portion 4b configured as described above. When the pulsator 4 turns (forward and reverse), the wall surface 4s having a steep inclination acts to give a force to push the laundry 50 in the horizontal direction, and the wall surface 4g having a gentle inclination moves the laundry 50 up and down. Contribute. Therefore, the wall surface 4s having a steep slope exhibits an effect when being washed or rinsed, and the wall surface 4g having a gentle slope exhibits an effect when drying.

The pulsator 4 may be an integrally molded product in which the base portion 4a and the wing portion 4b are integrally molded, or an assembly formed by combining the base portion 4a and the wing portion 4b as separate members. There may be. If the base portion 4a and the wing portion 4b are integrally formed of resin or the like, the cost can be reduced in terms of the number of parts and assembly workability. On the other hand, if the base part 4a and the wing part 4b are separate parts, a metal material having good thermal conductivity (for example, stainless steel) from the viewpoint of drying performance and a member can be appropriately selected from the viewpoint of design.
Although the pulsator 4 is provided with one row of wing portions 4b, the wing portions 4b may be arranged in a double row depending on the situation.

Further, as shown in FIG. 13, a plurality of pump-up blades 4k for scooping up water are provided radially on the back surface (bottom surface) 4B of the pulsator 4.
In order to make the pulsator 4 turn (rotate) smoothly, the center of gravity is preferably positioned on the rotation axis of the pulsator 4. Therefore, it is preferable to apply various modes for balance adjustment to the base portion 4a and / or the wing portion 4b in accordance with the shape of the pulsator 4.
For example, the thickness of the bottom surface side of the base portion 4a and / or the wing portion 4b is adjusted in accordance with the shape of the pulsator 4, and the position of the center of gravity is positioned on the rotation axis. The thickness adjustment of the pulsator 4 can be performed, for example, by forming a cavity on the bottom surface side (back surface side) where the height of the pulsator 4 is higher and reducing the weight of that portion.
Alternatively, one or more three-dimensional weight parts (or convex parts) are added to the base part 4a and / or the bottom face side (back face side) of the wing part 4b with respect to the rotational axis center of the pulsator 4 Thus, the balance can be adjusted by increasing the weight of the portion.
As the three-dimensional weight portion (or convex portion), for example, at least one or more ribs (or rib groups) provided near the pump-up blades 4k on the bottom surface side (back surface side) of the base portion 4a and / or the wing portion 4b. 4m, 4n, etc. If the ribs are arc-shaped ribs along the rotation direction of the pulsator 4, the resistance of water accompanying the turning of the pulsator 4 can be reduced.
Further, it is preferable that the pulsator 4 has a center of gravity (here, referred to as a dynamic center of gravity) at the time of turning (rotation) located on the rotation axis of the pulsator 4. Therefore, the volume of the space defined by the pump-up blades 4k adjacent to each other on the back surface of the base portion 4a is substantially equal between the regions facing each other around the rotation axis of the pulsator 4 (corresponding to the central hole in FIG. 13). It is good to form so that it may become. For this purpose, for example, a part of the back surface side of the base portion 4a is formed of a non-immersible low density member. More specifically, for example, a lid is provided so that water does not enter into a part or all of the space defined by adjacent pump-up blades 4k on the back surface side of the pulsator 4 in the height (depth) direction. It is preferable to provide a watertight structure so that the volume of the space formed on the back surface side of the pulsator 4 is substantially equal between the regions facing each other about the rotation axis of the pulsator 4. In addition, as the non-immersible low density member, a foamed resin material composed of closed cells, for example, foamed polystyrene can be used.

(Rotary motor)
A common rotating motor 11 for rotationally driving the pulsator 4 and the washing tub 5 is installed on the bottom surface of the water tub 2 and on the lower surface of the tilting table 20. In addition, rotation distribution means for distributing the rotation of the rotary motor 11 to the pulsator 4 or the washing tub 5, pulsator side rotation transmission means for transmitting rotation (turning) from the common rotation distribution means to the pulsator 4, and the common rotation Although a tank-side rotation transmitting means for transmitting rotation from the distributing means to the washing tub 5 is installed, these means are not particularly shown. The rotation motor 11 and the rotation distribution means perform predetermined rotation / stop and distribution in the washing process, the dewatering process, and the drying process, respectively, according to instructions from the control means.

(Water supply / drainage mechanism)
On the top surface of the water tank 2, a water supply mechanism 13 is installed on the lower surface side of the water tank cover 7. The water supply mechanism 13 has a water supply path 12 that is led out of the housing 1 and connected to an external water supply, and a water supply valve 14 that is installed in the middle of the water supply path 12 to open and close the flow of water. ing.
A drain port (not shown) is formed on the bottom surface of the water tank 2, and a drain hose 18 is connected to the drain port. A drain valve (not shown) for opening and closing the circulation of water is provided at the drain port or drain hose 18. Accordingly, when the water supply valve 14 and the drain valve are closed and the inner lid 8 is closed, the water tank 2 is in a sealed state.

(Drying means)
The drying means dries the laundry with hot air, and includes a drying fan 15 that supplies warm air into the washing tub 5 during a drying process, and a heater 17 that heats the air.
The drying fan 15 is installed on the lower surface of the horizontal table 19, and a heater 17 is installed at the casing outlet of the drying fan 15. A blower duct 16 that communicates with the casing discharge port and rises along the outer wall of the water tank 2 and opens at the opening edge of the upper part of the water tank 2 is installed. Further, since the air duct 16 is flexible in the vicinity of the communication portion with the casing discharge port, the air duct 16 tilts with the tilt of the water tank 2. In addition, when this drying means is installed in the tilting table 20, the air duct 16 is not required to be flexible.
The hot air heated by the heater 17 is used to dry the laundry in the washing tub 5 and then discharged to an exhaust duct (not shown). Then, after “water-cooled dehumidification” is performed to spray water toward the discharged warm air, it is sent to the air duct 16 and circulated again.

(Tilt movement of aquarium)
The tilting operation of the water tank 2 for tilting the water tank 2 as shown in FIG. 6 can be performed by various methods. For example, the tilting table 20 can be rotated about the tilting fulcrum 20a using a motor, a pinion, and a rack. Moreover, the water tank 2 can also be inclined by moving the rear hanging rod 3 supporting the water tank 2 up and down.

(Control means)
FIG. 7 is a block diagram illustrating the configuration of the control means for controlling the operation of the washing machine shown in FIG. The washing machine control means 110 includes a CPU 130, an input interface 120, an output interface 140, a memory 150, and a clock control unit 160 (connected to a timer 170). Connected to the input interface 120 are various operation switches (indicated by “... SW” in the figure) such as a driving course setting switch and a power switch for inputting a predetermined signal to the CPU 130 and an inclination angle detector. The output interface 140 is connected to a drying fan 15 to which a predetermined control signal is output from the CPU 130, a motor (generally referred to as the rotation motor 11 of the washing tub 5, the tilting motor of the water tub 2, etc.), or the like. .
Note that the safety SW indicates, for example, switches that confirm that a lid locking mechanism that locks the opening and closing of the outer lid 9 and a tilt locking mechanism that locks the tilt of the tilt plate 20 are operating.
Further, the memory 150 stores control conditions corresponding to the respective courses of the driving course. Then, the CPU 130 issues a control command for determining the tilt angle and tilting to the determined tilt angle in accordance with each stroke of the driving course.

(Control of washing machine)
FIGS. 8 to 10 illustrate an example of the control method of the control means 110. FIG. 8 is a schematic flowchart of a series of processes of the washing machine, and FIGS. 9 and 10 are times of a series of processes of the washing machine. An example of the chart is shown respectively. In FIG. 9, the washing tub 5 is inclined in the washing process and the drying process, whereas in FIG. 10, the washing tub 5 is erected between the washing process and the drying process.
This washing machine is capable of executing a washing process, a rinsing process, a dehydrating process, and a drying process of laundry, and a user can appropriately set an “operation course”.

Hereinafter, a description will be given with reference to FIG.
(I) In the initial stroke, when the power switch is turned on (ON), the washing tub 5 is tilted.
(Ii) If the set driving course includes a washing process, and if the amount of laundry put in is large, “upright washing” for washing the washing tub 5 in an upright state is executed and thrown in. When the amount of laundry is small, “inclined washing” is performed in which the washing tub 5 is washed in an inclined state.
(Iii) When the rinsing process is included in the set operation course, “upright rinsing” is performed in which the washing tub 5 is washed upright regardless of the amount of laundry put in.

(Iv) When the dehydration process is included in the set operation course, “upright dehydration” is performed in which the laundry tub 5 is dehydrated in an upright state regardless of the amount of laundry put in.
(V) When the set operation course includes a drying process, when the amount of laundry put in is large, “upright drying” is performed to dry the laundry tub 5 in an upright state, When the amount of laundry put in is small, “inclined drying” is performed in which the laundry tub 5 is dried in an inclined state.
(Vi) In the final stage, the power switch is automatically turned off (OFF), and the washing tub 5 is tilted. When the laundry is completely taken out and the lid is closed, the washing tub 5 stands upright, and a series of steps is completed. The washing tub 5 can be left inclined.

Next, based on the time chart of FIG. 9, the flow of washing control will be described with reference to FIG. 10 partially.
(S1-S2: Power ON, laundry input)
In FIG. 9, the washing tub 5 is inclined at an inclination angle of 20 degrees, for example, after the washing machine is turned on (ON), and the lid locks of the inner lid 8 and the outer lid 9 are released after the tilting is finished. The Then, since the inner lid 8 and the outer lid 9 can be opened and closed, the user can appropriately open the outer lid 9 (the inner lid 8 is also opened in conjunction) and put the laundry into the washing tub 5. At this time, since the washing tub 5 is inclined, it is easy to load the laundry.
When the power is turned off (OFF) while the washing tub 5 is tilted, the tilting of the washing tub 5 is mechanically locked during this time, and the inner lid 8 and the outer lid 9 can be freely opened and closed. The user can appropriately open the outer lid 9 (and open the inner lid 8 in conjunction) and put the laundry into the washing tub 5. At this time, since the washing tub 5 is tilted, the laundry can be easily put in as described above.

(S3-S4: set course, load amount detection and determination of water injection amount and inclination angle)
When the user sets a driving course and turns on the operation switch (ON), the outer lid 9 (or inner lid 8) is closed and the outer lid 9 (or inner lid 8) is locked so as not to be opened.
Note that once the outer lid 9 (or inner lid 8) is locked, the lid lock is not released unless the power switch is turned off (OFF) or the entire process of the set operation course is completed.

  Next, the load amount (weight of the loaded laundry) is detected by a known method. That is, after the rotation motor 11 is started and the pulsator 4 is rotated by a certain amount, the rotation motor 11 is stopped, and the weight of the laundry (converted into the “load amount”) by the inertial rotation amount of the pulsator 4 after the rotation is stopped. Detect possible values).

Then, based on the detection result of the load amount, the water injection amount and the inclination angle of the washing tub 5 in the washing process (same as the angle formed by the axial center with the vertical direction) are determined.
For example, in the case of the water tank 2 having a diameter of about 540 mm and a depth of about 540 mm, when the detected laundry weight is about 6 kg or less, the inclination angle is set to 30 degrees, for example. Then, as will be described later, the washing performance is improved, and a sufficient amount of water penetrating into the laundry can be secured.
On the other hand, for example, when the weight of the detected laundry exceeds about 6 kg, as shown in FIG. 10, the inclination angle is 0 degree, that is, the laundry tub 5 is kept upright without inclining and is sufficient to penetrate into the laundry. The amount of water is secured, and the water in the washing tub 5 does not spill during washing (hereinafter referred to as “upright washing method”).

(S5: water injection and tilting)
And based on the said determination, water injection and tilting are performed. That is, the tilting motor installed on the horizontal table 19 is driven to tilt the tilting table 20 to which the washing tub 5 is fixed. That is, the control means outputs a tilt command to the tilt motor. Then, when the tilt angle detector detects that the tilt angle has become 20 degrees, or when the tilt angle detector (corresponding to the position sensor) installed at the position of the tilt angle 20 degrees is operated, tilting is performed. Stop the motor.
In addition, after the water injection is finished (after the opened water supply valve is closed), the tilting is started and the washing is started during the tilting, but the water is poured in parallel with the tilting or after the tilting is finished. Water injection may be started.
In particular, in the case of the upright washing method shown in FIG. 10, it is preferable to inject water after the end of tilting so that water does not leak from the water tank 2 or to end tilting before the amount of water is almost full. .

(S6: Washing)
In washing, the tilt lock mechanism is operated in a state where the washing tub 5 is inclined at 20 degrees, and the pulsator 4 is rotated at a low speed in the locked state. When the end of the washing process approaches, the drain valve is opened, and the rotary motor 11 is decelerated and stopped while draining.

(S7: Tilt)
When the drainage is finished, the tilt lock mechanism is opened, and the tilt of the washing tub 5 is started to erect. That is, the tilting motor installed on the horizontal table 19 is driven again, and the tilting table 20 on which the washing tub 5 is fixed is tilted.
Then, when the tilt angle detector detects that the tilt angle has become 0 degree, or when the tilt angle detector installed at the position of the tilt angle 0 degree is activated, the tilt motor is stopped and the washing is performed. The tank 5 is set to be perpendicular to the floor (same as vertical).
Note that the tilt lock mechanism may be opened before the drainage is finished, and tilting of the washing tub 5 may be started. Even if a driving course that does not include a rinsing process is set, the laundry at the end of the washing process can be performed by performing washing for a predetermined time in the washing tub 5 in an upright state before the washing process is completed. Therefore, the rotational imbalance in the dehydration process immediately after that can be reduced.

(S8: Rinse)
The rinsing is performed by operating (locking) the tilt lock mechanism with the washing tub 5 standing upright. In FIG. 9, the rotary motor 11 is rotated at a low speed while supplying water, and after a predetermined amount of water is supplied, the water supply is stopped, but the rotation continues, and eventually the rotary motor 11 is decelerated and stopped immediately before the end of rinsing. The valve is opened to drain water. However, the present invention is not limited to such control.
For example, water injection → rinsing → dehydration → water injection → rinsing may be executed with a dehydration process of rotating the washing tub 5 at a high speed in the middle. At this time, since the washing tub 5 stands upright, even if the washing tub 5 is rotated at a high speed, generation of vibration and noise can be kept low.
That is, even when the laundry is biased to one side of the washing tub 5 at the end of the washing process, the washing bias is eliminated by rinsing the laundry tub 5 upright, and so on. Vibration and noise can be reduced in the dehydration process.
In addition, before starting water pouring for the rinsing process, the rotary motor 11 is rotated (for example, rotated at a rotational speed of about 800 rpm) with the drain valve opened, and “intermediate dewatering (rotating the washing tub 5 is rotated). ) "May be carried out, or water injection, rinsing (turning of the pulsator 4) and drainage may be executed simultaneously.

(S9: Dehydration)
Dehydration is performed by rotating the washing tub 5 at a high speed by the rotary motor 11 in a state where the washing tub 5 is upright. At this time, since the load of gravity component (force acting obliquely with respect to the rotation axis) does not act on the washing tub 5, the rotation is stabilized. Therefore, even if the laundry in the washing tub 5 is biased, intense vibration and noise may occur during high-speed rotation, and the washing tub 5 and the water tub 2 may collide with the housing 1. Absent.

(S10: Tilt)
When the dehydration is finished, the tilt lock mechanism is opened, and the tilt of the washing tub 5 is started and tilted. That is, the tilting motor is driven again, for example, when the tilt angle detector detects that the tilt angle is 30 degrees, or when the tilt angle detector installed at the position of the tilt angle is 30 degrees, The tilt motor is stopped and the tilt lock mechanism is activated (locked).

(Sll: dry)
Then, the heater 17 is energized (ON), the drying fan 15 is activated (ON), and hot air is supplied to the water tank 2 via the air duct 16. During this time, while the washing tub 5 is tilted, “stirring rotation” is performed by reversing the pulsator 4, an asymmetric force acts on the laundry, and the laundry tub 5 is more upright than when the laundry tub 5 is in an upright state. Agitation is promoted, drying can be performed efficiently, and drying unevenness can be reduced. However, when the amount of laundry put in is large, as shown in FIG. 10, the laundry tub 5 may be dried upright. “Agitation rotation” refers to an operation in which the pulsator 4 is largely inverted to replace the laundry.
In particular, the rotation of the pulsator 4 having the characteristic structure as described above promotes the vertical movement of the laundry and improves the drying efficiency. In the drying process, the rotational speed of the pulsator 4 in the left-right direction is preferably faster than that in the washing process in order to increase the drying efficiency.

  In the drying process, the rotary motor 11 and the drying fan 15 may be started in parallel with the tilting operation. Further, in FIGS. 9 and 10, the water supply valve 14 is opened during the drying process in order to prevent static electricity by slightly supplying water to the washing tub 5 (directly spraying the laundry), or supplying water by a switching valve (not shown). This is because when the hot air after changing the direction and drying the laundry returns into the circulating duct, water is sprayed toward the hot air in the duct. That is, it is for accelerating the dew condensation of the water (contained in the warm air) evaporated from the laundry. However, the water supply in the drying process may be stopped.

(S12: Tilt)
When the drying process is completed, the tilt lock mechanism is opened, and the washing tub 5 is tilted again to set the tilt angle to 20 degrees. The tilt of the washing tub 5 may be started immediately before the end of the drying process and in parallel with the drying.
(S13: Take out)
When the tilt angle reaches 20 degrees, the lid lock is released on condition that the tilt lock mechanism is activated (locked) and the rotary motor 11 is stopped. Then, the user can easily take out the laundry from the washing tub 5 by opening the outer lid 9 (and opening the inner lid 8 in conjunction). At this time, since the washing tub 5 is tilted, it is easy to reach the back of the washing tub 5 and the upper opening of the washing tub 5 faces the user's line of sight. Cheap. Note that when the amount of laundry is large, the user may designate the default position so that the laundry tub 5 stands upright when the laundry is taken out.

(S14: Tilt)
When the laundry is taken out and the outer lid 9 (and the inner lid 8) is closed, the washing tub 5 stands upright, and the lid lock is opened (becomes openable) in the upright state.
(S15: End)
Then, the power switch is automatically turned off (OFF), and all the series of steps are completed.
At this time, since the tilting table 20 is supported in a wide range of the horizontal table 19, the weight of the water tank 2 or the like does not act on the tilting fulcrum 20a. Therefore, the tilting fulcrum 20a is released from a load over a long time, and durability is improved.
Note that the user may designate a default position and end the washing tub 5 in an inclined state.

(Tilt effect)
When the washing tub 5 is rotated upright, the water surface forms a rotationally symmetric surface with the rotation axis as the center. On the other hand, when the washing tub 5 is inclined and rotated, the water surface is relative to the rotation axis. Therefore, the force acting on the washing water and the laundry in the washing tub 5 is asymmetric with respect to the rotation axis, and the water flow and the washing are compared with the case where the washing tub 5 is in an upright state. The movement of the object becomes complicated, the cleaning power increases, and the washing unevenness decreases.

(Determination of tilt angle)
In the above, the case where the inclination angle in the washing process of the washing tub 5 is 30 degrees, and the inclination angle in the loading and unloading of the laundry and the drying process is 20 degrees has been described as an example, but the present invention is limited to these. In the washing process, the predetermined inclination angle can be determined in accordance with the amount of laundry (corresponding to the load amount) within a range of 10 to 45 degrees. In addition, the inclination angle can be selected within a range of 0 to 30 degrees during the loading and unloading of the laundry and the drying process. That is, as described above, the inclination angle that maximizes the washing performance varies depending on the shape and size of the washing tub and the amount of laundry to be loaded. It is desirable to determine the process.

  In addition, it is desirable that the inclination angle at the time of loading / unloading the laundry is determined in consideration of the height of the user, the size of the housing, and the like. Furthermore, you may make it each user set the inclination angle which is easy to use each. At this time, the opening formed in the top cover 10, i.e., the outer lid 9, is formed when the washing tub 5 stands upright in order to respond to a request to put in or take out the laundry with the washing tub 5 standing upright. Therefore, the outer lid 9 includes an upper opening (corresponding to the inner lid 8) of the washing tub 5 when it is upright when projected onto a horizontal plane. To be covered (covered). That is, the outer lid 9 becomes long toward the rear surface.

  In addition, when the inclination angles before and after the tilt are the same, for example, when all the strokes are executed at the same tilt angle, for example, the tilt when shifting to the washing stroke after putting the laundry In addition, the tilt during the transition from the drying process to the removal of the laundry is naturally unnecessary. That is, the time required for a series of driving courses can be shortened by the amount of time required for tilting (changing the tilting angle), and the load on the tilting mechanism can be reduced.

  Further, the inclination angle in the washing process or the drying process is not limited to one, but one or two or more inclination angles are selected within a range of 10 to 45 degrees or 0 to 30 degrees. Or the inclination angle continuously fluctuates within the range, that is, the reciprocation between the minimum inclination angle (including upright) and the maximum inclination angle is performed once or twice or more. Good. At this time, more complicated water flow is generated in washing and the laundry is agitated, and the washing performance is improved.In drying, the laundry is further agitated, so warm air is also applied to the inside of the laundry lump. It can be included, and the drying speed is improved.

(Pulsator rotation control)
As shown in FIG. 4, when both side wall surfaces of the wing part 4b of the pulsator 4 are formed with steep and gentle slopes, the rotational speed and the rotational time in the left-right direction (forward direction and reverse direction) are set. It is better to make them different. For example, when the pulsator 4 rotates in the direction of the gentle slope of the wing portion 4b, the speed is made faster than when the pulsator 4 rotates in the direction of the steep slope of the wing portion 4b so that the laundry 50 can be surely moved up and down. . In order to prevent the laundry 50 from being entangled, it is preferable that the time for rotating the wing part 4b in the direction of the steep slope is shorter than the time for rotating the wing part 4b in the direction of the gentle slope.

  Further, at the end of the process of rotating the pulsator 4 with the washing tub 5 tilted (at the end of rotation of the pulsator 4), the lower side of the pulsator 4 is tilted as shown in FIG. It is preferable that the laundry 50 be positioned on the ascending side of the washing tub 5 so as to eliminate the unevenness of the laundry 50 in the washing tub 5 and to easily take out the laundry 50 from the washing tub 5. During drainage, it is preferable that the pulsator 4 is rotated halfway from the position shown in FIG. 11 to drain as shown in FIG.

(Application of the pulsator described in the above embodiment to other washing machines)
In the above-described embodiment, an example in which the pulsator 4 unique to the present application is applied to a washing machine of a type that performs a predetermined process in a state where the washing tub 5 is inclined is shown. However, the pulsator 4 of the present application adopts a pulsator method. Needless to say, it can be applied to any washing machine.
Then, an inclined surface is formed on the upper surface by lowering one end side and raising the other end side opposite to it, allowing the washing tub to be inclined forward, and rotating the pulsator while the washing tub is inclined. The drying performance can be improved even when the washing tub is inclined.

1 is a side sectional view of a washing machine according to an embodiment of the present invention. The perspective view which shows the pulsator currently used for the washing machine of FIG. The side view of the pulsator of FIG. Sectional drawing in the line orthogonal to the wing | blade part which shows the modification of the pulsator of FIG. Action | operation explanatory drawing of the wing | blade part which comprises a pulsator. The sectional side view of the washing machine which concerns on embodiment of this invention of the state which inclined the water tank. The block diagram explaining the structure of the control means in the washing machine shown in FIG. The schematic flowchart of the control method of the control means in the washing machine shown in FIG. The time chart 1 explaining the control method of the control means in the washing machine shown in FIG. 2 is a time chart for explaining a control method of the control means in the washing machine shown in FIG. The schematic diagram 1 explaining the process and the state of a pulsator in the state which inclined the washing tub. The schematic diagram 2 explaining the process in the state which inclined the washing tub, and the state of a pulsator. FIG. 3 is a detailed view of the back (bottom) side of the pulsator of FIG. 2.

Explanation of symbols

  1: Housing, 2: Water tank, 3: Hanging rod, 4: Pulse evening, 4A: Front surface of pulsator, 4B: Back surface of pulsator, 4a: Base part, 4b: Wing part, 4c: Drain hole, 4k: Pump Up blade, 4m: rib, 4n: rib, 5: washing tub, 6: balancer, 7: water tank cover, 8: inner lid, 9: outer lid, 10: top cover, 11: rotary motor, 12: water supply route , 13: Water supply mechanism, 14: Water supply valve, 15: Drying fan, 16: Blower duct, 17: Hi-Ichiba, 18: Drain hose, 19: Horizontal plate, 20: Tilt table, 50: Laundry

Claims (18)

A washing machine in which a pulsator as a rotating body is arranged at the bottom of the washing tub,
The pulsator is provided with a base portion whose surface is formed into an inclined surface by lowering one end side of the upper surface and raising the other end side of the upper surface facing the upper surface, and an inclined surface of the base portion, A washing machine having a wing portion along an inclination direction of an inclined surface.   The washing machine according to claim 1, wherein a protruding height of the wing portion from the inclined surface is made higher from a lower side of the base portion toward a higher side.   Of the left and right wall surfaces along the inclined direction of the inclined surface of the base portion of the wing portion, one wall surface is a steep slope that applies a circumferential force to the laundry, and the other wall surface is the vertical direction with respect to the laundry. The washing machine according to claim 1 or 2, wherein the washing machine is formed on a gentle slope on which the force is applied.   The time for the forward and reverse pulsators to rotate in the direction of the steep slope of the wing is shorter than the time of rotation in the direction of the gentle slope of the wing. Washing machine.   The washing machine according to claim 3, wherein the forward rotation speed and the reverse rotation speed of the pulsator that normally and reversely rotate are different from each other.   The washing machine according to any one of claims 1 to 5, wherein the wing portion and the base portion are integrally molded products.   The washing machine according to any one of claims 1 to 5, wherein the wing portion and the base portion are an assembly formed by joining separate members.   The washing machine according to any one of claims 1 to 7, wherein a plurality of pump-up blades are radially provided on the back surface of the pulsator.   The washing machine according to any one of claims 1 to 8, wherein the pulsator is balanced so that the center of gravity of the pulsator is located on the rotation axis of the pulsator.   The washing machine according to claim 9, wherein thicknesses of the base part and / or the wing part are partially different.   The washing machine according to claim 9 or 10, wherein a weight portion acting as a balancer is formed on a back surface side of the base portion and / or the wing portion.   The washing machine according to claim 11, wherein the weight portion includes at least one rib provided on a back surface side of the base portion and / or the wing portion along a rotation direction of the pulsator.   The volume of a space defined by adjacent pump-up blades on the back surface of the base is formed to be substantially equal in regions facing each other about the rotation axis of the pulsator. The washing machine described.   The washing machine according to claim 13, wherein a part or all of the height direction of the space defined by the pump-up blades on the back surface of the base is surrounded by a lid to form a watertight structure.   The washing machine according to claim 14, wherein the watertight structure is formed of a foamed resin.   The washing machine according to any one of claims 1 to 15, wherein the pulsator is provided with many drain holes on a side lower than a side having a higher height.   The washing machine according to any one of claims 1 to 16, further comprising a step of rotating the pulsator in a state where the washing tub is inclined and the washing tub is inclined.   18. When the rotation of the pulsator is completed, the lower side of the pulsator is positioned on the ascending side of the washing tub that is inclined and raised on one side. The washing machine according to crab.

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