JP2000051569A - Washing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To evade a problem caused by the mischief of a child without degrading handleability. SOLUTION: When it is judged that a safety mode is set, a control part starts the counting of time t1 (S4) and it judges whether or not an upper lid is open (S5). A main program is resumed when the upper lid is not open. Whether or not the time t1 has reached the suspension time of 5 seconds is judged when the upper lid is open (S8). When it elapses 5 seconds, the control part stops a load operated at present, stops a washing operation, displays abnormality by using the existing display lamp of a display part or the like and reports the abnormality by a buzzer (S9).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a washing machine.

[0002]

2. Description of the Related Art Conventionally, in general fully automatic washing machines,
An outer tub is elastically supported in the machine frame, and a washing and dewatering tub (hereinafter, abbreviated as dehydration tub) is rotatably arranged in the outer tub, and a pulsator for generating a water flow is disposed at the bottom of the dehydration tub. are doing. During washing and rinsing, the pulsator is alternately rotated left and right in a dewatering tank storing water, and during dehydration, the dewatering tank after draining is rotated in one direction at high speed.

In such a washing machine, as rinsing, water is stored in a washing tub and the laundry is rinsed by rotating a pulsator (in a broad sense), or water is injected while the dehydrating tub is rotated at a low speed to wash the laundry. Water is applied to remove the detergent in the laundry, and a shower rinse for draining the water is selectively performed. In addition, in the pool rinsing (broad sense), after a predetermined amount of water is stored, water injection is stopped and rinsing is performed (narrow sense).
And rinsing while rinsing while continuing to inject water and overflow.

[0004]

However, the above-described washing machine has the following problems.

[0005] (1) A lid is provided at an input port for loading laundry, and the lid is closed during the washing operation, but the lid is securely closed such as a locking mechanism. It can be easily opened by a small child if it can be reached. Therefore, it is conceivable that the child is mischievous. For example, when the lid is opened during the washing operation and a hard toy or the like is immersed in the dehydration tub, the toy is agitated at the time of washing, which may damage the dehydration tub and the laundry.

In order to prevent this, when the lid is opened, it is considered that a buzzer informs the user or the washing operation is temporarily interrupted. In this case, the user adds laundry during washing. Even if the user tries to open the cover, the buzzer sounds or the operation is interrupted, so that the user has to perform a release operation each time.

(2) At the end of shower rinsing, water that could not be completely drained remains at the bottom of the outer tub, or a large amount of water applied to the laundry remains. However, in the conventional washing machine, as soon as the shower rinsing is finished, that is,
Before the water remaining in the outer tub is drained or the water in the laundry is drained by its own weight and drained, the dehydration tub is rotated to perform dehydration. The water that flows into the outer tub is stirred in the dehydration tub and makes a loud noise, and the detergent contained in the residual water causes foaming. There was a risk of lowering.

(3) The water flow at the time of washing and rinsing is determined on the washing machine side according to the amount of laundry and the washing course, and the state of the water flow, that is, the strength of the flow and the reversal cycle of the flow direction, etc., according to the user's preference. Could not be adjusted. For this reason, it is conceivable to provide a key for changing the water flow so that the user can manually change the water flow.

However, if a change in the water flow is always accepted, a problem occurs. That is, there is a loosening period in the latter half of the washing, and here, a water flow that changes the left and right direction in a very short cycle is set so that the laundry can be loosened, for example. If it is changed, there is a possibility that loosening cannot be performed properly. In addition, in the water injection rinsing, rinsing is performed at an extremely high water level. In this state, the water flow is changed to a stronger water flow by the user, and when the water splash increases, water easily leaks out of the machine.

[0010] The present invention relates to an improvement in a washing machine and solves such a problem.

[0011]

A washing machine according to a first invention of the present application is arranged in a machine frame, and stores a laundry to perform a washing operation, and the washing tub. A cover that opens and closes an opening for loading laundry into the container, an open / close detection unit that detects the opening and closing of the cover, and when the open / close detection unit detects that the cover has been opened during the washing operation, A control unit that counts a predetermined delay time and performs an abnormal process when the counting of the delay time is completed without detecting that the lid is closed again.

A washing machine according to a second aspect of the present invention includes an outer tub elastically supported in a machine frame, a washing and dewatering tub rotatably supported in the outer tub and containing laundry. A water flow generating device for generating a water flow in the washing and dewatering tub; a motor for driving the washing and dewatering tub; and a control unit for driving and controlling loads such as the water flow generating device and the motor. In the washing machine performing a washing operation consisting of, comprising an opening and closing detection unit for detecting opening and closing of a lid for opening and closing the opening of the laundry into the washing and dehydration tub, the control unit,
During the washing operation, when the opening / closing detection unit detects that the lid is opened, a counting unit that starts counting a predetermined delay time, and without detecting that the lid is closed again. And abnormality processing means for performing abnormality processing when the counting of the delay time is completed by the counting means.

[0013] In addition, the control unit further includes a dehydration determination unit that determines whether a dehydration operation is being performed when the lid is opened by the open / close detection unit. If the dehydration determining means determines that the dehydrating operation is being performed, the abnormal processing is performed without waiting for the delay time.

In addition, there is provided an abnormality notifying section for notifying the user of an abnormality, and the abnormality processing means operates the abnormality notifying section as abnormality processing.

[0015] In addition, the abnormality processing means, as the abnormality processing, stops the operating load and stops the washing operation.

In addition, the control unit further includes a drainage determination unit that determines whether a drainage operation is being performed when the open / close detection unit detects that the lid is opened, and the abnormality processing unit includes: Without detecting that the lid has been closed again, when the counting of the delay time is completed by the counting means and the drainage determining means determines that the drainage operation is being performed, the drainage operation is completed. Thereafter, the washing operation is stopped.

In addition, the control unit includes a prohibition unit for prohibiting the reception of a command by the operation key even if the operation key is pressed during the abnormality processing by the abnormality processing unit.

In the washing machines according to the first and second aspects of the present invention, when the lid is opened during the washing operation, counting of the grace time is started. When the user adds laundry, the lid is closed immediately after the loading of the laundry, that is, by the end of the counting of the grace time, so that an abnormality is notified or the washing operation is stopped. Does not perform abnormal processing.

On the other hand, when the child opens the lid for mischief, since the lid is not closed, the counting of the grace time is completed, and abnormal processing such as abnormality notification and washing operation stop is performed.

Therefore, during normal use such as adding laundry, the abnormal processing is not performed, so that the usability is not impaired. For example, a problem caused by child mischief, such as damage in the washing tub. Can be avoided.

In addition, drainage may be performed as an abnormal treatment. In this case, even if a toy or the like is put into the washing tub by mischief, it can be easily taken out. In addition, in the washing machine of the second invention, if the timing when the lid is opened is during the dehydration operation, the abnormality notification and the washing operation are immediately stopped without delay.

During the dehydration operation, the dehydration tub is rotating at a high speed, and the danger is extremely high if the child is mischievous.
In this case, safety can be ensured by immediately performing the abnormality processing.

Further, if the timing when the lid is opened is during draining, the washing operation is stopped after the draining operation is completed.

Therefore, even if a toy or the like is put in the washing tub by mischief, it can be easily found and taken out.

Further, even if an operation key such as a start key is pressed while the abnormality is being notified or the washing operation is stopped, a command from the operation key is not accepted.

Therefore, it is possible to prevent the washing operation from being restarted by the operation of the child, or from interrupting the abnormal processing such as the abnormality notification being released.

Next, a washing machine according to a third aspect of the present invention has an outer tub resiliently supported in a machine frame, a washing and unloading machine rotatably supported in the outer tub and containing laundry. A water tub, a water supply device for supplying water to the washing and dewatering tub, a drainage device for draining from the outer tub, a water flow generating device for generating a water flow in the washing and dewatering tub, and driving the washing and dewatering tub And a control unit for controlling the driving of the water flow generating device, the water supply device, the drainage device and the motor, perform a washing operation including washing, rinsing, and dehydrating, and as the rinse, rotate the washing and dewatering tub at a low speed. In the washing machine for operating the water supply device and the drainage device while performing the shower rinsing operation by applying water to the laundry to remove the detergent component in the laundry, the control unit includes the drainage device when the shower rinsing is completed. While operating After while waiting, it is intended to rotate the washing and dewatering tank to perform dehydration.

In the washing machine according to the third aspect of the present invention, when the shower rinsing is completed, the washing machine stands by while the drainage device is operated. Then, when the water remaining in the outer tub is drained, or when the water in the laundry flows out by its own weight and is drained, the dehydration tub is rotated to start dehydration.

Therefore, noise at the start of dehydration caused by residual water in the outer tub is suppressed, and foaming is suppressed, so that dehydration can be performed smoothly.

A washing machine according to a fourth aspect of the present invention includes an outer tub elastically supported in a machine frame, a washing and dewatering tub rotatably supported in the outer tub and containing laundry. A water supply device for supplying water to the washing and dewatering tub, a drainage device for draining from the outer tub, a water flow generating device for generating a water flow in the washing and dewatering tub, and a motor for driving the washing and dewatering tub, The water flow generating device, a water supply device, a drainage device and a control unit for driving and controlling the motor, washing, rinsing, performing a washing operation including dehydration, as the rinse, after collecting water in the washing and dewatering tub. Activating the water flow generating device, rinsing the pool to remove the detergent in the laundry by the water flow, and operating the water supply device and the drainage device while rotating the washing and dewatering tub at a low speed to supply water to the laundry. Shower to remove detergent in laundry Rinsing is selectively performed, and in the dehydration, in the washing machine in which the washing and dewatering tub is first rotated in a low-speed region for a certain period of time, and then started up to a high-speed steady rotation speed, the control unit includes a shower rinse. In the subsequent spin-drying, the time for rotating the washing and spin-drying tub in the low-speed region is longer than that in spin-drying after rinsing.

More specifically, the control section rotates the washing and dewatering tub at a predetermined low rotation speed for a predetermined time before starting up to the steady rotation speed, and further performs a shower rinse. The predetermined time is made longer than when the reservoir rinsing is performed.

Alternatively, the control unit may rotate the washing and dewatering tub at a predetermined low speed for a predetermined time before starting up to the normal rotation speed, and further, when performing shower rinsing, perform the predetermined rotation. Before rotating at a predetermined speed, the motor is rotated at a predetermined speed lower than the predetermined speed.

In the washing machine according to the fourth aspect of the invention, when the shower rinsing is performed, in the subsequent dehydration, the washing and dewatering tub is rotated in the low speed region for a longer time than in the case where the pool rinsing is performed. Specifically, the time for rotating at a predetermined low speed is increased. Alternatively, before rotating at the predetermined low speed, the motor is rotated at a lower predetermined speed.

The rinsing of the reservoir referred to in the present invention includes a water rinsing rinse and a rinsing rinsing in a narrow sense.

[0035] When the shower rinsing water just upon dehydration start because not provided drainage time becomes the rest tends to outer tub, it is possible to create from the to drain enough water at low rotational speed to high speed In addition, noise at the start of dehydration caused by residual water in the outer tub is suppressed, and foaming is suppressed, so that dehydration can be performed smoothly.

In particular, since a large amount of water is discharged from the laundry at first, a large amount of water is accumulated in the outer tub. However, in a configuration in which the outer tub is rotated at a lower rotation speed, when the outer tub has a large amount of water, more water is accumulated. Since it is rotated slowly, sound and foaming can be suppressed more effectively.

A washing machine according to a fifth aspect of the present invention is provided within a machine frame and includes a washing tub for storing laundry, a water flow generating device for generating a water flow in the washing tub, and a driving device for driving the water flow generating device. Control and a control unit for controlling the water flow generating device so as to generate a water flow for loosening the laundry when the loosening period before the end of the washing is reached, in which the user manually sets the water flow. The control unit controls the water flow generating device such that, when a water flow is set by the water flow operation unit, a set water flow is generated based on a change command from the water flow operation unit. At the same time, when the loosening period starts, a change command of the water flow operation unit is not accepted. A washing machine according to a sixth aspect of the present invention is provided in a machine frame, and includes a washing tub for storing laundry, a water flow generating device for generating a water flow in the washing tub, and a control for driving and controlling the water flow generating device. Department and
Washing, in a washing machine that performs rinsing, the user includes a water flow operation unit for manually setting the water flow, the control unit,
When the water flow is set in the water flow operation unit, the water flow generation device is controlled so that the set water flow is generated based on a change command from the water flow operation unit, and the rinse is poured into the washing tub. In the case of water rinsing in which rinsing is performed while performing water rinsing, a command from the water flow operation unit is not received during water rinsing.

In the washing machines of the fifth and sixth aspects of the present invention,
Since the user can freely change the water flow by operating the water flow operation unit, the washing operation can be performed according to the user's preference.

Further, in the washing machine of the fifth invention, since the water flow is not changed during the loosening period, the loosening effect is not impaired and the loosening performance can be maintained.

In the washing machine according to the sixth aspect of the present invention, since the water flow is not changed during the water rinsing, water leakage to the outside of the machine due to water splash at a high water level can be prevented.

[0041]

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a side sectional view of a fully automatic washing machine 1 showing an embodiment of the washing machine according to the present invention, wherein the left side is the front side of the washing machine and the right side is the rear side.

In FIG. 1, reference numeral 2 denotes a pre-coated metal (P
CM) A machine frame 3 made of a steel plate is a substantially cylindrical outer tank made of a synthetic resin disposed in the machine frame 2. This outer tank 3
Is elastically supported by a suspension rod 4 via a vibration isolator 5 in the machine frame 2. Reference numeral 6 denotes a washing and spin-drying tub (hereinafter, abbreviated as a spin-drying tub) rotatably supported in the outer tub 3 so as to be rotatable in a horizontal direction. This dewatering tank 6 is made of stainless steel plate,
An annular fluid balancer 7 made of a synthetic resin is attached to the upper end. Further, a large number of dehydration holes 8 are opened in the body 6a of the dehydration tank 6.

Reference numeral 9 denotes a synthetic resin pulsator (a motor and a water flow generator of the present invention), which is rotatably disposed at the bottom of the dewatering tank 6. A wing body 9a is integrally formed radially on the upper surface of the pulsator 9, and a back blade 9b is integrally formed radially on the back surface. In addition, a large number of discharge holes (not shown) communicating with the back side of the pulsator 9 are opened in the upper surface of the pulsator 9 and the respective wing bodies 9a to allow fine air bubbles to be described later to pass therethrough.

The pulsator 9 arranged in the dewatering tank 6
A pump chamber 10 for accommodating the back blade 9b is formed between the pump chamber 10 and the bottom wall 6b of the dewatering tub 6. The pump chamber 10 is provided on the bottom wall 6b so as to surround a dehydration tub shaft 11. 10
A large number of suction ports 12 are provided. The pump chamber 1
From 0, a circulating water channel 13 extending upward along the body 6a of the dewatering tank 6 is provided. This circulation channel 13
It is connected to a discharge port 14 provided directly below the fluid balancer 7, and a bag-shaped lint filter 15 is attached to the discharge port 14.

Reference numeral 16 denotes a DC brushless motor (hereinafter abbreviated as a motor) attached to the outer bottom of the outer tub 3. The rotational force of the motor 16 is controlled by a motor pulley 17, a V-belt 18, a main pulley 19 and a power switching mechanism. The light is transmitted to the dehydration tub 6 and the pulsator 9 via the reference numeral 20. At the time of washing and rinsing, the clutch (not shown) of the power switching mechanism 20 is deactivated to disconnect the dewatering tub 6 from the pulsator 9 and the motor 16 is rotated only at a low speed in the pulsator 9. Rotate. In addition, at the time of dehydration, the dehydration tub 6 and the pulsator 9 are connected by the clutch of the power switching mechanism 20 being operated,
The motor 16 rotates the pulsator 9 and the dewatering tub 6 in one direction at high speed.

Reference numeral 21 denotes a synthetic resin pedestal attached to the bottom of the machine frame 2, and legs 22 are provided at four corners at the bottom. Reference numeral 23 denotes a synthetic resin upper surface plate that covers the upper part of the machine frame 2. An input port 24 for inputting laundry into the dewatering tub 6 is provided at a central portion of the upper surface plate 23,
An upper lid 25 (corresponding to a lid of the present invention) that can be opened and closed is provided at the inlet 24. Reference numeral 60 denotes an open / close detection switch for detecting the open / close of the upper lid (corresponding to the open / close detection unit of the present invention)
It is.

The front and rear portions of the upper plate 23 are provided with housings 26 and 27 for electrical components. An air pump 28 for sending air into the outer tub 3 and a control board (not shown) for controlling a washing operation are arranged in the front housing section 26. The upper surface is covered with an operation panel 29 for performing a washing operation.
A water level sensor 30 and a water supply valve 3
1 (corresponding to the water supply device of the present invention) and the like,
It is covered with a rear cover 32. The water level sensor 30 is connected via a pressure hose 33 to an air trap (not shown) formed at the rear of the bottom of the outer tub 3, and detects a water level change in the outer tub 3 by detecting a pressure change accompanying the water level change. Is to be detected. The water supply valve 31 is connected to a water supply port 34 provided on the upper surface plate 23. Tap water supplied from the outside is injected into the dehydration tank 6 from the water supply port 34 by opening the water supply valve 31. You.

Reference numeral 35 denotes a bottom portion of the outer tank 3,
Is a drain port provided near the outer peripheral side of the
6 (corresponding to the drainage device of the present invention) and the drainage hose 37
It is connected to the. The water in the outer tub 3 is discharged outside the machine through the drain hose 37 by opening the drain valve 36.

Numeral 38 denotes a bottom portion of the outer tub 3, which is located on the center side of the outer tub 3 from the drain port 35 and the pump chamber 10.
And is connected to the air pump 28 via an air hose 39. The air hose 39 is a first tube 39a having a large diameter extending from the introduction port 38 along the outer wall of the outer tub 3 to the lower part of the body of the outer tub 3, and is wound around the hanging rod 4 from the air pump 28 and A second tube 39b having a small diameter reaching the lower part of the body of the tank 3 and a connecting pipe 39c fixed to the lower part of the body of the outer tank 3 and connecting the first tube 39a and the second tube 39b. . The bottom surface of the outer tub 3 is a slightly inclined surface 3 at the center.
a, and the inlet 38 is located higher than the drain 35.

At the time of washing and rinsing, the pulsator 9 is filled with water to a predetermined water level in the dewatering tank 6.
Is rotated left and right at low speed. Then pulsator 9
The water in the dewatering tank 6 is agitated by the wings 9a on the upper surface of the blade, and a water flow is generated. Thereby, the laundry in the dewatering tub 6 is washed. In addition, the back blade 9 on the back surface of the pulsator 9
By the pump action of b, water between the bottom of the dewatering tank 6 and the bottom of the outer tank 3 is sucked up through the suction port 12, pushed out to the outer periphery of the pulsator 9, and ascends the circulation channel 13, and is discharged from the discharge port 14. It is discharged into the dehydration tank 6. At this time, lint and the like that have come out of the laundry by the lint filter 15 are collected.

During dewatering, the dewatering tank 6 and the pulsator 9 rotate at high speed in one direction while the drain valve 36 is open. The water in the laundry is shaken off by the centrifugal force, flows out of the dewatering hole 8 of the dewatering tub 6 into the outer tub 3, flows down the inner wall of the outer tub 3, and is discharged from the drain port 35.

When the air pump 28 is driven at the time of washing, air is sent into the outer tub 3 through the air hose 39, and air bubbles are successively generated from the inlet 38. The generated air bubbles pass through the suction port 12 and accumulate below the pulsator 9. The air bubbles accumulated below the pulsator 9 are removed by the back blade 9b functioning as an air bubble crushing device.
The pulsator 9 is crushed by being stirred to form a large number of fine bubbles, and floats through a discharge hole (not shown) opened in the pulsator 9. Then, the micronized bubbles come into contact with the laundry above and burst (split) and diffuse, and the minute vibration of the shock wave generated at this time makes it easy for the dirt components such as sebum entangled in the fibers of the laundry to be peeled off. Also,
Such bubbles promote the dissolution of the detergent contained in the laundry and improve the foaming of the detergent. Since the detergent bubbles and the fine bubbles generated in this way are interposed between the laundry and the pulsator 9, rubbing between the laundry and the pulsator 9 is reduced, and damage to the laundry is reduced. .

FIG. 2 is a plan view of the operation panel 29 showing details of an operation section and a display section for the washing operation. FIG.
In the figure, reference numeral 40 denotes a power switch for turning on the power of the washing machine main body, and reference numeral 41 denotes a start / pause key (hereinafter, abbreviated as a start key) for starting or interrupting the washing operation.

Reference numeral 42 denotes a course selection key group for selecting a washing course, and includes a plurality of course keys 42a provided corresponding to the respective courses. The washing course includes a “standard course” that performs standard washing, a “elaborate course” that performs elaborate washing, a “hour reduction course” that performs short-time washing, and a “own style” in which washing is performed under conditions set by the user. "Course", "Dry course" for washing dry-marked and perishable clothing, "Blanket course" for washing blankets, and "Goshigoshi course" for washing with strong washing to remove stubborn dirt. In addition, each course key 42a
, Course indicator lamps 42b are provided to indicate that the course is selected.

Reference numeral 43 denotes a water flow key (corresponding to the water flow operation section of the present invention) for the user to adjust the strength of the water flow. The water flow key 43 enables five-stage water flow adjustment. 44 is a washing key for setting a washing time, 45 is a rinsing key for setting the number of times of rinsing, and 46 is a spinning key for setting a spinning time. These washing keys 4
4. The rinsing key 45 and the dehydration key 46 are operated to set each condition when performing the “own course”. 4
Reference numeral 7 denotes a reservation key for setting the end time when washing is completed at the reserved time, and reference numeral 48 denotes a water level key for adjusting the water level. 49 is a detergent amount key. This detergent key 4
Reference numeral 9 denotes a key for notifying the device that a large amount of detergent has been introduced and that a detergent having good foaming is used.
Pressed when a lot of detergent is added or when using a foaming detergent.

Reference numeral 50 denotes a display unit (corresponding to an abnormality notification unit of the present invention) on which displays other than the course display lamp 42b are arranged in a concentrated manner. The display unit 50 is set with a progress display unit 51 indicating the degree of progress of the washing operation, a water flow display unit 52 indicating the strength of the water flow selected by the water flow key 43, the wash key 44, the rinse key 45, and the dehydration key 46. The washing time, the number of times of rinsing, the dehydration time, or the end time reserved by the reservation key 47 and the remaining time of the washing operation are displayed by the information display section 53, the water level key 48, or adjusted by the washing machine side. A water level table 54 displays the water level in the dewatering tub 6 that has been determined, and displays the estimated amount of detergent according to the water level.

FIG. 3 is an electric block diagram showing a control mechanism in the fully automatic washing machine of the present embodiment. Reference numeral 55 denotes a control unit, which mainly includes a known microcomputer. The control unit 55 includes a key input circuit 56 connected to various operation keys such as the start key 41, a display unit driving circuit 57 for driving various display units such as the information display unit 53, and a buzzer 59a (the present invention). , A water level sensor 30, an open / close detection switch 60, a load drive circuit 58, and the like. The load drive circuit 58 includes the water supply valve 31,
The drain valve 36 and the air pump 28 are connected.

A rotation sensor 61 for detecting the number of rotations of the motor 16 is connected to the control unit 55, and a motor drive circuit 62 for controlling the drive of the motor 16 is connected thereto. The motor drive circuit 62 includes a DC voltage supply unit 63 and an inverter circuit 64. The rotation sensor 61 feeds back a detection signal corresponding to an actual rotation speed NR of the motor 16 (hereinafter, referred to as an actual rotation speed) to the control unit 55. The DC voltage supply unit 63 generates a constant DC voltage and supplies it to the inverter circuit 64.

FIG. 4 is a waveform diagram showing an example of a control pulse signal output from the control section 55. The length Wb of one cycle of the control pulse signal is a fixed value determined by the switching frequency, and the control unit 55 sets the time width Wa of the “H” level according to the difference between the target rotation speed NP and the actual rotation speed NR. Change. That is, when the actual rotation speed NR is lower than the target rotation speed NP and the rotation speed needs to be increased, the time width Wa is increased. Conversely, when the actual rotation speed NR is higher than the target rotation speed NP and the rotation speed needs to be reduced, the time width Wa is narrowed. The control unit 55 calculates the actual rotation speed NP each time a detection signal is obtained from the rotation sensor 61, and changes the time width Wa of the control pulse signal as necessary. By such PWM control, a square wave voltage is applied to each winding of the motor 16.

The control unit 55 includes the key input circuit 5
6. Based on inputs from the water level sensor 30, the open / close detection switch 60, etc., the water supply valve 31, the drain valve 36, and the air pump 28 are controlled via the load drive circuit 58 in accordance with an operation program stored in the internal memory in advance. The operation is controlled, and the motor 16 is controlled via the motor drive circuit 62.

The control section 55 has a nonvolatile memory 65 therein. The nonvolatile memory 65 includes a washing course selected by the user, various conditions set by the user in the washing course, such as a washing time, a number of times of rinsing, a water flow, a water level, and details of an abnormality when an abnormality occurs. Is stored, the power switch 40 is turned off, and the control unit 5
5, the power supply to the nonvolatile memory 65 is stopped.
The contents stored in are saved.

The control operation in the washing operation based on the above configuration will be described below. The first feature of the washing machine of the present embodiment is that when the upper lid 25 is opened due to mischief of a child or the like during the washing operation, the abnormality is reported or the washing operation is stopped. The control operation will be described with reference to FIG.

When the upper lid opening routine is entered from the main program of the washing operation, the controller 55 initializes the time t1 in the internal counter, that is, sets t = 0 (S1). Next, it is determined whether or not the water level for the washing operation is determined (S
2) If the water level is determined, it is determined whether the safety mode is set. The safety mode is a mode for performing an abnormality process when the upper cover 25 is in an open state, and is set by performing a special operation on an existing operation key (for example, keeping the water level key pressed for 4 seconds). S
If the water level has not been determined in 2 or if the safety mode has not been set in S3, the process returns to the main program.

If it is determined in S3 that the safety mode has been set, the control unit 55 (counter)
A count of 1 is started (S4), and it is determined whether or not the upper lid 25 is open (S5). If the upper lid 25 is not open, the process returns to the main program. If the upper lid 25 is open, the control unit 55 (dehydration determining means) next determines whether or not a dehydration operation is being performed (S6). If it is not during the dehydrating operation, the control unit 55 (drainage determining means) determines whether or not the draining operation is being performed (S7).

If the control unit 55 determines in S7 that the water is not being drained, the time t1 is a grace time (5 seconds in this embodiment).
Is determined (S8). If the time has reached 5 seconds, the control unit 55 (the abnormality processing unit) stops the currently operating load, stops the washing operation, and displays the display unit 5.
An abnormal display is performed by using an existing indicator light of 0, and an abnormality is notified by the buzzer 59a (S9). And
The control unit 55 (prohibiting means) prohibits reception of various operation keys (S10).

In this state, the process waits for the upper lid 25 to be closed again, and when it is determined in S11 that the upper lid 25 has been closed,
The control unit 55 releases the prohibition of accepting various operation keys (S1).
2) Further, the abnormality display and the abnormality notification are canceled, and the washing operation is restarted (S13).

On the other hand, if it is determined in S6 that dehydration is in progress,
The control unit 55 immediately proceeds to S9 without waiting for the elapse of 5 seconds, stops the washing operation, and performs the abnormality display and the abnormality notification. When it is determined in S7 that the water is being drained, the control unit 5
5 performs an abnormality display and an abnormality notification (S14), continues the washing operation until the draining operation is completed, and stops the washing operation when it is determined in S15 that the draining operation is completed (S1).
6). Further, if it is determined in S8 that 5 seconds have not elapsed, the process returns to S5. For example, when the upper lid 25 is closed again within 5 seconds after the upper lid 25 is opened, such as when the upper lid 25 is opened to add laundry, the control unit 55 determines that the upper lid 25 is closed in S5. So return to the main program.

Next, the second feature of the washing machine of the present embodiment is that the user can manually set the state (strength) of the water flow at the time of washing and rinsing. In addition, dehydration start control when shower rinsing is performed as rinsing is a third feature point, and these control operations will be described with reference to the flowchart of FIG.

When the user puts laundry into the dehydration tub 6 and presses the start key 41, the washing operation is started. First, the control unit 55 performs a load amount detection process in the dehydration tub 6 (S1). Specifically, the pulsator 9 is rotated for a short time, then stopped naturally, and the total number of rotations of the pulsator 9 during energization and the inertial rotation is measured to determine the load amount. The more the pulsator 9 is, the harder it is for the pulsator 9 to rotate, and the longer the inertial rotation. Therefore, it is determined that the smaller the total number of rotations, the larger the load amount.

Next, the washing process is started.
Opens the water supply valve 31 and supplies water until the water level in the dewatering tank 6 reaches a water level determined according to the load (the higher the load, the higher the level) (S2). When the water supply is completed, the control unit 55
Starts ON / OFF control (intermittent drive control) of the motor to generate a water flow suitable for the washing course selected and set in advance by the user, and starts the washing operation (S3). For example,
For standard course, medium water level, ON time is 1.6 seconds, OF
The F time is controlled at 0.7 seconds and the rotation speed is controlled at 130 rpm.
In this washing machine, when the above-mentioned water flow set by the control unit 55 is set to “medium water flow”, the strength of the water flow is set to “medium strong water flow”, “strong water flow” by selecting with the water flow key 43. It can be made stronger in two stages, and weaker in two stages, such as "medium weak water flow" and "weak water flow". During the washing operation, for example, the user operates the water flow key 43 to set “strong water flow” when he / she operates the water flow key 43 and thinks that the laundry is slightly dirty and the laundry is also hard to be damaged, and the user wants to wash the laundry a little more strongly. The part 55 is S4
It is determined that the water flow key 43 has been pressed. Next, the control unit 55
Determines whether it is in the loosening water flow (S5). This loosening water stream is a water stream that loosens laundry to improve the rise of dehydration, and the control unit 55 determines that the washing operation is close to the end, for example, one minute before, the ON-OFF time shorter than the washing water stream. Ie, ON time 0.6 seconds, OFF
At a time of 0.3 seconds, the motor 16 is ON-OFF controlled to generate a relaxing water flow. In the loosening period, the controller 55 prohibits the reception of the water flow key 43.

When the water flow is set by the user during the relaxation period, and it is determined in S5 that the water flow is not in the relaxation flow, that is, the reception of the water flow key 43 is not prohibited,
The controller 55 changes the water flow to the newly set water flow, in this case “strong water flow”, and changes the ON-OFF time and the rotation speed of the motor 16 to those of the “strong water flow”.
Is ON-OFF controlled (S6).

On the other hand, the water flow key 4
If it is determined that the button 3 has been pressed, and it is determined in step S5 that the water flow is loose, that is, the reception of the water flow key 43 is prohibited, the control unit 55 does not change the water flow. Thus, S7
When it is determined that the washing time is over, the control unit 55 turns off the motor 16 and ends the washing process (S8).
Next, a dehydration process is started. In the dehydration process, first, the control unit 55
Opens the drain valve 36 to discharge the water in the outer tank to the outside of the machine (S9). When the drainage is completed, the operation shifts to a dehydration operation (here, the drainage after washing is referred to as “dehydration A”) (S1).
0).

Here, FIG. 7 is a flowchart showing the dehydration A control operation, and FIG. 8 is a graph showing the dehydration control pattern in the dehydration A. The control operation of the dehydration A will be described based on these figures.

First, the control unit 55 initializes a time t1 in an internal counter (t = 0) (S101). next,
The motor 16 is turned on to start the dewatering tub 6 (S10).
2). Then, when the rotation speed of the motor 16 (the dewatering tub 6) reaches the low speed rotation 120 rpm which is the first target rotation speed,
The motor 16 is subjected to PWM control so as to maintain 120 rpm (S103). The control unit 55 starts counting the time t1 (S104), and when 60 seconds have elapsed in S105,
The rotation speed of the motor 16 is increased to the next target rotation speed, that is, the low-speed rotation of 240 rpm, and P is maintained to maintain this rotation speed.
WM control is performed (S106). When the low-speed rotation reaches 240 rpm, the control unit 55 sets time t1 = 0 (S1
07), counting is started (S108). After elapse of 40 seconds in S109, the control unit 55 increases the rotation speed of the motor 16 to the final target rotation speed, that is, the steady rotation speed of 1000 rpm, and performs PWM control so as to maintain the rotation speed (S110). When the stationary rotation reaches 1000 rpm,
After setting the time t1 to 0 (S111), the control unit 55 starts counting (S112).

When the control section 55 increases the rotation speed to the target rotation speed of 1000 rpm, as described above, the control section 55 increases the time width Wa of the control pulse signal and increases the amount of power supplied to the motor 16. At this time, if a large amount of water remains in the outer tub 3 for some reason in the initial stage of dehydration, a large amount of bubbles may be generated in the outer tub 3 during the rotation ascending, and when this occurs, the foam becomes a resistance. Thus, a large load is applied to the dewatering tank 6. In this case, since the rotation speed of the dewatering tub 6 is hard to increase, the control unit 55 attempts to increase the rotation speed.
Increasing power supply. When the rotation speed is increased, bubbles are blown off, and when the load on the dewatering tub 6 is suddenly reduced, the power supply amount is considerably increased at this time. Can well exceed 1000 rpm of steady-state rotation. In this case, in normal PWM control,
Since the rotation cannot be immediately returned to 1000 rpm, the dehydration tank 6 rotates abnormally at a high speed, which may lead to a dangerous state. Therefore, here, control for dealing with such a situation is included.

In the above situation, when it is determined in S113 that the rotation speed of the motor 16 has exceeded the limit rotation speed of 1030 rpm, the control unit 55 turns off the motor 16 and
By operating the electromagnetic brake, the motor 16 is braked (S1
14). Thereby, the rotation speed of the motor 16 becomes 970 rpm
m (S115), the control unit 55
6 is turned on again, and the motor 1 is rotated at a constant rotation speed of 1000 rpm.
PWM control is performed so that 6 rotates (S116).

Thus, 200 seconds have elapsed since the motor 16 was rotated at the normal rotation speed of 1000 rpm (S11).
7), the control unit 55 turns off the motor 16 (S11).
8). Then, after setting the time t1 = 0 (S119), the counting is started (S120). When 40 seconds have elapsed (S121), the control unit 55 operates the electromagnetic brake to brake and stop the motor 16 (S122). Thus, the dehydration is completed.

Thus, in the dehydration A, 120 rpm,
A certain amount of water is drained from the laundry at a low rotation speed of 240 rpm, the load in the dewatering tub 6 is reduced to some extent, and then the high-speed steady rotation speed is increased to 1000 rpm. At this time, the vibration of the dewatering tub 6 is reduced.

Further, a limit rotation speed is provided above the normal rotation speed, and when the rotation speed of the motor 16 is going to rise far beyond the normal rotation speed, the rotation speed is rapidly reduced by turning off the motor 16 and braking. Control unit 55 to lower
, The dehydration tub 6 does not rotate abnormally at high speed, and is safe.

When the dehydration A in S10 is completed, the control unit 55 ends the dehydration process and shifts to the rinsing process. In the rinsing process, first, a shower rinse or a pool rinse is performed. Which one to perform depends on the washing course.

The control unit 55 determines whether the first rinsing is a shower rinsing or a pool rinsing (S11). If the rinsing is a shower rinsing, the shower rinsing is performed in S12. That is, the control unit 55 opens the water supply valve 31 while keeping the drain valve 36 open, and slowly rotates the motor 16. In this way, the injected water is evenly applied to the laundry in the dehydration tub 6, and the detergent in the laundry flows out and is discharged outside the machine.

When the shower rinsing is completed, the control unit 5
5 performs a dehydration operation (herein referred to as "dehydration B") set for shower rinsing (S13). That is, as shown in FIG. 9, the control unit 55 starts the motor 16 and first rotates the spin-drying tub 6 at an ultra-low speed rotation of 40 rpm for 60 seconds. Thereafter, the number of revolutions is increased and the low-speed revolution 12
After rotating the spin-drying tub at 0 rpm for 20 seconds and at a low speed rotation of 240 rpm for 20 seconds, the rotation speed is increased to a steady rotation of 1000 rpm. Thereafter, as in the case of the dehydration A, the motor 16 is turned off after 200 seconds, the brake is applied after 40 seconds, the dehydration tub 6 is stopped, and the dehydration is completed.

On the other hand, when it is determined in S11 that the first rinsing is a rinsing rinse, the control unit 55 performs a rinsing rinsing (S14). In the reservoir rinsing, the control unit 55 opens the water supply valve 31 to supply water to a predetermined water level, then stops supplying water, and controls the motor 16 to be ON-OFF. This allows
The pulsator 9 reversely rotates, and the laundry is rinsed by the generated water flow.

During the reservoir rinsing, the water flow key 43
When the water flow is changed and set, the control unit 55 turns ON / OFF the motor 16 in order to generate the set new water flow.
Perform control.

When the rinsing is finished, after draining in S15, the control unit 55 performs a dehydrating operation (herein referred to as “dehydrating C”) set for the rinsing (S).
16). That is, as shown in FIG. 10, the control unit 55 starts the motor 16 and firstly activates the motor 16 at a low speed rotation of 120 rpm.
The dewatering tank 6 is rotated for 0 seconds. Thereafter, the number of rotations is increased, and the dehydration tub 6 is rotated at a low speed rotation of 240 rpm for 20 seconds, and then is increased to a steady rotation of 1000 rpm. Thereafter, the motor 16 is turned off after 200 seconds, as in the case of the dehydration A.
Then, after 40 seconds, the brake is applied to stop the dehydration tub 6, and the dehydration is completed.

When the first rinsing is completed, a water rinsing rinsing or a pool rinsing is performed. Which one to perform depends on the washing course.

The control unit 55 determines whether the second rinsing is a water rinsing rinsing or a rinsing rinsing (S17). If the rinsing is a rinsing rinsing, the rinsing is performed as in S14 (S18).

On the other hand, if it is determined in S17 that the second rinsing is water rinsing, the controller 55 performs water rinsing. In the water rinsing, first, the control unit 55 opens the water supply valve 31 to start water supply (S19). Next, the water flow is set to the standard water flow in the injection rinsing, and the water flow key 43 is set.
Is prohibited (S20). Thereafter, when a predetermined water level is reached (S21), the control unit 55 continues to supply water,
The motor 16 is turned on and off, the pulsator 9 is rotated in the reverse direction, and the laundry is rinsed (S22). Then, when the rinsing time is over (S23), the control unit 55 closes the water supply valve 31 to stop water supply (S24), and further turns off the motor 16 to terminate the water injection rinsing (S25). During the water injection rinsing, even if the user operates the water flow key 43 to change the water flow, the control unit 55 does not change the water flow because the reception of the water flow key 43 is prohibited in S20.

When the second rinsing is completed, a final dehydration step is started. First, the controller 55 opens the drain valve 36 to perform drain (S26). When the drainage is completed, the motor 16 is started, and the dehydration tub 6 is rotated at a high speed to perform dehydration (S27). Thus, when the dehydration process ends, the washing operation ends.

In the washing machine of this embodiment, the previously executed washing course is stored even if the power is turned off, and the previous washing course is set when the power is turned on next time. The control operation will be described with reference to the flowchart of FIG.

When the power is turned on, the control unit 55 first reads the previously used washing course from the internal nonvolatile memory 65 (S1), and sets the read washing course as the washing course for driving. (S2). Also, the indicator light 42b corresponding to this washing course is turned on,
Notify that this washing course is set. Thereafter, it is determined whether or not another course key 42a is pressed (S
3) If it is determined that another course key 42a has been pressed,
The washing course corresponding to the pushed course key 42a is set as the washing course for driving (S4).

In S5, it is determined whether or not the start key 41 has been pressed.
Starts the operation of the set washing course (S
6). Next, the control unit 55 determines the time t in the internal counter.
1 is initialized (t = 0) (S7), and counting of time t1 is started (S8). If it is determined in S9 that two minutes have elapsed, the running washing course (including various conditions such as washing time, rinsing frequency, water flow, and water level set by the user in the washing course) is stored in the nonvolatile memory 65. (S10).

The storage in the non-volatile memory 65 after the lapse of a certain period of time of two minutes from the start of the washing operation can store the condition setting contents of the user performed at the beginning of the washing operation. That's why. Further, this is because the contents set by the inspector for the inspection during the inspection at the factory are not left. That is, in the case of the inspection, the operation is stopped immediately after a short time, so that the contents at this time do not remain.

Thus, when the washing operation is completed (S1)
1) The control unit 55 stores a flag for prohibiting entry into the inspection mode in the nonvolatile memory 65 (S1).
2). Then, the control unit 55 operates an automatic power-off mechanism (not shown) to turn off the power.

The inspection mode is a mode entered when a factory inspector performs an inspection at the time of shipment and a serviceman performs an inspection at the time of a failure inspection. By performing a special key operation (for example, keeping the course key 42a pressed for 6 seconds) while the power is on, the control unit 55
Enter this inspection mode. However, the control unit 55 does not enter the inspection mode if the prohibition flag is stored in the nonvolatile memory 65. In this case, even if the serviceman uses the inspection mode before driving, the prohibition flag is stored every time the washing operation is performed. Absent.
When a service person or the like enters the inspection mode while the prohibition flag is stored, the contents of the nonvolatile memory 65 can be initialized and the prohibition flag can be erased by performing a special operation.

As described above, in the washing machine of the present embodiment, if the upper lid is opened during the washing operation, if the upper lid is not closed again before a predetermined time (grace time), an abnormality notification is performed. Abnormal processing such as stopping the washing operation. Therefore, during normal use such as adding laundry, abnormal processing is not performed, so that it is possible to avoid problems caused by mischief of children, such as damage in the dehydration tub, without deteriorating usability. .

Further, if the timing of opening the upper lid is during the dehydrating operation, the abnormality notification and the washing operation are immediately stopped without delay, so that the dehydrating tub is rotating at a high speed and if a child is mischievous. During the dehydration operation with a very high degree of danger, safety can be reliably ensured.

Further, if the lid is opened at the time of draining, the washing operation is stopped after the draining operation is completed. Therefore, even if a toy or the like is put in the dewatering tank due to mischief, it is easily found. Then you can take it out.

Further, even if an operation key such as the start key is pressed during the notification of an abnormality or the stoppage of the washing operation, the instruction by the operation key is not accepted, so that the washing operation is restarted by the operation of the child. It is possible to prevent the abnormal processing from being interrupted, such as an error notification being released.

In the washing machine of the present embodiment, at the start of spin-drying after shower rinsing, the washing machine is rotated at a rotation speed of 40 rpm, which is lower than the low rotation speed of 120 rpm initially rotated by the pool rinse, and then rotated. Number 120r
pm.

Therefore, in the case of shower rinsing, since there is no drainage time, water tends to remain in the outer tub at the start of dehydration as compared to pool rinsing, but water is sufficiently discharged at a low rotation speed. Since the start-up is started at a high speed, the noise at the start of dehydration caused by residual water in the outer tub is suppressed, and foaming is suppressed, so that dehydration can be performed smoothly.

In particular, since a large amount of water comes out of the laundry at first, a large amount of water accumulates in the outer tub, but the rotation is performed at a lower rotation speed. As a result, sound and foaming can be suppressed more effectively.

As another embodiment, instead of rotating at 40 rpm at the start of dehydration after shower rinsing, 120 rpm
The rotation time of pm may be extended, for example, to 60 seconds instead of 20 seconds.

As another embodiment, when the shower rinsing is completed, the drain valve is kept open for a predetermined period of time, for example, about 60 seconds, so that the water remaining in the outer tub is drained or the water in the laundry is drained. The dewatering tank may be rotated at the time when the water flows out and drains under its own weight.

Also in such another embodiment, the noise at the start of dehydration caused by residual water in the outer tub is suppressed, and foaming is suppressed, so that dehydration can be performed smoothly.

Further, in the washing machine of this embodiment, the user can freely change the water flow by operating the water flow key, so that the washing operation can be performed according to the user's preference.

Further, since the water flow is not changed during the loosening period, the loosening effect is not impaired and the loosening performance can be maintained.

Further, since the water flow is not changed during the water injection rinsing, water leakage to the outside of the machine due to water splash at a high water level can be prevented.

The water flow generating device of the present invention is not limited to a pulsator but may be any device that generates a water flow. The water supply device of the present invention may be any mechanism for supplying water, such as a bath water pump for pumping bath water, and the drainage device of the present invention may be any mechanism for draining, such as a drain pump.

[Brief description of the drawings]

FIG. 1 is a side sectional view showing a configuration of a fully automatic washing machine according to an embodiment of the present invention.

FIG. 2 is a plan view of the operation panel showing details of an operation unit and a display unit for a washing operation.

FIG. 3 is an electric block diagram showing a control mechanism of the fully automatic washing machine.

FIG. 4 is a waveform chart showing an example of a PWM control pulse signal.

FIG. 5 is a flowchart illustrating a control operation of an upper cover opening routine of the fully automatic washing machine according to the embodiment of the present invention.

FIG. 6 is a flowchart showing a control operation of a washing operation, which is also characterized by water flow change control and dehydration start control.

FIG. 7 is a flowchart showing a control operation of dehydration A.

FIG. 8 is a graph showing a dehydration control pattern in dehydration A.

FIG. 9 is a graph showing a dehydration control pattern in dehydration B.

FIG. 10 is a graph showing a dehydration control pattern in dehydration C.

FIG. 11 is a flowchart showing a control operation for storing a washing course in the nonvolatile memory.

[Explanation of symbols]

2 Machine frame 3 Outer tub 6 Washing and dewatering tub (Washing tub) 9 Pulsator (Water flow generator) 16 Motor (Water flow generator) 25 Top lid (Lid) 31 Water supply valve (Water supply device) 36 Drainage valve (Drainage device) 43 Water flow key (water flow operation unit) 50 Display unit (abnormality notification unit) 55 Control unit (counting unit, abnormality processing unit, dehydration determination unit, drainage determination unit, prohibition unit) 59a Buzzer (abnormality notification unit) 60 Open / close detection switch (open / close) Detector)

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Kazutaka Nakanishi 2-5-5 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Hiroyuki Hoshino 2-5-2 Keihanhondori, Moriguchi-shi, Osaka No. 5 Sanyo Electric Co., Ltd. F term (reference) 3B155 BA23 CA06 CB06 JB06 JB21 JB26 KA31 LA04 LB02 LB18 MA01 MA06 MA07 MA08 MA10

Claims (13)

[Claims] 1. A washing tub arranged in a machine frame for storing laundry and performing a washing operation, a lid for opening and closing an opening for loading laundry into the washing tub, and opening and closing of the lid And an opening / closing detecting unit for detecting the opening of the lid during the washing operation, when the opening / closing detecting unit detects that the lid is opened, counts a predetermined delay time, and detects that the lid is closed again. Without counting, when the counting of the grace time is completed,
A washing machine comprising: a control unit for performing an abnormality process. 2. An outer tub elastically supported in a machine frame, a washing and dewatering tub rotatably supported in the outer tub and containing laundry, and generating a water flow in the washing and dewatering tub. A water flow generating device, a motor that drives the washing and dewatering tub, and a control unit that drives and controls loads such as the water flow generating device and the motor; An opening / closing detection unit for detecting opening / closing of a lid for opening / closing an opening of the laundry into the washing / dehydrating tub, wherein the control unit controls the lid by the opening / closing detection unit during a washing operation. When the opening is detected, the counting means for starting counting of a predetermined grace time, and the counting means completes counting of the grace time without detecting that the lid is closed again. Then, the error processing Washing machine, characterized in that it comprises a processing means. 3. The control unit further includes a dehydration determination unit that determines whether a dehydration operation is being performed when the open / close detection unit detects that the lid is opened, and the abnormality processing unit includes: 3. The washing machine according to claim 2, wherein when the dehydration determining unit determines that the dehydrating operation is being performed, the abnormal processing is performed without waiting for the delay time. 4. The washing machine according to claim 2, further comprising an abnormality notification unit that notifies a user of an abnormality, wherein the abnormality processing unit operates the abnormality notification unit as abnormality processing. . 5. The abnormality processing means includes:
The washing machine according to any one of claims 2 to 4, wherein the operating load is stopped to stop the washing operation. 6. The control unit further includes a drain determination unit that determines whether a drain operation is being performed when the lid is opened by the open / close detection unit. Without detecting that the lid is closed, the counting of the grace time is completed by the counting means,
The washing machine according to claim 5, wherein when the drainage determining means determines that the drainage operation is being performed, the washing operation is stopped after the drainage operation is completed. 7. The apparatus according to claim 1, wherein the control unit includes a prohibition unit that prohibits reception of a command by the operation key even if an operation key is pressed during the abnormality processing by the abnormality processing unit. Item 7. The washing machine according to any one of items 2 to 6. 8. An outer tub elastically supported in a machine frame, a washing and dewatering tub rotatably supported in the outer tub and containing laundry, and supplying water to the washing and dewatering tub. A water supply device, a drainage device that drains water from the outer tub, a water flow generation device that generates a water flow in the washing and dewatering tub, a motor that drives the washing and dehydration tub, the water flow generation device, a water supply device, Drainage device and a control unit that controls the drive of the motor, washing, rinsing, performing a washing operation including dehydration, as the rinse, operating the water supply device and the drainage device while rotating the washing and dewatering tub at low speed, In a washing machine that performs shower rinsing to remove detergent in the laundry by applying water to the laundry, when the shower rinsing is completed, the control unit waits for a predetermined time while operating the drainage device, and then performs dehydration. To do A washing machine characterized by rotating a washing and dewatering tub. 9. An outer tub elastically supported in a machine frame, a washing and dewatering tub rotatably supported in the outer tub and containing laundry, and supplying water to the washing and dewatering tub. A water supply device, a drainage device that drains water from the outer tub, a water flow generation device that generates a water flow in the washing and dewatering tub, a motor that drives the washing and dehydration tub, the water flow generation device, a water supply device, Drainage device and a control unit for controlling the drive of the motor, washing, rinsing, performing a washing operation including dehydration, as the rinse, after the water is collected in the washing and dewatering tub, the water flow generating device is operated. Rinsing with a water flow to remove the detergent content in the laundry, and operating the water supply device and the drainage device while rotating the washing and dewatering tub at a low speed to pour water on the laundry to wash the detergent content in the laundry. Remove the shower rinse and do selectively In the dehydration, after the washing and dehydration tub is first rotated for a certain time in a low-speed region,
In the washing machine which starts up to a high-speed steady rotation speed, the control unit is characterized in that in the dehydration after shower rinsing, the time for rotating the washing and dewatering tub in the low-speed region is longer than in the dehydration after pool rinsing. Washing machine. 10. The control unit according to claim 1, wherein the control unit rotates the washing and dewatering tub at a predetermined low rotation speed for a predetermined time before starting the rotation at the steady rotation speed. The washing machine according to claim 9, wherein the predetermined time is longer than when the washing is performed. 11. The control unit rotates the washing and dewatering tub at a low speed predetermined rotation speed for a predetermined time before starting up to the steady rotation speed, and further performs the predetermined rotation when shower rinsing is performed. The washing machine according to claim 9, wherein the rotating machine is rotated at a predetermined rotation number lower than the predetermined rotation number before rotating at a predetermined number. 12. A washing tub arranged in a machine frame and containing laundry, a water flow generating device for generating a water flow in the washing tub, a drive control of the water flow generating device, and a control of the water flow before the end of washing. A control unit for controlling the water flow generating device so as to generate a water flow for loosening the laundry when the loosening period is reached, comprising: a water flow operation unit for a user to manually set a water flow; The unit, when a water flow is set by the water flow operation unit, based on a change command from the water flow operation unit, controls the water flow generation device so that the set water flow is generated, and when the relaxation period starts, A washing machine that does not receive a change command of the water flow operation unit. 13. A washing tub which is disposed in a machine frame and stores laundry, a water flow generating device for generating a water flow in the washing tub, and a control unit for controlling the driving of the water flow generating device, comprising: A washing machine for rinsing, wherein a water flow operation unit for a user to manually set a water flow is provided, and when the water flow is set by the water flow operation unit, a change command from the water flow operation unit is provided. Based on the, while controlling the water flow generating device to generate a set water flow, if the rinsing is a water rinsing to perform rinsing while pouring into the washing tub, during the water rinsing, the water flow operation unit command. Washing machine characterized by not accepting.