JP2021029614A - Management device for washing machine, washing machine management system and program - Google Patents

Abstract

To automatically set operation contents of a washing machine corresponding to the preference of a user.SOLUTION: In a washing machine 1 that performs a washing operation on the basis of a control value, a questionnaire part 212 for displaying questionnaire question information related to a result of the washing operation on a display apparatus 302, and a control value change part 214 for receiving questionnaire reply information, which is a reply to the questionnaire question information, and changing the control value on the basis of the questionnaire reply information are provided in a management device for washing machine 201. The questionnaire question information includes, for example, a first question of whether or not there are concerns about stain removal. The control value change part 214 changes the control value so as to realize any of increasing a detergent amount, prolonging a time for washing, prolonging a time for dissolving a detergent, and prolonging a prewashing process when a reply to the first question is affirmative.SELECTED DRAWING: Figure 1

Description

The present invention relates to a washing machine management device, a washing machine management system and a program.

The following Patent Documents 1, 2 and 3 describe a washing machine that detects the state of tap water, detergent solution, dirt components, etc., and automatically sets the operation contents such as washing, rinsing, dehydration, and drying. There is.

Japanese Unexamined Patent Publication No. 2011-244885 Japanese Unexamined Patent Publication No. 2014-64791 JP-A-2018-175395

According to the techniques of Patent Documents 1, 2 and 3 described above, the operation content automatically set is the operation content that the manufacturer has determined in advance to be appropriate. However, there is a user's "preference" in the operation contents such as washing, rinsing, dehydration, and drying, and it is practically impossible to automatically set the operation contents that match the tastes of all users. Further, although individual operation contents such as washing, rinsing, dehydration, and drying can be manually set by the user, it is complicated for the user to manually set individual operation contents according to his / her own preference.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a washing machine management device, a washing machine management system, and a program capable of automatically setting the operation contents of the washing machine according to the preference of the user. And.

In order to solve the above problems, the washing machine management device of the present invention includes a questionnaire unit for displaying questionnaire question information regarding the result of the washing operation on a display device for a washing machine that performs a washing operation based on a control value, and the questionnaire. It is characterized by including a control value changing unit that receives questionnaire response information that is an answer to question information and changes the control value based on the questionnaire response information.

According to the present invention, the operation content of the washing machine can be automatically set according to the preference of the user.

It is a block diagram of the washing machine management system by one Embodiment of this invention. It is a perspective view which shows the external structure of the washing machine in this embodiment. It is a front view of the washing machine with the outer lid and the tank storage lid open. It is a perspective view of the washing machine seen from diagonally above front with the outer lid and the tank storage lid open. It is a schematic diagram which shows the internal structure of a washing machine. It is a perspective view which shows the state which the front panel of a washing machine is removed. It is a schematic diagram which shows the piping route of a washing machine. It is a schematic diagram which shows the outline of the function of a water quality sensor. It is a block diagram which shows the control circuit configuration of a washing machine. It is a process drawing explaining the operation process of a washing machine. It is a detailed flowchart of the main part of FIG. It is a detailed flowchart of the main part of FIG. It is a control sequence diagram of the operation which learns the preference of each performance of a user. It is a figure which shows various screens displayed on a smart phone. It is a figure which shows the relationship between the answer result of a questionnaire, and the amount of change of a point. It is a figure which shows the example of the conversion table stored in a server.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. It should be noted that each figure is merely schematically shown to the extent that the present invention can be fully understood. Therefore, the present invention is not limited to the illustrated examples. Further, in each figure, common components and similar components may be designated by the same reference numerals, and duplicate description thereof may be omitted.

<Washing machine management system>
FIG. 1 is a block diagram of a washing machine management system S according to an embodiment of the present invention.
The washing machine management system S includes a washing machine 1, a server 201 (a management device for a washing machine), a push notification server 202, and a smart phone 300 (a portable communication terminal). The washing machine 1 is provided in the user's house and includes a control device 100 and a communication unit 140.

The control device 100 includes an operation panel 14 and a microcomputer 110. Then, the control device 100 communicates with the server 201 via the communication unit 140, the router 204, and the Internet 200. When the smart phone 300 is outside the home, it communicates with the server 201 and the push notification server 202 via the communication carrier network 203. When the smart phone 300 is located in the house, it communicates with the push notification server 202 via the communication carrier network 203, and communicates with the server 201 or the communication unit 140 via the router 204.

The server 201 remotely controls the washing machine 1 and notifies the user's smart phone 300 of the remote control information via the push notification server 202. The communication carrier network 203 is a communication network operated by a communication carrier network such as an LTE / 3G network. The router 204 communicates with the washing machine 1 and the like by a protocol such as a wired LAN (Local Area Network), a wireless LAN, and Bluetooth (registered trademark).

The server 201, push notification server 202, and smartphone 300 are all general computers such as a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and an SSD (Solid State Drive). The SSD is equipped with the above hardware, and stores the OS (Operating System), application programs, various data, and the like. The OS and application programs are expanded in RAM and executed by the CPU.

In FIG. 1, the inside of the server 201 shows a function realized by an application program or the like of the server 201 as a block. That is, the server 201 includes a questionnaire unit 212 (questionnaire means) and a control value changing unit 214 (control value changing means). Details of these operations will be described later. Further, the smart phone 300 includes a display device 302 which is a flat panel display and a touch sensor 304 fixed to the display device 302.

<External configuration of washing machine 1>
Hereinafter, the external configuration of the washing machine 1 according to the present embodiment will be described with reference to FIGS. 2, 3, and 4. In the illustrated example, the washing machine 1 is a washer / dryer having a function of drying an object to be washed. In the following description, the object to be washed may be referred to as "clothing".
FIG. 2 is a perspective view showing an external configuration of the washing machine 1 in the present embodiment.
In FIG. 2, the washing machine 1 includes a housing 11, a top cover 12, an outer lid 13, an operation panel 14, a tank storage lid 15, and a front panel 16. The top cover 12, the outer lid 13, and the tank storage lid 15 are arranged at the rear portion of the upper surface, the center portion of the upper surface, and the front portion of the upper surface of the housing 11, respectively, and are rotatable with respect to the housing 11 at the rear end portions. It is pivotally supported. Further, an operation panel 14 for operating the washing machine 1 is provided on the upper surface of the outer lid 13.

A first charging section 31 is provided below the outer lid 13. The first charging unit 31 functions as a manual charging unit for the user to manually charge a washing treatment liquid such as a detergent or a softener (finishing agent) into the water tank 21 (see FIG. 4). Further, below the tank storage lid 15, a washing treatment liquid charging device 30 for automatically charging the washing treatment liquid into the water tank 21 is arranged.

FIG. 3 is a front view of the washing machine 1 with the outer lid 13 and the tank storage lid 15 open.
In FIG. 3, the washing treatment liquid charging device 30 includes a tank 42, and the tank 42 includes a tank 42a for detergent and a tank 42b for softener. Further, the upper end portions of the tanks 42a and 42b are opened upward, and the openings are referred to as charging portions 32a and 32b for detergents and softeners. Further, both may be collectively referred to as a second input unit 32. Further, the loading portions 32a and 32b are provided with loading port lids 43a and 43b which are configured to be openable and closable by the user. When the inlet lid 43a is closed, the detergent tank 42a is sealed, and when the inlet lid 43b is closed, the softener tank 42b is sealed. The inlet lids 43a and 43b may be collectively referred to as the inlet lid 43.

FIG. 4 is a perspective view of the washing machine 1 viewed from diagonally above and forward with the outer lid 13 and the tank storage lid 15 open.
As shown in FIG. 4, when the outer lid 13 of the washing machine 1 is opened, an opening 11a is formed inside the housing 11. Inside the opening 11a, a water tank 21 that functions as a washing / dehydrating tub into which the object to be washed is put is arranged. Further, the first charging portion 31 is arranged at the upper left front portion of the housing 11 and at a position outside the water tank 21. Further, the tank 42 is arranged at the upper front portion of the housing 11 and at a position in front of the first charging portion 31.

The tank 42 stores a plurality of washing treatment liquids. The washing treatment liquid charging device 30 measures the washing treatment liquid contained in the tank 42 and automatically charges an appropriate amount of the washing treatment liquid into the water tank 21. Therefore, the washing treatment liquid charging device 30 includes a transport pump 46 (see FIG. 6) that measures the washing treatment liquid and conveys it from the tank 42 to the water tank 21.

<Internal configuration of washing machine 1>
FIG. 5 is a schematic view showing the internal configuration of the washing machine 1.
As shown in FIG. 5, the washing machine 1 is provided with an outer tub 22 inside the housing 11, and further includes a water tub 21 inside the outer tub 22.
The outer tub 22 is provided with an outer tub cover 22a provided on the upper surface portion, a lid member 22b for sealing the opening provided on the outer tub cover 22a, and a bottom portion so as to be dropped more than other parts. It has a drop portion 22c and a drop portion 22c. The water tank 21 has a bottomed cylindrical shape with an open upper surface. The water tank 21 has a body plate 21a forming a cylindrical body portion, a rotary blade 21b rotating at the bottom of the water tank 21, and a balance ring 21c for maintaining the balance of the water tank 21. A plurality of through holes 21aa are formed in the body plate 21a for water passage and ventilation. Further, the balance ring 21c is a fluid balancer in which a fluid is sealed.

The washing machine 1 includes a drive device 23 for rotationally driving the water tank 21 and the rotor blades 21b, a rotation detection device 24 for detecting the operation of the drive device 23, and a motor current detection device 25. The drive device 23 includes a motor 23a that rotates the water tank 21 and the rotary blade 21b, a clutch mechanism 23b that defines the rotation mode (stirring, dehydration) of the water tank 21 and the rotary blade 21b, and a rotary shaft 23c connected to the rotary blade 21b. And have. The rotating shaft 23c is arranged at the center of the water tank 21 in the top view.

Further, the washing machine 1 has a water supply unit 20 for supplying water to the water tank 21, a drying unit 71 for heating air to obtain dry air, and a drying air for circulating in the upper rear part of the housing 11. It includes a fan 72, a ventilation duct 73, and a drying duct 81.

The blower duct 73 is arranged between the fan 72 and the blowout nozzle 74, and the drying unit 71 is arranged in the middle portion thereof. The blower duct 73 is connected to the blowout nozzle 74 by a bellows tube 73a. The blowing nozzle 74 blows out the drying air sent by the fan 72 and heated by the drying unit 71 into the outer tank 22. The drying duct 81 is arranged between the outer tank 22 and the fan 72. The drying duct 81 is connected to the drop portion 22c of the outer tank 22 by a bellows pipe 81a, and has a dehumidifying mechanism inside.

In the above configuration, the washing machine 1 supplies water from the water supply unit 20 to the outer tub 22 so that the water tub 21 is immersed in water during, for example, a washing step or a rinsing step. Further, for example, in the drying process, the washing machine 1 rotates the fan 72 to send air to the air blowing duct 73, heats the air in the drying unit 71 to obtain the drying air, and sends the drying air to the outer tank 22 and the water tank. It passes through the inside of 21. As a result, the washing machine 1 dries the object to be washed housed inside the water tank 21. Then, the washing machine 1 sends the air that has passed through the insides of the outer tub 22 and the water tub 21 from the drying duct 81 to the air duct 73 by the fan 72, and repeats the same operation.

Further, as shown in FIG. 5, the washing machine 1 includes a water injection hose 51a, a charging hose 54a, and a washing hose 61a. The water injection hose 51a is a hose for flowing water from the water supply unit 20 to the outer tank 22. The charging hose 54a is a hose that allows water to flow from the first charging section 31 to the outer tank 22. The cleaning hose 61a is a hose that allows water to flow from the water supply unit 20 to the outer tank 22 when cleaning the water tank 21 or the outer tank 22. The water injection hose 51a constitutes a part of the first water supply path 51 (see FIG. 7) described later. The charging hose 54a constitutes a part of the charging path 54 (see FIG. 7) described later. The cleaning hose 61a constitutes a part of the first cleaning path 61 (see FIG. 7) described later.

Further, the washing machine 1 includes a discharge path 63 for discharging water and a drain valve 65 for opening and closing the discharge path 63.
Further, the washing machine 1 includes a case 41 for accommodating the tank 42 in the front upper part of the housing 11. The tank 42 has a structure that can be freely removed and attached to the case 41 by moving it in the vertical direction. The case 41 preferably has a structure that accommodates at least two or more tanks 42 for the detergent and the softener so that the detergent and the softener can be automatically charged into the water tank 21.

FIG. 6 is a perspective view showing a state in which the front panel of the washing machine 1 is removed.
As shown in FIG. 6, the case 41 has a horizontally long rectangular shape in the front view shape and a vertically long rectangular shape in the side view shape. Therefore, the case 41 has a substantially rectangular parallelepiped shape whose overall shape is thin in the depth direction. The case 41 is arranged so as to extend in the vertical direction along the inner wall surface of the front panel 16 (see FIG. 2). A transfer pump 46 is arranged below the case 41.

Returning to FIG. 5, a vibration damping member 45 that suppresses vibration of the washing treatment liquid is mounted between the case 41 and the water tank 21. The vibration damping member 45 may be mounted on the tank 42, or may be mounted on both the case 41 and the tank 42. By providing the vibration damping member 45 in this way, it is possible to suppress a situation in which the washing treatment liquid contained in the tank 42 sways and jumps.

Further, the case 41 is attached to the front upper part of the housing 11, and is arranged so as to be sandwiched between the inner wall surface of the front panel 16 and the housing 11. Therefore, the washing machine 1 can suppress the shaking of the washing treatment liquid contained in the tank 42 even if the vibration damping member 45 is not provided. Therefore, the vibration damping member 45 can be omitted. However, by providing the vibration damping member 45, the washing machine 1 can more efficiently suppress the shaking of the washing treatment liquid contained in the tank 42 as compared with the case where the vibration damping member 45 is not provided.

Further, the second charging portion 32 and the tank 42 of the washing treatment liquid charging device 30 are arranged in front of the center of the water tank 21 (for example, the rotating shaft 23c). Further, the drying unit 71 is arranged behind the center of the water tank 21 so as to be separated from the second charging portion 32 and the tank 42. The outer tub 22 is provided with a pneumatic chamber 29, and a water level sensor 28 for detecting the water level of the washing water stored in the outer tub 22 is provided above the pneumatic chamber 29.

The air duct 73 is provided with a temperature sensor 26a that detects the temperature of the air blown into the water tank 21 during the drying operation. Further, the drop portion 22c of the outer tub 22 is provided with a temperature sensor 26b that detects the temperature of the washing water and the temperature of the air sucked into the drying duct 81 during the drying operation. Further, a temperature sensor 26c is provided between the drop portion 22c and the drain valve 65. The temperature sensor 26b detects the temperature of the washing water, the temperature of the cooling water discharged to the outside of the machine from the discharge path 63 during the drying operation, and the like. Further, an acceleration sensor 27 for detecting the vibration acceleration due to the vibration of the outer tank 22 is provided on the upper part of the side surface of the outer tank 22. The signals detected by the water level sensor 28, the temperature sensors 26a, 26b, 26c, and the acceleration sensor 27 are transmitted to the control device 100.

The water quality sensor 35 detects the conductivity of the washing liquid during tap water before washing or washing (washing, rinsing, dehydrating), and is arranged on the outer peripheral edge of the bottom wall portion 22d of the outer tub 22. Further, the water quality sensor 35 includes a base made of synthetic resin (not shown) and a pair of electrodes 36A and 36B (see FIG. 8). Further, the water quality sensor 35 is formed with a groove portion extending along the radial direction (normal direction) of the outer tank 22 (not shown). The surface from the peripheral wall portion 22e of the outer tank 22 to the bottom wall portion 22d of the outer tank 22 through the groove portion of the water quality sensor 35 is configured to be a substantially continuous surface. For example, in the dehydration step during the washing operation, a part of the rinse water discharged from the through hole 21aa of the water tank 21 to the outer tank 22 flows down along the peripheral wall portion 22e of the outer tank 22, and the groove portion of the water quality sensor 35 is outside. It flows through the bottom wall portion 22d of the tank 22.

<Structure of piping path of washing machine 1>
FIG. 7 is a schematic view showing a piping route of the washing machine 1.
As shown in FIG. 7, the washing machine 1 includes a first water supply path 51, a second water supply path 52, a transport path 53, and an input path 54 as piping paths used when washing the object to be washed. ing.
The first water supply path 51 connects the water supply unit 20 and the first input unit 31, and supplies water from the water supply unit 20 to the first input unit 31.
The second water supply path 52 connects the intermediate portion of the first water supply path 51 and the transfer path 53, and supplies water from the water supply unit 20 to the transfer path 53 via the first water supply path 51.
The transport path 53 connects the tank 42 and the first charging section 31, and transports the washing treatment liquid discharged from the tank 42 via the transport pump 46.
The charging path 54 connects the first charging section 31 and the water tank 21 (outer tank 22), and the washing treatment liquid and water are charged from the first charging section 31 into the water tank 21.

A switching valve 64 for switching the flow is arranged at the connection point between the second water supply path 52 and the transport path 53. The switching valve 64 selectively switches to either "the direction in which the washing treatment liquid flows from the tank 42 to the transport path 53" or "the direction in which water flows from the second water supply path 52 to the transport path 53". Further, a transfer pump 46 and check valves 47a and 47b for preventing backflow of fluid are arranged on the transfer path 53. The check valves 47a and 47b are arranged on the upstream side (tank 42 side) and the downstream side (first input section 31 side) of the transfer pump 46, respectively. Further, the washing machine 1 includes a first washing path 61, a second washing path 62, and a discharge path 63 as piping paths used when washing the water tank 21, the outer tub 22, the case 41, and the like. The first cleaning path 61 connects the water supply unit 20 and the first input unit 31, and supplies water for cleaning from the water supply unit 20 to the first input unit 31.

The second cleaning path 62 connects the intermediate portion of the first cleaning path 61 with the case 41, and supplies cleaning water from the water supply unit 20 to the case 41 via the first cleaning path 61. The discharge path 63 connects the case 41 and the drain port 66, and drains water from the case 41. The drainage path 63 includes a drainage pipe 63a connecting the case 41 and the drying duct 81, a drainage pipe 63b connecting the drying duct 81 and the outer tank 22, and a drainage valve 65 and a drainage port 66 provided in the outer tank 22. It is provided with a drainage pipe 63c for connecting to and. The outer tank 22 is provided with a drain valve 65. By opening the drain valve 65, the washing machine 1 discharges the washing treatment liquid and water from the drain port 66 to the outside via the drain pipe 63c.

The washing machine 1 transfers the washing treatment liquid contained in the tank 42 to the water tank 21 via the transport path 53 when the washing treatment liquid is automatically charged (that is, when the washing treatment liquid is charged into the water tank 21 by the washing treatment liquid charging device 30). Is conveyed to the first input section 31. Then, the washing machine 1 can charge the conveyed washing treatment liquid from the first charging unit 31 into the water tank 21 through the charging path 54. Therefore, in the washing machine 1, the washing treatment liquid passes through the first charging unit 31 regardless of whether it is manually charged or automatically charged. Therefore, by passing water through the first charging unit 31, the amount of water used when the detergent is charged. Can be reduced.

As described above, the washing machine 1 conveys the washing treatment liquid contained in the tank 42 from the tank 42 to the first charging unit 31 through the conveying path 53. At that time, although a part of the washing treatment liquid remains in the transport path 53, the washing treatment liquid remaining in the transport path 53 is transported to the first charging unit 31 by the water supplied from the second water supply path 52. be able to. Further, the second water supply path 52 is connected to an intermediate portion of the first water supply path 51. Therefore, even if the transport path 53 is blocked and an unintended pressure is applied to the transport path 53, the washing machine 1 applies the pressure applied to the transport path 53 to the first water supply path 51. It can be released to the outside (water tank 21 side) through. Therefore, the washing machine 1 can reduce the pressure applied to the transport path 53 even when such a phenomenon occurs. As a result, the washing machine 1 can maintain the performance of the transport path 53 for a relatively long time.

Further, the washing machine 1 can wash the first charging section 31 by flowing washing water from the water supply unit 20 to the first charging section 31 along the first washing path 61. Further, the washing machine 1 can wash the case 41 by flowing washing water from the water supply unit 20 to the case 41 along the second washing path 62. The bottom of the case 41 is provided with, for example, a nozzle (not shown) that fits in the lower part of the tank 42. According to the present embodiment, the nozzle can be cleaned together with the case 41.
Further, the washing machine 1 discharges the washing water supplied to the first washing path 61 to the water tank 21 along the charging path 54, and discharges the washing water supplied to the second washing path 62 to the drain pipe. It can be discharged to the water tank 21 along 63a (via the drying duct 81). Therefore, the washing machine 1 can wash the water tub 21 and the outer tub 22.

<Circuit configuration of washing machine 1>
FIG. 8 is a schematic diagram showing an outline of the functions of the water quality sensor 35.
As shown in FIG. 8, the water quality sensor 35 includes a pair of electrodes 36A and 36B, coils 38a and 39a, and an oscillation circuit 39. Here, the pair of electrodes 36A and 36B are connected to the coil 38a, and the resonance circuit 38 is formed by these. The coil 38a is magnetically coupled to the coil 39a, and the coil 39a is connected to the oscillation circuit 39. The oscillation circuit 39 transmits a signal corresponding to the conductivity between the electrodes 36A and 36B to the microcomputer (hereinafter referred to as a microcomputer) 110 of the control device 100. A capacitor, which is a component, is provided inside the oscillation circuit 39 (not shown). The characteristics of the water quality sensor 35 change depending on the capacitance of this capacitor, and the resistance value region of the water quality that makes it easier to read changes.

FIG. 9 is a block diagram showing a control circuit configuration of the washing machine 1.
In FIG. 9, the control device 100 includes a microcomputer 110 and drive circuits 129a to 129i. The microcomputer 110 includes a storage unit 111, a process control unit 112, a rotation speed calculation unit 113, a clothes weight calculation unit 114, a conductivity measurement unit 115, a detergent amount / washing time determination unit 116, and a detergent state determination unit. It includes 117, a foaming determination unit 118, and a washing treatment liquid injection determination unit 119.

Here, the microcomputer 110 is a general computer such as a CPU (Central Processing Unit), a DSP (Digital Signal Processor), a RAM (Random Access Memory), a ROM (Read Only Memory), and an EEPROM (Electrically Erasable Programmable Read-Only Memory). In the ROM and EEPROM, a control program executed by the CPU, a microprogram executed by the DSP, various data, and the like are stored. In FIG. 9, the inside of the microcomputer 110 shows the functions realized by the control program, the micro program, and the like as blocks.

That is, the microcomputer 110 includes a storage unit 111, a process control unit 112, a rotation speed calculation unit 113, a clothes weight calculation unit 114, a conductivity measurement unit 115, a detergent amount / washing time determination unit 116, and a detergent state. A determination unit 117, a foam determination unit 118, and a washing treatment liquid injection determination unit 119 are provided. The microcomputer 110 is connected to the operation panel 14. The operation panel 14 includes an LED 14a for displaying various information to the user and an operation switch 14b operated by the user. As a result, the microcomputer 110 controls the operating state of the washing machine 1 based on the user's operation instruction by the operation panel 14.

Further, the microcomputer 110 controls the communication unit 140 connected to the router 204 (see FIG. 1) of the home network, and receives an operation instruction from the remote control service of the server 201. Thereby, the microcomputer 110 can control the washing machine 1 based on both the operation by the operation panel 14 of the washing machine 1 and the remote control from the server 201. The storage unit 111 is composed of the above-mentioned RAM, ROM, EEPROM, etc., and stores a program executed by the microcomputer 110, various data, and the like. In particular, the storage unit 111 stores driving patterns in various driving courses. When the operation course is specified from the operation panel 14 or the like, the microcomputer 110 reads out the operation pattern corresponding to the operation course from the storage unit 111. This operation pattern defines the contents of the washing process, the rinsing process, the dehydration process, and the drying process.

The process control unit 112 controls each unit of the washing machine 1 based on the contents of each process described above. For example, the process control unit 112 drives and controls the water supply unit 20 via the drive circuit 129a, and drives and controls the drain valve 65 via the drive circuit 129b. Further, the process control unit 112 drives and controls the switching valve 64 via the drive circuit 129c, drives and controls the motor 23a of the drive device 23 via the drive circuit 129e for the motor, and via the drive circuit 129f for the clutch. The clutch mechanism 23b is switched to control the drive circuit 129g for the heater switch. As a result, the process control unit 112 controls the energization of the drying unit 71 (referred to as “heater” in the drawing), controls the fan 72 via the drive circuit 129h for the fan, and drives the drive circuit 129i for the transfer pump. It has a function of driving and controlling the transfer pump 46 via the above.

The rotation speed calculation unit 113 has a function of calculating the rotation speed of the motor 23a based on the detection value from the rotation detection device 24 (see FIG. 5).
The clothes weight calculation unit 114 has a function of calculating the weight of clothes, that is, the object to be washed in the water tank 21, based on the rotation speed calculated by the rotation speed calculation unit 113 and the detection value of the motor current detection device 25. Have. When the weight of the object to be washed increases, the load for rotating the water tank 21 increases, and it becomes necessary to increase the motor current flowing through the motor 23a. Therefore, the weight of the object to be washed can be calculated based on the motor current and the rotation speed of the motor 23a.
The conductivity measuring unit 115 has a function of measuring the conductivity of tap water or washing liquid by using the value detected from the water quality sensor 35.
The detergent amount / washing time determination unit 116 has a function of determining the detergent amount and the washing time of clothes based on the conductivity and the like measured by the conductivity measuring unit 115, and the details will be described later.

The detergent state determination unit 117 has a function of determining the state of the detergent based on the conductivity and the like measured by the conductivity measuring unit 115, and the details will be described later.
The foaming determination unit 118 has a function of determining the washing time, the amount of water, and the motor rotation speed based on the state of the washing liquid determined by the conductivity measuring unit 115 and the detergent state determining unit 117, and the details will be described later. ..
The washing treatment liquid charging determination unit 119 has a function of controlling the charging of the washing treatment liquid. More specifically, the washing treatment liquid input determination unit 119 controls the transfer pump 46 by the drive circuit 129i for the transfer pump based on the amount of detergent determined by the detergent amount / wash time determination unit 116.

<Process control of washing machine 1>
FIG. 10 is a process diagram illustrating a series of operation steps in the washing operation (washing, rinsing, dehydration, etc.) of the washing machine 1.
First, when the power of the washing machine 1 is turned on by the user, the process proceeds to step S0. Here, the microcomputer 110 controls the communication unit 140 (see FIG. 1) and communicates with the server 201 via the router 204 of the home network. At this time, information such as control values stored in the server 201 is received and stored in the storage unit 111. Further, in step S0, the process control unit 112 receives the selection of the operation course by the user and the input of the washing treatment liquid input setting (ON / OFF).

Next, in step S1, the user puts the laundry to be washed into the water tank 21. When the user operates the operation panel 14 to give an operation start instruction, the process control unit 112 (see FIG. 9) rotates the rotary blade 21b (see FIG. 5). Further, the clothing weight calculation unit 114 of the microcomputer 110 calculates the amount of cloth for the clothing before water supply.
Next, in step S2, the process control unit 112 discharges tap water into the outer tank 22. Air may be contained in a hose (not shown) connected to the water supply unit 20. Therefore, the process control unit 112 discharges the compressed air together with the tap water into the outer tank 22.

In step S3, the detergent amount / washing time determination unit 116 calculates the amount of detergent to be added and the time required to complete washing based on the amount of cloth for clothes, the temperature of tap water, and the hardness of water. Then, the result is displayed on the operation panel 14. Here, since the water temperature and the hardness of the tap water were detected during the previous rinsing operation (step S30 described later) and stored in the storage unit 111, the stored contents are applied. Since the water temperature and hardness of tap water do not change suddenly every day but change slowly, it is possible to determine the amount of detergent using the water temperature and water hardness of tap water measured at the time of the previous washing. Is. When the washing machine 1 is installed and operated for the first time, it is preferable to use initial values (for example, water temperature 15 ° C., hardness 120 ppm) that do not significantly deteriorate the washing performance.
Further, in step S3, the transport pump 46 is controlled by the drive circuit 129i based on the amount of detergent determined by the detergent amount / washing time determination unit 116 only when the setting of the washing treatment liquid injection is ON in step S0. Then, the washing treatment liquid is supplied to the first charging section 31 through the transport path 53.

In step S4, first, the process control unit 112 opens the water supply unit 20 to supply detergent and water to the first charging unit 31 and the outer tank 22. Here, when the water level reaches a predetermined position, the process control unit 112 closes the water supply unit 20. Further, when water is supplied to the first input unit 31, since it is branched into the first water supply path 51 and the second water supply path 52, the washing treatment liquid remaining in the transfer path 53 can be conveyed to the first input unit 31. it can.
In step S5, the process control unit 112 measures the temperature of the supplied water containing the detergent by the temperature sensor 26b (or the temperature sensor 26c). Next, the process control unit 112 measures the conductivity with the water quality sensor 35 after executing the mixing step of homogenizing the detergent and water. Next, the process control unit 112 determines the detergent melting time based on the water temperature and conductivity of tap water. The details will be described later.

In step S6, the process control unit 112 drives the motor 23a for the detergent melting time determined in step S5 to rotate the water tank 21 and the rotor blade 21b, and uses the generated water flow to dissolve the detergent to achieve a high concentration. Produces a detergent solution. The method for producing the high-concentration detergent solution is not limited to the method in which both the water tank 21 and the rotary blade 21b are rotated, but only the rotary blade 21b is rotated or the circulation pump (not shown) is rotated in the reverse direction. It may be the method used.

In step S7, the conductivity measuring unit 115 measures the conductivity of the generated detergent solution with the water quality sensor 35, and the detergent state determination unit 117 reviews the determined detergent type, and the detergent actually added. Determine the concentration of. Since the generated detergent solution dissolves the detergent in a constant amount of water, a change in the concentration of the detergent can be detected as a change in conductivity. When the amount of detergent added is large (the concentration of detergent is high), the conductivity is higher than when the amount of detergent added is small (the concentration of detergent is low). Therefore, even if the foaming determination unit 118 determines that the rinsing operation is once, it is possible to change the rinsing operation to two times when the amount of detergent added is large. In this step S7, in order to improve the measurement accuracy of the conductivity, the water tank 21 and the rotor blade 21b that were rotating to dissolve the detergent are temporarily stopped, and then the rotation is restarted in the next step S8. .. Therefore, if this step S7 is skipped, the total operation time can be further shortened.

In step S8, the process control unit 112 supplies water from the water supply unit 20 to a water amount (water level) smaller than the water amount in the subsequent main washing steps (S13 to S19) while rotating the water tank 21 and the rotary blade 21b. Further, since water is supplied to the first input unit 31 at the same time, the transport path 53 can be washed at the same time with the water branched to the first water supply path 51 and the second water supply path 52.

In step S9, the pre-washing step is executed. That is, the process control unit 112 washes clothes in a state where the amount of water is smaller than the amount of water in the subsequent main washing steps (S13 to S19), that is, with a high-concentration detergent solution. Hereinafter, the operation of infiltrating the clothes with a high-concentration detergent solution while rotating the rotary blade 21b by the drive device 23 in a state where the water level is lower than that of the main washing step is referred to as high-concentration washing. Although the high-concentration cleaning step in the present embodiment is operated at a constant water level without supplying water, it may be operated while supplying water. However, a process performed in a separate step (discontinuously) before the water level reaches a predetermined level, such as the detergent melting operation in step S6, is not included in the high-concentration cleaning step.

Further, in the present embodiment, in the case of the liquid detergent and the liquid detergent (concentrated), high-concentration cleaning is performed while rotating the motor (rotary blade 21b) at a higher rotation speed than in the case of the powder detergent. As a result, it is possible to suppress foaming when a powder detergent is used at the time of high-concentration washing where foaming is likely to occur, and to further enhance the cleaning power when a liquid detergent is used.
Further, in the present embodiment, the operation time of the high-concentration washing step, which was conventionally about 30 seconds, is set to about 2 minutes and 30 seconds. In this way, by prolonging the operation time of the high-concentration washing step, it is possible to effectively remove oil stains on food. On the other hand, it is also necessary to consider the need for "shortening the time" to shorten the overall washing time. Therefore, it is desirable to lengthen the operation time of the high-concentration washing process and shorten the operation time of the main washing process.

In step S10, first, the clothing weight calculation unit 114 calculates the weight of the clothing containing water. Then, the cloth quality (water absorption) of the clothes is determined from the weight of the clothes containing water calculated in step S1 and the weight of the clothes containing water calculated in step S10. The following steps are controlled according to the fabric quality of the identified clothing.

In step S11, the process control unit 112 acquires the water temperature before the washing process. This is because when the water temperature is high, the chemical action of the detergent is improved, the detergency is improved, and the washing time can be shortened. By measuring the water temperature before the washing process, for example, accurate water temperature can be detected even during washing using the remaining hot water in the bath, and the washing time can be changed. When the measured water temperature is high or the water hardness is low, the washing time can be shortened by skipping steps S18 and S19 described later.
In this way, the ease of foaming during the washing process is controlled (shortened or extended) by measuring the conductivity of the washing liquid using the water quality sensor 35 and controlling the foaming determination unit 118. Becomes possible. The storage unit 111 stores in advance a table for determining the washing time (shortened or extended time) according to the degree of dirt. A plurality of threshold values may be set according to the amount of cloth calculated in step S1.

In step S12, the process control unit 112 supplies water to the water tank 21 to a predetermined set water level. In step S13, the process control unit 112 performs the first main wash, and then measures the conductivity of water. Let d1 be the degree of dirtiness at this point based on the measured conductivity. In step S14, the process control unit 112 performs the first "unraveling", and then measures the conductivity of water. Let d2 be the degree of contamination at this point based on the measured conductivity. Similar to steps S13 and S14, in steps S15 and S16, the process control unit 112 executes the second main washing and "unraveling". The degree of contamination in each is d3 and d4. In steps S17 and S18, the process control unit 112 executes the third main washing and "unraveling". The degree of dirt in each is d5 and d6. In step S19, the process control unit 112 executes the fourth main wash. The degree of dirt at that time is d7.

In step S20, the process control unit 112 monitors the unbalanced state of the clothes and determines whether or not to shift to dehydration.
In step S21, the process control unit 112 opens the drain valve 65 to drain the wash water in the outer tank 22.
In step S22, the process control unit 112 rotates the water tank 21 to dehydrate the water contained in the clothes.
In step S23, the process control unit 112 closes the drain valve 65, opens the water supply unit 20, and supplies rinse water to the water tank 21. Then, while rotating the water tank 21, rinse water is sprayed on the clothes in the water tank 21.
In step S24, the process control unit 112 closes the water supply unit 20 while rotating the water tank 21 to dehydrate the rinse water from the clothes.
In step S25, the process control unit 112 closes the drain valve 65, opens the water supply unit 20, and supplies rinse water to the water tank 21. Then, while rotating the water tank 21, rinse water is sprayed on the clothes in the water tank 21.

In step S26, the process control unit 112 closes the water supply unit 20, stops the water tank 21, opens the drain valve 65, and drains the rinse water in the outer tank 22.
In step S27, the process control unit 112 rotates the water tank 21 to dehydrate the water contained in the clothes.
Execution of the rotary shower rinse in steps S23 and S25 is determined by the foaming determination unit 118. When the foaming determination unit 118 determines that the number of rotary shower rinses is one, the foam determination unit 118 transmits a command to skip from step S23 to step S27 to the process control unit 112 to set the number of rotary shower rinses to one. It is possible.

In step S28, when dehydration is normally completed, there is no water in the outer tank 22, and the water quality sensor 35 is operated to measure the conductivity without water. The conductivity measured here is stored in the storage unit 111 as an initial value, and can be used for determining a failure of the water quality sensor 35 and correcting a secular change due to dirt adhesion to the electrode unit.
In step S29, the process control unit 112 closes the drain valve 65, opens the water supply unit 20, and supplies the rinse water to the outer tank 22 to the water level at which the water hardness is detected.

In step S30, the conductivity measuring unit 115 operates the water quality sensor 35 and the temperature sensor 26b (or the temperature sensor 26c) to measure the water temperature and conductivity of the rinse water and calculate the hardness of the water. The water temperature and water hardness measured here are stored in the storage unit 111 and used for determining the amount of detergent and the washing time next time.
Further, in step S30, the process control unit 112 supplies the washing treatment liquid to the water tank 21 only when the setting for charging the washing treatment liquid is ON in step S0. That is, in step S30, the process control unit 112 measures the water temperature and conductivity of the rinse water to calculate the hardness of the water, and then drives the process control unit 112 based on the amount of the finishing agent determined by the detergent amount / washing time determination unit 116. The transfer pump 46 is controlled by the circuit 129i. As a result, the finishing agent is supplied to the first charging unit 31 via the transport path 53.

In step S31, the process control unit 112 supplies water to the set water level.
In step S32, the process control unit 112 opens the water supply unit 20 while rotating the rotary blade 21b (or the water tank 21) in a state where the rinse water is stored in the outer tank 22 to stir the clothes, and opens the water tank. The finishing agent is added to 21. At the same time, water is supplied to the first input unit 31 at the same time, so that the water is branched into the first water supply path 51 and the second water supply path 52. As a result, the washing treatment liquid remaining in the transport path 53 can be transported to the first charging unit 31.

In step S33, the process control unit 112 executes the first rinsing agitation after the finishing agent is added, and then measures the conductivity of water. As shown in FIG. 5, since the water quality sensor 35 in the present embodiment is provided at the lower part (bottom) of the outer tank 22, the water quality sensor 35 is submerged during the rinsing process. The conductivity of rinse water can be measured. Let s1 be the degree of rinsing at this point based on the measured conductivity.
In steps S34 and S35, the process control unit 112 similarly executes the second and third rinse stirrings after the finishing agent is added. Let the rinsing degree at each time point be s2 and s3.

In this way, the rinsing time can be controlled (shortened or extended) by measuring the conductivity of the rinsing water using the water quality sensor 35 during the rinsing process. More specifically, the storage unit 111 stores in advance a table for determining the rinsing time (shortening or extending time) from the amount of change in the conductivity of the rinsing water. Further, the amount of change in the conductivity of the rinse water may be determined by comparing with the conductivity of tap water measured in step S30. Further, the amount of change in the conductivity of the rinse water can be used not only for shortening / extending the rinse time but also for increasing / decreasing the number of rinses. Therefore, the detergent state determination unit 117 may perform the rinsing operation once. Further, even if the foaming determination unit 118 determines that "the detergent is a concentrated type liquid detergent" and determines that the rinsing operation is one time, if it is determined that the rinsing operation is insufficient, an additional rinsing operation is executed. It is possible to do. Further, the timing at which the water quality sensor 35 is operated during the rinsing step is not limited to the execution of steps S33 to S35, and the water quality sensor 35 is operated at the time of execution of the above-mentioned steps S23, S25, etc. to control (shorten or shorten) the rinsing time. May be extended). Further, the process control unit 112 may control (shorten or extend) the rinsing time in step S23 or S25 depending on the cloth quality of the clothes determined in step S10.

In step S36, the process control unit 112 monitors the unbalanced state of the clothes and determines whether or not to shift to the final dehydration.
In step S37, the process control unit 112 opens the drain valve 65 to drain the rinse water in the outer tank 22. Further, in order to stabilize the start-up during dehydration, the process may proceed to step S38 (dehydration step) with a certain amount of rinse water remaining.
In step S38, the process control unit 112 rotates the water tank 21 at high speed to dehydrate the water contained in the clothes. Further, by measuring the water dehydrated from the clothes using the water quality sensor 35, it is possible to determine the amount of water contained in the laundry. When the water tank 21 rotates during the dehydration step, the water contained in the laundry is separated from the laundry and discharged from the through hole 21aa of the water tank 21 toward the inner surface of the peripheral wall portion 22e of the outer tank 22. The water discharged to the peripheral wall portion 22e flows down the inner surface of the peripheral wall portion 22e by the action of gravity and flows into the groove portion of the water quality sensor 35. As a result, the water quality sensor 35 can detect the conductivity of water during dehydration.

That is, in the water quality sensor 35 at the time of dehydration, the detected value (conductivity) changes according to the amount of water passing through by flowing water into the groove of the water quality sensor 35. For example, when the laundry has high water absorption such as a bath towel, the amount of water discharged is large and the detected value (conductivity) is high. On the other hand, for example, when the laundry has low water absorption such as a shirt, the amount of water discharged is small and the detected value (conductivity) is low.
In this way, the dehydration time can be controlled (shortened or extended) by measuring the conductivity of the water dehydrated from the clothes measured by using the water quality sensor 35 during the dehydration step. The storage unit 111 stores in advance a table for determining the dehydration time (shortening or extending time). A plurality of threshold values may be set according to the amount of cloth calculated in step S1.

The timing of operating the water quality sensor 35 during the dehydration step is not limited to step S38, and may be operated in other dehydration steps (steps S22, S24, S27). Further, the dehydration time may be controlled (shortened or extended) according to the detection result of the water quality sensor 35.
In step S39, the process control unit 112 rotates the fan 72 via the drive circuit 129h to send air to the air blowing duct 73, heats the air with the drying unit (heater) 71 to obtain dry air, and obtains dry air. Passes through the inside of the outer tank 22 and the water tank 21. As a result, the washing machine 1 dries the object to be washed (cloth) housed inside the water tank 21. Then, the washing machine 1 can send the air that has passed through the inside of the outer tub 22 and the water tub 21 from the drying duct 81 to the air duct 73 by the fan 72, and repeat the same operation.

In step S40, the process control unit 112 rotates the fan 72 via the drive circuit 129h to send air to the air duct 73, and allows the dry air to pass through the outer tank 22 and the inside of the water tank 21. Before the execution of step S40, the object to be washed (cloth) inside the water tank 21 was in a dry and high temperature state. By executing step S40, the washing machine 1 can lower the temperature of the washing object (cloth) housed inside the water tank 21. Then, the washing machine 1 can send the air that has passed through the inside of the outer tub 22 and the water tub 21 from the drying duct 81 to the air duct 73 by the fan 72, and repeat the same operation.
In step S99, the microcomputer 110 controls the communication unit 140 and connects to the server 201 via the router 204 of the home network. At this time, the information stored in the microcomputer 110 is transmitted to the server 201, and the server 201 receives the information. Then, the microcomputer 110 turns off the power of the washing machine 1.

<Details of step S5>
FIG. 11 is a detailed flowchart of step S5 described above.
When the process proceeds to step S51 in FIG. 11, the process control unit 112 measures the temperature (water temperature) of the water containing the supplied detergent by the temperature sensor 26b (or the temperature sensor 26c). Next, when the process proceeds to step S52, the detergent state determination unit 117 determines the detergent state. More specifically, the detergent state determination unit 117 determines whether the type of detergent is a liquid detergent or a powder detergent. The detergent state determination will be described later with reference to FIG.

Next, in step S53, it is determined whether or not the measured water temperature is higher than the predetermined threshold value t1. Here, if it is determined that "Yes" (water temperature> t1), the process proceeds to step S54, and if it is determined that "No" (water temperature ≤ t1), the process proceeds to step S55. Here, since it was experimentally found that the degree of dissolution of the detergent changes significantly at about 10 ° C., in the present embodiment, 13 ° C., which is slightly higher than 10 ° C., is set as the threshold value t1 in consideration of variation.

In step S54, it is determined whether or not the detergent is a liquid detergent based on the processing result of step S52 described above. If "Yes" (liquid detergent) is determined here, the process proceeds to step S56, and the detergent melting time is set to a predetermined value T0. If "No" (not a liquid detergent) is determined in step S54, the process proceeds to step S57, and the detergent melting time is set to a predetermined value T1. Similarly, in step S55, it is determined whether or not the detergent is a liquid detergent. If "Yes" (liquid detergent) is determined here, the process proceeds to step S58, and the detergent melting time is set to a predetermined value T2. If "No" (not a liquid detergent) is determined in step S55, the process proceeds to step S59, and the detergent melting time is set to a predetermined value T3.

Considering the solubility of the liquid detergent and the powder detergent in water, it is preferable to make the detergent dissolution time T1 longer than the detergent dissolution time T0 and the detergent dissolution time T3 longer than the detergent dissolution time T2. Further, since the detergent is less likely to dissolve in water when the water temperature is lower, it is preferable to make the detergent dissolving time T2 longer than the detergent dissolving time T0 and the detergent dissolving time T3 longer than the detergent dissolving time T1.
Further, when the washing treatment liquid charging setting is turned ON in step S0, the detergent charged into the outer tub 22 is a liquid detergent, so that step S56 or S58 is executed. In steps S56 or S58, the rotational speed of the motor 23a or the operation of the circulation pump (not shown) can be suppressed to reduce energy consumption.

However, if the powder detergent is charged into the first charging unit 31 due to an erroneous operation by the user, the determination in steps S54 and S55 is forcibly set to "No" by performing a predetermined operation on the operation panel 14. can do. Thereby, in step S57 or S59, the detergent melting time can be set to T1 or T3.
As described above, according to the present embodiment, the detergent dissolving time T0 to T3 can be set according to the type of detergent and the water temperature, and the detergent dissolving time is shortened when liquid washing is used or when the water temperature is high. By doing so, it is possible to shorten the overall operation time.

<Details of step S52>
FIG. 12 is a detailed flowchart of step S52 described above.
When the process proceeds to step S520 in FIG. 12, the process control unit 112 controls the motor 23a via the drive circuit 129e to rotate the water tank 21 and the rotor blade 21b. As a result, a water flow is generated in the detergent and water supplied to the outer tank 22 and the water tank 21, and the detergent and water become uniform. Here, when the detergent is a powder detergent, it is difficult to make the detergent and water uniform, so the process control unit 112 sets the rotation speed of the motor 23a high. On the other hand, when the detergent is a liquid detergent, the detergent and water are easily made uniform, so that the process control unit 112 sets the rotation speed of the motor 23a lower than that in the case of the powder detergent.

Further, in step S520, the detergent and water are made uniform by the rotation of the water tank 21 and the rotary blade 21b, but the water tank 21 may be fixed and the rotary blade 21b may be rotated, and a circulation pump (not shown) may be used. The detergent and water may be homogenized.
Further, since step S520 is a step of stirring the detergent and water at the highest concentration throughout the washing step, the rotation speed of the motor 23a can be suppressed and the risk of foaming can be suppressed. Further, as described above, when the washing treatment liquid charging setting is turned ON in step S0, the detergent charged into the outer tub 22 is a liquid detergent, so that the rotation speed of the motor 23a in step S520 is suppressed. be able to.

Next, in step S521, the conductivity measuring unit 115 measures the uniformed conductivity of water by the water quality sensor 35. When measuring the conductivity, in order to improve the measurement accuracy, the conductivity measuring unit 115 supplies water to the outer tank 22 by the water supply unit 20, circulates by a circulation pump (not shown), the water tank 21 and the rotor blade 21b. Stop the rotation of. Further, at that time, it is desirable that the water flow in the outer tank 22 and the water tank 21 is contained and that the high-concentration cleaning liquid is not foamed. Therefore, in step S520 described above, it is preferable to keep the rotation speed of the motor 23a low. As a result, the water flow generated in the outer tub 22 is weakened, so that the time until the rotation of the motor 23a is stopped and the time until the water flow in the outer tub 22 is settled can be shortened. The measurement accuracy of conductivity can be improved.

Next, when the process proceeds to step S522, the detergent state determination unit 117 determines whether or not the conductivity is less than the threshold value EC1. If "Yes" is determined here, the process proceeds to step S524, and the detergent state determination unit 117 determines that the applied detergent is "liquid detergent (concentrated)". Further, the detergent state determination unit 117 switches the characteristic of the water quality sensor 35 to "liquid detergent (concentration)" according to the determination result. Further, the process control unit 112 selects the "washing method (A)" optimized for the "liquid detergent (concentration)" as the washing method. The "washing method (A)" is, for example, a washing method in which rinsing is performed once. On the other hand, if "No" is determined in step S522, the process proceeds to step S523, and it is determined whether or not the conductivity is less than the threshold value EC2. Here, if it is determined as "Yes" (that is, when EC1 ≤ conductivity <EC2), the process proceeds to step S525, and the detergent state determination unit 117 determines that the applied detergent is "liquid detergent". judge. Further, the process control unit 112 selects a "washing method (B)" optimized for the "liquid detergent" as the washing method. The "washing method (B)" is, for example, a washing method in which rinsing is performed twice.

If "No" is determined in step S523 (that is, in the case of EC2 ≤ conductivity), the process proceeds to step S526, and the detergent state determination unit 117 determines that the applied detergent is "powder detergent". judge. Further, the process control unit 112 selects a "washing method (C)" optimized for the "powder detergent" as the washing method. The washing methods (A) to (C) described above differ in the washing time, the amount of water, the rotation speed of the motor 23a, and the like. For example, detergent powders tend to foam easily. Therefore, the washing method (C) of the powder detergent is shorter than the washing method (A) of the liquid detergent (concentrated), the washing time is shortened, the amount of water is increased, the detergent concentration is diluted, or the rotation speed of the motor is increased. It is preferable to lower it so that bubbles are less likely to be generated. As a result, foaming can be suppressed, and deterioration of cleaning performance and insufficient rinsing can be prevented. On the contrary, since the liquid detergent (concentrated) tends to be difficult to foam, the washing method (A) of the liquid detergent (concentrated) is to lengthen the washing time, reduce the amount of water to increase the detergent concentration, or rotate the motor. You should increase the speed. As a result, the cleaning performance can be improved while the risk of foaming is low.

Further, since the electric conductivity of the liquid detergent tends to be in the middle of the powder detergent and the liquid detergent (concentrated), it is preferable that the washing method (B) is in the middle of the washing methods (A) and (C). In the present embodiment, it is not necessary to install a sensor for detecting foaming because an appropriate washing method can be selected by detecting the type of detergent instead of "the state of foaming itself". It is not necessary to distinguish whether the liquid detergent is a concentrated type or not. That is, the same washing method may be applied to both regardless of the type of liquid detergent. Further, although not shown, the foaming determination unit 118 detects not only the detergent type but also factors related to the ease of foaming such as water temperature, water hardness, and bath water usage status in step S524, step S525, and step S526. By doing so, the accuracy of the foaming determination unit 118 can be improved. Further, since the concentrated type liquid detergent which may be rinsed once has a lower conductivity than the liquid detergent which has been rinsed twice, it is based on the judgment result by the foaming determination unit 118. You may change the number of rinses.

<Learning movement>
FIG. 13 is a control sequence diagram of an operation for learning the preference of each performance of the user.
In step S202 of FIG. 13, when the user turns on the power of the washing machine 1, the washing machine 1 requests the server 201 for the latest control value (step S204). The "control value" is the value of various "control parameters" in the washing machine 1. For example, when the "control parameter" is the "rotational speed of the motor 23a", the "control value" becomes a value such as "300 rpm". Upon receiving the request for the control value from the washing machine 1, the control value changing unit 214 (see FIG. 1) of the server 201 transmits the latest stored control value to the washing machine 1 (step S206). As a result, the control device 100 of the washing machine 1 stores the latest control value in the storage unit 111, and the washing machine 1 is put into the standby state.

After that, the user gives an operation start instruction to the washing machine 1 in the standby state via the operation panel 14 (step S208). Further, the user can also give an operation start instruction from the smart phone 300 instead of the step S208 (step S210). This operation start instruction can be given on the operation course detail screen 310 shown in FIG. The details of the operation course detail screen 310 will be described later, but on this operation course detail screen 310, the user confirms the operation contents (operation contents such as washing, rinsing, dehydration, drying, etc.) before instructing to start washing. It can be fixed.

When the washing machine 1 receives the operation start instruction in step S208 or S210, the washing machine 1 performs the washing operation. More specifically, the washing machine 1 executes the operation steps of steps S1 to S40 (see FIG. 10) described above. When the washing operation is completed, the washing machine 1 transmits the operation end information notifying that the washing is completed and the washing information obtained during washing to the server 201 (step S212). The processing of steps S208 and S210 in FIG. 13 corresponds to step S0 in FIG. 10, and the processing of step S212 in FIG. 13 corresponds to step S99 in FIG.

When the questionnaire unit 212 (see FIG. 1) of the server 201 receives the operation end information, it transmits the questionnaire question information to the smartphone 300 via the push notification server 202 (see FIG. 1) (step S214). .. Here, the "questionnaire question information" is information for specifying the content of the questionnaire. For example, the content of the character string shown on each button 332 to 342 on the questionnaire response screen 330 (see FIG. 14) is the questionnaire question. It becomes information. When the smart phone 300 receives the questionnaire question information, it can display a notification screen to that effect, thereby prompting the user to answer the questionnaire.

Then, when the user performs a predetermined operation on the smartphone 300, the questionnaire response screen 330 (see FIG. 14) for the user to answer the questionnaire is displayed. The details of the questionnaire response screen 330 will be described later, but when the user answers the questionnaire on the questionnaire response screen 330, the questionnaire result is transmitted to the server 201 as the questionnaire response information (step S216). The "questionnaire response information" is, for example, an on / off state of each button 332-342.

Upon receiving the questionnaire response information, the control value changing unit 214 (see FIG. 1) of the server 201 executes the questionnaire response process (step S218). The contents are as listed below.
(1) Common ID management between washing information and questionnaire: The control value changing unit 214 of the server 201 assigns an ID (identification information) to each washing machine 1, and stores this ID and the washing information in association with each other. doing. The questionnaire response information received by the control value changing unit 214 in step S216 is also given the same ID as the corresponding washing machine 1, and the washing information and the questionnaire response information are associated with each other.

(2) Questionnaire digitization The control value changing unit 214 of the server 201 changes the control values of some control parameters according to the questionnaire response information. Here, a control parameter whose control value changes according to the questionnaire response information is called a questionnaire correspondence parameter. Further, the control value changing unit 214 stores a value called a point value for all the parameters corresponding to the questionnaire. Here, the point value is similar to the control value in that the control content of the control parameter (questionnaire-corresponding parameter) is determined. However, while the control value takes various dimensions, initial values, and change width, the point value has a unified range such as "-100 to +100", and the initial value is "0". Is.

Further, the control value changing unit 214 sets a control parameter (questionnaire-corresponding parameter) for changing the point value and a change amount of the point value (hereinafter referred to as a point change amount) for a combination of answers to all the questionnaire items. , Is defined. For example, on the questionnaire response screen 330, the on / off states of the six buttons 332-342 are toggled, and there are " ²⁶ = 64" combinations of answers. The server 201 defines a questionnaire correspondence parameter for changing the point value and a point change amount corresponding to the combination of these 64 kinds of answers. Here, the point change amount has a positive value when the control content is strengthened (increased) and a negative value when the control content is weakened (decreased).

(3) Calculation of point value and storage The control value changing unit 214 integrates the amount of point change each time the questionnaire is executed, and stores the integrated result as the point value. As a result, the point value changes from a positive value to a negative value, from a negative value to a positive value, from a positive value to a larger positive value, or from a negative value to a smaller negative value. It changes according to the information. In this way, by updating the point value based on the questionnaire response information and storing the latest control value based on the point value in the control value changing unit 214 of the server 201, the user's preference is reflected in the control value. The control value changing unit 214 can be trained. As described above, the changed control value is transferred to the washing machine 1 when step S204 is executed in the washing machine 1.

In FIG. 13, when the process proceeds to step S220 next, the server 201 transmits the status display screen update information to the smart phone 300. This notifies the smart phone 300 of the latest control value. The smart phone 300 displays the radar chart display screen 350 (see FIG. 14) according to the latest control value accordingly. The details of the radar chart display screen 350 will be described later.

Further, the server 201 can transmit the status display screen update information to the smart phone 300 based on the integrated result of the questionnaire, and can show the user's favorite control parameters in a graph. (Refer to the radar chart display screen 350 of FIG. 14) This allows the user to confirm how the questionnaire result, that is, the questionnaire response information affects the control, in a more understandable expression.

<Specific example of screen display>
(Driving course detail screen 310)
FIG. 14 is a diagram showing various screens displayed on the smart phone 300.
As described above, in the washing machine 1, the user can select a desired one from various driving courses. The driving course can be selected either on the operation panel 14 of the washing machine 1 (see FIG. 2) or on the driving course selection screen (not shown) displayed on the smartphone 300.

When the driving course is designated by the smart phone 300, the microcomputer 110 of the washing machine 1 (see FIG. 9) reads out the driving pattern corresponding to the designated driving course from the storage unit 111. Then, when this driving pattern is notified to the smart phone 300, for example, the driving course detail screen 310 shown at the left end of FIG. 14 is displayed on the smart phone 300. On the operation course detail screen 310, the user can confirm or correct the operation contents (operation contents such as washing, rinsing, dehydration, and drying) before the washing start instruction.

The main menu bar 380 is displayed at the upper end of the driving course detail screen 310, and the sub menu bar 390 is displayed at the lower end. A "back" button 382 and a help button 384 are displayed on the main menu bar 380. Further, the home button 391, the concierge button 392, the status confirmation button 393, the support button 394, and the setting button 395 are displayed on the submenu bar 390.

Further, below the main menu bar 380, a "washing" button 312 and a "washing-drying" button 314 are displayed. A start button 326 and a star-shaped button 328 are displayed above the sub-menu bar 390. Here, the "washing" button 312 mainly displays a control value related to "washing" between the "washing" button 312 and the start button 326, and the "washing-drying" button 314 is a "washing" button. A control value mainly related to "washing-drying" is displayed between the button 312 and the start button 326.

In addition, the water amount display unit 316 displays the designation of the water amount. In addition, the "washing" display unit 318 displays the time of the "washing" process. Further, the "rinse" display unit 320 displays the contents of the "rinse" process. Further, the "warm air mist" display unit 324 displays the contents of the "warm air mist" process. The driving course detail screen 310 in the illustrated example shows an example in the "My style AI course". Therefore, when another driving course is selected, contents different from the illustrated example are displayed on each display unit 316, 318, 320, 324.
After confirming or correcting the driving content on the driving course detail screen 310, the user taps the start button 326 to execute the driving start instruction by the smart phone 300 (step S210 in FIG. 13).

(Questionnaire response screen 330)
As described above, in step S214 of FIG. 13, the questionnaire question information is transmitted from the server 201 to the smart phone 300. After that, when a predetermined operation is performed on the smart phone 300, the questionnaire response screen 330 shown in the center of FIG. 14 is displayed on the smart phone 300. Similar to the driving course details screen 310, the main menu bar 380 and the sub menu bar 390 are displayed at the upper and lower ends of the questionnaire response screen 330.

Also, between the main menu bar 380 and the sub menu bar 390, there is a message "Please select the item you were interested in in the previous Myya style AI course", a "cleaning" button 332, and "Clothing damage" button 334, "Large amount of detergent used" button 336, "Rinse condition" button 338, "Weak dehydration" button 340, "Long running time" button 342, Answer button 346 And are displayed.

Each of the above-mentioned buttons 332 to 342 is toggled on / off each time the user taps it. The "cleaning" button 332 is turned on when "cleaning" is a concern, and turned off in other cases. Further, the "clothing damage" button 334 is turned on when "clothing damage" is anxious, and turned off in other cases. Also, the "high detergent usage" button 336 is turned on when it seems "high detergent usage" and turned off otherwise.

Further, the "rinse condition" button 338 is turned on when the "rinse condition" is anxious, and is turned off in other cases. Also, the "weak dehydration" button 340 is turned on when it seems "weak dehydration" and turned off otherwise. Further, the "long driving time" button 342 is turned on when it seems that the "running time is long", and turned off in other cases. The user switches the on / off state by tapping each button 332-342. Then, when the answer button 346 is tapped when the on / off state has a desired result, this on / off state is transmitted to the server 201 as questionnaire response information as described in step S216 of FIG. ..

(Radar chart display screen 350)
As described above, in step S220 of FIG. 13, the server 201 transmits the status display screen update information to the smart phone 300. After that, when the user performs a predetermined operation on the smart phone 300, the radar chart display screen 350 is displayed on the smart phone 300 at the right end of FIG. Similar to the driving course detail screen 310, the main menu bar 380 and the sub menu bar 390 are displayed at the upper and lower ends of the radar chart display screen 350. Further, between the main menu bar 380 and the sub menu bar 390, there are an initialization button 352, a radar chart 354, a detergent amount indicator 356, an operation time indicator 358, a questionnaire button 360, and a "drive" button. 362 and are displayed.

When the user taps the initialization button 352, the smart phone 300 outputs a command to the server 201 to initialize the control value in the "my style AI course" (return to a predetermined initial value). In addition, the radar chart 354 shows "drying well", "improving dirt removal", "rinsing firmly", "suppressing damage to clothes", and "squeezing dehydration well" with respect to the currently set control values. It shows the evaluation results for six kinds of evaluation items, "to do" and "to suppress wrinkles after dehydration".

In addition, the detergent amount indicator 356 shows the evaluation result about the detergent amount. Further, the operation time indicator 358 shows an evaluation result regarding the operation time. When the user taps the questionnaire button 360, the smart phone 300 shifts the display screen to the questionnaire response screen 330. Further, when the user taps the "drive" button 362, the smart phone 300 shifts the display screen to the driving course selection screen (not shown).

FIG. 15 is a diagram showing the relationship between the questionnaire response information and the amount of change in points.
In the questionnaire response screens 330A and 330B shown in FIG. 15, of the buttons 332 to 342, those in the on state are hatched, and those in the off state are not hatched.
For example, in the questionnaire response screen 330A, the "cleaning" button 332 is in the on state, and the other buttons 334 to 342 are in the off state. The point change amount of the control parameter "washing time" corresponding to the questionnaire response screen 330A is "+10", and the point change amount of the control parameter "detergent amount" is "+5". Therefore, when the answer button 346 is tapped on the questionnaire response screen 330A, the point value of the control parameter "washing time" increases by "10", and the point value of the "detergent amount" increases by "5".

Further, on the questionnaire response screen 330B, the "cleaning" button 332 and the "clothing damage" button 334 are in the on state, and the other buttons 336 to 342 are in the off state. The point change amount of the control parameter "washing time" corresponding to the questionnaire response screen 330B is "-10", and the point change amount of the control parameter "detergent amount" is "+10". Therefore, when the answer button 346 is tapped on the questionnaire response screen 330B, the point value of the control parameter "washing time" decreases by "10" and the point value of the "detergent amount" increases by "10".

FIG. 16 is a diagram showing an example of a conversion table stored in the server 201.
In FIG. 16, as an example of the conversion table, a washing time table 402 and a detergent amount table 404 are shown. The washing time table 402 defines the relationship between the point value of the "washing time" and the control value. For example, if the point value is in the range of "+1 to +50", the control value of the washing time is set to "16 minutes". Further, the detergent amount table 404 defines the relationship between the point value of the "detergent amount" and the control value. For example, if the point value is in the range of "+1 to +50", the control value of the detergent amount is set to "1.1 times". More specifically, this means "1.1 times the amount per unit weight of the object to be washed with respect to a predetermined reference amount".

<Variations of learning behavior>
(Specific example 1)
Next, an example other than that shown in FIG. 15 will be described with respect to the method of determining the point value and the control value for the questionnaire response information.
For example, as shown in the questionnaire response screen 330A of FIG. 15, when the user turns on the "cleaning" button 332 (when answering "I'm worried about removing dirt"), the process control unit 112 sends the process control unit 112. By increasing the "amount of detergent to be added" in step S3 of FIG. 10 or extending the main washing time from steps S13 to S19, it is possible to improve the stain removal as compared with the previous washing operation. On the contrary, when the "cleaning" button 332 is in the off state, the process control unit 112 reduces the "detergent amount to be added" in step S3 of FIG. 10 or shortens the main washing time of steps S13 to S19. To do. As a result, it is possible to suppress excessive stain removal, reduce the amount of detergent used, shorten the operation time to reduce energy consumption, and realize a washing operation with reduced running costs.

In the above example, the amount of detergent and the main washing time were changed based on the questionnaire response information, but the objects to be changed were the detergent melting time in step S4 of FIG. 10, the time of the pre-washing step in step S9, and each step. It may be the amount of water supplied, the rotation speed of the rotary blade 21b operating in each process, the operating rate, and the like. Further, based on the questionnaire response information, the drying unit 71 and the fan 72 may be driven to warm the clothes with warm air.

(Specific example 2)
Further, for example, when the user turns on the "clothing damage" button 334 (when he / she answers that he / she is worried about the clothing damage), the process control unit 112 uses the books of steps S13 to S19 in FIG. By shortening the washing time or shortening the rinsing and stirring time of steps S33 to S35, damage to clothes can be suppressed as compared with the previous washing operation. On the contrary, when the "clothes damage" button 334 is turned off, the process control unit 112 extends the main washing time of steps S13 to S19 in FIG. 10 or the rinsing stirring time of steps S33 to S35. As a result, it is possible to improve the degree of dirt removal and rinsing as compared with the previous washing operation.

Further, in the above-mentioned example, the main washing time and the rinsing stirring time were changed based on the questionnaire response information, but the objects to be changed were the detergent dissolving time in step S4 of FIG. 10, the time of the pre-washing step in step S9, and so on. The amount of water supplied in each process, the rotation speed and operating rate of the rotary blade 21b operating in each process, the rotation speed and acceleration rate of the motor 23a during dehydration in each process, and the like may be used. Further, based on the questionnaire response information, the drying unit 71 and the fan 72 may be driven to warm the clothes with warm air.

(Specific example 3)
Further, as shown in the questionnaire response screen 330B of FIG. 15, when the user turns on both the "cleaning" button 332 and the "clothing damage" button 334, the washing time is shortened and the amount of detergent is increased. Can be considered. However, as another example, the process control unit 112 increases the amount of detergent to be added in step S3 of FIG. 10, and rinses and stirs steps S33 to S35 without changing the main washing time of steps S13 to S19. You may save time. As a result, it is possible to remove dirt better than in the previous operation and to suppress damage to clothes.

In the above-mentioned example, an example of changing the amount of detergent to be added, the main washing time, or the rinsing and stirring time is described based on the questionnaire response information, but the object to be changed is the detergent melting time in step S4 of FIG. , The time of the pre-washing process in step S9, the amount of water supplied in each process, the rotation speed and operating rate of the rotary blade 21b operating in each process, the rotation speed and acceleration rate of the motor 23a during dehydration in each process, and the like. You may. Further, based on the questionnaire response information, the drying unit 71 and the fan 72 may be driven to warm the clothes with warm air.

<Effect of embodiment>
As described above, according to the present embodiment, the washing machine management device (201) displays the questionnaire question information regarding the result of the washing operation for the washing machine (1) that performs the washing operation based on the control value (302). ), And a control value changing unit (214) that receives questionnaire response information that is an answer to the questionnaire question information and changes the control value based on the questionnaire response information.
As a result, the operation content of the washing machine can be automatically set according to the user's preference.

In addition, the questionnaire question information includes the first question as to whether or not the stain is removed, and the control value changing unit (214) determines that the answer to the first question is affirmative. The control value is changed so as to realize one of increasing the amount of detergent, lengthening the washing time, lengthening the detergent dissolving time, and lengthening the pre-washing process.
As a result, when the user replies that he / she is concerned about the removal of dirt, the control value can be changed so that the removal of dirt is improved.

In addition, the questionnaire question information includes a second question as to whether or not the clothing is damaged, and the control value changing unit (214) determines that the answer to the second question is affirmative. The control value is changed so as to realize one of the following: shortening the washing time, shortening the rinsing stirring time, lowering the rotation speed of the motor, and lowering the operating rate of the motor.
As a result, when the user replies that the damage to the clothes is anxious, the control value can be changed so as to suppress the damage to the clothes.

Further, when the answers to both the first question and the second question are affirmative, the control value changing unit (214) shortens the washing time, increases the amount of detergent, and reduces the rinsing and stirring time. Change the control value to achieve either shortening and increasing the amount of detergent.
As a result, when the user replies that he / she is worried about the stain removal and the user is concerned about the damage to the clothes, the control value is set so as to improve the stain removal and suppress the damage to the clothes. Can be changed.

<Modification example>
The present invention is not limited to the above-described embodiment, and various modifications are possible. The above-described embodiments are exemplified for the purpose of explaining the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the configurations described. Further, another configuration may be added to the configuration of the above embodiment, and a part of the configuration may be replaced with another configuration. In addition, the control lines and information lines shown in the figure show what is considered necessary for explanation, and do not necessarily show all the control lines and information lines necessary for the product. In practice, it can be considered that almost all configurations are interconnected. Possible modifications to the above embodiment are, for example, as follows.

(1) In the above embodiment, as the washing machine 1, a vertical washing / drying machine in which the rotation axis of the washing / dehydrating tub is in a substantially vertical direction has been described as an example, but the washing machine 1 is not limited to this. A drum-type washing / drying machine in which the rotation axis of the washing / dehydrating tub is substantially horizontal may be used, or a vertical-type washing machine or a drum-type washing machine having no drying function may be used.

(2) The water quality sensor 35 in the above embodiment is not limited to the configuration described in the above embodiment, and may have a configuration capable of detecting the conductivity of the detergent solution. For example, in the above embodiment, the capacitance of the capacitor (not shown) included in the oscillation circuit 39 is changed to switch the characteristics, but the constants of the resistor and the coil may be changed.

(3) In the above embodiment, the operation panel 14 and the smart phone 300 of the washing machine 1 are manually operated by the user, but the operation panel 14 and the smart phone 300 are controlled by the voice input of the user. May be good.

(4) In the above embodiment, the questionnaire response information is converted into a point value and quantified, and the point value is converted into a control value. However, the questionnaire response information may be directly converted into a control value without converting the questionnaire response information into a point value and quantifying it.

(5) In the above embodiment, the operation of driving the drying unit 71 and the fan 72 to warm the clothes with warm air has been described. However, the means for warming the clothes is not limited to the warm air provided by the drying unit 71, and the clothes and the washing water may be warmed by another heat source (not shown) submerged in water.

(6) In the above-mentioned specific examples 1 and 3, when the user selects "I want to improve the stain removal", an example in which the amount of detergent in step S3 of FIG. 10 is changed in order to improve the stain removal. I mentioned it. However, in the washing machine 1 equipped with the washing treatment liquid charging device 30, the timing of charging the detergent does not necessarily have to be only step S3 in FIG. For example, it is possible to additionally add detergent in the main washing steps of steps S13 to S19. As a result, when there is a lot of dirt, it is possible to improve the removal of dirt by adding an additional detergent.

(7) In the above-mentioned specific example 2, when the user selects "I want to suppress the damage to the cloth", the main washing time is shortened, or the rinsing stirring time in steps S33 to S35 is shortened. It was. Similarly, in Specific Example 3, an example of shortening the rinsing and stirring time was given. However, if the washing machine 1 is equipped with the washing treatment liquid charging device 30, it is possible to adjust the charging amount, the charging timing, and the like of the softener. This makes it possible to eliminate the "stiff feeling" that the user feels due to "damage to clothing".

(8) In the above-mentioned Specific Examples 1 to 3, some control contents in the washing, rinsing, dehydrating, and drying steps were changed based on the questionnaire response information. However, it may be replaced with another driving course mounted on the washing machine 1. For example, when the user selects "I want to improve the dirt removal", it is possible to drive in the "driving course for improving the dirt removal" mounted on the washing machine 1. Further, when the user selects "I want to improve the rinsing condition", it is possible to drive on the "driving course with improved rinsing performance" mounted on the washing machine 1.

(9) In the above embodiment, the server 201 has the functions of the questionnaire unit 212 and the control value changing unit 214. However, the control device 100 or the smartphone 300 of the washing machine 1 may be provided with the functions of the questionnaire unit 212 and the control value changing unit 214. As a result, the washing machine 1 can be controlled while reducing the number of hardware.

(10) Since the hardware such as the control device 100, the server 201, the push notification server 202, and the smart phone 300 in the above embodiment can be realized by a general computer, the process diagrams, flowcharts, and the like shown in FIGS. A control sequence diagram and other programs for executing various processes described above may be stored in a storage medium or distributed via a transmission line.

(11) The process diagram, flowchart, control sequence diagram, and other above-described processes shown in FIGS. 10 to 13 have been described as software-like processes using a program in the above-described embodiment, but some or all of them have been described as software-like processes. May be replaced with hardware-like processing using an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or the like.

S Washing machine management system 1 Washing machine 201 server (Washing machine management device)
212 Questionnaire Department (Questionnaire Means)
214 Control value changing unit (control value changing means)
300 smart phone (portable communication terminal)
302 Display device 304 Touch sensor

Claims (8)

Regarding a washing machine that performs washing operation based on a control value, a questionnaire unit that displays questionnaire question information regarding the result of the washing operation on a display device, and a questionnaire unit.
A management device for a washing machine, comprising: a control value changing unit that receives questionnaire response information that is an answer to the questionnaire question information and changes the control value based on the questionnaire response information. The questionnaire question information includes the first question as to whether or not the dirt is removed.
When the answer to the first question is affirmative, the control value changing unit increases the amount of detergent, prolongs the washing time, prolongs the detergent dissolving time, and prolongs the pre-washing step. The management device for a washing machine according to claim 1, wherein the control value is changed so as to realize any one of them. The questionnaire question information includes a second question as to whether or not the damage to clothing is a concern.
When the answer to the second question is affirmative, the control value changing unit shortens the washing time, shortens the rinsing stirring time, lowers the rotation speed of the motor, and lowers the operating rate of the motor. The management device for a washing machine according to claim 2, wherein the control value is changed so as to realize any of the above. When the answers to the first question and the second question are both affirmative, the control value changing unit shortens the washing time and increases the amount of the detergent, and the rinse stirring time. The management device for a washing machine according to claim 3, wherein the control value is changed so as to realize any of the above-mentioned shortening and increasing the amount of the detergent. The management device for a washing machine according to any one of claims 1 to 4, wherein the questionnaire unit and the control value changing unit are provided in the washing machine. The management device for a washing machine according to any one of claims 1 to 4, wherein the questionnaire unit and the control value changing unit are provided in a portable communication terminal. A washing machine that performs washing operation based on the control value,
A control value that receives the questionnaire unit that displays the questionnaire question information regarding the result of the washing operation on the display device and the questionnaire response information that is the answer to the questionnaire question information, and changes the control value based on the questionnaire response information. A washing machine management system including a changing part and a management device for a washing machine having a changing part. Computer,
For a washing machine that performs a washing operation based on a control value, a questionnaire means for displaying questionnaire question information regarding the result of the washing operation on a display device >>,
A control value changing means that receives questionnaire response information that is an answer to the questionnaire question information and changes the control value based on the questionnaire response information.
A program to function as.

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