CN108060547B - Washing method capable of setting washing parameters - Google Patents

Abstract

A washing method capable of setting washing parameters is applied to a washing machine, a washing machine control module, an input module and a display module, wherein the control module is a microcontroller, and the washing method comprises the following steps of S1: inputting at least one user washing requirement and corresponding parameters thereof in an input module; s2: the micro processor receives the washing requirement and the parameters thereof; s3: calculating operation data of each operation module when the washing machine operates according to washing requirements and parameters thereof specified by a user; s4: the microprocessor sends the operation data to the corresponding operation module to carry out the washing treatment. The invention has intuitive interface setting, and provides convenience for users; the washing index setting of the user influences the operation parameters of the washing machine in the washing state, and the real man-machine interaction is realized.

Description

Washing method capable of setting washing parameters

Technical Field

The invention relates to the technical field of electric appliances, in particular to a washing method capable of setting washing parameters.

Background

At present, the washing programs of most washing machines in the market are well solidified before the washing machines leave a factory, upgrading and optimizing cannot be carried out, and users can only select corresponding programs through a control interface. With the continuous updating of the fabric of the clothes, the original program can not meet the washing requirements of users, and the users only can replace the computer board when wanting to update the washing program, so the cost is higher.

The interface between the existing user and the washing machine is very professional parameters such as temperature, speed, rinsing times and the like, and the washing machine can only mechanically execute the parameters set by the user and cannot really make a washing scheme from the point of attention of the user.

There is no interaction or communication between the user and the washing machine, and the purpose of satisfying and paying attention to different personal preferences and concerns of each customer cannot be realized.

With the development of the internet of things, more and more washing machines are connected to the cloud server, and the updating application of the washing program is more and more common.

Patent application No.: 201410419662.2A method for updating washing machine program, which only describes the method for updating washing machine program, and only focuses on the development from cloud server and washing machine hardware from large direction, and proposes a feasible concept that can download washing program from cloud server to washing machine by cloud server, and how to realize it is not described in detail.

The present invention has been made to solve these problems.

Disclosure of Invention

The invention aims to provide a washing method capable of setting washing parameters.

The aim is achieved by the following technical scheme,

a washing method capable of setting washing parameters is applied to a washing machine, the washing machine comprises a control module, an input module and a display module, the control module is a microcontroller, the washing method comprises the following steps,

s1: inputting at least one user washing requirement and corresponding parameters thereof in an input module;

s2: the micro processor receives the washing requirement and the parameters thereof;

s3: calculating the operation data of each operation module when the washing machine operates according to the washing requirement and the parameters thereof specified by the user, wherein the step S3 specifically comprises the following steps:

s24: calculating the current attention ratio of each demand: the current attention ratio is current attention/total attention,

s25: setting each demand final attention ratio as an initial value;

s26: calculating a difference between the current attention ratio and the final attention ratio of each laundry demand;

s27: initializing the operation module; the operation module controls the washing time, the dehydration time, the heating time,

The intake water level, the attention execution demand for fast washing is washing time, the attention removal execution demand for dry removal is dewatering time, the attention execution demand for low power consumption is heating time, the attention execution demand for water conservation is intake water level,

s28: washing time (nominal washing time × (1+ fast difference of washing)); the dehydration time is the rated dehydration time (1+ dehydration difference);

heating time (rated heating time) (1+ power consumption difference); the water inlet level is the rated water inlet level (1+ water saving difference);

s4: the microprocessor sends the operation data to the corresponding operation module to carry out the washing treatment.

In one embodiment, after the processing of step S4, the method further includes the following steps:

preferably, the washing machine further has a communication module; the micro processor of the washing machine is connected with the cloud server through the communication module; the microprocessor is respectively connected with the communication module, the input module and the display module.

Preferably, the display module can be a mobile phone display screen, and the mobile phone display screen is connected with the washing machine or the cloud server through a mobile phone processor and a mobile phone built-in communication module.

In one embodiment, after the processing of step S4, the method further includes the following steps: s5: after washing is finished, scoring evaluation is carried out on the completion satisfaction degree of the washing requirements of the user, and the micro processor carries out operation according to the scoring;

s6: the microprocessor tells the operation result to set the final attention ratio of the quick washing.

Preferably, the user washing requirements include fast washing, dry dewatering, low power consumption and water saving, and the input mode corresponding to each requirement is to simulate knob input on the input module.

Preferably, the initial value of the final attention per demand is 0.25.

In an embodiment, the step S6 specifically includes the following steps:

s13: the micro processor collects the scores of each demand evaluation of the user, including the quick washing score and the dry removing score, the power consumption is low, and the water score is saved;

s14: calculating the evaluation score ratio of each demand, wherein the washing fast score ratio is washing fast score/total score; removing dry fraction ratio, namely removing dry fraction/total fraction; the power consumption reduction fraction is less than the power consumption reduction fraction/total fraction; saving water fraction (water fraction/total fraction); the total fraction is the quick fraction obtained by washing, the dry fraction obtained by removing, the low power consumption fraction and the water fraction saved;

s15: the microprocessor analyzes and calculates the demand attention ratio: after the fast washing analysis, the attention ratio is equal to the final attention ratio of the fast washing (fast washing score ratio-fast washing current attention ratio); after the dry analysis is performed, obtaining a final dry attention ratio- (obtaining a dry score ratio-obtaining a current dry attention ratio);

after the power consumption reduction analysis, the attention ratio is smaller than the final attention ratio which is smaller than the power consumption (the power consumption reduction ratio is smaller than the current attention ratio which is smaller than the power consumption); and (4) after water saving analysis, namely the final water saving attention ratio- (water saving point ratio-current water saving attention ratio).

In one embodiment, the processing of S15 further includes the following steps:

s16: the micro processor uploads the analysis result to the cloud server through the communication module;

s17: the cloud server finishes the data and performs manual audit confirmation;

s18: after the manual examination, the cloud server issues the confirmed reasonable data to the washing machine;

s19: the microprocessor of the washing machine puts the confirmed index attention ratio into the storage space as the final attention ratio for each index to be washed faster in the next operation.

Has the advantages that:

1. the clothes are washed from the user standpoint, the complex setting of professional parameters is eliminated, the intuitive interface setting is realized, and convenience is provided for the user.

2. The washing index setting of the user influences the operation parameters of the washing machine in the washing state, such as the washing time, and the real man-machine interaction is realized.

3. Through a scoring mechanism, a satisfaction feedback result of a user is collected and is confirmed by the cloud server and then is transmitted back to the washing machine, a basis is provided for next washing parameters, intelligent closed-loop management is achieved, and the washing method is optimized.

4. The scheme of the invention is to directly borrow the self-contained storage space in the microcontroller, the scheme has low cost, no additional hardware design is needed, and the microcontroller directly accesses the self-contained storage space in the microcontroller, so the efficiency is higher.

5. The washing machine is provided with a communication module and can be networked; a user can score the washing results of the washing machine through a mobile phone screen;

if the washing machine is not provided with the communication module and cannot be networked, a user can score the washing machine through the control panel, and the control mode is more flexible.

Drawings

Fig. 1 is a block diagram of a washing machine according to the present invention.

Fig. 2 is a block diagram of a washing machine with a communication module according to the present invention.

Fig. 3 is a display interface of the display module of the washing machine of the present invention.

Fig. 4 is a flowchart of embodiment 1 of the washing machine of the present invention.

Fig. 5 is still another flow chart of embodiment 1 of the washing machine of the present invention.

Fig. 6 is a flow chart of embodiment 2 of the washing machine of the present invention.

Fig. 7 is still another flow chart of the embodiment 2 of the washing machine of the present invention.

Fig. 8 is a schematic view of the laundry requirement in the laundry method of the present invention.

FIG. 9 is a further schematic representation of the laundry requirements of the laundry process of the present invention.

Detailed Description

In order to make the technical problems solved, technical solutions adopted and technical effects achieved by the present invention clearer, the technical solutions of the embodiments of the present invention will be further described in detail with reference to the accompanying drawings, and the described embodiments are only a part of embodiments of the present invention, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, the washing machine has a control module, an input module, and a display module.

The microprocessor is respectively connected with the input module and the display module. Preferably, the control module is a microprocessor, and the display module is a display screen. Hereinafter, the microprocessor is abbreviated as MCU. The micro-processor is internally provided with an erasable storage space, a washing program is written in the erasable storage space, and the micro-processor controls the operation of the washing machine according to the washing program. The storage space in the microprocessor is utilized, so that the cost is low, additional storage equipment is not needed, and the cost is low; in addition, compared with the time required for accessing an external storage device, the time required for accessing the internal storage space by the microcontroller is shorter, the access efficiency is higher, and the running speed is higher.

In the input module, at least one user washing requirement and corresponding parameters are input, and the input mode can be keyboard input simulated on the display module, or hand input on the display module, or knob input simulated on the display module. Consumer washing needs include, but are not limited to, fast wash, dry dewatering, low power consumption, and water conservation.

Referring to fig. 2, the preferred washing machine also has a communication module. The microprocessor of the washing machine is connected with the cloud server through the communication module. The communication module is a WIFI module which is provided with a wired network port, a Bluetooth module, a 3G module or a 4G module. The microcontroller is respectively connected with the communication module, the input module and the display module. Preferably, the display module can be a mobile phone display screen, and the mobile phone display screen is connected with the washing machine or the cloud server through a mobile phone processor and a mobile phone built-in communication module.

Example 1: the washing method of the present invention for setting washing parameters will be described in detail.

Referring to fig. 3, in this embodiment, simulated knob input on the display module is employed.

The washing machine comprises a washing machine body, a display module, an input module and a display module, wherein the display module is used for displaying a washing interface of the washing machine body, the display module is used for displaying four washing requirements of fast washing, dry removing, low power consumption and water saving, the input module can input required parameters corresponding to each requirement, and after washing is completed, the display module can display a mark for fast washing, a mark for dry removing, a mark for low power consumption and a mark for water saving.

Each display area is provided with an analog knob below, the dial plate is arranged below the knob, in this embodiment, the dial plate is divided into 0-100 parts, scales 20, 40, 60, 80 and 100 are marked on the dial plate, a pointer is arranged on the knob, the position of the current knob is indicated through the pointing direction of the pointer, for example, the pointer points 40, and the value which can be read by the processor through the knob is indicated as 40.

The washing machine is powered on, after the microprocessor is powered on, the display areas display the washing speed, the dewatering dryness, the power consumption and the water saving, the washing time, the dewatering water content, the attention degree of the water consumption and the power consumption of a user can be set through the knobs below each display area, the larger the numerical value indicated by the pointer on the knob corresponding to the washing speed is, the smaller the washing time expected by the user is, and the same is true.

The user's washing time, the degree of concern of dehydration moisture content, water consumption and power consumption are identified by sliding the knob on the display module and then changing the pointer direction.

After the washing program is finished, the display area displays the function of scoring each demand, and gives a mark for quickly scoring the washing, a mark for dry scoring, a mark for less power consumption and a mark for saving water; at this time, by sliding the knob below each display area, the user scores results of quick washing, dry drying, low power consumption and water saving, and completes user satisfaction feedback after washing, and the microprocessor collects data such as scoring feedback of each demand and expected value of each demand of the user and sends the data to the cloud server through the communication module. The larger the data pointed by the pointer in the knob, the higher the user satisfaction.

The washing requirements comprise four items, corresponding to the four display areas, namely fast washing, dry removal, low power consumption and water saving.

Attention, expression symbol, value range, and value range description corresponding to each requirement are described with reference to fig. 8 and 9.

Referring to fig. 4, the flow chart of the laundry method is as follows:

s1: inputting at least one user washing requirement and corresponding parameters thereof in an input module;

s2: the micro processor receives the washing requirement and the parameters thereof;

s3: calculating operation data of each operation module when the washing machine operates according to washing requirements and parameters thereof specified by a user;

s4: the microprocessor sends the operation data to the corresponding operation module to carry out the washing treatment.

The washing method will be described in detail with reference to the flow chart.

Referring to fig. 5, the specific steps are as follows:

s21: switching on the power supply of the washing machine; after the power supply is switched on, the display area on the display screen becomes bright, the display is fast to wash, the clothes are dried, the power consumption is low, and the water is saved.

S22: an analog knob on the display module is manually slid.

S23: the microprocessor acquires the indication information corresponding to each knob, namely the attention of the washing requirement, and the attention of the washing machine is fast: uptime; removing the dry attention: upscharged; low power consumption attention: up power; water conservation concerns: upwater.

S24: calculating the current attention ratio of each demand: the current attention ratio is current attention/total attention,

wash fast current attention ratio: time/(uptime + upsteed + upstower + upwater);

removing the current attention ratio: the predicted is upsteed/(uptime + upsteed + upstower + upstater);

the current attention ratio of power consumption is low: the power is upper/(upper + upper);

the current attention ratio of water conservation: pwater/(uptime + upsteed + upstower + upstater).

S25: setting the final attention ratio of each demand as an initial value, washing quickly and obtaining the final attention ratio: ptimedef is 0.25; dry final focus ratio: pspeeeddef is 0.25; the power consumption is low, and the final attention ratio is as follows: ppowerdef is 0.25; water saving final attention ratio: pwaterdef is 0.25, in this embodiment, the final attention ratio is constant, the weight of each demand is the same, so the final attention ratio of each demand is set to the same value,

to ensure that ptimedef + pspeededef + pwoerdeff + pwaterdef is 1, the final attention ratio for each demand is set to 0.25.

S26: calculating the difference between the current attention ratio and the final attention ratio of each laundry demand, wherein the fast-washing difference is as follows:

pdelttime ═ ptime-ptimedef; removing a dry difference value: pdeltpredicted is pspeed-pspeeded; less difference in power consumption:

pdeltpower ═ power-pwoerdef; saving water difference value: pdeltwater ═ pwater-pwater.

S27: initializing the operation module; the operation module controls the washing time, the dehydration time, the heating time and the water inlet level, the attention execution demand for fast washing is the washing time Tumbletime, the attention execution demand for dry removal is the dehydration time Speedtime, the attention execution demand for low power consumption is the heating time Heattime, the water saving attention execution demand is the water inlet level filllevel,

the washing machine needs to meet the requirement of low power consumption, and the electric quantity can be saved only by reducing the heating time on the premise of ensuring the rotation speed of the washing machine and further ensuring the cleanness of clothes.

S28: washing time Tumbletime is rated washing time Tumbletime (1+ fast washing difference pdelttime); the dehydration time, namely the rated dehydration time, namely, the dehydration time, 1+ to obtain a dry difference value pdeltspeced;

heating time heattime is rated heating time heattimed (1+ power consumption difference pdeltpower); the intake water level filllevel is the rated intake water level filllelated (1+ water saving difference pdeltwater).

S29: the micro-processor sends the washing time, the dehydration time, the heating time and the water inlet level to the corresponding operation modules respectively for washing.

Specifically, in this embodiment, after the user connects the washing machine to the power supply, the display area is brightened, the user manually slides the knob corresponding to the lower side with fast washing to 70, the user manually slides the knob corresponding to the lower side with dry washing to 10, the user manually slides the knob corresponding to the lower side with low power consumption to 10, the user manually slides the knob corresponding to the lower side with saved water to 10, corresponding upper time is 70, upper speed is 10, upper power is 10, upwater, and as can be seen from the above step S24, the current attention ratio of washing is obtained: ptime ═ 0.7; removing the current attention ratio: pspeed ═ 0.1; the current attention ratio of power consumption is low: crown is 0.1; the current attention ratio of water conservation: pwater is 0.1. From this figure, the user is more concerned about the need to wash the clothes faster, and wants to wash the clothes in less time, and is not very conscious of other washing needs. From S25 and S26, the difference in washing speed is: pdelttime ═ 0.45; removing a dry difference value: pdeltpredicted ═ 0.15; less difference in power consumption: pdeltpower ═ 0.15; saving water difference value: pdeltwater ═ 0.15. Calculating the washing time by S27 and S28, setting the rated washing time tunblerated as 30 minutes, the rated dewatering time as 10 minutes, the rated heating time as 10 minutes, the rated water level filllevelated as 5 liters,

step S28 is a technical solution obtained from a book of submissions, where the washing time is equal to the rated washing time

tubbletimeted (1-fast wash difference pdelttime), wash time, tubbletime 16.5, less than the nominal wash time of 30 minutes, consistent with the expected value of fast wash 70.

The micro-processor sends the washing time, the dehydration time, the heating time and the water inlet level to the corresponding operation modules respectively for washing.

Example 2: the upgrading of the laundry method will be described with reference to still another embodiment.

The difference between this embodiment and embodiment 1 is that the value of the final attention ratio of each requirement is not fixed, the value used for the first time is the same as that of embodiment 1, the four washing requirements are divided into 1, and after washing is finished, the final attention ratio of the requirement is updated correspondingly according to the washing result evaluation fed back by the user.

Referring to fig. 6, the flow chart is as follows:

s1: in the input module, at least one user washing demand and its corresponding parameters are input.

S2: the microprocessor receives a washing demand and its parameters.

S3: and calculating the operation data of each operation module when the washing machine operates according to the washing requirement and the parameters thereof specified by the user.

S4: the microprocessor sends the operation data to the corresponding operation module to carry out the washing treatment.

S5: after washing is finished, scoring evaluation is carried out on the completion satisfaction degree of the washing requirements of the user, and the micro processor carries out calculation according to the scoring.

S6: the microprocessor speaks an operation result to set a final attention ratio of the quick washing;

in the step S6, the washing machine scores through a mobile phone display screen for operation according to the existence of a communication module when the washing machine has the communication module, and then transmits the score to a cloud server for auditing and transmitting the score back to a washing machine microprocessor as the final attention ratio of the next washing speed; when the washing machine is not provided with the communication module, the mark is marked on the display module of the washing machine, the display module can be a control panel, namely, the mark is marked on the control panel, the micro processor directly sets the final attention ratio of the quick washing speed after operation, the processing mode is not limited by the existence of the communication module, and the processing is more flexible and convenient.

Referring to fig. 6, the specific steps of the process are as follows:

s01: switching on the power supply of the washing machine; after the power supply is switched on, the display area becomes bright, the display is washed quickly, the clothes are dried, the power consumption is low, and water is saved.

S02: an analog knob on the display module is manually slid.

S03: the microprocessor acquires the indication information corresponding to each knob, and the attention of the washing machine is fast: uptime; removing the dry attention: upscharged; low power consumption attention: up power; water conservation concerns: upwater.

S04: calculating the current attention ratio of each demand: the current attention ratio is current attention/total attention,

wash fast current attention ratio: time/(uptime + upsteed + upstower + upwater);

removing the current attention ratio: the predicted is upsteed/(uptime + upsteed + upstower + upstater);

the current attention ratio of power consumption is low: the power is upper/(upper + upper);

the current attention ratio of water conservation: pwater/(uptime + upsteed + upstower + upwater);

s05: judging whether the washing method is used for the first time;

s06: taking the confirmed demand attention ratio as a final attention ratio of each demand, namely a quick-washing final attention ratio, a dry final attention ratio, a low-power-consumption final attention ratio and a water-saving final attention ratio;

s07: setting each demand attention ratio as an initial value, washing quickly to obtain a final attention ratio: ptimedef is 0.25; dry final focus ratio: pspeeeddef is 0.25; the power consumption is low, and the final attention ratio is as follows: ppowerdef is 0.25; water saving final attention ratio: pwaterdef is 0.25; the weight of each demand is the same when used for the first time, so the final attention ratio of each demand is set to the same value.

S08: calculating the difference between the current attention ratio and the final attention ratio, and washing the difference quickly: pdelttime ═ ptime-ptimedef;

removing a dry difference value: pdeltpredicted is pspeed-pspeeded; less difference in power consumption: pdeltpower ═ power-pwoerdef;

saving water difference value: pdeltwater ═ pwater-pwater.

S09: initializing the operation module; the operation module controls the washing time, the dehydration time, the heating time and the water inlet level, the attention execution demand for fast washing is the washing time Tumbletime, the attention execution demand for dry removal is the dehydration time Speedtime, the attention execution demand for low power consumption is the heating time Heattime, the water saving attention execution demand is the water inlet level filllevel,

the washing machine needs to meet the requirement of low power consumption, and the electric quantity can be saved only by reducing the heating time on the premise of ensuring the rotation speed of the washing machine and further ensuring the cleanness of clothes.

S10: washing time Tumbletime is rated washing time Tumbletime (1-fast washing difference pdelttime); the dehydration time, namely the rated dehydration time, namely, the dehydration time, 1+ to obtain a dry difference value pdeltspeced;

heating time heattime is rated heating time heattimed (1-power consumption difference pdeltpower); the intake water level filllevel is the rated intake water level filllelated (1-water saving difference pdeltwater).

S11: the micro-processor sends the washing time, the dehydration time, the heating time and the water inlet level to the corresponding operation modules respectively for washing.

S12: after washing is finished, the user slides the knob under the display area to score and evaluate the washing result.

S13: the microprocessor collects the score of each demand evaluation of a user, the fast score Uervaluetime is obtained by washing, the dry score Uervaluespeed is obtained, the power consumption is low, the score Uervaluepower is obtained, and the water fraction uservaluewater is saved.

S14: calculating the evaluation score ratio of each demand, wherein the washing fast score ratio is washing fast score/total score; removing dry fraction ratio, namely removing dry fraction/total fraction; the power consumption reduction fraction is less than the power consumption reduction fraction/total fraction; saving water fraction (water fraction/total fraction); the total fraction is the quick fraction of washing, the dry fraction of removing, the low power consumption fraction and the water fraction saving.

S15: the microprocessor analyzes and calculates the demand attention ratio: after the fast washing analysis, the attention ratio is equal to the final attention ratio of the fast washing (fast washing score ratio-fast washing current attention ratio); after the dry analysis is performed, obtaining a final dry attention ratio- (obtaining a dry score ratio-obtaining a current dry attention ratio);

after the power consumption reduction analysis, the attention ratio is smaller than the final attention ratio which is smaller than the power consumption (the power consumption reduction ratio is smaller than the current attention ratio which is smaller than the power consumption); and (4) after water saving analysis, namely the final water saving attention ratio- (water saving point ratio-current water saving attention ratio).

S16: and the microprocessor uploads the analysis result to the cloud server through the communication unit.

S17: and the cloud server finishes the manual audit and confirmation of the data.

S18: and after the manual examination, the cloud server issues the confirmed reasonable data to the washing machine.

S19: the microprocessor of the washing machine puts the confirmed index attention ratio into the storage space as the final attention ratio for each index to be washed faster in the next operation.

Specifically, in this embodiment, after the user connects the washing machine to the power supply, the display area is brightened, the user manually slides the knob corresponding to the lower side with fast washing to 70, the user manually slides the knob corresponding to the lower side with dry washing to 10, the user manually slides the knob corresponding to the lower side with low power consumption to 10, the user manually slides the knob corresponding to the lower side with saved water to 10, corresponding upper time is 70, upper speed is 10, upper power is 10, upwater, and as can be seen from the above step S24, the current attention ratio of washing is obtained: ptime ═ 0.7; dry current concern ratio: pspeed ═ 0.1; less power consumption is currently a concern: crown is 0.1; water saving current concern ratio: pwater is 0.1. From this figure, the user is more concerned about the need to wash the clothes faster, and wants to wash the clothes in less time, and is not very conscious of other washing needs. From S25 and S26, the difference in washing speed is: pdelttime ═ 0.45; removing a dry difference value: pdeltpredicted ═ 0.15; less difference in power consumption: pdeltpower ═ 0.15; saving water difference value: pdeltwater ═ 0.15. The washing time is calculated by S27 and S28, and the rated washing time tunblerated is set to 30 minutes, the rated dewatering time speeded is set to 10 minutes, the rated heating time heatrated is set to 10 minutes, and the rated water level filllevelated is set to 5 liters.

Step S28 is the technical solution obtained in the book of intersection, so that the washing time (Tumbletime) is the rated washing time (1-fast washing difference pdelttime), and it can be known from this example that the washing time (Tumbletime) is 16.5 minutes, the used time is less than 30 minutes of the rated washing time, and it is in accordance with the expected value of fast washing 70.

The micro-processor sends the washing time, the dehydration time, the heating time and the water inlet level to the corresponding operation modules respectively for washing.

After washing is finished, a user rotates a knob under the use display area to score and evaluate the washing result; the display area becomes bright, and the marking function of each washing requirement is displayed, and the mark is given to quick washing, dry washing, low power consumption and water saving; at this time, by turning a knob below each display area, 100 points are given to the washing speed, 0 points are removed, 0 points are consumed less, and 0 points are saved in water, and the user performs such points, which means that the washing speed is satisfactory, and the washing speed is not satisfactory, and the washing speed, the electricity consumption and the water saving are not so much concerned, and it can be known from steps S14 and S15 that the washing speed score ratio is 1, the washing speed score ratio is 0, the electricity consumption and the water saving score ratio are 0, and after the washing speed analysis, the attention ratio is that the washing speed final attention ratio (the washing speed score ratio-the washing speed current attention ratio) is 0.25- (1-0.7) -0.25; removing the attention ratio after dry analysis, namely removing the attention ratio of dry final attention ratio- (removing dry fraction ratio-removing dry current attention ratio) ═ 0.25- (0-0.1) ═ 0.35; after the power consumption reduction analysis, the attention ratio is reduced to power consumption, the final attention ratio is reduced to power consumption, the current attention ratio is reduced to power consumption, and the attention ratio is 0.25- (0-0.1) to 0.35; after water saving analysis, the attention ratio is equal to the final attention ratio of water saving (the water saving point ratio-the current attention ratio of water saving) is equal to 0.25- (0-0.1) and equal to 0.35. The microprocessor uploads the analysis result to the cloud server through the communication unit after analyzing each requirement, the cloud server finishes manual examination and confirmation of data, the cloud server issues the confirmed reasonable data to the washing machine, and the microprocessor of the washing machine puts the confirmed index attention ratio into a storage space to serve as the final attention ratio for washing each index when the washing machine operates next time. Meanwhile, the data is stored in the cloud server, and the microprocessor can request the cloud server to issue the data again when the data of the washing machine is abnormal after the washing machine is started next time. Therefore, the satisfaction degree score of the user on the washing result influences the setting of the washing parameters of the next time, the washing result is fed back to the washing process of the next time, the interaction between the washing method and the user is realized, and the optimization processing of the washing method is realized.

Customer attention performance:

after obtaining the attention ratio difference of the current program, each module of the MCU needs to convert it into an operation that can be actually performed by the washing machine. After the washing machine finishes washing, the setting and the final operation result of the user are reported to the server, and data are prepared for the intelligent closed-loop management in the later period.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (6)

1. A washing method capable of setting washing parameters is applied to a washing machine, the washing machine comprises a control module, an input module and a display module, the control module is a microprocessor, and is characterized in that,

the laundry method comprises the steps of,

s1: inputting at least one user washing requirement and corresponding parameters thereof in an input module;

s2: the micro processor receives the washing requirement and the parameters thereof;

s3: calculating the operation data of each operation module when the washing machine operates according to the washing requirement and the parameters thereof specified by the user, wherein the step S3 specifically comprises the following steps:

s24: calculating the current attention ratio of each demand: the current attention ratio is current attention/total attention,

s25: setting each demand final attention ratio as an initial value;

s26: calculating a difference between the current attention ratio and the final attention ratio of each laundry demand;

s27: initializing the operation module; the operation module controls washing time, dehydration time, heating time and water inlet level, the attention execution requirement for fast washing is the washing time, the attention execution requirement for dry dehydration is the dehydration time, the attention execution requirement for low power consumption is the heating time, the attention execution requirement for water conservation is the water inlet level,

s28: washing time (nominal washing time × (1+ fast difference of washing)); the dehydration time is the rated dehydration time (1+ dehydration difference);

heating time (rated heating time) (1+ power consumption difference); the water inlet level is the rated water inlet level (1+ water saving difference);

s4: the microprocessor sends the operation data to the corresponding operation module to carry out laundry treatment;

after the processing of step S4, the method further includes the following steps: s5: after washing is finished, scoring evaluation is carried out on the completion satisfaction degree of the washing requirements of the user, and the micro processor carries out operation according to the scoring;

s6: the microprocessor sets the washing speed of the operation result to be higher than the final attention ratio;

the user washing requirements comprise fast washing, dry dewatering, low power consumption and water saving, and the input mode corresponding to each requirement is to simulate knob input on the input module.

2. A laundry washing method according to claim 1, wherein the laundry washing machine further has a communication module; the micro processor of the washing machine is connected with the cloud server through the communication module; the microprocessor is respectively connected with the communication module, the input module and the display module.

3. The laundry method according to claim 2, wherein the display module is a mobile phone display screen, and the mobile phone display screen is connected with the laundry machine or the cloud server through a mobile phone processor and a mobile phone built-in communication module.

4. A laundry washing method according to claim 1, wherein the initial value of each required final focus ratio is 0.25.

5. A laundry method according to claim 2, wherein the step S6 specifically comprises the steps of:

s13: the micro processor collects the scores of each demand evaluation of the user, including the quick washing score and the dry removing score, the power consumption is low, and the water score is saved;

s14: calculating the evaluation score ratio of each demand, wherein the washing fast score ratio is washing fast score/total score; removing dry fraction ratio, namely removing dry fraction/total fraction; the power consumption reduction fraction is less than the power consumption reduction fraction/total fraction; saving water fraction (water fraction/total fraction); the total fraction is the quick fraction obtained by washing, the dry fraction obtained by removing, the low power consumption fraction and the water fraction saved;

s15: the microprocessor analyzes and calculates the demand attention ratio: after the fast washing analysis, the attention ratio is equal to the final attention ratio of the fast washing (fast washing score ratio-fast washing current attention ratio); after the dry analysis is performed, obtaining a final dry attention ratio- (obtaining a dry score ratio-obtaining a current dry attention ratio);

after the power consumption reduction analysis, the attention ratio is smaller than the final attention ratio which is smaller than the power consumption (the power consumption reduction ratio is smaller than the current attention ratio which is smaller than the power consumption); and (4) after water saving analysis, namely the final water saving attention ratio- (water saving point ratio-current water saving attention ratio).

6. A laundry process according to claim 5, further comprising the step of, after the treatment of S15:

s16: the micro processor uploads the analysis result to the cloud server through the communication module;

s17: the cloud server finishes the data and performs manual audit confirmation;

s18: after the manual examination, the cloud server issues the confirmed reasonable data to the washing machine;

s19: the microprocessor of the washing machine puts the confirmed index attention ratio into the storage space as the final attention ratio for each index to be washed faster in the next operation.

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