CN113975877B

CN113975877B - Control method and device of water purifying equipment, electronic equipment and storage medium

Info

Publication number: CN113975877B
Application number: CN202111492975.7A
Authority: CN
Inventors: 詹婷; 陈静
Original assignee: Gree Electric Appliances Inc of Zhuhai
Current assignee: Gree Electric Appliances Inc of Zhuhai
Priority date: 2021-12-08
Filing date: 2021-12-08
Publication date: 2022-08-26
Anticipated expiration: 2041-12-08
Also published as: CN113975877A

Abstract

The application relates to a control method and device of a water purifying device, an electronic device and a storage medium. The method comprises the following steps: in the working process of the water purifying equipment, acquiring pump operation parameters of the water purifying equipment; calculating the pump operation variable quantity of the water purifying equipment according to the pump operation parameters; adjusting the flushing parameters of the water purification equipment based on the pump operation variation and the initial flushing parameters in the working process of the water purification equipment to obtain the adjusted flushing parameters; and controlling the water purification equipment to flush according to the adjusted flushing parameters. By adopting the method provided by the embodiment of the application, the flushing program of the water purifying equipment can be adjusted according to the real-time blocking condition of the filter element in the working process of the water purifying equipment, so that the flushing program can adapt to the water quality of the area where the water purifying equipment is located, the flushing effect and the water-saving requirement are both considered, the automatic adjustment of the flushing program of the water purifying equipment is realized, and the flushing efficiency of the water purifying equipment can be improved.

Description

Control method and device of water purifying equipment, electronic equipment and storage medium

Technical Field

The present application relates to the field of water purification devices, and in particular, to a method and an apparatus for controlling a water purification device, an electronic device, and a storage medium.

Background

With the continuous improvement of the quality of life of people, the filtration technology is developed and widely applied to water purification equipment. With the increase of the filtering water amount of the water purifying equipment, the filter element is blocked by pollutants and concentrated scales in the water, so that the water purifying speed is reduced. Therefore, in order to extend the service life of the filter cartridge, the water purifying apparatus is generally provided with a preset flushing program, and the preset flushing program is automatically executed.

However, predetermine the washing procedure and need compromise washing effect and using water wisely demand, generally set up according to typical or general quality of water region, can't adjust according to the actual running state of filter core, however, because the quality of water difference of all districts of whole nation is big, in the in-service use in-process, partial area is because quality of water is relatively poor, can have the dirty stifled speed of filter core very fast, it is not enough to wash the frequency, can produce the not good problem of washing effect, and partial area is because quality of water is better, can have the filter core to wash frequent problem, lead to the water waste.

Disclosure of Invention

In view of the above, it is necessary to provide a control method, a control device, an electronic device and a storage medium for a water purification apparatus, which can automatically adjust a flushing program of a filter element of the water purification apparatus.

A method of controlling a water purification apparatus, the method comprising:

in the working process of the water purifying equipment, acquiring pump operating parameters of the water purifying equipment;

calculating the pump operation variable quantity of the water purifying equipment according to the pump operation parameters;

adjusting the flushing parameters of the water purifying equipment based on the pump operation variation and the initial flushing parameters in the working process of the water purifying equipment to obtain adjusted flushing parameters;

and controlling the water purification equipment to flush according to the adjusted flushing parameters.

In one embodiment, after the obtaining the pump operation parameters of the water purification apparatus, before the calculating the pump operation variation of the water purification apparatus according to the pump operation parameters, the method further includes:

and if the washing condition corresponding to the initial washing parameter is achieved, controlling the water purifying equipment to wash according to the initial washing parameter.

In one embodiment, the pump operation is varied by the difference between the two pump operation parameters.

In one embodiment, the pump operation variation is a pump operation parameter variation coefficient of the water purification apparatus calculated according to each pump operation parameter and a water purification parameter corresponding to each pump operation parameter.

In one embodiment, the method for calculating and obtaining the variation coefficient of the pump operation parameter of the water purification device comprises:

determining water purification parameters of the water purification equipment corresponding to the operation parameters of the pumps;

determining an average water purification parameter and an average pump operation parameter according to the pump operation parameters and the water purification parameters respectively;

and calculating to obtain the pump operation parameter variation coefficient of the water purification equipment according to the operation parameter difference value of each pump operation parameter and the average pump operation parameter and the water purification parameter difference value of each water purification parameter and the average water purification parameter.

In one embodiment, the pump operation parameter variation coefficient is a ratio of a sum of products of each operation parameter difference and a corresponding water purification parameter difference to a sum of squares of each water purification parameter difference.

In one embodiment, the pump operating parameter includes at least one of pump current and pump speed.

In one embodiment, the water purification parameter includes at least one of a water purification time period and a water purification amount.

In one embodiment, the adjusting the flushing parameters of the water purifying equipment based on the pump operation variation and the initial flushing parameters of the water purifying equipment during the operation process to obtain adjusted flushing parameters includes:

if the pump operation variation is larger than a first variation, setting a first flushing parameter as the adjusted flushing parameter, wherein the first flushing parameter comprises any one of a first flushing interval, a first single flushing time length, a first flushing voltage and a first flushing pump rotating speed, the first flushing interval is smaller than an initial flushing interval in the initial flushing parameter, the first single flushing time length is larger than an initial single flushing time length in the initial flushing parameter, the first flushing voltage is larger than an initial flushing voltage in the initial flushing parameter, and the first flushing pump rotating speed is larger than the initial flushing pump rotating speed in the initial flushing parameter;

if the pump operation variable quantity is less than the second variable quantity, the second flushing parameter is set to the adjusted flushing parameter, the second flushing parameter comprises any one of a second flushing interval, a second single flushing time length, a second flushing voltage and a second flushing pump rotating speed, the second flushing interval is greater than the initial flushing interval in the initial flushing parameter, the second single flushing time length is less than the initial single flushing time length in the initial flushing parameter, the second flushing voltage is less than the initial flushing voltage in the initial flushing parameter, and the second flushing pump rotating speed is less than the initial flushing pump rotating speed in the initial flushing parameter.

In one embodiment, the first flushing interval is a time interval after the initial flushing interval is shortened by a first proportion, and the second flushing interval is a time interval after the initial flushing interval is increased by a second proportion;

the first single flushing time length is the time length obtained by increasing the initial single flushing time length by a third proportion, and the second single flushing time length is the time length obtained by decreasing the initial single flushing time length by a fourth proportion;

the first flushing voltage is the voltage obtained by increasing the initial flushing voltage by a fifth proportion, and the second flushing voltage is the voltage obtained by decreasing the initial flushing voltage by a sixth proportion;

the first flushing pump rotating speed is the pump rotating speed obtained by increasing the initial flushing pump rotating speed by a seventh proportion, and the second flushing pump rotating speed is the pump rotating speed obtained by decreasing the initial flushing pump rotating speed by an eighth proportion.

A control device for a water purification apparatus, the device comprising:

the parameter acquisition module is used for acquiring the pump operation parameters of the water purification equipment in the working process of the water purification equipment;

the calculation module is used for calculating the pump operation variation of the water purification equipment according to the pump operation parameters;

the parameter adjusting module is used for adjusting the flushing parameters of the water purifying equipment based on the pump operation variable quantity and the initial flushing parameters in the working process of the water purifying equipment to obtain the adjusted flushing parameters;

and the flushing control module is used for controlling the water purifying equipment to flush according to the adjusted flushing parameters.

An electronic device comprises a memory and a processor, wherein the memory stores a computer program, and the processor realizes the steps of the control method of the water purifying device when executing the computer program.

A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the steps of the control method of a water purification device as described above.

According to the control method and device, the electronic equipment and the storage medium of the water purifying equipment, the pump operation parameters of the water purifying equipment are obtained in the working process of the water purifying equipment; calculating the pump operation variable quantity of the water purifying equipment according to the pump operation parameters; adjusting the flushing parameters of the water purification equipment based on the pump operation variation and the initial flushing parameters in the working process of the water purification equipment to obtain the adjusted flushing parameters; and controlling the water purification equipment to flush according to the adjusted flushing parameters. By adopting the method of the embodiment, the flushing program of the water purifying equipment can be adjusted according to the real-time blocking condition of the filter element in the working process of the water purifying equipment, so that the flushing program can adapt to the water quality of the area where the water purifying equipment is located, the flushing effect and the water saving requirement are both considered, the automatic adjustment of the flushing program of the water purifying equipment is realized, and the flushing efficiency of the water purifying equipment can be improved.

Drawings

FIG. 1 is a diagram illustrating an application environment of a control method of a water purifying apparatus according to an embodiment;

FIG. 2 is a schematic flow chart illustrating a control method of the water purifying apparatus according to an embodiment;

FIG. 3 is a schematic flow chart of a control method of a water purification apparatus according to an embodiment;

FIG. 4 is a block diagram showing the structure of a control device of the water purifying apparatus according to an embodiment;

FIG. 5 is a diagram illustrating an internal structure of an electronic device in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In one embodiment, the application environment of the control method of the water purification apparatus provided by the present application may relate to both the water purification apparatus 102 and the external control apparatus 104, as shown in fig. 1. Wherein, the water purification unit 102 communicates with the external control unit 104 through network, protocol or bluetooth. Specifically, during the operation of the water purification apparatus 102, the external control apparatus 104 obtains the pump operation parameters of the water purification apparatus 102; calculating the pump operation variation of the water purification equipment 102 according to the pump operation parameters; the flushing parameters of the water purification apparatus 102 are adjusted based on the pump operation variation and the initial flushing parameters in the working process of the water purification apparatus 102, and the adjusted flushing parameters are obtained. When determining that the water purification apparatus 102 reaches the adjusted post-flush condition corresponding to the adjusted post-flush parameter, the external control apparatus 102 sends a flush instruction to the water purification apparatus 102 to control the water purification apparatus 102 to flush according to the flush instruction.

In one embodiment, the application environment of the control method of the water purification apparatus provided by the present application may only relate to the water purification apparatus 102. Wherein, a controller is arranged in the water purifying device 102. Specifically, in the working process of the water purification unit 102, the controller obtains the pump operation parameters of the water purification unit 102; calculating the pump operation variation of the water purification equipment 102 according to the pump operation parameters; based on the pump operation variation and the initial flushing parameter of the water purification apparatus 102 during the operation process, the flushing parameter of the water purification apparatus 102 is adjusted to obtain the adjusted flushing parameter, and the water purification apparatus 102 is controlled to flush according to the adjusted flushing parameter.

The water purifying device 102 may be a household water purifying device or a commercial water purifying device, the water purifying device 102 includes, but is not limited to, a cotton filter element water purifier, a reverse osmosis water purifier, an ultrafiltration water purifier, and the like, the controller in the water purifying device 102 may be a control circuit board or a control chip, the external control device 104 may be a terminal or a server, the terminal includes a smart phone, a tablet computer, a portable wearable device, and the like, and the server may be implemented by an independent server or a server cluster formed by a plurality of servers.

In one embodiment, as shown in fig. 2, a method for controlling a water purifying apparatus is provided, which is described by taking an example of the method applied to a controller of the water purifying apparatus 102 in fig. 1, and includes:

and S202, acquiring the pump operation parameters of the water purifying equipment in the working process of the water purifying equipment.

In one embodiment, the water purifying apparatus is an apparatus for producing purified water by using a reverse osmosis process, in which water flows from a low concentration to a high concentration, and the water flows from the high concentration to the low concentration after being pressurized, i.e., a principle of the reverse osmosis process, thereby filtering contaminants, scales, and the like in the water. The filter element of the water purifying device can be an activated carbon filter element, an ultrafiltration membrane filter element, a Reverse Osmosis membrane filter element (RO) and the like. The water purifying equipment further comprises a water pump, which can be a booster pump, including but not limited to a gas-liquid booster pump, a gas booster pump, an air booster pump, a chlorine booster pump and the like, and can be selected according to the actual application of the water purifying equipment.

In one embodiment, the pump operation parameter refers to an operation parameter of a water pump of the water purification apparatus, including but not limited to a current and a rotation speed of the water pump, which are respectively referred to as a pump current and a pump rotation speed, i.e. the pump operation parameter includes at least one of the pump current and the pump rotation speed. Along with the increase of the water filtration quantity of the water purification equipment or the change of water quality, pollutants and water scales in water can cause the filter element of the water purification equipment to be blocked, so that the operation parameters of the pump are changed, namely the operation parameters of the pump can reflect the real-time blocking condition of the filter element of the water purification equipment, and the filter element is washed. Generally, a wastewater electromagnetic valve of the water purifying equipment is opened by controlling, a water inlet electromagnetic valve is controlled to be electrified, and a water pump is controlled to be electrified, so that a filter element of the water purifying equipment is washed.

Theoretically, along with the gradual blockage of the filter element of the water purifying equipment, the pump current can be gradually increased, and the pump rotating speed can be gradually reduced. Therefore, the water purifying equipment can determine the real-time blocking condition of the filter element according to the pump operation parameters, and further determine whether to flush the filter element or not so as to prolong the service life of the filter element and achieve the effect of saving water. Specifically, in the working process of the water purifying equipment, the pump operation parameters of the water purifying equipment are obtained. The working circuit of the water pump of the water purifying device may be provided with a pump operation parameter detection component, specifically, a current detection component and a rotation speed detection component, such as an ammeter, a tachometer, a current sensor, a rotation speed sensor, and the like, so as to obtain the pump operation parameter by detection, that is, obtain the pump current and the pump rotation speed by detection.

In one embodiment, since the detection time of the pump operation parameter detection assembly is short, the obtained pump operation parameters include a plurality of pump operation parameters, specifically, the pump operation parameters detected at each detection time point may be the pump operation parameters detected at each detection time point, and the pump operation parameters detected at each detection parameter point may also be the pump operation parameters detected at each detection time point. When the pump operation parameters obtained at each detection time point are detected, the time intervals between the detection time points may be the same or different. For example, 4 pump operation parameters are obtained, and if the pump operation parameters are detected respectively at 10 minutes, 20 minutes, 30 minutes and 40 minutes of water purification in the water purification apparatus, the time intervals between the detection time points are the same. If the detection time points are detected respectively when the water purifying equipment purifies water for 10 minutes, 11 minutes, 20 minutes and 26 minutes, the time intervals among the detection time points are different, namely the detection time points are random detection time points. Wherein, the detection parameter point can be confirmed according to the water purification volume, specifically can be for detecting the water purification volume point, when detecting at each detection water purification volume point and obtaining pump operating parameter, the water purification volume difference value between each detection water purification volume point can be the same, also can not be the same. For example, 4 pump operation parameters are obtained, and if the pump operation parameters are detected at 10 liters, 20 liters, 30 liters and 40 liters of clean water in the water purifying plant, the clean water amount difference values between the detected clean water amount points at this time are the same. If the difference values are detected respectively in 10 liters, 11 liters, 20 liters and 26 liters of purified water of the water purifying equipment, the purified water quantity difference values between the detected purified water quantity points are different, namely the detected purified water quantity points are random detected purified water quantity points.

In one embodiment, when the water purification equipment is produced, the washing conditions for washing the filter element are preset, and the washing conditions preset for different water purification equipment are different. The preset flushing condition can be a preset water purification time length or a preset water purification amount, and the flushing parameters contained in the preset flushing condition are called as initial flushing parameters. Specifically, the initial flush parameters may include any one of an initial flush interval, an initial single flush duration, an initial flush voltage, and an initial flush pump speed. And if the water purifying time of the water purifying equipment reaches the preset water purifying time or the water purifying quantity of the water purifying equipment reaches the preset water purifying quantity, the preset flushing condition of the water purifying equipment is determined to be reached. Therefore, if the washing condition corresponding to the initial washing parameter is achieved, the water purifying equipment is controlled to wash according to the initial washing parameter, and the subsequent calculation processing step is continuously executed after washing. In addition, if the washing condition corresponding to the initial washing parameter is not reached, the subsequent calculation processing steps are directly continued to be executed.

And step S204, calculating the pump operation variation of the water purifying equipment according to the pump operation parameters.

In one embodiment, the pump operation variation of the water purification unit is calculated according to the pump operation parameter. The variable quantity of the pump operation parameters can reflect the speed of the change of the pump operation parameters, namely the real-time blockage condition of the filter element. The pump operation variation can be a difference value of two pump operation parameters, and the two pump operation parameters at the moment can be pump operation parameters obtained by detecting time points or pure water amount points at any two times, can be adjacent two times, and can also be nonadjacent two times. For example, when the pump operation variation is a difference between the pump operation parameters corresponding to any two detection time points, 4 pump operation parameters are obtained and detected when the water purifying equipment purifies water for 10 minutes, 20 minutes, 30 minutes and 40 minutes, respectively, and when the pump operation variation is calculated, the difference between the pump operation parameters corresponding to the water purifying equipment purifies water for 10 minutes and 20 minutes may be calculated, or the difference between the pump operation parameters corresponding to the water purifying equipment purifies water for 10 minutes and 30 minutes may be calculated. For example, when the pump operation variation is the difference between the pump operation parameters corresponding to the detected water purification amount points at any two times, 4 pump operation parameters are obtained and detected at 10 liters, 20 liters, 30 liters and 40 liters of purified water of the water purification apparatus, respectively, and when the pump operation variation is calculated, the difference between the pump operation parameters corresponding to 10 liters and 20 liters of purified water of the water purification apparatus may be calculated, or the difference between the pump operation parameters corresponding to 10 liters and 30 minutes of purified water of the water purification apparatus may be calculated.

In one embodiment, the pump operating parameter includes at least one of pump current and pump speed. If the pump operation parameter is the pump current, the pump operation variation is the pump current variation, i.e. the difference between the two pump currents. If the pump operation parameter is the pump rotation speed, the pump operation variation is the pump rotation speed variation, that is, the difference between the two pump rotation speeds.

Wherein, if the obtained pump currents are respectively in the water purifying device for purifying water T ₁ Pump current A detected by duration ₁ And in the water purification unit ₂ Duration-detected pump current A ₂ Or, if the obtained pump current is respectively the water purified Q in the water purifying equipment ₁ Pump current A obtained by liter detection ₁ And in the water purification equipment water purification Q ₂ Pump current A detected by liter ₂ If the pump current variation Δ a is greater than the pump current variation Δ a, the calculation formula is:

ΔA＝A ₂ -A ₁

wherein, if the obtained pump rotating speeds are respectively the water purification T of the water purification equipment ₁ Pump speed R obtained by duration detection ₁ And in the water purification unit ₂ Pump speed R obtained by duration detection ₂ Or if the obtained pump rotating speeds are respectively the water purification Q of the water purification equipment ₁ Pump speed R measured in liters ₁ And in the water purification equipment water purification Q ₂ Pump speed R measured in liters ₂ If the pump speed variation Δ R is greater than the preset value, the calculation formula is as follows:

ΔR＝R ₂ -R ₁

in one embodiment, the pump operation variation may also be a pump operation parameter variation coefficient corresponding to the pump operation parameter, where the pump operation parameter variation coefficient may be obtained by calculation according to the pump operation parameter and a water purification parameter corresponding to the pump operation parameter, that is, the pump operation variation may also be a pump operation parameter variation coefficient of the water purification apparatus obtained by calculation according to each pump operation parameter and a water purification parameter corresponding to each pump operation parameter. Specifically, the water purification parameters of the water purification apparatus include at least one of a water purification duration and a water purification amount.

In particular, as the water purification apparatus is continuously operated, the pump operation parameters are continuously detected and acquired. Wherein, the mode of calculating the pump operation parameter variation coefficient who obtains water purification unit includes: determining water purification parameters of the water purification equipment corresponding to the operation parameters of each pump; determining an average water purification parameter and an average pump operation parameter according to the pump operation parameters and the water purification parameters respectively; and calculating to obtain the pump operation parameter variation coefficient of the water purification equipment according to the operation parameter difference value of each pump operation parameter and the average pump operation parameter and the water purification parameter difference value of each water purification parameter and the average water purification parameter. Specifically, the pump operation parameter variation coefficient is a ratio of the sum of products of each operation parameter difference and the corresponding water purification parameter difference to the sum of squares of each water purification parameter difference.

In one embodiment, if the pump operation parameter is a pump current, the pump operation variation is a pump current variation coefficient. Because the filter element of the water purifying equipment is gradually blocked, the pump current can be gradually increased, and therefore, the pump current change coefficient is the pump current increase coefficient, and the magnitude of the pump current increase coefficient can reflect the speed of the pump current increase. Wherein, the time length of water purification of the water purification equipment corresponding to the pump current is determined, and if the acquired pump current is water purification T of the water purification equipment respectively ₁ Pump current A detected by duration ₁ In water purification equipment water purification T ₂ Pump current A detected by duration ₂ Until the water purification T of the water purification equipment _i Pump current A detected by duration _i 。

Determining the average water purification duration according to the water purification duration

The calculation formula is as follows:

determining an average pump current from the pump currents

The calculation formula is as follows:

calculating to obtain the pump current variation coefficient b of the water purifying equipment according to the pump current difference value of each pump current and the average pump current and the water purifying time length difference value of each water purifying time length and the average water purifying time length _A The calculation formula is as follows:

the pump current variation coefficient is the ratio of the sum of products of each pump current difference and the corresponding water purification time length difference to the sum of squares of each water purification time length difference.

In one embodiment, the water purification amount of the water purification device corresponding to the pump current is determined, and if the obtained pump currents are respectively the water purification Q in the water purification device ₁ Pump current A detected by liter ₁ In the water purifying equipment, the water Q is purified ₂ Pump current A detected by liter ₂ Until the water is purified in the water purifying equipment Q _i Pump current A detected by liter _i 。

Determining the average purified water amount according to each purified water amount

The calculation formula is as follows:

determining an average pump current from the pump currents

The calculation formula is as follows:

calculating and obtaining a pump current change coefficient b of the water purifying equipment according to a pump current difference value of each pump current and the average pump current and a purified water amount difference value of each purified water amount and the average purified water amount _A The calculation formula is as follows:

the pump current variation coefficient is the ratio of the sum of products of each pump current difference value and the corresponding purified water quantity difference value to the sum of squares of each purified water quantity difference value.

In one embodiment, if the pump operation parameter is a pump speed, the pump operation variation is a pump speed variation coefficient. As the filter element of the water purifying equipment is gradually blocked, the rotating speed of the pump can be gradually reduced, so that the change coefficient of the rotating speed of the pump is the attenuation coefficient of the rotating speed of the pump, and the reduction speed of the rotating speed of the pump can be reflected by the change coefficient of the rotating speed of the pump. Determining the water purification duration of the water purification equipment corresponding to the pump rotating speed, and if the obtained pump rotating speeds are water purification T of the water purification equipment respectively ₁ Pump speed R obtained by duration detection ₁ In water purification equipment water purification T ₂ Pump speed R obtained by duration detection ₂ Until the water purification T of the water purification equipment _i Pump speed R obtained by duration detection _i 。

The calculation formula is as follows:

determining an average pump speed from the pump speeds

The calculation formula is as follows:

calculating and obtaining a pump rotating speed change coefficient b of the water purifying equipment according to a pump rotating speed difference value of each pump rotating speed and the average pump rotating speed and a water purifying time difference value of each water purifying time and the average water purifying time _R The calculation formula is as follows:

the pump rotating speed variation coefficient is the ratio of the sum of the products of the pump rotating speed difference values and the corresponding water purification time length difference values to the sum of squares of the water purification time length difference values.

In one embodiment, the purified water amount of the water purification device corresponding to the pump rotation speed is determined, and if the obtained pump rotation speeds are respectively the purified water Q in the water purification device ₁ Pump speed R measured in liters ₁ In the water purifying equipment, the water Q is purified ₂ Pump speed R measured in liters ₂ Until the water is purified in the water purifying equipment Q _i Pump speed R measured in liters _i 。

The calculation formula is as follows:

determining an average pump speed from the pump speeds

The calculation formula is as follows:

calculating and obtaining a pump rotating speed change coefficient b of the water purifying equipment according to a pump rotating speed difference value of each pump rotating speed and the average pump rotating speed and a purified water quantity difference value of each purified water quantity and the average purified water quantity _R The calculation formula is as follows:

the pump rotating speed variation coefficient is the ratio of the sum of the products of the pump rotating speed difference values and the corresponding purified water quantity difference values to the sum of squares of the purified water quantity difference values.

It should be noted that the pump operation variation may be determined according to a single type of pump operation parameter, for example, the corresponding pump current variation, pump rotation speed variation, pump current variation coefficient, and pump rotation speed variation coefficient are determined according to the pump current and the pump rotation speed, respectively. In addition, the pump operation variation may also be determined synthetically from various types of pump operation parameters, for example, from the pump current and the pump speed, the corresponding pump operation variation being determined synthetically. Specifically, a functional relationship among various types of pump operation parameters is established in advance, and the pump operation variation is determined comprehensively.

And S206, adjusting the flushing parameters of the water purifying equipment based on the pump operation variable quantity and the initial flushing parameters in the working process of the water purifying equipment to obtain the adjusted flushing parameters.

In one embodiment, in order to adapt the flushing parameters to the real-time blocking condition of the filter element of the water purifying equipment and take the flushing effect and the water saving requirement into consideration, the initial flushing parameters in the working process of the water purifying equipment need to be adjusted, and then the filter element of the water purifying equipment is flushed. The adjusted initial flushing parameters are referred to as adjusted flushing parameters. Specifically, since the pump operation variation reflects the real-time blockage of the filter element, the initial flushing parameter can be adjusted according to the calculated pump operation variation.

In one embodiment, the initial flushing parameter includes a preset first variation and a preset second variation, wherein the first variation is greater than or equal to the second variation. The amount of pump operation variation is compared to the amount of variation contained in the initial flush parameters. In the comparison, the pump operation variation amount needs to be compared with a corresponding variation amount. For example, if the pump operation variation is the pump current variation, the pump operation variation is compared with the pump current variation included in the initial flushing parameter. And if the pump operation variation is the pump current variation coefficient, comparing the pump operation variation with the pump current variation coefficient contained in the initial flushing parameter.

In one embodiment, if the pump operation variation is greater than the first variation, it indicates that the real-time blocking speed of the filter element is faster, and if the filter element is flushed according to the initial flushing parameters, the flushing effect is poor. Thus, the first flush parameter may be set to the adjusted post-flush parameter. When the initial flushing parameters are adjusted, the initial flushing parameters can be directly switched to the first flushing parameters, or the initial flushing parameters can be gradually adjusted to the first flushing parameters. The first flushing parameter includes any one of a first flushing interval, a first single flushing duration, a first flushing voltage, and a first flushing pump rotational speed. Specifically, the first flushing interval is smaller than the initial flushing interval in the initial flushing parameters, the first single flushing duration is longer than the initial single flushing duration in the initial flushing parameters, the first flushing voltage is longer than the initial flushing voltage in the initial flushing parameters, and the first flushing pump rotation speed is longer than the initial flushing pump rotation speed in the initial flushing parameters.

The first flushing interval is a time interval after the initial flushing interval is shortened by a first proportion, and the first proportion may be a preset proportion, and is expressed as a%. The first single rinsing duration is a duration of the initial single rinsing duration increased by a third proportion, which may be a preset proportion, expressed as b%. The first rinsing voltage is a voltage obtained by increasing the initial rinsing voltage by a fifth proportion, which may be a preset proportion and is expressed as c%. The first flush pump speed is the pump speed after the initial flush pump speed is increased by a seventh proportion, which may be a preset proportion, expressed as d%.

In one embodiment, if the pump operation variation is smaller than the second variation, it indicates that the real-time blocking speed of the filter element is slow, and if the filter element is flushed according to the initial flushing parameters, the waste of flushing water is caused. Thus, the second flush parameter may be set to the adjusted post-flush parameter. When the initial flushing parameters are adjusted, the initial flushing parameters can be directly switched to the second flushing parameters, or the initial flushing parameters can be gradually adjusted to the second flushing parameters. The second flushing parameter comprises any one of a second flushing interval, a second single flushing time length, a second flushing voltage and a second flushing pump rotating speed. Specifically, the second flushing interval is greater than the initial flushing interval in the initial flushing parameters, the second single flushing duration is less than the initial single flushing duration in the initial flushing parameters, the second flushing voltage is less than the initial flushing voltage in the initial flushing parameters, and the second flushing pump rotation speed is less than the initial flushing pump rotation speed in the initial flushing parameters.

Wherein the second flushing interval is a time interval after the initial flushing interval is increased by a second proportion, and the second proportion may be a preset proportion, which is denoted as e%. The second single rinsing duration is a duration of the initial single rinsing duration reduced by a fourth proportion, which may be a preset proportion, expressed as f%. The second flushing voltage is a voltage obtained by reducing the initial flushing voltage by a sixth proportion, and the sixth proportion can be a preset proportion and is expressed as g%. The second washing pump rotation speed is the pump rotation speed after the initial washing pump rotation speed is reduced by an eighth proportion, and the eighth proportion can be a preset proportion and is expressed as h%. It should be noted that, the data values of the first proportion and the second proportion, the third proportion and the fourth proportion, the fifth proportion and the sixth proportion, and the seventh proportion and the eighth proportion may be the same or different, and may be specifically limited according to the actual situation of the water purification apparatus.

And S208, controlling the water purifying equipment to flush according to the adjusted flushing parameters.

In one embodiment, after the adjusted washing parameters are obtained, the water purification equipment is controlled to wash the filter element of the water purification equipment according to the obtained adjusted washing parameters, so that the washing effect is improved, and the requirement of saving water is met. Specifically, the waste water electromagnetic valve of the water purifying device is controlled to be opened, the water inlet electromagnetic valve is controlled to be electrified, and the water pump is controlled to be electrified, so that the filter element of the water purifying device is washed.

In the control method of the water purification equipment, the pump operation parameters of the water purification equipment are obtained in the working process of the water purification equipment; calculating the pump operation variable quantity of the water purifying equipment according to the pump operation parameters; adjusting the flushing parameters of the water purification equipment based on the pump operation variation and the initial flushing parameters in the working process of the water purification equipment to obtain the adjusted flushing parameters; and controlling the water purifying equipment to flush according to the adjusted flushing parameters. By adopting the method of the embodiment, the flushing program of the water purifying equipment can be adjusted according to the real-time blocking condition of the filter element in the working process of the water purifying equipment, so that the flushing program can adapt to the water quality of the area where the water purifying equipment is located, the flushing effect and the water saving requirement are both considered, the automatic adjustment of the flushing program of the water purifying equipment is realized, and the flushing efficiency of the water purifying equipment can be improved.

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is further described in detail below with reference to the accompanying drawings and a specific embodiment. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In a specific embodiment, a controller is arranged in the water purifying device, the controller can control the working process of the water purifying device and the washing program of the reverse osmosis membrane filter element, and an ammeter and a tachometer are arranged in a working circuit of a water pump of the water purifying device so as to respectively detect and obtain the pump current and the pump speed. Fig. 3 is a schematic flow chart showing a method for controlling a water purifying apparatus by a controller, which comprises the following steps:

the water purifying equipment starts to work, and at least one of pump current and pump rotating speed in the working process of the water purifying equipment is obtained;

if the water purifying time of the water purifying equipment reaches the preset water purifying time or the water purifying amount reaches the preset water purifying amount, determining that the preset flushing condition of the water purifying equipment is reached, and controlling the water purifying equipment to flush according to the initial flushing parameters;

if the situation that the preset flushing condition of the water purifying equipment is not met is determined, calculating the pump operation variation of the water purifying equipment according to the pump operation parameters, and adjusting the flushing parameters of the water purifying equipment based on the pump operation variation and the initial flushing parameters in the working process of the water purifying equipment to obtain the adjusted flushing parameters; wherein, the pump operation variable quantity is the difference of the pump operating parameter twice, or, the pump operation variable quantity is according to each pump operating parameter to and the water purification parameter that each pump operating parameter corresponds, calculates the pump operating parameter coefficient of change of the water purification unit who obtains, specifically includes:

taking a pump operation parameter as a pump current, and taking a difference value of the pump current with a pump operation variable quantity of two times as an example;

if the obtained pump currents are respectively in the water purifying equipment ₁ Long time or pure water Q ₁ Pump current A detected by liter ₁ And in the water purification unit ₂ Long time or pure water Q ₂ Pump current A obtained by liter detection ₂ Then, the pump current variation Δ a is calculated by the following formula:

ΔA＝A ₂ -A ₁

if pump current variable delta A is greater than first pump current variable, it is fast to explain the real-time jam speed of filter core, if wash according to the initial parameter of washing, can lead to washing the effect not good. Therefore, the first flushing parameter is set as the adjusted flushing parameter, the first flushing parameter includes any one of a first flushing interval, a first single flushing time, a first flushing voltage and a first flushing pump rotating speed, the first flushing interval is a time interval after the initial flushing interval is shortened by a%, the first single flushing time is a time after the initial single flushing time is increased by b%, the first flushing voltage is a voltage after the initial flushing voltage is increased by c%, and the first flushing pump rotating speed is a pump rotating speed after the initial flushing pump rotating speed is increased by d%;

if the pump current variation delta A is smaller than the second pump current variation, the real-time blocking speed of the filter element is relatively low, and if the filter element is washed according to the initial washing parameters, the waste of washing water can be caused. Therefore, setting a second flushing parameter as the adjusted flushing parameter, where the second flushing parameter includes any one of a second flushing interval, a second single flushing duration, a second flushing voltage, and a second flushing pump rotation speed, and the second flushing interval is a time interval after the initial flushing interval is increased by e%; the second single-time washing time length is the time length after the initial single-time washing time length is reduced by f%; the second flushing voltage is the voltage after the initial flushing voltage is reduced by g%; the second washing pump rotating speed is the pump rotating speed after the initial washing pump rotating speed is reduced by h%;

if the pump current variation delta A is between the first pump current variation and the second pump current variation, the initial flushing parameters of the water purifying equipment do not need to be adjusted, wherein the first pump current variation is larger than or equal to the second pump current variation;

taking the pump operation parameter as the pump rotating speed and taking the difference value of the pump rotating speeds with the pump operation variable quantity of two times as an example;

if the obtained pump rotating speeds are respectively the water purification T of the water purification equipment ₁ Long time or pure water Q ₁ Pump speed R measured in liters ₁ And in water purification unit ₂ Long time or pure water Q ₂ Pump speed R measured in liters ₂ If the pump speed variation Δ R is greater than the preset value, the calculation formula is as follows:

ΔR＝R ₂ -R ₁

if the pump rotating speed variation delta R is larger than the first pump rotating speed variation, the real-time blocking speed of the filter element is higher, and if the filter element is washed according to the initial washing parameters, the washing effect is poor. Therefore, the first flushing parameter is set as the adjusted flushing parameter, the first flushing parameter includes any one of a first flushing interval, a first single flushing time length, a first flushing voltage and a first flushing pump rotating speed, the first flushing interval is a time interval after the initial flushing interval is shortened by a%, the first single flushing time length is a time length after the initial single flushing time length is increased by b%, the first flushing voltage is a voltage after the initial flushing voltage is increased by c%, and the first flushing pump rotating speed is a pump rotating speed after the initial flushing pump rotating speed is increased by d%;

if the pump rotation speed variation Δ R is smaller than the second pump rotation speed variation, it indicates that the real-time blocking speed of the filter element is slow, and if the filter element is flushed according to the initial flushing parameters, the flushing water is wasted. Therefore, setting a second flushing parameter as the adjusted flushing parameter, where the second flushing parameter includes any one of a second flushing interval, a second single flushing duration, a second flushing voltage, and a second flushing pump rotation speed, and the second flushing interval is a time interval after the initial flushing interval is increased by e%; the second single-time washing time length is the time length after the initial single-time washing time length is reduced by f%; the second flushing voltage is the voltage after the initial flushing voltage is reduced by g%; the second washing pump rotating speed is the pump rotating speed obtained after the initial washing pump rotating speed is reduced by h%;

if the pump rotating speed variation delta R is between the first pump rotating speed variation and the second pump rotating speed variation, the initial flushing parameters of the water purifying equipment do not need to be adjusted, wherein the first pump rotating speed variation is larger than or equal to the second pump rotating speed variation;

taking pump operation parameters as pump current and pump operation variation as a pump current variation coefficient as an example;

3.1, if the obtained pump currents are respectively in the water purifying equipment for purifying water T ₁ Pump current A detected by duration ₁ In water purification unit for purifying water T ₂ Pump current A detected by duration ₂ Until the water purification T of the water purification equipment _i Duration-detected pump current A _i ；

Determining the average water purification time length according to the water purification time length

The calculation formula is as follows:

determining an average pump current from the pump currents

The calculation formula is as follows:

calculating to obtain the pump current variation coefficient b of the water purifying equipment according to the pump current difference value of each pump current and the average pump current and the water purifying time length difference value of each water purifying time length and the average water purifying time length _A Meter for measuringThe calculation formula is as follows:

3.2, if the obtained pump currents are respectively the water purified Q in the water purifying equipment ₁ Pump current A detected by liter ₁ In the water purifying equipment, the water Q is purified ₂ Pump current A obtained by liter detection ₂ Until the water is purified in the water purifying equipment Q _i Pump current A detected by liter _i ；

The calculation formula is as follows:

determining an average pump current from the pump currents

The calculation formula is as follows:

if the pump current changes by a factor b _A If the current change coefficient is larger than the first pump current change coefficient, the real-time blocking speed of the filter element is higher, and if the filter element is washed according to the initial washing parameters, the washing effect is poor. Thus, the first flush parameter is set to the adjusted post-flush parameterThe first flushing parameter comprises any one of a first flushing interval, a first single flushing time, a first flushing voltage and a first flushing pump rotating speed, the first flushing interval is a time interval after the initial flushing interval is shortened by a%, the first single flushing time is a time after the initial single flushing time is increased by b%, the first flushing voltage is a voltage after the initial flushing voltage is increased by c%, and the first flushing pump rotating speed is a pump rotating speed after the initial flushing pump rotating speed is increased by d%;

if the pump current changes by a factor b _A And if the current change coefficient is smaller than the second pump current change coefficient, the real-time blocking speed of the filter element is low, and if the filter element is washed according to the initial washing parameters, the waste of washing water can be caused. Therefore, setting a second flushing parameter as the adjusted flushing parameter, where the second flushing parameter includes any one of a second flushing interval, a second single flushing duration, a second flushing voltage, and a second flushing pump rotation speed, and the second flushing interval is a time interval after the initial flushing interval is increased by e%; the second single-time washing time length is the time length after the initial single-time washing time length is reduced by f%; the second flushing voltage is the voltage after the initial flushing voltage is reduced by g%; the second washing pump rotating speed is the pump rotating speed obtained after the initial washing pump rotating speed is reduced by h%;

if the pump current changes by a factor b _A The initial washing parameters of the water purifying equipment do not need to be adjusted between the first pump current change coefficient and the second pump current change coefficient, wherein the first pump current change coefficient is larger than or equal to the second pump current change coefficient;

taking the pump operation parameter as the pump rotating speed and the pump operation variable quantity as the pump rotating speed variation coefficient as an example;

4.1, if the obtained pump rotating speeds are respectively the water purification T of the water purification equipment ₁ Pump speed R obtained by duration detection ₁ In water purification equipment water purification T ₂ Pump speed R obtained by duration detection ₂ Until the water purification T of the water purification equipment _i Pump speed R obtained by duration detection _i ；

The calculation formula is as follows:

determining an average pump speed from the pump speeds

The calculation formula is as follows:

calculating to obtain a pump rotating speed change coefficient b of the water purifying equipment according to a pump rotating speed difference value of each pump rotating speed and the average pump rotating speed and a water purifying time length difference value of each water purifying time length and the average water purifying time length _R The calculation formula is as follows:

4.2, if the obtained pump rotating speeds are respectively the water purification Q of the water purification equipment ₁ Pump speed R measured in liters ₁ In the water purifying equipment, the water Q is purified ₂ Pump speed R measured in liters ₂ Until the water is purified in the water purifying equipment Q _i Pump speed R measured in liters _i ；

The calculation formula is as follows:

determining an average pump speed from the pump speeds

The calculation formula is as follows:

if the pump speed changes by a factor b _R The rotating speed change coefficient of the first pump is larger than the rotating speed change coefficient of the first pump, so that the real-time blocking speed of the filter element is higher, and if the filter element is washed according to initial washing parameters, the washing effect is poor. Therefore, the first flushing parameter is set as the adjusted flushing parameter, the first flushing parameter includes any one of a first flushing interval, a first single flushing time length, a first flushing voltage and a first flushing pump rotating speed, the first flushing interval is a time interval after the initial flushing interval is shortened by a%, the first single flushing time length is a time length after the initial single flushing time length is increased by b%, the first flushing voltage is a voltage after the initial flushing voltage is increased by c%, and the first flushing pump rotating speed is a pump rotating speed after the initial flushing pump rotating speed is increased by d%;

if the pump speed changes by a factor b _R And if the real-time blocking speed of the filter element is lower than the second pump rotating speed change coefficient, the waste of washing water can be caused if the filter element is washed according to the initial washing parameters. Therefore, setting a second flushing parameter as the adjusted flushing parameter, where the second flushing parameter includes any one of a second flushing interval, a second single flushing duration, a second flushing voltage, and a second flushing pump rotation speed, and the second flushing interval is a time interval after the initial flushing interval is increased by e%; the second single flushing time is the time after the initial single flushing time is reduced by f%; the second flushing voltage is the voltage after the initial flushing voltage is reduced by g%; the second washing pump rotating speed is the pump rotating speed after the initial washing pump rotating speed is reduced by h%;

if the pump speed changes by a factor b _R The initial flushing parameters of the water purifying equipment do not need to be adjusted between the first pump rotating speed change coefficient and the second pump rotating speed change coefficient, wherein the first pump rotating speed change coefficient is larger than or equal to the second pump rotating speed change coefficient;

and after the adjusted washing parameters of the water purification equipment are determined, controlling the water purification equipment to wash the reverse osmosis membrane filter element of the water purification equipment according to the adjusted washing parameters.

It should be understood that, although the steps in the flowcharts shown above are shown in sequence as indicated by the arrows, the steps are not necessarily performed in sequence as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least a part of the steps in each of the flowcharts described above may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, and the order of performing the steps or stages is not necessarily sequential, but may be performed alternately or alternately with other steps or at least a part of the steps or stages in other steps.

In one embodiment, as shown in fig. 4, there is provided a control device of a water purifying apparatus, including: a parameter acquisition module 410, a calculation module 420, a parameter adjustment module 430, and a flush control module 440, wherein:

the parameter acquisition module 410 is used for acquiring the pump operation parameters of the water purification equipment in the working process of the water purification equipment.

And the calculating module 420 is used for calculating the pump operation variation of the water purifying equipment according to the pump operation parameters.

And the parameter adjusting module 430 is configured to adjust the flushing parameter of the water purifying equipment based on the pump operation variation and the initial flushing parameter in the working process of the water purifying equipment, so as to obtain an adjusted flushing parameter.

And the flushing control module 440 is used for controlling the water purifying equipment to flush according to the adjusted flushing parameters.

In one embodiment, the calculating module 420 is configured to calculate a difference between two pump operation parameters, and the pump operation variation includes the difference.

In one embodiment, the calculating module 420 is configured to calculate a pump operation parameter variation coefficient of the water purifying apparatus according to each of the pump operation parameters and a water purifying parameter corresponding to each of the pump operation parameters, where the pump operation variation includes the pump operation parameter variation coefficient.

In one embodiment, the calculation module 420 comprises the following units:

and the water purification parameter determination unit is used for determining the water purification parameters of the water purification equipment corresponding to the pump operation parameters.

And the average value calculating unit is used for determining an average water purification parameter and an average pump operation parameter according to the pump operation parameters and the water purification parameters respectively.

And the variation coefficient calculation unit is used for calculating and obtaining the pump operation parameter variation coefficient of the water purification equipment according to the operation parameter difference value of each pump operation parameter and the average pump operation parameter and the water purification parameter difference value of each water purification parameter and the average water purification parameter.

In one embodiment, the variation coefficient calculation unit is configured to determine a ratio of a sum of products of each of the operation parameter differences and the corresponding water purification parameter difference to a sum of squares of each of the water purification parameter differences as the pump operation parameter variation coefficient.

In one embodiment, the parameter adjusting module 430 is further configured to set a first flushing parameter as the adjusted flushing parameter when the pump operation variation is greater than a first variation, where the first flushing parameter includes any one of a first flushing interval, a first single flushing duration, a first flushing voltage, and a first flushing pump rotation speed, the first flushing interval is smaller than an initial flushing interval in the initial flushing parameter, the first single flushing duration is greater than an initial single flushing duration in the initial flushing parameter, the first flushing voltage is greater than an initial flushing voltage in the initial flushing parameter, and the first flushing pump rotation speed is greater than an initial flushing pump rotation speed in the initial flushing parameter.

In one embodiment, the parameter adjusting module 430 is further configured to set a second flushing parameter as the adjusted flushing parameter when the pump operation variation is smaller than a second variation, where the second flushing parameter includes any one of a second flushing interval, a second single flushing duration, a second flushing voltage, and a second flushing pump rotation speed, the second flushing interval is greater than an initial flushing interval in the initial flushing parameter, the second single flushing duration is smaller than an initial single flushing duration in the initial flushing parameter, the second flushing voltage is smaller than an initial flushing voltage in the initial flushing parameter, and the second flushing pump rotation speed is smaller than an initial flushing pump rotation speed in the initial flushing parameter.

In one embodiment, the first flushing interval is a time interval after the initial flushing interval is shortened by a first proportion, and the second flushing interval is a time interval after the initial flushing interval is increased by a second proportion; the first single flushing time length is the time length of the initial single flushing time length increased by a third proportion, and the second single flushing time length is the time length of the initial single flushing time length decreased by a fourth proportion; the first flushing voltage is the voltage obtained by increasing the initial flushing voltage by a fifth proportion, and the second flushing voltage is the voltage obtained by decreasing the initial flushing voltage by a sixth proportion; the first flushing pump rotating speed is the pump rotating speed obtained by increasing the initial flushing pump rotating speed by a seventh proportion, and the second flushing pump rotating speed is the pump rotating speed obtained by decreasing the initial flushing pump rotating speed by an eighth proportion.

In one embodiment, the flushing control module 440 is further configured to control the water purifying apparatus to flush according to the initial flushing parameter when it is determined that the flushing condition corresponding to the initial flushing parameter is reached.

For specific limitations of the control device of the water purification apparatus, reference may be made to the above limitations of the control method of the water purification apparatus, which are not described herein again. All or part of each module in the control device of the water purifying equipment can be realized by software, hardware and a combination thereof. The modules may be embedded in a hardware form or may be independent of a processor in the electronic device, or may be stored in a memory in the electronic device in a software form, so that the processor calls and executes operations corresponding to the modules.

In one embodiment, an electronic device is provided, the internal structure of which may be as shown in fig. 5. The electronic device includes a processor, a memory, and a communication interface connected by a system bus. Wherein the processor of the electronic device is configured to provide computing and control capabilities. The memory of the electronic equipment comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The communication interface of the electronic device is used for carrying out wired or wireless communication with external control equipment, and the communication interface is also used for acquiring related control instructions. Wireless may be achieved through WIFI, carrier network, NFC (near field communication), or other technologies. The computer program is executed by a processor to implement a control method of a water purification apparatus.

In one embodiment, the electronic device further includes a display screen and an input device, where the display screen of the electronic device may be a liquid crystal display screen or an electronic ink display screen, and the input device of the electronic device may be a touch layer covered on the display screen, or a key, a trackball, or a touch pad provided on a housing of the electronic device.

Those skilled in the art will appreciate that the configuration shown in fig. 5 is a block diagram of only a portion of the configuration associated with the present application, and does not constitute a limitation on the electronic device to which the present application is applied, and a particular electronic device may include more or less components than those shown in the drawings, or may combine certain components, or have a different arrangement of components.

In one embodiment, an electronic device is provided, which includes a memory and a processor, wherein the memory stores a computer program, and the processor implements the steps of the control method of the water purifying device when executing the computer program.

In one embodiment, a computer-readable storage medium is provided, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the control method of the water purification apparatus as described above.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical storage, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), for example.

All possible combinations of the technical features of the embodiments described above may not be described for the sake of brevity, but should be considered as being within the scope of the present disclosure as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A method of controlling a water purification apparatus, the method comprising:

in the working process of the water purifying equipment, pump operation parameters detected by the water purifying equipment at a plurality of water purifying parameter detection points are obtained;

calculating the pump operation variable quantity of the water purifying equipment according to the pump operation parameters; the pump operation variation comprises a pump operation parameter variation coefficient; the pump operation parameter variation coefficient is the ratio of the sum of products of the difference of each pump operation parameter and the difference of the corresponding water purification parameter to the sum of squares of the difference of each water purification parameter;

adjusting the flushing parameters of the water purifying equipment based on the pump operation variable quantity and the initial flushing parameters in the working process of the water purifying equipment to obtain adjusted flushing parameters;

2. The method for controlling a water purifying apparatus according to claim 1, further comprising, after the obtaining the pump operation parameter of the water purifying apparatus, before the calculating the pump operation variation of the water purifying apparatus according to the pump operation parameter:

3. The control method of a water purifying apparatus as claimed in claim 1, wherein the pump operation variation further includes a difference between the two pump operation parameters.

4. The method for controlling a water purification unit according to claim 1, wherein the calculating a manner of obtaining the coefficient of variation of the pump operation parameter of the water purification unit includes:

5. The method of claim 4, wherein the pump operation parameter variation coefficient is a ratio of a sum of products of each of the operation parameter differences and corresponding water purification parameter differences to a sum of squares of each of the water purification parameter differences.

6. The control method of a water purification apparatus according to any one of claims 1 to 5, wherein the pump operation parameter includes at least one of a pump current and a pump rotation speed.

7. The control method of a water purification apparatus according to any one of claims 1 to 5, wherein the water purification parameter includes at least one of a water purification time period and a water purification amount.

8. The method for controlling a water purification apparatus according to any one of claims 1 to 5, wherein the adjusting the flushing parameter of the water purification apparatus based on the pump operation variation and the initial flushing parameter during the operation of the water purification apparatus to obtain the adjusted flushing parameter comprises:

9. The control method of a water purifying apparatus as claimed in claim 8,

the first flushing interval is a time interval after the initial flushing interval is shortened by a first proportion, and the second flushing interval is a time interval after the initial flushing interval is increased by a second proportion;

the first single flushing time length is the time length of the initial single flushing time length increased by a third proportion, and the second single flushing time length is the time length of the initial single flushing time length decreased by a fourth proportion;

10. A control device of a water purifying apparatus, the device comprising:

the parameter acquisition module is used for acquiring pump operation parameters detected by the water purification equipment at a plurality of water purification parameter detection points in the working process of the water purification equipment;

the calculation module is used for calculating the pump operation variation of the water purification equipment according to the pump operation parameters; the pump operation variation comprises a pump operation parameter variation coefficient; the pump operation parameter variation coefficient is the ratio of the sum of products of the difference of each pump operation parameter and the difference of the corresponding water purification parameter to the sum of squares of the difference of each water purification parameter;

11. An electronic device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor implements the steps of the method of controlling a water purification device of any one of claims 1 to 9 when executing the computer program.

12. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of controlling a water purification apparatus of any one of claims 1 to 9.