CN119467848A - Method and device for regulating effluent quality, mineralization faucet and storage medium - Google Patents

Abstract

The present application relates to the field of water purification technology, and provides a method, device, mineralized faucet and storage medium for regulating the quality of water output. By obtaining the biological information of the user, the present application can recommend water quality ranges for different groups of people, which helps to meet the personalized needs of different groups of people for drinking water, and ensures that all types of people can obtain drinking water that best suits their physical needs. A water quality display area is set on the mineralized faucet, which can intuitively display the recommended water quality range, so that users can clearly understand the water quality requirements suitable for their bodies. At the same time, users can also trigger water output instructions in the operation control area of the mineralized faucet, and control the water output according to the water output instructions, which improves the user's operational convenience and experience. Compared with traditional water purifier products with a single function, the present application makes the water purifier product have stronger functionality and flexibility by intelligently adjusting the water quality of the output water.

Description

Method and device for regulating water quality of outlet water, mineralized faucet and storage medium

Technical Field

The application relates to the technical field of water purification, in particular to a method and a device for regulating the quality of effluent, a mineralized faucet and a storage medium.

Background

Along with the improvement of the living standard of people, the requirements on the safety and quality of daily drinking water are also increased along with the rise of water. Different crowds show diversified trends on the demands of water quality based on the physiological characteristics and living habits of the different crowds. For example, children are in a critical stage of growth and development, and their immune system and physical functions are relatively weak, so that the requirements for drinking water are particularly strict, and water quality with high purity, no impurities and no harmful substances is more prone to be selected so as to ensure healthy growth. For the elderly, the body functions gradually decline with the age, and the absorption capacity of the nutritional ingredients such as minerals is correspondingly weakened. Proper amount of water containing mineral matters can not only meet the daily drinking water demands of the people, but also supplement microelements required by the body to a certain extent, thereby being beneficial to maintaining the health of the body.

However, most water purifier products sold in the market at present are single in function, only can provide water quality with fixed standards, and are difficult to meet the individual demands of different crowds on drinking water.

Disclosure of Invention

Based on the method, the device, the mineralized faucet and the storage medium for regulating the water quality of the water outlet are provided, and the problems that the water purifier products in the current market are single in function and cannot meet the personalized requirements of different crowds on drinking water are solved.

The first aspect of the application provides a method for regulating the quality of effluent, which comprises the following steps:

acquiring biological information of a user;

Determining a recommended water quality range according to the biological information;

displaying the recommended water quality range in a water quality display area of the mineralized faucet;

Receiving a water outlet instruction triggered by the user in an operation control area of the mineralized faucet according to the recommended water quality range;

and controlling the mineralized faucet to carry out water outlet according to the water outlet instruction.

Optionally, the determining the recommended water quality range according to the biological information includes:

determining an age group of the user according to the biological information, determining a recommended water quality range according to the age group, or

And identifying based on the biological information to obtain personalized features of the user, and determining a recommended water quality range according to the personalized features.

Optionally, displaying the recommended water quality range in the water quality display area of the mineralized faucet includes:

Determining a first display mode according to the age of the user, and displaying the recommended water quality range in a water quality display area of the mineralized faucet according to the first display mode, or

And determining a second display mode according to the personalized characteristics of the user, and displaying the recommended water quality range in a water quality display area of the mineralized faucet according to the second display mode.

Optionally, the controlling the mineralizing tap to discharge water according to the water outlet instruction includes:

Acquiring expected water quality of the water outlet in the water outlet instruction;

determining a desired soluble material content difference value according to the desired effluent quality;

obtaining the actual content difference of the soluble substances of the mineralized tap;

and controlling the mineralized faucet to discharge water according to the expected soluble substance content difference value and the actual soluble substance content difference value.

Optionally, the controlling the mineralized faucet to output water according to the expected soluble substance content difference value and the actual soluble substance content difference value comprises:

Obtaining an expected deviation according to the expected soluble substance content difference and the actual soluble substance content difference;

Calculating a flow adjustment amount based on the expected deviation by using a proportional-integral-derivative control module;

and controlling the mineralized faucet to discharge water according to the flow adjustment quantity.

Optionally, the method further comprises:

acquiring the working state of the mineralized tap;

and displaying the working state in a state display area of the mineralized tap.

Optionally, the method further comprises:

monitoring the actual effluent quality of the mineralized tap;

Comparing the actual effluent water quality with a preset standard water quality range;

and when the actual water quality of the water outlet is not in the preset standard water quality range, controlling the mineralized faucet to alarm.

A second aspect of the present application provides a device for regulating the quality of effluent, the device comprising:

the acquisition module is used for acquiring the biological information of the user;

the determining module is used for determining a recommended water quality range according to the biological information;

The display module is used for displaying the recommended water quality range in a water quality display area of the mineralized faucet;

The triggering module is used for receiving a water outlet instruction triggered by the user in the operation control area of the mineralized faucet according to the recommended water quality range;

And the control module is used for controlling the mineralized faucet to carry out water outlet according to the water outlet instruction.

A third aspect of the present application provides a mineralized faucet comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor executing the computer program to perform the steps of the method of regulating the quality of effluent.

A fourth aspect of the present application provides a computer readable storage medium storing a computer program which, when executed by a processor, implements the steps of the effluent quality adjustment method.

According to the application, by acquiring the biological information of the user, the water quality range can be recommended for different people, the personalized requirements of different people on the drinking water can be met, and various people can be ensured to obtain the drinking water which is most suitable for the body requirements of the people. The water quality display area is arranged on the mineralized tap, so that the recommended water quality range can be intuitively displayed, and a user can clearly know the water quality requirement suitable for the body of the user. Meanwhile, the user can trigger a water outlet instruction in the operation control area of the mineralized faucet, water outlet control is performed according to the water outlet instruction, and the operation convenience and experience of the user are improved. Compared with the traditional water purifier product with single function, the intelligent water purifier has the advantages that the water quality of the discharged water is intelligently adjusted, so that the water purifier product has stronger functionality and flexibility. The water quality of the water outlet can be flexibly adjusted according to the actual demands of users, so that the applicability and market competitiveness of the mineralized faucet are improved.

Drawings

In order to more clearly illustrate the embodiments of the application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a mineralized faucet according to an embodiment of the present application.

Fig. 2 is a schematic flow chart of a method for regulating the quality of effluent according to an embodiment of the present application.

FIG. 3 is a schematic illustration of a display interface for a mineralized faucet according to an embodiment of the present application.

Fig. 4 is a schematic diagram of a Δtds-PH curve provided by an embodiment of the present application.

FIG. 5 is a functional block diagram of a water quality control device according to an embodiment of the present application.

FIG. 6 is a schematic view of another embodiment of a mineralized faucet according to the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Along with the improvement of modern living standard, the requirements of people on the quality of drinking water are also higher and higher. The traditional faucet only meets the basic water outlet function, but cannot meet the requirements of modern families on water quality monitoring, mineralization, attractive appearance and the like. Therefore, a novel faucet integrating water quality monitoring, mineralization and intelligent display, namely a mineralization faucet, is generated. The mineralized faucet not only has a basic water outlet function, but also can monitor water quality in real time, improves water quality through the mineralized filter element, and provides visual water quality information and an operation interface through an intelligent display module.

Referring to fig. 1, a schematic diagram of a mineralized faucet according to an embodiment of the present application is shown.

The mineralized faucet mainly comprises a faucet body, a display module, a filter element assembly, a control module, a detection module, a communication module and a radar.

The tap body is a main structure of the mineralized tap and comprises a connecting part and a main body part. The connecting part is connected with the main body part through rotation, so that a user can conveniently adjust the angle and the position of the faucet. The main body part is provided with an installation area for installing the display module. At least one display area is provided on the connection portion or the main body portion for mounting the light emitting unit.

The display module is used for displaying a user interface and the like. The user interface may have multiple display areas to meet the display requirements of different information. A light emitting unit may also be provided in the display area for providing a backlight or indication function. The color or length can be changed according to the instruction of the control module so as to intuitively reflect the water quality condition or remind a user of carrying out certain operations.

The detection module is arranged on the water supply water path and is used for acquiring a soluble substance content value (such as a total dissolved solid value or conductivity) of the water supply water path and transmitting the acquired soluble substance content value to the control module for processing. The detection module includes a detector.

The filter element component is used for mineralizing water flow in the water supply waterway. The filter element component is arranged on a water supply water path, and the water quality is improved through the mineralized filter element, so that more healthy and better-taste drinking water is provided. The filter element component comprises a water inlet end and a water outlet end, and the water inlet end and the water outlet end are respectively provided with a detector.

The control module is an intelligent core of the mineralized faucet, is respectively connected with the display module, the light-emitting unit and the like, and is used for controlling the color or the length of the light-emitting unit and the display content of the display module. The control module can intelligently adjust the water quality of the effluent according to the biological information of the user so as to meet the personalized requirements of the user.

The communication module is used for communicating with the control module to realize remote control and data transmission. The communication module can transmit the content value of the soluble substance to a remote device or a server, so that the user can check and manage the content value at any time.

The radar can be used for sensing the approach or the departure of a user, so that the faucet is automatically closed, and more convenient and energy-saving water experience is realized. The radar can also be combined with other water quality monitoring sensors to construct a water quality monitoring system together. When the water quality is abnormal, the radar can be matched with the display module and the light-emitting unit to send out an early warning signal, so that a user is reminded to process in time.

The mineralization tap can be connected with a water purifier for use, and a user can conveniently obtain mineralized and purified drinking water through the mineralization tap, so that daily drinking water requirements of families are met.

Fig. 2 is a schematic flow chart of a method for adjusting the quality of effluent according to an embodiment of the present application, where the method for adjusting the quality of effluent includes the following steps.

S21, acquiring biological information of the user.

Biological information refers to information generated by organisms at various levels of genetics, physiology, ecology and the like. The biological information includes biological characteristic information (such as fingerprint, iris, face, etc.) and physiological information (such as heart rate, blood pressure, blood sugar, etc.).

One or more sensors can be arranged on the mineralized faucet, and biological information of a water taking user can be directly obtained through the one or more sensors. One or more sensors can be arranged near the mineralized tap, and biological information of a water taking user can be acquired through the one or more sensors and then sent to the mineralized tap.

Different types of sensors can be correspondingly arranged according to different categories of biological information required to be acquired. For example, a fingerprint recognition sensor is embedded in the surface of the mineralized tap to facilitate the touch of a user, a face recognition sensor is arranged on a wall or a ceiling near the mineralized tap to record the facial characteristics of the user, an infrared body temperature sensor is arranged on the side or above the mineralized tap to measure the body temperature of the user, a heart rate monitoring sensor in the form of a bracelet or a handle is designed on the mineralized tap, the user naturally contacts during the use to monitor the heart rate condition of the user taking water, and a skin conductivity sensor in the form of touch is designed, so that the user can measure the body moisture condition by touching the mineralized tap during the use. The embodiment of the application does not limit the installation position, the installation quantity and the type of the sensors, and can flexibly select and configure the sensors according to actual requirements so as to realize a more intelligent and safer mineralized faucet system as long as the required biological information can be accurately and reliably obtained.

S22, determining a recommended water quality range according to the biological information.

The recommended water quality range is a water quality standard interval which is customized according to the biological information of the user and is suitable for drinking so as to meet the requirements of different people on healthy drinking water.

The mineralized faucet is pre-stored with a corresponding relation table between biological information and recommended water quality range, and the recommended water quality range matched with the biological information of the water taking user can be inquired according to the corresponding relation table.

In an alternative embodiment, said determining a recommended water quality range from said biological information comprises:

Determining an age group of the user according to the biological information;

and determining a recommended water quality range according to the age group.

Wherein the biological information can comprise one or more of heart rate, blood pressure and blood sugar. Heart rate, blood pressure and blood sugar are indexes reflecting physiological conditions of human bodies, and certain correlation exists between the heart rate, the blood pressure and the blood sugar and age groups. By analyzing the trend of these indices in different age groups, the approximate age group of a person can be estimated. For example, heart rate gradually decreases with age, with neonatal heart rate being faster, typically over 100 beats/minute, child to adolescent heart rate gradually decreasing to the normal range, but still higher than adult, adult heart rate being broader, typically between 60-100 beats/minute, and elderly heart rate levels being lower than younger but still within a certain range. As another example, blood pressure generally tends to rise gradually with age, with childhood blood pressure being relatively low and geriatric blood pressure being relatively high.

The mineral substances are trace elements necessary for human bodies, but the demands of people of different ages for the mineral substances are different, and the people of different ages have different adaptability to the pH value of water. For example, children may have a weaker immune system and may be more likely to drink near neutral water to avoid irritation to the gastrointestinal tract, and high purity water with a PH between 6.8 and 7.2 and a moderate mineral content is recommended. Adults recommend drinking water with a pH of between 6.5 and 7.5 and a proper mineral content. The long may need water containing appropriate amounts of minerals such as calcium, magnesium, etc. to supplement the body's needs.

A first correspondence between a combination of one or more of heart rate, blood pressure, blood glucose and age group may be established in advance, and a second correspondence between age group and recommended water quality range may be established. Inquiring a target age bracket matched with one or more of heart rate, blood pressure and blood sugar through the first corresponding relation. After the age bracket is inquired, inquiring the recommended water quality range matched with the age bracket through the second corresponding relation.

According to the optional implementation mode, the age groups are determined according to the biological information, so that personalized recommended water quality ranges are provided for groups of different age groups, the intelligent level of water quality adjustment is improved, and personalized requirements of people of different age groups are met.

In another alternative embodiment, the determining the recommended water quality range based on the biological information includes:

Identifying based on the biological information to obtain personalized features of the user;

and determining a recommended water quality range according to the personalized features.

The biological information may include one or more of face images, iris images, and the like.

Face images and iris images are unique and identifiable as a form of biometric identification, and thus can be used to individually provide services to users.

Facial features or iris features of the water intake user can be identified based on the face image or iris image and compared with user information stored in the database. By comparison, the system can confirm the identity of the user. After confirming the identity of the user, personal information associated with the user, such as the user's health, eating habits, drinking preferences, etc., that were previously registered by the user or entered during use, may be retrieved from the user database. Based on the retrieved personal information of the user, a recommended water quality range suitable for the user may be further analyzed and determined. For example, if the user has a particular health problem (e.g., kidney disease), a lower mineral content water quality may be recommended. Or if the user prefers sweet and refreshing water, mineral water containing a certain amount of minerals may be recommended.

The AI model (deep learning algorithm, convolutional Neural Network (CNN) and the like) can also be used for learning a large number of face images and related health data or facial micro-expressions, eye spirit and the like, and a correlation model between the face characteristics and the health conditions can be established. Thus, when the face image of the water taking user is acquired, the face image is received into the AI model, and the AI model judges the physiological health state, the facial micro-expression, the eye spirit and the like according to the learned characteristics. Thereby determining the recommended water quality range according to the corresponding relation between the physiological health state, the facial micro-expression, the eye spirit and the like which are pre-established and stored and the recommended water quality range.

According to the optional implementation mode, the personalized features of the users are identified based on the biological information, and the recommended water quality range is determined according to the personalized features, so that the customized water quality selection is provided for each user, the personalized degree of water quality adjustment is improved, and more convenient and comfortable use experience is provided for the user.

S23, displaying the recommended water quality range in a water quality display area of the mineralized faucet.

The mineralized faucet according to the embodiment of the application is provided with a display interface, as shown in fig. 3, wherein the display interface comprises a water quality display area, an operation control area and a state display area. The water quality display area is used as an intuitive window for a user to acquire water quality information. By displaying the determined recommended water quality range on the water quality display area of the mineralized faucet, the user can clearly see the proper water quality range recommended by the mineralized faucet according to the biological information of the user. The user does not need to carry out complicated water quality detection and comparison, and can quickly know the recommended water quality range for the user by simply checking the water quality display area of the mineralized faucet. The drinking water can be more scientifically selected by a user according to the recommended water quality range, so that the user can be protected from the healthy driving.

The intelligent recommendation system of the mineralized faucet does not constantly display information, but adopts flexible and various display modes so as to adapt to the requirements and preferences of different users. In the specific implementation, the recommended water quality range can be displayed in a water quality display area of the mineralized faucet according to the biological information of the user.

An alternative embodiment is to customize the display means (i.e. the first display means) according to the age of the user, and to display the recommended water quality range in the water quality display area of the mineralized faucet according to the first display means. For children, the system can show recommended water quality by using more lively and colorful icons and animations, and simultaneously ensures accurate and attractive information transmission by being matched with simple and understandable text description. For middle-aged and elderly users, the system may be more prone to use clear and concise words and charts, so as to reduce reading burden and improve information readability.

Another alternative embodiment is to customize the display mode (i.e. the second display mode) according to the personalized features of the user, and display the recommended water quality range in the water quality display area of the mineralized faucet according to the second display mode. For users with special health requirements, the system can highlight the water quality parameters which can meet the special health requirements, such as low sodium, high calcium and the like, on the water quality display area, and attach corresponding health prompts and suggestions to help the user make more intelligent choices.

According to the optional implementation mode, the recommended water quality range is intuitively displayed in the water quality display area, so that the intellectualization of water quality recommendation is realized, and the participation feeling and satisfaction of a user are improved through a personalized display mode. The user is not a passive recipient any more, but becomes an active participant in the whole intelligent recommendation process, and can easily acquire and understand the water quality information suitable for the user according to the actual situation and the requirement of the user.

S24, receiving a water outlet instruction triggered by the user in the operation control area of the mineralized faucet according to the recommended water quality range.

After the user views the water quality range recommended by the mineralized faucet, the user can input the expected water quality of the outlet water, for example, PH7.5 according to the actual requirements and preferences of the user by touching or clicking the water quality display area of the mineralized faucet or interfaces such as a mobile phone APP. After the mineralized faucet detects the touch or click operation of a user, a water outlet instruction is triggered according to the touch or click operation.

S25, controlling the mineralized faucet to carry out water outlet according to the water outlet instruction.

In order to accurately and quickly respond to the demands of users, the mineralized faucet analyzes the water outlet instruction so as to extract the water quality of the water outlet expected by the users. And then, the mineralizing tap automatically adjusts the filtering, mineralizing or purifying device in the mineralizing tap according to the water quality parameters of the outlet water. The devices can comprise filter elements, mineralized balls, ultraviolet sterilizers and the like of different types, and can accurately adjust the PH value of the water quality of the effluent so as to meet the specific demands of users.

In an alternative embodiment, the controlling the mineralized faucet to discharge water according to the water outlet instruction comprises:

Acquiring expected water quality of the water outlet in the water outlet instruction;

determining a desired soluble material content difference value according to the desired effluent quality;

obtaining the actual content difference of the soluble substances of the mineralized tap;

and controlling the mineralized faucet to discharge water according to the expected soluble substance content difference value and the actual soluble substance content difference value.

By collecting a large amount of experimental data, such as different upstream and downstream soluble substance content values and different pH values, a corresponding relation model between the difference of the soluble substance content (the difference between the upstream and downstream soluble substance content values) and the pH value is established, and a delta TDS-PH curve is shown in FIG. 4. The mineralized faucet finds a difference in the content of the soluble substance (a difference in the content of the desired soluble substance) corresponding to the desired effluent quality according to the established delta TDS-PH curve.

The mineralized tap monitors the actual content value of the soluble substances at the upstream and the downstream according to the upstream and the downstream sensors, and calculates the actual content difference value of the soluble substances according to the actual content value of the soluble substances at the upstream and the downstream.

Finally, according to the expected soluble substance content difference and the actual soluble substance content difference, the working state (such as flow, time, temperature, etc.) of the filtering, mineralizing or purifying device in the mineralizing tap is adjusted to change the soluble substance content of the outlet water so as to gradually approach the water quality expected by the user. Assuming that the desired dissolved substance content difference is Δtds_desired, the actual dissolved substance content difference is Δtds_actual, and the flow value to be adjusted is calculated based on the difference between Δtds_desired and Δtds_actual and the response characteristic of the system (e.g., the coefficient of influence of the flow change on the Δtds change), so that the water is controlled according to the flow value to be adjusted.

In the process of controlling the water outlet, the system can also monitor the water quality condition of the water outlet in real time and carry out fine adjustment according to the actual condition. If the water quality of the water is still in great gap with the water quality expected by the user, the system can continuously adjust the working state of the mineralized faucet until the water quality of the water meets the requirements of the user.

According to the optional implementation mode, the mineralized faucet is controlled to carry out water outlet according to the expected soluble substance content difference value and the actual soluble substance content difference value, so that not only the water outlet quality expected by a user is considered, but also the current actual working state of the mineralized faucet is combined, and more accurate and efficient water quality adjustment is realized. The application not only improves the accuracy and efficiency of water quality regulation, but also ensures that users can obtain stable, reliable and expected water quality service. The intelligent control mode enables the mineralized faucet to better meet personalized requirements of users, and satisfaction of user experience is improved.

In an alternative embodiment, the controlling the mineralized faucet to discharge water according to the desired soluble substance content difference and the actual soluble substance content difference comprises:

Obtaining an expected deviation according to the expected soluble substance content difference and the actual soluble substance content difference;

Calculating a flow adjustment amount based on the expected deviation by using a proportional-integral-derivative control module;

and controlling the mineralized faucet to discharge water according to the flow adjustment quantity.

And calculating a difference value according to the difference value of the content of the expected soluble substance and the difference value of the content of the actual soluble substance, and obtaining the expected deviation. By calculating the desired deviation, the difference between the desired dissolved species content difference (desired state) and the actual dissolved species content difference (actual state) can be quantified, providing an explicit reference for subsequent control operations.

If the desired dissolved species content difference is greater than the actual dissolved species content difference (ΔTDS_desired > ΔTDS_actual), this indicates that the present dissolved species content in the effluent is lower than the desired dissolved species content. In other words, the water has insufficient mineral or other soluble substances, and the water quality PH cannot meet the demands of users. It is necessary to increase the water flow rate of the mineralized faucet or to increase the water outlet speed thereof, and to shorten the residence time of the water in the mineralizer, so as to increase the content of the soluble substances in the outlet water to make it approach or reach the desired outlet water quality. If the desired dissolved species content difference is less than the actual dissolved species content difference (Δtds_desired < Δtds_actual), this indicates that the present effluent water has a higher dissolved species content than the desired dissolved species content. In other words, the water has an excessive content of minerals or other soluble substances, and the PH of the water exceeds the user's needs. It is desirable to reduce the water flow rate or the water rate of the mineralized faucet and to extend the residence time of the water in the mineralizer to reduce the content of soluble materials in the water to approximate or achieve the desired water quality of the water. If the desired dissolved species content difference is equal to the actual dissolved species content difference (Δtds_desired=Δtds_actual), this indicates that the dissolved species content in the current effluent is exactly equal to the desired dissolved species content difference. In other words, the content of minerals or other soluble substances in the water has reached the desired standard, and the PH of the water just meets the needs of the user. At this time, no adjustment of the water flow of the mineralized faucet is required. The current water outlet state can be kept, and the water quality of the water outlet can be continuously monitored to ensure the stability of the water outlet.

To smoothly adjust flow and reduce overshoot and oscillation, a proportional-integral-derivative (PID) control module is used for control. The PID control module calculates the flow adjustment based on the desired deviation, i.e., how much water quality adjustment is needed. And adjusting the opening of a flow valve of the water outlet of the mineralized faucet according to the calculated flow adjustment quantity so as to adjust the water outlet flow or the water outlet speed, thereby controlling the water outlet quality of the mineralized faucet. The PID control module can comprehensively consider the current value, the past value and the change trend of the deviation, so that more accurate and stable flow adjustment quantity is calculated, the accurate control of mineralized tap water outlet is facilitated, and meanwhile, the effective utilization and saving of water resources are realized.

The input of the PID control module is the desired deviation between the desired dissolved species content difference (Δtds_desired) and the actual dissolved species content difference (Δtds_actual), i.e (t) =Δtds_desired- Δtds_actual. The expected deviation reflects the difference between the current effluent quality and the target water quality and is the basis for the control module to adjust.

The output of the PID control module is that the outlet flow adjustment quantity u (t) =Kp×e (t) +Ki× +.e (t) dt+Kd×de (t)/dt of the mineralized tap is used for controlling the content of the soluble substances in the outlet water. The flow adjustment quantity is comprehensively calculated according to the deviation e (t) and the historical change of the deviation (obtained through integral and differential calculation), and aims to realize the accurate control of the effluent quality.

Where Kp is a scaling factor that determines the immediate degree of response of the control module to the deviation. When the deviation is large, the proportional term will produce a large adjustment to reduce the deviation rapidly. However, excessive scaling factors may cause system overshoot and oscillations. Ki is the integral coefficient used to eliminate the static error of the system. It compensates for the accumulation (i.e., integration) of the bias to ensure that the system eventually reaches the desired steady state value. The presence of the integral term helps to smooth the transient of the system, reducing overshoot and ringing. Kd is a differential coefficient used to predict future trend of variation of the deviation and compensate in advance. It suppresses rapid changes in the system by reacting to the rate of change of the deviation (i.e., differentiation), thereby enhancing the stability and response speed of the system.

According to the optional implementation mode, the deviation is continuously sampled and the flow adjustment quantity is calculated through the PID control algorithm, and the control system can adjust the water outlet flow of the mineralized faucet in real time so as to ensure that the content of the soluble substances in the water outlet reaches the expected value, thereby indirectly controlling the PH value of the water outlet, and realizing the accurate control of the water quality of the water outlet and the effective utilization of water resources.

In an alternative embodiment, the method further comprises:

acquiring the working state of the mineralized tap;

and displaying the working state in a state display area of the mineralized tap.

The system acquires the current working state of the mineralized faucet in real time through a built-in sensor or an external equipment interface (such as the Internet of things technology). The current operating state may include critical operating parameters such as outlet flow, pressure, temperature, cartridge life remaining, equipment networking conditions, fault codes, water quality PH, etc.

The acquired working state information can be displayed on a state display area of the mineralized faucet in real time, so that a user can intuitively know the running state of the equipment, and daily maintenance and fault investigation are facilitated.

The residual life information of the filter element can be presented to a user in a state display area in an intuitive mode, such as a percentage progress bar, residual days or recommended replacement date, and the like, so that the filter element can be replaced in time by the user, and the water quality of the yielding water is ensured.

The mineralized faucet has the function of the Internet of things and can be connected to a home network or a cloud server. Networking state information (such as Wi-Fi signal strength, network delay, etc.) is displayed in a state display area, so that a user is ensured to know the network connection condition of the device. If the network connection is lost, the system will issue a warning and prompt the user to check the network settings.

And displaying the current water outlet flow in real time, so that a user can know the water outlet efficiency of the equipment. If the water flow is lower than the preset value, the system gives a warning to prompt a user to check whether the water pipe is blocked or whether the equipment needs maintenance.

When the equipment fails, the system automatically detects and generates corresponding fault codes. The fault code will be displayed in the status display area while the system will provide possible fault causes and solution suggestions. The user can quickly locate the problem according to the fault code and take corresponding solving measures, so that the reliability and stability of the equipment are improved.

According to the optional implementation mode, functions of predicting the residual life of the filter element, monitoring the networking condition of equipment, recommending water quality parameters to be displayed, displaying the water flow, prompting fault codes and the like are added, so that the use experience of a user and the intelligent level of the equipment are greatly improved.

In an alternative embodiment, the method further comprises:

monitoring the actual effluent quality of the mineralized tap;

Comparing the actual effluent water quality with a preset standard water quality range;

and when the actual water quality of the water outlet is not in the preset standard water quality range, controlling the mineralized faucet to alarm.

A first sensor is disposed upstream of the filter cartridge for detecting a soluble species content value (i.e., a first soluble species content value) upstream of the filter cartridge. The first soluble substance content value is a soluble substance content value before water flows through the filter element, that is, a soluble substance content value of raw water. Likewise, a second sensor is disposed downstream of the filter element for detecting a dissolved species content value (i.e., a second dissolved species content value) downstream of the filter element. The second soluble material content value is a soluble material content value after water flows through the filter element. And according to the first soluble substance content value and the second soluble substance content value, a target soluble substance content difference value is obtained.

In order to calculate the PH of the water based on the target soluble substance content difference, it is necessary to collect water sample data from different sources and conditions in advance, and fit a correlation or a functional relationship that may exist between the soluble substance content difference and the PH based on the water sample data, so that the PH of the water is calculated based on the target soluble substance content difference using the fitted correlation or functional relationship.

The value of the dissolved substance content is generally used to measure the total amount of dissolved substances in water, and these dissolved substances may include salts, minerals, organic substances, and the like. By detecting the content value of the soluble substance, the quality of water quality and the effect of the water treatment apparatus can be evaluated. In the embodiment of the application, in order to more accurately monitor the PH of water quality in water treatment equipment, the content value of the soluble substance can comprise the total dissolved solid value or the conductivity. The total dissolved solids (total dissolved solids, TDS) value refers to the total amount of solids dissolved in water, including the content of both inorganic and organic materials. Measurement units were milligrams per liter (1 mg/l=1 ppm), indicating how much milligrams of total dissolved solids was dissolved in 1 liter of water. The higher the TDS value, the more dissolved substances contained in the water. The conductivity value is generally used to approximate the salt content in the solution, the higher the conductivity, the higher the TDS value. The TDS sensor is an instrument for reflecting the mineralization degree of water quality by measuring the conductivity of water. Conductivity is an indicator of the concentration of ions in a mass of water and reflects the ability of dissolved substances in water to conduct electricity. Dissolved substances in water form ions which are able to transfer an electric current when moving in water, so that the conductivity can be used to evaluate the concentration of ions in water. The higher conductivity indicates that the higher the ion concentration in the water, the more dissolved species may be contained. During water treatment, conductivity can be used to monitor changes in water quality, as well as to evaluate the effectiveness of the water treatment apparatus.

When the actual water quality of the water is not in the preset standard water quality range, the system can control the mineralized faucet to alarm. The alert mode may include an audible alert, a light alert, or a screen display alert, etc. For example, the system can send out an audio alarm through a built-in loudspeaker, or remind a user to pay attention through a red warning lamp or a flashing expression icon of a display area, and the visual feedback can quickly attract the attention of the user, so that the user is reminded to take measures in time for processing.

In order to more intuitively show the water quality of the water, the system can adopt the forms of color light bars, color rings, expressions or numerical values and the like to feed back the PH value or the TDS value. The color lamp strip or the color ring can change color according to the range of the PH value, for example, green indicates good water quality, yellow indicates general water quality, and red indicates poor water quality. The expression icons can be designed into more vivid and interesting patterns, such as smiling faces which indicate that the water quality meets the standard and crying faces which indicate that the water quality does not meet the standard. The accurate value of the PH value or the TDS value can be directly displayed to the user through the numerical display, so that the user can conveniently and accurately judge.

According to the optional implementation mode, the real-time monitoring and alarming functions of the actual effluent quality and the more visual PH value feedback mechanism are added, so that the use experience of a user and the intelligent level of equipment are further improved.

According to the effluent quality adjusting method provided by the embodiment of the application, the water quality range can be recommended for different people by acquiring the biological information of the user, so that the personalized requirements of different people on the drinking water can be met, and various people can be ensured to obtain the drinking water which is most suitable for the body requirements of the people. The water quality display area is arranged on the mineralized tap, so that the recommended water quality range can be intuitively displayed, and a user can clearly know the water quality requirement suitable for the body of the user. Meanwhile, the user can trigger a water outlet instruction in the operation control area of the mineralized faucet, water outlet control is performed according to the water outlet instruction, and the operation convenience and experience of the user are improved. Compared with the traditional water purifier product with single function, the intelligent water purifier has the advantages that the water quality of the discharged water is intelligently adjusted, so that the water purifier product has stronger functionality and flexibility. The water quality of the water outlet can be flexibly adjusted according to the actual demands of users, so that the applicability and market competitiveness of the mineralized faucet are improved.

FIG. 5 is a functional block diagram of a water quality control device according to an embodiment of the present application.

In some embodiments, the outlet water quality adjusting device 50 may include a plurality of functional modules composed of program code segments. Program code for each of the program segments in the outlet water quality conditioning device 50 may be stored in a memory of the mineralized faucet and executed by at least one processor to perform the functions of outlet water quality conditioning (described in detail with reference to fig. 1).

In this embodiment, the outlet water quality adjusting device 50 may be divided into a plurality of functional modules according to the functions performed by the same. The functional modules may include an acquisition module 501, a determination module 502, a display module 503, a trigger module 504, a control module 505, a monitoring module 506, a comparison module 507, and an alarm module 508. The module referred to herein is a series of computer readable instructions capable of being executed by at least one processor and of performing a fixed function, stored in a memory. In the present embodiment, the functions of the respective modules will be described in detail in the following embodiments.

The acquiring module 501 is configured to acquire biological information of a user.

The determining module 502 is configured to determine a recommended water quality range according to the biological information.

The display module 503 is configured to display the recommended water quality range in a water quality display area of the mineralized faucet.

The triggering module 504 is configured to receive a water outlet instruction triggered by the user in the operation control area of the mineralized faucet according to the recommended water quality range.

The control module 505 is configured to control the mineralizing faucet to perform water outlet according to the water outlet instruction.

The obtaining module 501 is further configured to obtain a working state of the mineralized faucet;

the display module 503 is further configured to display the operating state in a state display area of the mineralized faucet.

The monitoring module 506 is configured to monitor an actual outlet water quality of the mineralized faucet;

the comparison module 507 is configured to compare the actual effluent water quality with a preset standard water quality range;

the alarm module 508 is configured to control the mineralized faucet to alarm when the actual outlet water quality is not within the preset standard water quality range.

In an alternative embodiment, the determining module 502 determines the recommended water quality range based on the biological information includes:

and determining the age bracket of the user according to the biological information, and determining the recommended water quality range according to the age bracket.

In an alternative embodiment, the determining module 502 determines the recommended water quality range based on the biological information includes:

And identifying based on the biological information to obtain personalized features of the user, and determining a recommended water quality range according to the personalized features.

In an alternative embodiment, the displaying module 503 displays the recommended water quality range in a water quality display area of the mineralized faucet includes:

and determining a first display mode according to the age range of the user, and displaying the recommended water quality range in a water quality display area of the mineralized faucet according to the first display mode.

In an alternative embodiment, the displaying module 503 displays the recommended water quality range in a water quality display area of the mineralized faucet includes:

And determining a second display mode according to the personalized characteristics of the user, and displaying the recommended water quality range in a water quality display area of the mineralized faucet according to the second display mode.

In an alternative embodiment, the control module 505 controls the mineralizing faucet to emit water according to the water emitting instruction comprises:

Acquiring expected water quality of the water outlet in the water outlet instruction;

determining a desired soluble material content difference value according to the desired effluent quality;

obtaining the actual content difference of the soluble substances of the mineralized tap;

and controlling the mineralized faucet to discharge water according to the expected soluble substance content difference value and the actual soluble substance content difference value.

Wherein said controlling said mineralized faucet to deliver water according to said desired soluble material content differential and said actual soluble material content differential comprises:

Obtaining an expected deviation according to the expected soluble substance content difference and the actual soluble substance content difference;

Calculating a flow adjustment amount based on the expected deviation by using a proportional-integral-derivative control module;

and controlling the mineralized faucet to discharge water according to the flow adjustment quantity.

It should be understood that the various modifications and embodiments of the water quality control method provided in the foregoing embodiments are equally applicable to the water quality control device in this embodiment, and those skilled in the art will clearly know the implementation procedure of the water quality control device in this embodiment through the foregoing detailed description of the water quality control method, which is not described in detail herein for brevity.

According to the effluent quality adjusting device provided by the embodiment of the application, the water quality range can be recommended for different people by acquiring the biological information of the user, so that the personalized requirements of different people on the drinking water can be met, and various people can be ensured to obtain the drinking water which is most suitable for the body requirements of the people. The water quality display area is arranged on the mineralized tap, so that the recommended water quality range can be intuitively displayed, and a user can clearly know the water quality requirement suitable for the body of the user. Meanwhile, the user can trigger a water outlet instruction in the operation control area of the mineralized faucet, water outlet control is performed according to the water outlet instruction, and the operation convenience and experience of the user are improved. Compared with the traditional water purifier product with single function, the intelligent water purifier has the advantages that the water quality of the discharged water is intelligently adjusted, so that the water purifier product has stronger functionality and flexibility. The water quality of the water outlet can be flexibly adjusted according to the actual demands of users, so that the applicability and market competitiveness of the mineralized faucet are improved.

The embodiment of the application also provides a computer readable storage medium, wherein a computer program is stored on the computer readable storage medium, and the computer program realizes all or part of the steps of the effluent quality adjusting method when being executed by a processor.

Referring to fig. 6, a schematic diagram of a mineralized faucet according to an embodiment of the present application is shown. In a preferred embodiment of the application, the mineralizing tap 6 comprises a memory 601, at least one processor 602, at least one communication bus 603.

It will be appreciated by those skilled in the art that the structure of the mineralized faucet shown in FIG. 6 is not limiting of embodiments of the present application. The mineralizing tap 6 may also comprise more or less other hardware or software than shown, or a different arrangement of components.

In some embodiments, the mineralizing tap 6 is a device capable of automatically performing numerical calculation and/or information processing according to preset or stored instructions, and the hardware includes, but is not limited to, a microprocessor, an application specific integrated circuit, a programmable gate array, a digital processor, an embedded device, and the like. The mineralizing tap 6 may also comprise a client device including, but not limited to, any electronic product that can interact with a client by way of a keyboard, mouse, remote control, touch pad, or voice-controlled device, such as a personal computer, tablet, smart phone, digital camera, etc.

It should be noted that the mineralized faucet 6 is only used as an example, and other electronic products that may be present in the present application or may be present in the future are also included in the scope of the present application by way of reference.

In some embodiments, the memory 601 stores a computer program that, when executed by the at least one processor 602, performs all or part of the steps of the effluent quality conditioning method as described. The Memory 601 includes Read-Only Memory (ROM), programmable Read-Only Memory (PROM), erasable programmable Read-Only Memory (Erasable Programmable Read-Only Memory, EPROM), one-time programmable Read-Only Memory (One-time Programmable Read-Ony Memory, OTPROM), electrically erasable rewritable Read-Only Memory (EEPROM), compact disc Read-Only Memory (Compact Disc Read-Only Memory, CD-ROM) or other optical disc Memory, magnetic disk Memory, magnetic tape Memory, or any other medium that can be used for computer readable storage or carrying data. Further, the computer-readable storage medium may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function, and the like.

In some embodiments, the at least one processor 602 is the control core (Crol Unit) of the mineralized faucet 6, connects the various components of the entire mineralized faucet 6 using various interfaces and lines, runs or executes programs or modules stored in the memory 601, and invokes data stored in the memory 601 to perform various functions and process data of the mineralized faucet 6. For example, the at least one processor 602 may implement all or part of the steps of the method for regulating the quality of effluent according to the embodiments of the present application, or may implement all or part of the functions of the apparatus for regulating the quality of effluent when executing a computer program stored in the memory. The at least one processor 602 may be comprised of integrated circuits, such as a single packaged integrated circuit, or may be comprised of multiple integrated circuits packaged with the same or different functionality, including one or more central processing units (Central Processing Unit, CPU), microprocessors, digital processing chips, graphics processors, combinations of various control chips, and the like.

In some embodiments, the at least one communication bus 603 is arranged to enable connected communication between the memory 601 and the at least one processor 602 or the like. Although not shown, the mineralized faucet 6 may also include a power source (e.g., a battery) for powering the various components, preferably the power source may be logically coupled to the at least one processor 602 via a power management device, such that the power management device performs functions of managing charging, discharging, and power consumption. The power supply may also include one or more of any of a direct current or alternating current power supply, recharging device, power failure detection circuit, power converter or inverter, power status indicator, etc. The mineralizing tap 6 may further comprise various sensors, bluetooth modules, wi-Fi modules, etc., which are not described herein.

The integrated units implemented in the form of software functional modules described above may be stored in a computer readable storage medium. The software functional modules described above are stored in a storage medium and include instructions for causing a mineralized faucet (which may be a personal computer, mineralized faucet, or network device, etc.) or processor (processor) to perform portions of the methods described in the various embodiments of the application.

In the several embodiments provided by the present application, it should be understood that the disclosed apparatus and method may be implemented in other manners. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the modules is merely a logical function division, and there may be other manners of division when actually implemented.

The modules described as separate components may or may not be physically separate, and components shown as modules may or may not be physical units, may be located in one place, or may be distributed over multiple network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

Claims (10)

1. A method for regulating effluent water quality, characterized in that the method comprises: Obtaining the user's biometric information; determining a recommended water quality range based on the biological information; The recommended water quality range is displayed in the water quality display area of the mineral faucet; receiving a water output instruction triggered by the user in the operation control area of the mineral faucet according to the recommended water quality range; The mineralized faucet is controlled to discharge water according to the water discharge instruction. 2. The method for regulating effluent water quality according to claim 1, characterized in that determining the recommended water quality range according to the biological information comprises: Determine the age group of the user according to the biological information, and determine the recommended water quality range according to the age group; or Based on the biological information, identification is performed to obtain the personalized characteristics of the user, and the recommended water quality range is determined according to the personalized characteristics. 3. The method for regulating the outlet water quality according to claim 2, characterized in that the display of the recommended water quality range in the water quality display area of the mineralized faucet includes: Determine a first display mode according to the age group of the user, and display the recommended water quality range in the water quality display area of the mineral faucet according to the first display mode; or A second display mode is determined according to the personalized characteristics of the user, and the recommended water quality range is displayed in the water quality display area of the mineral faucet according to the second display mode. 4. The method for regulating the quality of water outlet according to claim 1, characterized in that the step of controlling the mineralized faucet to outlet water according to the water outlet instruction comprises: Obtaining the expected outlet water quality in the outlet water instruction; Determining an expected soluble matter content difference according to the expected effluent water quality; Obtaining the actual soluble substance content difference of the mineralized tap; The mineral faucet is controlled to discharge water according to the expected soluble substance content difference and the actual soluble substance content difference. 5. The method for regulating the quality of effluent water according to claim 4, characterized in that the step of controlling the effluent water from the mineralized tap according to the difference between the expected soluble substance content and the actual soluble substance content comprises: Obtaining an expected deviation according to the expected soluble substance content difference and the actual soluble substance content difference; Calculating a flow adjustment amount based on the desired deviation using a proportional-integral-derivative control module; The mineralized faucet is controlled to discharge water according to the flow adjustment amount. 6. The method for regulating effluent water quality according to claim 1, characterized in that the method further comprises: Obtaining the working status of the mineralization faucet; The working status is displayed in the status display area of the mineralization faucet. 7. The method for regulating effluent water quality according to claim 1, characterized in that the method further comprises: Monitoring the actual water quality of the mineralized faucet; Comparing the actual effluent water quality with a preset standard water quality range; When the actual outlet water quality is not within the preset standard water quality range, the mineral faucet is controlled to sound an alarm. 8. A device for regulating the quality of effluent water, characterized in that the device comprises: An acquisition module, used to acquire the user's biometric information; A determination module, used to determine a recommended water quality range based on the biological information; A display module, used to display the recommended water quality range in the water quality display area of the mineral faucet; A trigger module, configured to receive a water outlet instruction triggered by the user in the operation control area of the mineral faucet according to the recommended water quality range; A control module is used to control the mineralized faucet to discharge water according to the water discharge instruction. 9. A mineralized faucet, characterized in that the mineralized faucet comprises a memory, a processor, and a computer program stored in the memory and executable on the processor, wherein the processor implements the steps of the method for regulating the outlet water quality as described in any one of claims 1 to 7 when executing the computer program. 10. A computer-readable storage medium storing a computer program, wherein the computer program, when executed by a processor, implements the steps of the method for regulating effluent water quality as claimed in any one of claims 1 to 7.