CN117550664A

CN117550664A - Water purifying method, device, equipment and medium for large-scale direct drinking water equipment

Info

Publication number: CN117550664A
Application number: CN202410038877.3A
Authority: CN
Inventors: 邢春泉; 黄刚; 姜晓君; 夏静; 徐伟华
Original assignee: Qingdao Zhongrun Equipment Instrument Co ltd
Current assignee: Qingdao Zhongrun Equipment Instrument Co ltd
Priority date: 2024-01-11
Filing date: 2024-01-11
Publication date: 2024-02-13

Abstract

The application relates to a water purifying method, a device, equipment and a medium of a large-scale direct drinking water equipment, which comprise the steps of obtaining a direct drinking water equipment starting message and generating a water flow detection instruction according to the direct drinking water equipment starting message; acquiring water flow attribute data according to the water flow detection instruction, and generating a corresponding direct drinking water equipment adjusting instruction according to the water flow attribute data; acquiring real-time water quantity data of the wastewater tank, and generating a circulating working instruction when the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value; and acquiring real-time water quantity data of the water purifying tank, and generating a device circulation ending instruction when the real-time water quantity data of the water purifying tank is smaller than a rated water purifying increment in a preset time period. The application has the effect of reducing the wastewater rate of the direct drinking water equipment in water purification treatment.

Description

Water purifying method, device, equipment and medium for large-scale direct drinking water equipment

Technical Field

The invention relates to the technical field of direct drinking water, in particular to a water purifying method, device, equipment and medium of large-scale direct drinking water equipment.

Background

At present, water pollution becomes a serious problem with the development of industry and the progress of urban treatment. The water may contain various harmful substances such as heavy metals, chemicals, bacteria, viruses, etc. Therefore, people have increased attention to the quality of drinking water, and the demand for the quality of drinking water has correspondingly increased. The direct drinking water purifying equipment can effectively remove impurities and harmful substances in water, provide purer drinking water and accord with the pursuit of people on health. In the conventional drinking water method, the use of bottled water and barreled water may result in the generation of a large amount of plastic waste. The large direct drinking water purifying device provides a convenient and economical drinking water solution. The user can directly obtain clean drinking water from the equipment without purchasing and carrying a large amount of bottled water or barreled water, thereby being beneficial to reducing environmental pollution.

The prior art solutions described above have the following drawbacks: in the process of filtering and purifying water quality, large-scale direct drinking water equipment has the problems that the equipment operation and the water purification flow are improper, the wastewater rate is high, and the wastewater rate is high to possibly cause the waste of water resources, so that improvement space exists.

Disclosure of Invention

In order to reduce the wastewater rate of the direct drinking water equipment in water purification treatment, the application provides a water purification method, a device, equipment and a medium of the large direct drinking water equipment.

The first object of the present invention is achieved by the following technical solutions:

a water purification method of a large-scale direct drinking water apparatus, the water purification method of the large-scale direct drinking water apparatus comprising:

acquiring a direct drinking water equipment starting message, and generating a water flow detection instruction according to the direct drinking water equipment starting message;

acquiring water flow attribute data according to the water flow detection instruction, and generating a corresponding direct drinking water equipment adjusting instruction according to the water flow attribute data;

acquiring real-time water quantity data of a wastewater tank, and generating a circulating working instruction when the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value;

and acquiring real-time water quantity data of the water purifying tank, and generating a device circulation ending instruction when the real-time water quantity data of the water purifying tank is smaller than a rated water purifying increment in a preset time period.

By adopting the technical scheme, when the direct drinking water equipment is started, when the direct drinking water equipment starting message is acquired, the control system of the direct drinking water equipment can generate an instruction for detecting the water flow attribute in the direct drinking water equipment as a water flow detection instruction, so that the state of the direct drinking water when the equipment works can be acquired in real time, and corresponding operation treatment can be rapidly carried out according to the water flow real-time state; when a water flow detection instruction is acquired, detecting water flow in the direct drinking water equipment according to the acquired water flow detection instruction to obtain water flow attribute data in the direct drinking water equipment, generating a corresponding instruction for adjusting the direct drinking water equipment by a direct drinking water equipment control system according to the acquired water flow attribute data in the direct drinking water equipment, and taking the instruction as a direct drinking water equipment adjusting instruction, so that the direct drinking water equipment can be processed in a targeted manner according to the water flow attribute data in the direct drinking water equipment acquired in real time, and the amount of waste water generated when the equipment purifies water is reduced; acquiring water content data in a real-time wastewater tank when the historical direct drinking water equipment normally works, taking the highest value and the lowest value in the water content data of the equipment in the historical normal working state acquired in real time as preset water quantity threshold values, comparing the water content data in the wastewater tank acquired in real time in the current state with the preset water quantity threshold values, and when the water quantity data in the wastewater tank acquired in real time reaches the preset water quantity threshold values, generating an instruction for controlling the direct drinking water equipment to perform water purification treatment on wastewater again as a circulating working instruction by using the direct drinking water equipment control system, so that the water quantity of wastewater generated by the direct drinking water equipment in water purification can be reduced; the method comprises the steps of acquiring data of water content in a water purifying tank in real time, acquiring data of each water purifying increment of the water purifying tank in a water purifying device in a history use record in a preset time period, comparing the water content data in the water purifying tank acquired in real time with the rated water purifying increment in the preset time period, and generating an instruction for controlling the water purifying device to finish water purifying treatment of wastewater again when the data of the water content in the water purifying tank acquired in real time is smaller than the rated water purifying increment in the preset time period by using the data of the water purifying tank in the history use record as the rated water purifying increment, so that the water purifying efficiency of the water purifying device is improved, and the water purifying loss of the device is reduced.

The present application may be further configured in a preferred example to: the step of obtaining water flow attribute data according to the water flow detection instruction and generating a corresponding direct drinking water equipment adjusting instruction according to the water flow attribute data comprises the following steps:

acquiring water flow attribute data according to the water flow detection instruction, wherein the water flow attribute data comprises water flow speed data, equipment temperature data, residual chlorine content data and water pressure data;

and comparing the water flow attribute data with a preset attribute threshold value to obtain an attribute comparison result, and generating a corresponding direct drinking water equipment adjusting instruction according to the attribute comparison result.

By adopting the technical scheme, when the water flow detection instruction is acquired, in order to quickly adjust and process water flows in different working stages, water flow attribute data in the direct drinking water equipment are acquired according to the acquired water flow detection instruction, wherein the water flow attribute data comprise water flow speed data, equipment temperature data, residual chlorine content data and water pressure data, so that real-time recording of all water flow attributes in the equipment is facilitated, and the water flow attribute data can be quickly processed when abnormality occurs; and comparing the acquired water flow attribute data with a preset attribute threshold value to obtain a water flow attribute comparison result, and generating a corresponding instruction for controlling the direct drinking water equipment to adjust according to the acquired water flow attribute comparison result so as to control the direct drinking water equipment to adjust the data of abnormal conditions, thereby being beneficial to reducing the generation of wastewater and improving the safety of direct drinking water.

The present application may be further configured in a preferred example to: the generating the corresponding direct drinking water equipment adjusting instruction according to the attribute comparison result comprises the following steps:

generating an attribute abnormal message according to the attribute comparison result, and acquiring abnormal attribute data according to the attribute abnormal message;

and calculating the difference value between the abnormal attribute data and the preset attribute threshold value, obtaining a corresponding abnormal attribute difference value, and generating a corresponding direct drinking water equipment adjusting instruction according to the abnormal attribute difference value.

By adopting the technical scheme, when the attribute comparison result is obtained, an attribute abnormality message is generated according to the attribute comparison result and when the comparison result is abnormal, abnormal attribute data in water flow attribute data of the direct drinking water equipment is obtained, so that the abnormal situation can be intuitively reflected through specific data when the direct drinking water equipment is abnormal; and calculating the difference value between the acquired abnormal water flow attribute data and a preset attribute threshold value, taking the difference value between the abnormal data and a corresponding preset threshold value to obtain an abnormal attribute difference value, and generating a corresponding instruction for controlling the direct drinking water equipment to adjust according to the obtained abnormal attribute difference value, so that the water purifying rate of the direct drinking water equipment in the water purifying process is improved.

The present application may be further configured in a preferred example to: the generating the corresponding direct drinking water equipment adjusting instruction according to the abnormal attribute difference value specifically comprises:

when the abnormal attribute difference is a water flow speed difference value and a water pressure difference value, generating a water pressure regulating instruction according to the water flow speed difference value and the water pressure difference value;

and when the abnormal attribute difference is the residual chlorine content difference, the equipment temperature difference and the water flow speed difference, generating a temperature regulation instruction according to the water flow speed difference and the equipment temperature difference.

By adopting the technical scheme, when the abnormal attribute difference value is obtained, the abnormal attribute is processed, when the obtained abnormal attribute difference value is the water flow speed difference value and the water pressure difference value, the water pressure required to be regulated is calculated according to the obtained water flow speed difference value and the water pressure difference value through a formula, and a water pressure regulation instruction is generated according to the obtained water pressure regulation quantity, so that more accurate regulation quantity is obtained, the water pressure can be accurately regulated, and the waste water quantity generated in the water purification process is further improved; when the obtained abnormal attribute difference is the residual chlorine content difference, the equipment temperature difference and the water flow velocity difference, according to the obtained water flow velocity difference and the equipment temperature difference, the adjustment quantity of the temperature required to be adjusted is calculated through a preset formula in the system, and according to the obtained temperature adjustment quantity, an adjustment instruction for controlling the equipment temperature is generated, so that the temperature can reach the optimal sterilizing and disinfecting effect, and the safety of drinking water production of the direct drinking water equipment is further improved.

The present application may be further configured in a preferred example to: the step of obtaining the real-time water quantity data of the wastewater tank, and the step of generating a circulation working instruction when the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value comprises the following steps:

acquiring the preset water quantity threshold value, and comparing the real-time water quantity data of the wastewater tank with the preset water quantity threshold value to obtain a water quantity comparison result;

and when the water quantity comparison result shows that the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value, generating a wastewater filtering instruction.

By adopting the technical scheme, the water content data in the real-time wastewater tank is obtained when the historical direct drinking water equipment works normally, the highest value and the lowest value in the water content data of the equipment in the historical normal working state obtained in real time are used as preset water quantity threshold values, the water quantity data of the real-time wastewater tank in the current state is obtained, and the water quantity data of the real-time wastewater tank in the current state is compared with the preset water quantity threshold values to obtain a water quantity comparison result; the water quantity comparison result is obtained, and when the water quantity comparison result is that the real-time water quantity data of the wastewater tank reaches the preset water quantity threshold value, the generated wastewater is subjected to filtering treatment again, so that an instruction for controlling the direct drinking water equipment to filter the wastewater can be generated, and the accuracy of operation control of the direct drinking water equipment in water purification can be improved.

The present application may be further configured in a preferred example to: the step of obtaining real-time water quantity data of the water purifying tank, and the step of generating equipment circulation ending instructions when the real-time water quantity data of the water purifying tank is smaller than rated water purifying increment in a preset time period comprises the following steps:

acquiring equipment working time, segmenting the equipment working time according to a preset time period to obtain each working time period, and acquiring a water purifying increment in the preset time period according to each working time period;

comparing the real-time water quantity data of the water purifying tank with the water purifying increment in the preset time period, and generating a circulation stopping filtering instruction when the real-time water quantity data of the water purifying tank is smaller than the rated water purifying increment in the preset time period.

By adopting the technical scheme, the working time length of the direct drinking water equipment is obtained, the equipment working time is processed in sections according to the preset time period, different time periods are obtained, and the purified water increment corresponding to the different time periods is obtained according to the different working time periods, so that the accuracy of corresponding operation when the direct drinking water equipment performs purified water treatment is improved; the obtained real-time water quantity data of the water purifying tank is compared with the water purifying increment in the preset time period, and when the real-time water quantity data of the water purifying tank is smaller than the rated water purifying increment in the preset time period, the control system can generate an instruction for controlling the direct drinking water equipment to stop filtering the wastewater again, so that the water purifying efficiency of the direct drinking water equipment is improved, and the water purifying loss of the equipment is reduced.

The second object of the present invention is achieved by the following technical solutions:

a large-scale direct drinking water apparatus water purification device, the large-scale direct drinking water apparatus water purification device comprising:

the water flow detection instruction generation module is used for acquiring a direct drinking water equipment starting message and generating a water flow detection instruction according to the direct drinking water equipment starting message;

the direct drinking water equipment adjusting instruction generating module is used for acquiring water flow attribute data according to the water flow detection instruction and generating a corresponding direct drinking water equipment adjusting instruction according to the water flow attribute data;

the circulation working instruction generation module is used for acquiring real-time water quantity data of the wastewater tank, and generating a circulation working instruction when the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value;

and the generating equipment circulation ending instruction module is used for acquiring real-time water quantity data of the water purifying tank, and generating equipment circulation ending instructions when the real-time water quantity data of the water purifying tank is smaller than rated water purifying increment in a preset time period.

The third object of the present application is achieved by the following technical solutions:

a computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor implementing the steps of the method for purifying water of a large-scale direct drinking water device when executing the computer program.

The fourth object of the present application is achieved by the following technical solutions:

a computer readable storage medium storing a computer program which when executed by a processor performs the steps of the above-described large scale direct drinking water apparatus water purification method.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the direct drinking water equipment is started, when a direct drinking water equipment starting message is acquired, a control system of the direct drinking water equipment can generate an instruction for detecting the water flow attribute in the direct drinking water equipment as a water flow detection instruction, so that the state of the direct drinking water when the equipment works can be acquired in real time, and corresponding operation treatment can be rapidly carried out according to the water flow real-time state; when a water flow detection instruction is acquired, detecting water flow in the direct drinking water equipment according to the acquired water flow detection instruction to obtain water flow attribute data in the direct drinking water equipment, generating a corresponding instruction for adjusting the direct drinking water equipment by a direct drinking water equipment control system according to the acquired water flow attribute data in the direct drinking water equipment, and taking the instruction as a direct drinking water equipment adjusting instruction, so that the direct drinking water equipment can be processed in a targeted manner according to the water flow attribute data in the direct drinking water equipment acquired in real time, and the amount of waste water generated when the equipment purifies water is reduced; acquiring water content data in a real-time wastewater tank when the historical direct drinking water equipment normally works, taking the highest value and the lowest value in the water content data of the equipment in the historical normal working state acquired in real time as preset water quantity threshold values, comparing the water content data in the wastewater tank acquired in real time in the current state with the preset water quantity threshold values, and when the water quantity data in the wastewater tank acquired in real time reaches the preset water quantity threshold values, generating an instruction for controlling the direct drinking water equipment to perform water purification treatment on wastewater again as a circulating working instruction by using the direct drinking water equipment control system, so that the water quantity of wastewater generated by the direct drinking water equipment in water purification can be reduced; acquiring data of the water content in the water purifying tank in real time, acquiring data of each water purifying increment of the water purifying tank in the water purifying device in the history use record in a preset time period, comparing the water content data in the water purifying tank acquired in real time with the rated water purifying increment in the preset time period, and generating an instruction for controlling the water purifying device to finish water purifying treatment of the wastewater again when the data of the water content in the water purifying tank acquired in real time is smaller than the rated water purifying increment in the preset time period by the control system, so that the water purifying efficiency of the water purifying device is improved, and the water purifying loss of the device is reduced;

2. When a water flow detection instruction is acquired, in order to quickly adjust water flows in different working stages, water flow attribute data in the direct drinking water equipment are acquired according to the acquired water flow detection instruction, wherein the water flow attribute data comprise water flow speed data, equipment temperature data, residual chlorine content data and water pressure data, so that real-time recording of all water flow attributes in the equipment is facilitated, and the water flow attribute data can be quickly processed when abnormality occurs; comparing the acquired water flow attribute data with a preset attribute threshold value to obtain a water flow attribute comparison result, and generating a corresponding instruction for controlling the direct drinking water equipment to adjust by the direct drinking water equipment according to the acquired water flow attribute comparison result so as to control the direct drinking water equipment to adjust the data of abnormal conditions, thereby being beneficial to reducing the generation of waste water and improving the safety of direct drinking water;

3. when an abnormal attribute difference value is obtained, processing the abnormal attribute, and when the obtained abnormal attribute difference value is a water flow speed difference value and a water pressure difference value, calculating the water pressure required to be regulated according to a formula according to the obtained water flow speed difference value and the water pressure difference value, and generating a water pressure regulating instruction according to the obtained water pressure regulating quantity, thereby being beneficial to obtaining more accurate regulating quantity, accurately regulating the water pressure and further improving the waste water quantity generated in the water purification process; when the obtained abnormal attribute difference is the residual chlorine content difference, the equipment temperature difference and the water flow speed difference, calculating an adjustment quantity of which the temperature needs to be adjusted according to the obtained water flow speed difference and the equipment temperature difference by a preset formula in the system, and generating an adjustment instruction for controlling the equipment temperature according to the obtained temperature adjustment quantity, so that the temperature can reach the optimal sterilization and disinfection effect, and the safety of drinking water production of the direct drinking water equipment is further improved;

4. Acquiring water content data in a real-time wastewater tank when the historical direct drinking water equipment works normally, taking the highest value and the lowest value in the water content data of the equipment in the historical normal working state acquired in real time as a preset water quantity threshold value, acquiring the water quantity data of the real-time wastewater tank in the current state, and comparing the water quantity data of the real-time wastewater tank in the current state with the preset water quantity threshold value to obtain a water quantity comparison result; the method comprises the steps that a water quantity comparison result is obtained, when the water quantity comparison result shows that the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value, generated wastewater is subjected to filtering treatment again, so that an instruction for controlling the direct drinking water equipment to filter the wastewater is generated, and the accuracy of operation control of the direct drinking water equipment in water purification can be improved;

5. the method comprises the steps of obtaining the working time length of the direct drinking water equipment, carrying out sectional treatment on the equipment working time according to a preset time period to obtain different time periods, and obtaining purified water increment corresponding to the different time periods according to the different working time periods, so that the accuracy of corresponding operation when the direct drinking water equipment carries out purified water treatment is improved; the obtained real-time water quantity data of the water purifying tank is compared with the water purifying increment in the preset time period, and when the real-time water quantity data of the water purifying tank is smaller than the rated water purifying increment in the preset time period, the control system can generate an instruction for controlling the direct drinking water equipment to stop filtering the wastewater again, so that the water purifying efficiency of the direct drinking water equipment is improved, and the water purifying loss of the equipment is reduced.

Drawings

FIG. 1 is a flow chart of a method for purifying water in a large-scale direct drinking water apparatus according to an embodiment of the present application;

FIG. 2 is a flowchart showing the implementation of step S20 in a water purifying method of a large-scale direct drinking water apparatus according to an embodiment of the present application;

FIG. 3 is a flowchart showing the implementation of step S22 in a water purifying method of a large-scale direct drinking water apparatus according to an embodiment of the present application;

FIG. 4 is a flowchart illustrating a method for purifying water in a large-scale drinking water apparatus according to an embodiment of the present application;

FIG. 5 is a flowchart showing the implementation of step S30 in a water purifying method of a large-scale direct drinking water apparatus according to an embodiment of the present application;

FIG. 6 is a flowchart showing the implementation of step S40 in a water purifying method of a large-scale direct drinking water apparatus according to an embodiment of the present application;

FIG. 7 is a schematic block diagram of a water purifying device of a large-scale direct drinking water apparatus according to an embodiment of the present application;

fig. 8 is a schematic view of an apparatus in an embodiment of the present application.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

In one embodiment, as shown in fig. 1, the application discloses a water purifying method of a large-scale direct drinking water device, which specifically comprises the following steps:

s10: and acquiring a direct drinking water equipment starting message, and generating a water flow detection instruction according to the direct drinking water equipment starting message.

In this embodiment, the direct drinking device start message refers to a message triggered when the direct drinking device starts. The water flow detection instruction is an instruction for detecting water flow in the direct drinking water equipment.

Specifically, when the direct drinking water equipment is started, in order to acquire the state of the direct drinking water when the equipment works in real time, corresponding operation processing can be rapidly performed according to the real-time state of water flow, so that when a starting message of the direct drinking water equipment is acquired, a command for detecting the water flow attribute in the direct drinking water equipment can be generated by a control system of the direct drinking water equipment and used as a water flow detection command.

S20: and acquiring water flow attribute data according to the water flow detection instruction, and generating a corresponding direct drinking water equipment adjusting instruction according to the water flow attribute data.

In the present embodiment, the water flow attribute data refers to data containing an attribute of water flow in the direct drinking apparatus. The direct drinking water equipment adjusting instruction refers to an instruction for adjusting the direct drinking water equipment.

Specifically, in order to be able to carry out targeted processing on the equipment according to the attribute of the water flow in the direct drinking equipment obtained in real time, therefore, when the water flow detection instruction is obtained, the water flow in the direct drinking equipment is detected according to the obtained water flow detection instruction, the data of the attribute of the water flow in the direct drinking equipment is obtained, and according to the obtained data of the attribute of the water flow in the direct drinking equipment, the direct drinking equipment control system can generate a corresponding instruction for adjusting the direct drinking equipment as a direct drinking equipment adjusting instruction so as to reduce the amount of generated wastewater when the equipment purifies water.

S30: and acquiring real-time water quantity data of the wastewater tank, and generating a circulating working instruction when the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value.

In this embodiment, the real-time water amount data of the wastewater tank refers to data for acquiring the water content in the wastewater tank in real time. The circulation working instruction is an instruction for controlling the direct drinking water equipment to perform water purification treatment on the wastewater again.

Specifically, when the direct drinking water device works, the real-time water quantity data of the wastewater tank is obtained, so that the wastewater quantity generated by the direct drinking water device during water purification can be reduced, therefore, by obtaining the water content data in the wastewater tank in real time when the historical direct drinking water device works normally, taking the highest value and the lowest value in the water content data of the device in the historical normal working state obtained in real time as preset water quantity threshold values, comparing the water content data in the wastewater tank obtained in real time in the current state with the preset water quantity threshold values, when the water quantity data of the wastewater tank obtained in real time reaches the preset water quantity threshold values, if the highest value of the preset water quantity threshold values is 40 liters, the lowest value is 5 liters, and when the water quantity data of the wastewater tank obtained in real time is 50 liters, the direct drinking water device control system can generate an instruction for controlling the direct drinking water device to process wastewater again as a circulating working instruction.

S40: and acquiring real-time water quantity data of the water purifying tank, and generating a device circulation ending instruction when the real-time water quantity data of the water purifying tank is smaller than a rated water purifying increment in a preset time period.

In this embodiment, the real-time water amount data of the water purifying tank refers to data of acquiring the water content in the water purifying tank in real time. The purified water increment refers to the amount of water increment in the purified water tank. The equipment circulation ending instruction refers to an instruction for controlling the equipment to end water purification treatment of the wastewater again.

Specifically, in order to increase the water purification efficiency of the direct drinking water apparatus and reduce the water purification loss of the apparatus, the data of the water content in the water purification tank is obtained in real time during the operation of the direct drinking water apparatus, and the data of the increase amount of each water purification in the water purification tank in the history use record in a preset time period is obtained, the data of the water content in the water purification tank obtained in real time is compared with the rated water purification increment in the preset time period as the rated water purification increment, and when the data of the water content in the water purification tank obtained in real time is smaller than the rated water increment in the preset time period, for example, when the water purification increment obtained in the history equipment operation record is 25 liters after the direct drinking water apparatus is operated for one hour, the current water purification increment obtained in real time is 5 liters and smaller than the water purification increment obtained in the history equipment operation record, so that the control system generates an instruction for controlling the direct drinking water apparatus to finish water purification treatment again as an equipment cycle end instruction.

In this embodiment, when the direct drinking water device is started, when a direct drinking water device starting message is obtained, the control system of the direct drinking water device generates an instruction for detecting the water flow attribute in the direct drinking water device as a water flow detection instruction, so that the state of the direct drinking water when the device works can be obtained in real time, and corresponding operation processing can be rapidly performed according to the water flow real-time state; when a water flow detection instruction is acquired, detecting water flow in the direct drinking water equipment according to the acquired water flow detection instruction to obtain water flow attribute data in the direct drinking water equipment, generating a corresponding instruction for adjusting the direct drinking water equipment by a direct drinking water equipment control system according to the acquired water flow attribute data in the direct drinking water equipment, and taking the instruction as a direct drinking water equipment adjusting instruction, so that the direct drinking water equipment can be processed in a targeted manner according to the water flow attribute data in the direct drinking water equipment acquired in real time, and the amount of waste water generated when the equipment purifies water is reduced; acquiring water content data in a real-time wastewater tank when the historical direct drinking water equipment normally works, taking the highest value and the lowest value in the water content data of the equipment in the historical normal working state acquired in real time as preset water quantity threshold values, comparing the water content data in the wastewater tank acquired in real time in the current state with the preset water quantity threshold values, and when the water quantity data in the wastewater tank acquired in real time reaches the preset water quantity threshold values, generating an instruction for controlling the direct drinking water equipment to perform water purification treatment on wastewater again as a circulating working instruction by using the direct drinking water equipment control system, so that the water quantity of wastewater generated by the direct drinking water equipment in water purification can be reduced; the method comprises the steps of acquiring data of water content in a water purifying tank in real time, acquiring data of each water purifying increment of the water purifying tank in a water purifying device in a history use record in a preset time period, comparing the water content data in the water purifying tank acquired in real time with the rated water purifying increment in the preset time period, and generating an instruction for controlling the water purifying device to finish water purifying treatment of wastewater again when the data of the water content in the water purifying tank acquired in real time is smaller than the rated water purifying increment in the preset time period by using the data of the water purifying tank in the history use record as the rated water purifying increment, so that the water purifying efficiency of the water purifying device is improved, and the water purifying loss of the device is reduced.

In one embodiment, as shown in fig. 2, in step S20, water flow attribute data is obtained according to the water flow detection instruction, and a corresponding direct drinking device adjustment instruction is generated according to the water flow attribute data, which specifically includes:

s21: and acquiring water flow attribute data according to the water flow detection instruction, wherein the water flow attribute data comprises water flow speed data, equipment temperature data, residual chlorine content data and water pressure data.

Specifically, when the water flow detection instruction is acquired, in order to acquire data of different water flow attributes in real time, real-time monitoring is performed, so that according to the water flow detection instruction, the water flow speed sensor is controlled to detect the water flow speed, the temperature sensor is controlled to detect the equipment temperature, the chlorine sensor is controlled to detect the residual chlorine content and the pressure sensor is controlled to detect the water flow pressure, and the acquired water flow speed data, equipment temperature data, residual chlorine content data and water pressure data are counted and summarized to be used as water flow attribute data.

S22: and comparing the water flow attribute data with a preset attribute threshold value to obtain an attribute comparison result, and generating a corresponding direct drinking water equipment adjusting instruction according to the attribute comparison result.

In this embodiment, the attribute comparison result refers to a result obtained by comparing the water flow attribute data with a preset attribute threshold.

Specifically, in order to improve the purification rate of water flow and reduce the amount of waste water generated by the direct drinking water equipment during operation, when the obtained water flow attribute data is compared with a preset attribute threshold value, the obtained water flow velocity data is compared with the preset water flow velocity threshold value, the obtained equipment temperature data is compared with the preset temperature threshold value, the obtained residual chlorine content data is compared with the preset residual chlorine content threshold value and the water pressure data is compared with the preset water pressure threshold value one by one, a water flow attribute comparison result is obtained, and a corresponding control direct drinking water equipment adjusting instruction is generated according to the obtained attribute comparison result.

In one embodiment, as shown in fig. 3, in step S22, the water flow attribute data is compared with a preset attribute threshold to obtain an attribute comparison result, and a corresponding direct drinking water equipment adjustment instruction is generated according to the attribute comparison result, which specifically includes:

s221: generating attribute exception information according to the attribute comparison result, and acquiring exception attribute data according to the attribute exception information.

In this embodiment, the attribute abnormality message refers to a message triggered when abnormality occurs in the water flow attribute in the direct drinking device. The abnormal attribute data refers to data of an attribute of abnormal water flow of the direct drinking water equipment.

Specifically, in order to quickly process the abnormal attribute data, when an attribute comparison result is obtained, an attribute abnormal message is generated when the comparison result is abnormal, and according to the attribute abnormal message, the data of the corresponding abnormal attribute of the water flow of the direct drinking water equipment is obtained, for example, when the water flow rate comparison result is abnormal, the flow rate of the water flow in the direct drinking water equipment in the current state is obtained; when the residual chlorine content comparison result is abnormal, the residual chlorine content in the direct drinking water equipment in the current state is obtained and recorded in the system, and the obtained data in the abnormal state are used as abnormal attribute data.

S222: and calculating the difference value between the abnormal water flow attribute data and a preset attribute threshold value, obtaining a corresponding abnormal attribute difference value, and generating a corresponding direct drinking water equipment adjusting instruction according to the abnormal attribute difference value.

Specifically, in order to facilitate rapid and accurate processing in the case of abnormal conditions, the difference value between the abnormal water flow attribute data and a preset attribute threshold is calculated, and if the obtained water flow velocity is abnormal, the obtained water flow velocity in the direct drinking water equipment is different from the preset water flow velocity threshold to obtain a water flow velocity difference value; when the water pressure is abnormal, the difference value between the water pressure obtained in the current state and a preset water pressure threshold value is calculated, the water pressure difference value is obtained, and the like, so that various different abnormal water flow attribute difference values are obtained, and when the corresponding abnormal attribute difference value is obtained, a corresponding instruction for controlling the direct drinking water equipment to adjust is generated according to the abnormal attribute.

In one embodiment, as shown in fig. 4, in step S222, the difference value between the abnormal water flow attribute data and the preset attribute threshold is calculated, a corresponding abnormal attribute difference value is obtained, and a corresponding direct drinking device adjustment instruction is generated according to the abnormal attribute difference value, which specifically includes:

s2221: and when the abnormal attribute difference is a water flow speed difference value and a water pressure difference value, generating a water pressure regulating instruction according to the water flow speed difference value and the water pressure difference value.

In this embodiment, the difference between the water flow rates refers to a value obtained by calculating a difference between the obtained abnormal water flow rate and a preset water flow rate. The water pressure difference value is a value obtained by calculating the difference value between the obtained abnormal water flow pressure and the preset water pressure. The water pressure adjusting instruction refers to an instruction for controlling the direct drinking water equipment to adjust the water pressure.

Specifically, in order to accurately process the direct drinking water equipment in an abnormal state, the obtained water flow velocity difference value and the water pressure difference value are calculated by the following formulas: c (C) ₁ =α×（V/V ₀ ）+β×(P ₀ -P)/P ₀ Wherein C ₁ Is a constant value, alpha and beta are weight values, V is a water flow velocity difference value, V ₀ For maximum water flow rate, P is the air pressure value of the equipment, P ₀ For the difference in water pressure, P is used ₀ The calculation of P in the formula is to reduce the error of the air pressure abnormality in the direct drinking water equipment caused by the steam generated by the air evaporation when the direct drinking water equipment works, more accurate water pressure adjustment values can be calculated through the calculation formula, for example, when the water flow speed difference is 10m/min, the calculated water pressure adjustment amount is 5Pa, when the water flow speed difference is 15m/min, the calculated water pressure adjustment amount is 10Pa through the formula, and the like, and according to the obtained water pressure amount to be adjusted, a corresponding instruction for controlling the water pressure of the direct drinking water equipment to be adjusted is generated and used as the water pressure adjustment instruction.

S2222: and when the abnormal attribute difference is the residual chlorine content difference, the equipment temperature difference and the water flow speed difference, generating a temperature regulation instruction according to the water flow speed difference and the equipment temperature difference.

In this embodiment, the residual chlorine content difference is a value obtained by calculating a difference between the obtained abnormal residual chlorine content and a preset residual chlorine content. The temperature difference is a value obtained by calculating the difference between the acquired abnormal equipment temperature and the preset equipment temperature. The temperature regulation instruction refers to an instruction for controlling the direct drinking water equipment to regulate the equipment temperature.

Specifically, when the obtained difference value of the abnormal property is the residual chlorine content difference value, the equipment temperature difference value and the water flow velocity difference value, calculating the obtained water flow velocity difference value and the equipment temperature difference value by the formula: q=kχv× (T-T)/(p×a), where Q is a temperature adjustment amount, k is a proportionality coefficient, V is a water flow velocity difference, T is room temperature, T is a device temperature difference, P is an atmospheric pressure value, a is a pipe cross-sectional area, T-T is used to reduce an error caused by a change in an external environment temperature, the temperature adjustment amount is calculated by calculating the water flow velocity difference, and a corresponding instruction for controlling the temperature of the drinking device to be adjusted is generated as a temperature adjustment instruction based on the acquired suction-adjusted temperature amount.

In one embodiment, as shown in fig. 5, in step S30, real-time water volume data of the wastewater tank is obtained, and when the real-time water volume data of the wastewater tank reaches a preset water volume threshold, a circulation work instruction is generated, which specifically includes:

s31: and acquiring a preset water quantity threshold value, and comparing the real-time water quantity data of the wastewater tank with the preset water quantity threshold value to obtain a water quantity comparison result.

In this embodiment, the water volume comparison result is a result obtained by comparing the real-time water volume data of the wastewater tank with a preset water volume threshold.

Specifically, in order to improve the accuracy of operation control of the direct drinking water device during water purification, water content data in a real-time wastewater tank during normal operation of the historical direct drinking water device is obtained, the highest value and the lowest value in the water content data of the device during normal operation of the historical direct drinking water device, which are obtained in real time, are used as preset water quantity threshold values, real-time wastewater tank water quantity data in the current state are obtained, and the real-time wastewater tank water quantity data in the current state are compared with the preset water quantity threshold values to obtain water quantity comparison results.

S32: and when the water quantity comparison result shows that the real-time water quantity data of the wastewater tank reaches the preset water quantity threshold value, generating a wastewater filtering instruction.

In this embodiment, the wastewater filtering instruction refers to an instruction for controlling the direct drinking device to filter wastewater.

Specifically, the water quantity comparison result is obtained, so that the water purification rate of the direct drinking water equipment in the water purification process can be improved, and when the water quantity comparison result shows that the real-time water quantity data of the wastewater tank reaches the preset water quantity threshold value, the generated wastewater is subjected to filtering treatment again, so that an instruction for controlling the direct drinking water equipment to filter the wastewater is generated and is used as a wastewater filtering instruction.

In one embodiment, as shown in fig. 6, in step S40, real-time water volume data of the water purifying tank is obtained, and when the real-time water volume data of the water purifying tank is smaller than a rated water purifying increment in a preset time period, a device cycle end instruction is generated, which specifically includes:

s41: acquiring equipment working time, segmenting the equipment working time according to a preset time period to obtain each working time period, and acquiring the purified water increment in the preset time period according to each working time period.

In this embodiment, the device operation time refers to the period of time during which the direct drinking device is operating normally.

Specifically, in order to improve the accuracy of corresponding operations when the direct drinking water equipment performs water purification treatment, the working time of the direct drinking water equipment is processed in a segmented mode according to a preset time period by acquiring the working time of the direct drinking water equipment, different time periods are obtained, and the water purification increment corresponding to the different time periods is acquired according to the different working time periods and is used as the water purification increment in the preset time period.

S42: comparing the real-time water quantity data of the water purifying tank with the water purifying increment in the preset time period, and generating a stop circulation filtering instruction when the real-time water quantity data of the water purifying tank is smaller than the rated water purifying increment in the preset time period.

In this embodiment, the stop-cycle filtering instruction refers to an instruction for controlling the direct drinking device to stop filtering the wastewater again.

Specifically, in order to increase the water purification efficiency of the direct drinking water device and reduce the water purification loss of the device, therefore, by comparing the obtained real-time water volume data of the water purification tank with the water purification increment in the preset time period, when the real-time water volume data of the water purification tank is smaller than the rated water purification increment in the preset time period, the control system generates an instruction for controlling the direct drinking water device to stop filtering the wastewater again as a circulating filtration stopping instruction.

It should be understood that the sequence number of each step in the foregoing embodiment does not mean that the execution sequence of each process should be determined by the function and the internal logic of each process, and should not limit the implementation process of the embodiment of the present application in any way.

In an embodiment, a large-scale direct drinking water apparatus water purifying device is provided, and the large-scale direct drinking water apparatus water purifying device corresponds to the large-scale direct drinking water apparatus water purifying method in the embodiment one by one. As shown in fig. 7, the large-scale direct drinking water equipment water purifying device comprises a water flow detection instruction generation module, a direct drinking water equipment adjusting instruction generation module, a circulation work instruction generation module and an equipment circulation ending instruction generation module. The functional modules are described in detail as follows:

The water flow detection instruction generation module is used for acquiring the direct drinking water equipment starting message and generating a water flow detection instruction according to the direct drinking water equipment starting message;

and the generating equipment circulation ending instruction module is used for acquiring real-time water quantity data of the water purifying tank, and generating equipment circulation ending instructions when the real-time water quantity data of the water purifying tank is smaller than rated water purifying increment within a preset time period.

Optionally, the generating the direct drinking water apparatus adjusting instruction module includes:

the water flow attribute data acquisition sub-module is used for acquiring the water flow attribute data according to the water flow detection instruction, wherein the water flow attribute data comprises water flow speed data, equipment temperature data, residual chlorine content data and water pressure data;

and the generation equipment adjustment instruction submodule is used for comparing the water flow attribute data with a preset attribute threshold value to obtain an attribute comparison result, and generating the corresponding direct drinking equipment adjustment instruction according to the attribute comparison result.

Optionally, the generating device adjustment instruction submodule includes:

the method comprises the steps of obtaining an abnormal attribute data unit, generating an attribute abnormal message according to an attribute comparison result, and obtaining abnormal attribute data according to the attribute abnormal message;

and the generation regulation instruction unit is used for calculating the difference value between the abnormal water flow attribute data and a preset attribute threshold value, obtaining a corresponding abnormal attribute difference value, and generating a corresponding direct drinking water equipment regulation instruction according to the abnormal attribute difference value.

Optionally, generating the adjustment instruction unit includes:

the water pressure regulating instruction generating subunit is used for generating a water pressure regulating instruction according to the water flow speed difference value and the water pressure difference value when the abnormal attribute difference value is the water flow speed difference value and the water pressure difference value;

and the generated temperature regulation instruction subunit is used for generating a temperature regulation instruction according to the water flow speed difference and the equipment temperature difference when the abnormal attribute difference is the residual chlorine content difference, the equipment temperature difference and the water flow speed difference.

Optionally, the generating the cyclical work instruction module includes:

the water quantity comparison result submodule is used for obtaining a preset water quantity threshold value, and comparing the real-time water quantity data of the wastewater tank with the preset water quantity threshold value to obtain a water quantity comparison result;

And the generated wastewater filtering instruction submodule is used for generating a wastewater filtering instruction when the water quantity comparison result shows that the real-time water quantity data of the wastewater tank reaches the preset water quantity threshold value.

Optionally, the generating the device cycle end instruction module includes:

the water purification increment sub-module is used for acquiring the working time of the equipment, segmenting the working time of the equipment according to the preset time periods to obtain each working time period, and acquiring the preset water purification increment in the preset time period according to each working time period;

the generation and circulation stopping filtering instruction submodule is used for comparing the real-time water quantity data of the water purifying tank with a preset water purifying increment in a preset time period, and when the real-time water quantity data of the water purifying tank is smaller than a rated water purifying increment in the preset time period, a circulation stopping filtering instruction is generated.

The specific limitation of the water purifying device of the large-scale direct drinking device can be referred to as limitation of the water purifying method of the large-scale direct drinking device, and the detailed description is omitted herein. All or part of the modules in the water purifying device of the large-scale direct drinking water equipment can be realized by software, hardware and the combination thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above modules.

In one embodiment, a computer device is provided, which may be a server, and the internal structure of which may be as shown in fig. 8. The computer device includes a processor, a memory, a network interface, and a database connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program when executed by the processor is used for realizing a water purifying method of the large-scale direct drinking water equipment.

In one embodiment, a computer device is provided comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing the steps of when executing the computer program:

acquiring real-time water quantity data of the wastewater tank, and generating a circulating working instruction when the real-time water quantity data of the wastewater tank reaches a preset water quantity threshold value;

In one embodiment, a computer readable storage medium is provided having a computer program stored thereon, which when executed by a processor, performs the steps of:

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the various embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of the functional units and modules is illustrated, and in practical application, the above-described functional distribution may be performed by different functional units and modules according to needs, i.e. the internal structure of the apparatus is divided into different functional units or modules to perform all or part of the above-described functions.

The above embodiments are only for illustrating the technical solution of the present application, and are not limiting; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present application, and are intended to be included in the scope of the present application.

Claims

1. The water purifying method of the large-scale direct drinking water equipment is characterized by comprising the following steps of:

2. The method of claim 1, wherein the obtaining water flow attribute data according to the water flow detection command and generating a corresponding direct drinking device adjustment command according to the water flow attribute data comprises:

3. The method of claim 2, wherein generating the corresponding direct drinking device adjustment command according to the attribute comparison result comprises:

4. The method for purifying water in a large-scale direct drinking water apparatus according to claim 3, wherein the generating the corresponding direct drinking water apparatus adjusting instruction according to the abnormal attribute difference value specifically includes:

5. The method for purifying water in a large-scale direct drinking water apparatus according to claim 1, wherein the obtaining real-time water volume data of the wastewater tank, and when the real-time water volume data of the wastewater tank reaches a preset water volume threshold, generating the circulation work instruction comprises:

6. The method for purifying water in a large-scale direct drinking water apparatus according to claim 1, wherein the acquiring real-time water volume data of the water purifying tank, and when the real-time water volume data of the water purifying tank is smaller than a rated purified water increment in a preset time period, generating the apparatus cycle end instruction comprises:

7. The utility model provides a large-scale direct drinking water equipment purifier which characterized in that, large-scale direct drinking water equipment purifier includes:

8. The large scale direct drinking apparatus water purifying apparatus according to claim 7, wherein the generating direct drinking apparatus adjusting instruction module includes:

9. A computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, characterized in that the processor, when executing the computer program, carries out the steps of the method for purifying water of a large drinking water apparatus according to any one of claims 1 to 6.

10. A computer readable storage medium storing a computer program, wherein the computer program when executed by a processor performs the steps of the water purification method of a large scale direct drinking water apparatus as claimed in any one of claims 1 to 6.