CN108280637B - Artificial intelligence internet of things charging valve and method - Google Patents

Abstract

An artificial intelligence internet of things charging valve and a method relate to an internet of things device for charging by utilizing two-dimensional codes, payment treasures and WeChat. The method solves the problems that the existing heat rate metering mode and the existing fee payment mode are inflexible and cannot meet the requirements of people. Artificial intelligence thing networking charging valve includes central processing unit, inlet tube temperature sensor, wet return temperature sensor, memory circuit, actuating mechanism, valve body and WIFI communication module. The device adopts full electronic devices, has long service life, simple structure, strong flexibility and energy conservation. The guidance significance of the artificial intelligence internet of things charging valve is that the user is encouraged to save energy and reduce emission besides the convenience of charging. The invention has wide application range, simple structure, high flexibility and high compilability.

Description

Artificial intelligence internet of things charging valve and method

Technical Field

The invention belongs to the field of Internet of things, and relates to an Internet of things device for charging by using two-dimensional codes, payers and wechat.

Background

When cold winter comes, the northern area is heated in order to provide a comfortable working environment and a living environment. With the coming of the heating season in northern areas, the haze condition is further aggravated, and the fire coal causes atmospheric pollution and harms public health.

The existing heating mode is basically central heating, and a heat user has only two selection modes: or the heat supply enterprises can pay the full amount of heat according to the area of the house or stop heating. The heat supply and charging mode is unreasonable, when the user leaves the residential house in a staged manner, the heat supply company can still provide heat for the user according to the normal state, the haze pollution degree can be aggravated under the condition, and meanwhile, the economic expenditure cannot be saved for the heat user.

Therefore, the existing metering mode and the existing payment mode are too single to meet the requirements of people. Therefore, a contradiction exists between the heat supply enterprise and the heat consumer, the heat supply enterprise consumes a large amount of people and material resources to collect heat fees, the heat consumer has low willingness to pay the heat fees due to various reasons, and even if the heat fee is paid, the heat consumer cannot conveniently go to the specified place of the heat supply enterprise.

In order to bring convenience to hot users, an artificial intelligent IC card charging valve appears, the device charges according to heat flow, but the device has the problems that the IC card needs to be handled in a designated business hall when being paid, and the card swiping payment mode still has the problems that the user wastes time and labor when paying.

Disclosure of Invention

The invention aims to solve the problems that the existing heat charge metering mode and the existing charge payment mode are inflexible and cannot meet the requirements of people, and provides an artificial intelligence internet of things charging valve and a method.

The invention relates to an artificial intelligence internet of things charging valve which comprises a central processing unit (RoseFinch7100 internet of things chip), a water inlet pipe temperature sensor, a water return pipe temperature sensor, a storage circuit, an actuating mechanism, a valve body and a WIFI communication module, wherein the central processing unit is connected with the central processing unit;

the water inlet pipe temperature sensor is used for monitoring the temperature of the water inlet pipe and sending the temperature to the central controller;

the water return pipe temperature sensor is used for monitoring the temperature of the water outlet pipe and sending the temperature to the central controller;

judging whether the water heater is in a heating period or a heating stop period according to the temperature of the water inlet pipe and the temperature of the water outlet pipe;

if the heating system is in the heating stop period, the heating company sends an instruction to the central processing unit and controls the valve body to be normally opened through the execution mechanism;

if the central controller is in the heating period, the central controller measures heat energy according to the temperature of the water inlet pipe and the temperature of the water return pipe, the valve body is opened under the condition that the heat cost balance is more than 0, and otherwise, the central controller gives an alarm and closes the valve body in a delayed mode;

the storage circuit is used for storing payment data of the heat user, which is issued by a heat supply enterprise on a remote control platform through the Internet of things communication module;

the heat supply company communicates with the central controller through the internet of things communication module, and monitors the heat rate balance of a heat user in the storage circuit, the state of the valve body, the temperature of the water inlet pipe and the temperature of the water outlet pipe.

Preferably, the mobile phone system further comprises a WIFI communication module, the hot user configures the mobile phone APP, and the central processor communicates with at most four mobile phone APPs through the WIFI communication module;

the mobile phone APP receives a defaulting notice issued by the remote control platform through the Internet of things communication module, and also receives a heat charge consumption condition, a heat supply temperature and a valve body state;

the mobile phone APP can remotely control the valve body to be closed through the WIFI communication module;

under the state that the heat rate balance is greater than 0, the mobile phone APP can also be opened through the WIFI communication module remote control valve body.

Preferably, the payment mode of the hot user comprises the step of storing cash in an IC card, and the step of scanning a two-dimensional code, paying a treasure or paying a WeChat by a mobile phone APP.

Preferably, the charging mode selects charging according to unit area time or charging according to energy consumption of the meter.

The method for realizing the artificial intelligence internet of things charging valve comprises the following steps:

step one, judging whether heat supply or other purposes are provided;

if the heating period is the heating period, reading the water supply temperature and executing the step two; if the heat supply period is not the heat supply period, reading the expense balance and executing the step three;

step two, checking whether heat supply is started;

if so, reading the expense balance and executing the step four; if the result is negative, opening the valve body, and returning to the step I to execute the main program;

step three, checking whether the valve body is closed or not; if the valve is on, the valve body is opened; if the valve is closed, closing the valve body;

step four, checking whether the user has money;

if yes, continuing to open the valve body, and returning to the step one to execute the main program; if the balance is insufficient, reading the water temperature back, and executing the step five;

checking whether the heat supply is normal;

if the heat supply is normal, closing the valve body, and returning to the step one to execute the main program; if the heat supply is abnormal, the valve body is continuously opened, and the step one is returned to execute the main program.

The invention has the beneficial effects that:

the invention solves the contradiction between the heat supply enterprise and the heat supply user, also solves the problem of difficult charge of the heat supply enterprise, lightens the labor intensity of the working personnel of the heat supply enterprise, organically combines charge with control and monitoring, achieves the purposes that the heat supply enterprise can supply heat for the heat supply user after paying for the heat supply user, does not pay for the heat supply, supplies heat for the heat of buying money, stores the charge information of the heat supply user on a charge center platform of the heat supply enterprise, distributes the charge information of the heat supply user to each heat supply user control valve through the Internet of things by a remote control platform, judges whether to supply heat for the user after reading the charge information in a data memory, monitors the water temperature of a water supply pipe through a temperature transmitter on the heat supply pipe, and judges the start or the end of the heat supply. The remote control platform can know the heat supply situation and the quality of equipment in real time through the valve body opening state of each hot user of thing networking real-time supervision, and this device can be opened the valve body automatically and make things convenient for the heat supply enterprise to reform transform and maintain heat supply equipment during stopping warm by heating when heating the end through installing the temperature sensor on the pipeline. This device can also monitor whether heating up in winter is up to standard. A function of this device is exactly that the hot user can be through APP controlling part of smart mobile phone installation, and the remote switch of control valve body must not be owing for the heat fee when opening the valve body, and the valve body can be closed for a long time at home, reduces the heat fee and consumes, and this device can support 4 WIFI terminals to log in at most. The heat supply center can issue payment information to the heat user through the Internet of things, and inform the heat user of reminding to pay in time so as to avoid delaying heat supply, and the valve body of the heat user can be remotely switched on and off. The device adopts full electronic devices, has long service life, simple structure, strong flexibility and energy conservation.

The Zhongxing micro NB-IoT safety Internet of things chip RoseFinch7100 adopted by the invention has high safety confidentiality and reliable operation, the NB-IoT safety Internet of things chip RoseFinch7100 adopts a CoAP communication protocol in communication, the protocol has the characteristics of reliable data and simple and easy use of CoAP protocol transmission based on cloud service, the simple and easy use of CoAP protocol transmission based on cloud service has the characteristics of reliable data and simple and easy use, and the artificial intelligence Internet of things charging valve developed by utilizing the NB-IoT safety Internet of things chip RoseFinch7100 has the advantages of simple and convenient installation, no stay wire, namely, one pipeline physical connection, low cost which is as low as 20 yuan per terminal annual fee, and no flow limitation. The Internet of things mode adopted by the invention is different from the existing communication technology, the existing communication technology can also realize data uploading, the construction and installation are very complex and difficult, time and labor are wasted, the building is full of wiring, the cost of using the broadband is high like a spider web, the cost-efficiency ratio is low, enterprises and users cannot bear the broadband, the cost of using GPRS and 4G networks is higher, the same function can be completed, the installation is simple and convenient, the time and the labor are saved, the cost-efficiency ratio is high, the enterprise and the users can bear the broadband, the cost of 2G, 3G and 4G is not lower than 20 yuan per month at least, and the maintenance cost is not lower in one year if the Internet of things is not built by themselves. The guidance significance of the artificial intelligence internet of things charging valve is that the user is encouraged to save energy and reduce emission besides the convenience of charging.

The device can be matched with an ultrasonic or mechanical heat meter to use a synthetic flow meter type charging device, can also be matched with a temperature distribution method communication module to form a temperature distribution type heat charging device, can also be matched with a cold and hot water meter communication module to form a cold and hot water charging device, can also be matched with a gas meter communication module to form a gas charging device, can also be matched with a central air conditioner cold and hot amount metering communication module to form an air conditioner cold and hot amount charging device, and can be used for charging and controlling if temperature control data is input when the device is used for heat charging. The invention can be used for heating and charging independently and charges according to unit area or unit time. Therefore, the invention has wide application range, simple structure, high flexibility and high compilability.

Drawings

FIG. 1 is a schematic block diagram of an artificial intelligence internet of things toll valve in accordance with the present invention;

FIG. 2 is a circuit diagram of a toll valve body;

FIG. 3 is a circuit diagram of the connection between the execution circuit and the CPU;

fig. 4 is a circuit diagram of the connection between the WIFI communication module and the central processing unit;

FIG. 5 is a circuit diagram of the connection of the memory circuit to the CPU;

FIG. 6 is a main program flowchart;

FIG. 7 is a user interrupt routine flow diagram;

fig. 8 is a flowchart of the management interruption procedure.

Detailed Description

The following detailed description of the embodiments of the present invention will be provided with reference to the drawings and examples, so that how to apply the technical means to solve the technical problems and achieve the technical effects can be fully understood and implemented. It should be noted that, as long as there is no conflict, the embodiments and the features of the embodiments of the present invention may be combined with each other, and the technical solutions formed are within the scope of the present invention.

The mobile phone is a necessary article for people, the user can pay at any place and any time by using the Internet of things, and the situation that the valve is closed and the use is stopped due to the shortage of fee due to the lack of time payment can be avoided, so that the life is not influenced.

The artificial intelligent Internet of things charging valve can realize that a charging management department remotely turns off the valve of a defaulting user.

The artificial intelligent internet of things charging valve charges according to the actual heat energy of the user, the user charges the charge with a mobile phone according to the condition of the user, and the valve can be remotely controlled to be closed under the condition of long-term absence, so that the aims of saving energy and saving cost are fulfilled.

The charging mode is selected according to the unit area time or the energy consumption of the meter, and is selected according to the preference of the user.

Receiving a mathematical model of meter charging:

ΔA＝A-A_τ

A_τ＝Q_τ·M

in the formula, Delta A → residual amount (Yuan) in IC card or data memory

A → user deposits money amount (Yuan) in IC card or data memory

A_τ→ amount of money (yuan) consumed by user in unit time

Q_τ→ energy consumed by user per unit time (KWh)

M → Unit energy Unit price (Yuan/kwh)

Mathematical model of charging mode per unit area time:

ΔA＝A-A_τ

A_τ＝F·ΔΤ·Ν

in the formula, Delta A → residual amount (Yuan) in IC card or data memory

A_τ→ amount of money (yuan) consumed by user in unit time

F → user area (m)²)

Δ T → user time of use (h)

N → Unit area and price of energy consumption per unit time (Yuan/f.t)

The other applications (cold and hot water charge, gas charge, air conditioner cold and hot charge … …) are the same as the above meter model, but the energy consumption price is different, the unit energy consumption price is that the price is fixed when the IC card or the data storage is charged, and the price change is determined by the management department and can not be changed by the user.

Example (b): see the flow charts of fig. 6-8.

The main procedure is as follows:

and initializing the system and reading the state value setting.

Step one, judging whether heat supply or other purposes are provided;

if the heating period is the heating period, reading the water supply temperature and executing the step two; if the heat supply period is not the heat supply period, reading the expense balance and executing the step three;

the local government has definite provisions for the heating period, and can judge whether the heating period is currently set according to the time.

Step two, checking whether heat supply is started;

if so, reading the expense balance and executing the step four; if the result is negative, opening the valve body, and returning to the step I to execute the main program;

step three, checking whether the valve body is closed or not; if the valve is on, the valve body is opened; if the valve is closed, closing the valve body;

step four, checking whether the user has money;

if yes, continuing to open the valve body, and returning to the step one to execute the main program; if the balance is insufficient, reading the water temperature back, and executing the step five;

checking whether the heat supply is normal;

if the heat supply is normal, closing the valve body, and returning to the step one to execute the main program; if the heat supply is abnormal, the valve body is continuously opened, and the step one is returned to execute the main program.

Two interrupt routines:

interrupt 1: the user checks the arrears break, see fig. 7.

Step 11, whether a user inputs an arrearage checking command or not;

if so, sending the expense balance to the user terminal; if not, executing step 12;

step 12, checking whether a valve body is closed or not;

if the valve body is in a closed state, executing step 13; if the valve body is in the open state, executing step 14;

step 13, whether a valve opening command is received or not, if so, opening the valve body and returning to the main program; if not, returning to the main program;

step 14, whether a valve closing command is received or not, if so, closing the valve body and returning to the main program; if not, returning to the main program.

Interruption 2: the charge management department checks the interrupt program, see fig. 8.

Step 21, whether a defaulting checking instruction is received or not;

if yes, sending a defaulting notice, closing the valve body through the Internet of things, and returning to the main program; if not, go to step 22;

step 22, judging whether the user has recharged;

if yes, updating the balance of the user, and then executing the step 23; if not, returning to the main program;

step 23, monitoring whether the valve is closed or not,

if the state is a closed state, remotely opening the valve and returning to the main program; if the state is open, the main program is returned.

The specific implementation circuit is shown in fig. 2 to 5, where SW1 is a WIFI chip reset button, E0 and E1 are antennas, and the minimum system with U1 as a core is shown in fig. 2.

The central processing unit is a RoseFinch7100 Internet of things chip U1, the storage circuit is an FM25CL02 chip U2, the execution mechanism is a motor MG1, and the Internet of things communication module is a USIM card U4;

pins 34 and 35 of a RoseFinch7100 Internet of things chip U1 are respectively connected with the signal output ends of a water inlet pipe temperature sensor and a water return pipe temperature sensor;

a pin 3 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 1 of the chip U2, a pin 4 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 2 of the FM25CL02 chip U2, a pin 5 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 5 of the FM25CL02 chip U2, and a pin 6 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 6 of the FM25CL02 chip U2;

a pin 36 of the RoseFinch7100 Internet of things chip U1 is connected with a base electrode of a triode VT1 through a resistor R1, a collector electrode of the triode VT1 is grounded, an emitter electrode of the triode VT1 is connected with a positive power supply terminal of a motor MG1, and a negative power supply terminal of the motor MG1 is grounded;

the 11 pin of the RoseFinch7100 Internet of things chip U1 is simultaneously connected with the 8 pin of the USIM card U4, one end of the resistor R13 and one end of the resistor R15, the other end of the resistor R15 is grounded, and the other end of the resistor R13 is connected with the 20 pin of the RoseFinch7100 Internet of things chip U1;

the 12 pins of the RoseFinch7100 Internet of things chip U1 are connected with the 3 pins of the USIM card U4 through a resistor R9;

a pin 13 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 5 of a USIM card U4 through a resistor R10;

a 14 pin of the RoseFinch7100 Internet of things chip U1 is connected with a 6 pin of a USIM card U4 through a resistor R11, and the 6 pin of the USIM card U4 is grounded through a capacitor C9;

the pin 7 of the USIM card U4 is simultaneously connected with one end of the resistor R14 and one end of the resistor R16, the other end of the resistor R16 is grounded, and the other end of the resistor R14 is connected with the pin 20 of the RoseFinch7100 Internet of things chip U1.

The WIFI communication module is a WIFI chip U3 of an EPS8266, a pin 5 of a WIFI chip U3 of the EPS8266 is connected with a pin 9 of a RoseFinch7100 Internet of things chip U1, and a pin 6 of a WIFI chip U3 of the EPS8266 is connected with a pin 10 of the RoseFinch7100 Internet of things chip U1;

the 16 pins of the WIFI chip U3 of the EPS8266 are grounded;

a pin 15 of the WIFI chip U3 of the EPS8266 is connected with a power supply VCC, a pin 13 of the WIFI chip U3 of the EPS8266 is connected with the power supply VCC through a light emitting diode D1 and a resistor R4 which are connected in series, and a pin 11 of the WIFI chip U3 of the EPS8266 is connected with the power supply VCC through a light emitting diode D2 and a resistor R5 which are connected in series;

the 10 feet of the WIFI chip U3 of the EPS8266 are grounded through a reset button SW 1;

the 17 feet of the WIFI chip U3 of the EPS8266 are connected with an antenna E0.

Although the embodiments of the present invention have been described above, the above descriptions are only for the convenience of understanding the present invention, and are not intended to limit the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (8)

1. The artificial intelligence internet of things charging valve is characterized by comprising a central processing unit, a water inlet pipe temperature sensor, a water return pipe temperature sensor, a storage circuit, an actuating mechanism and a valve body;

the water inlet pipe temperature sensor is used for monitoring the temperature of the water inlet pipe and sending the temperature to the central controller;

the water return pipe temperature sensor is used for monitoring the temperature of the water outlet pipe and sending the temperature to the central controller;

judging whether the water heater is in a heating period or a heating stop period according to the temperature of the water inlet pipe and the temperature of the water outlet pipe;

if the heating system is in the heating stop period, the heating company sends an instruction to the central processing unit and controls the valve body to be normally opened through the execution mechanism;

if the central controller is in the heating period, the central controller measures heat energy according to the temperature of the water inlet pipe and the temperature of the water return pipe, the valve body is opened under the condition that the heat cost balance is more than 0, and otherwise, the central controller gives an alarm and closes the valve body in a delayed mode;

the storage circuit is used for storing payment data of the heat user issued by a heat supply enterprise on a remote control platform through the Internet of things communication module;

the heat supply company communicates with the central controller through the Internet of things communication module and monitors the heat charge balance of a heat user in the storage circuit, the state of the valve body, the temperature of the water inlet pipe and the temperature of the water outlet pipe;

the central processing unit is a RoseFinch7100 Internet of things chip U1, the storage circuit is an FM25CL02 chip U2, the execution mechanism is a motor MG1, and the Internet of things communication module is a USIM card U4;

pins 34 and 35 of a RoseFinch7100 Internet of things chip U1 are respectively connected with the signal output ends of a water inlet pipe temperature sensor and a water return pipe temperature sensor;

a pin 3 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 1 of the chip U2, a pin 4 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 2 of the FM25CL02 chip U2, a pin 5 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 5 of the FM25CL02 chip U2, and a pin 6 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 6 of the FM25CL02 chip U2;

a pin 36 of the RoseFinch7100 Internet of things chip U1 is connected with a base electrode of a triode VT1 through a resistor R1, a collector electrode of the triode VT1 is grounded, an emitter electrode of the triode VT1 is connected with a positive power supply terminal of a motor MG1, and a negative power supply terminal of the motor MG1 is grounded;

the 11 pin of the RoseFinch7100 Internet of things chip U1 is simultaneously connected with the 8 pin of the USIM card U4, one end of the resistor R13 and one end of the resistor R15, the other end of the resistor R15 is grounded, and the other end of the resistor R13 is connected with the 20 pin of the RoseFinch7100 Internet of things chip U1;

the 12 pins of the RoseFinch7100 Internet of things chip U1 are connected with the 3 pins of the USIM card U4 through a resistor R9;

a pin 13 of the RoseFinch7100 Internet of things chip U1 is connected with a pin 5 of a USIM card U4 through a resistor R10;

a 14 pin of the RoseFinch7100 Internet of things chip U1 is connected with a 6 pin of a USIM card U4 through a resistor R11, and the 6 pin of the USIM card U4 is grounded through a capacitor C9;

the pin 7 of the USIM card U4 is simultaneously connected with one end of the resistor R14 and one end of the resistor R16, the other end of the resistor R16 is grounded, and the other end of the resistor R14 is connected with the pin 20 of the RoseFinch7100 Internet of things chip U1.

2. The artificial intelligence internet of things toll valve as claimed in claim 1, further comprising a WIFI communication module, wherein a hot user configures the mobile phone APP, and the central processor communicates with at most four mobile phone APPs through the WIFI communication module;

the mobile phone APP receives a defaulting notice issued by the remote control platform through the Internet of things communication module, and also receives a heat charge consumption condition, a heat supply temperature and a valve body state;

the mobile phone APP can remotely control the valve body to be closed through the WIFI communication module;

under the state that the heat rate balance is greater than 0, the mobile phone APP can also be opened through the WIFI communication module remote control valve body.

3. The artificial intelligence thing networking charging valve of claim 2, characterized by, WIFI communication module is the WIFI chip U3 of EPS8266, 5 feet of the WIFI chip U3 of EPS8266 connect with RoseFinch7100 thing networking chip U1 9 feet, 6 feet of the WIFI chip U3 of EPS8266 connect with RoseFinch7100 thing networking chip U1 10 feet;

the 16 pins of the WIFI chip U3 of the EPS8266 are grounded;

a pin 15 of the WIFI chip U3 of the EPS8266 is connected with a power supply VCC, a pin 13 of the WIFI chip U3 of the EPS8266 is connected with the power supply VCC through a light emitting diode D1 and a resistor R4 which are connected in series, and a pin 11 of the WIFI chip U3 of the EPS8266 is connected with the power supply VCC through a light emitting diode D2 and a resistor R5 which are connected in series;

the 10 feet of the WIFI chip U3 of the EPS8266 are grounded through a reset button SW 1;

the 17 feet of the WIFI chip U3 of the EPS8266 are connected with an antenna E0.

4. The artificial intelligence thing networking charging valve of claim 3, characterized in that, the payment mode of the hot user includes that the IC card deposits cash, still includes cell-phone APP scanning two-dimensional code, payment treasure or little letter payment.

5. The artificial intelligence internet of things charging valve of claim 4, wherein the charging mode is selected from charging per unit area time or charging per energy consumption of the meter.

6. An implementation method of the artificial intelligence internet of things charging valve based on any one of claims 1 to 5, characterized by comprising the following steps:

step one, judging whether heat supply or other purposes are provided;

if the heating period is the heating period, reading the water supply temperature and executing the step two; if the heat supply period is not the heat supply period, reading the expense balance and executing the step three;

step two, checking whether heat supply is started;

if so, reading the expense balance and executing the step four; if the result is negative, opening the valve body, and returning to the step I to execute the main program;

step three, checking whether the valve body is closed or not; if the valve is on, the valve body is opened; if the valve is closed, closing the valve body;

step four, checking whether the user has money;

if yes, continuing to open the valve body, and returning to the step one to execute the main program; if the balance is insufficient, reading the water temperature back, and executing the step five;

checking whether the heat supply is normal;

if the heat supply is normal, closing the valve body, and returning to the step one to execute the main program; if the heat supply is abnormal, the valve body is continuously opened, and the step one is returned to execute the main program.

7. The method for implementing the artificial intelligence internet of things charging valve as claimed in claim 6, further comprising a user fee checking interrupt program, wherein the user fee checking interrupt program comprises the following steps:

step 11, whether a user inputs an arrearage checking command or not;

if so, sending the expense balance to the user terminal; if not, executing step 12;

step 12, checking whether a valve body is closed or not;

if the valve body is in a closed state, executing step 13; if the valve body is in the open state, executing step 14;

step 13, whether a valve opening command is received or not, if so, opening the valve body and returning to the main program; if not, returning to the main program;

step 14, whether a valve closing command is received or not, if so, closing the valve body and returning to the main program; if not, returning to the main program.

8. The method for implementing the artificial intelligence internet of things charging valve as claimed in claim 7, further comprising a charging management department checking fee interrupt program, wherein the charging management department checking fee interrupt program comprises the following steps:

step 21, whether a defaulting checking instruction is received or not;

if yes, sending a defaulting notice, closing the valve body through the Internet of things, and returning to the main program; if not, go to step 22;

step 22, judging whether the user has recharged;

if yes, updating the balance of the user, and then executing the step 23; if not, returning to the main program;

step 23, monitoring whether the valve is closed or not,

if the state is a closed state, remotely opening the valve and returning to the main program; if the state is open, the main program is returned.

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