CN114240223A - Multi-port control method for intelligent lighting platform - Google Patents

Abstract

The invention belongs to the field of intelligent illumination platforms, in particular to a multi-port control method for an intelligent illumination platform, which aims at solving the problems that the existing intelligent illumination platform is complex to operate, ambiguous in classification, free of a quick query method, incapable of quickly checking all data of the platform and incapable of completing energy consumption metering and remote meter reading statistical functions of electric energy metering equipment when in use, and provides the following scheme, wherein the scheme comprises the following steps: s1, user login: in the invention, all operation data of the platform, instruction, state, data, operation time and other information of operated equipment can be checked through operation history, energy consumption measurement and remote meter reading statistical functions of electric energy metering equipment can be completed through a data center, and a power utilization plan can be managed and controlled.

Description

Multi-port control method for intelligent lighting platform

Technical Field

The invention relates to the technical field of intelligent lighting platforms, in particular to a multi-port control method for an intelligent lighting platform.

Background

The intelligent lighting is also called as an intelligent public lighting management platform or an intelligent street lamp, remote centralized control and management of the street lamp are realized by applying an advanced, efficient and reliable power line carrier communication technology, a wireless GPRS/CDMA communication technology and the like, the intelligent street lamp has the functions of automatically adjusting brightness according to traffic flow, controlling remote lighting, actively alarming faults, preventing theft of lamp cables, remotely reading meter and the like, and can greatly save power resources, improve the public lighting management level and save maintenance cost.

When the existing intelligent illumination platform is used, the operation is complex, the classification is not clear, a quick query method is not available, all data of the platform cannot be quickly checked, the energy consumption metering and remote meter reading statistical functions of electric energy metering equipment cannot be completed, and the single lamp state cannot be controlled in a centralized manner, so that a multi-port control method for the intelligent illumination platform is provided for solving the problems.

Disclosure of Invention

The invention aims to solve the defects that in the prior art, when an intelligent illumination platform is used, the operation is complicated, the classification is not clear, a quick query method is not available, all data of the platform cannot be quickly checked, the energy consumption metering and remote meter reading statistical functions of electric energy metering equipment cannot be completed, and the state of a single lamp cannot be intensively controlled, and provides a multi-port control method for the intelligent illumination platform.

In order to achieve the purpose, the invention adopts the following technical scheme:

a multi-port control method for an intelligent lighting platform, comprising the steps of:

s1, user login: a user enters a website of the lamp networking platform through browsers such as IE, 360 and the like;

s2, operation state:

s21, device status: after logging in the platform, clicking the left navigation bar 'equipment state', entering a page, and displaying a host name, equipment grouping, current, voltage and the like in a list;

s22, single lamp state: clicking the left navigation bar in the single-lamp state, clicking the name of the left equipment in the list after entering the page, and checking the existing state of the single lamp of each host; clicking the history on the right side of the list can check the history of the single-lamp execution command;

s23, lighting ratio: clicking the left navigation bar to turn on the light rate, clicking the name of the left equipment in the list after entering the page, checking the current on-off state of a single lamp under each host, turning off the light grey state and turning on the green state, clicking the left upper equipment light rate in the list, and checking the general view of the single lamp switches under all the hosts;

s3, management center:

s31, equipment management: the user can add the equipment, change the equipment information and inquire the local address of the equipment through equipment management;

s32, single lamp management: the equipment has the functions of single lamp and centralized inspection, and the operation data flow can be increased when the inspection is started;

s33, managing the electric meter: completing configuration of the equipment ammeter, and realizing selection of the type of the ammeter by clicking to update;

s34, system setting: the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

s35, life cycle: the user inputs data to be filled, and the system automatically generates the service life according to the use condition;

s36, user management: user information and login passwords can be modified;

s4, operation and maintenance center:

s41, alarm list: displaying alarm information, alarm processing states and processing time of all equipment;

s42, alarm setting: the alarm equipment and the alarm reason required by the group can be set according to actual requirements;

s5, control center:

s51, centralized control: the user can select the control mode of the host, and can close the control loop and adjust the brightness of the single lamp under the host by clicking the 'manual control' on the on-line switch;

s52, centralized setting: the method comprises the steps of setting timing control parameters, setting longitude and latitude control parameters and setting illuminance control parameters;

s521, timing setting: the timing switch time takes a week as a unit, a user can customize the lamp switching time according to needs and select an action loop, and the time input is based on the quotation marks input by English;

s522, light control setting: under the modes including a light control mode, such as timing light control, comprehensive control and the like, the on-off of an output loop can be controlled according to the brightness of the illumination by setting light control parameters, 2 groups of light on-off time are built in the illumination, and in the illumination time, the equipment is executed according to light control logic, otherwise, the equipment is executed according to other logic, such as timing;

s523, longitude and latitude control: the device can automatically calculate the time for turning on and off the lamp by setting the longitude and latitude parameters, and simultaneously, the system designs a group of lamp-on correction values and lamp-off correction values;

s53, single lamp control: the function of single lamp control can accurately control each lamp, and the single lamp can be finely managed and can be illuminated as required through the realization of the single lamp control;

s54, single lamp setting: the grouping condition of the single lamps under each host can be checked, and the brightness can be adjusted;

s6, data center:

s61, energy consumption data: the platform can accomplish energy consumption measurement and the long-range statistical function of checking meter to electric energy metering equipment, and through energy consumption management function, the user can master field device's power consumption information in real time, accomplishes the management and the control to the power consumption plan, and energy-conserving contrast: energy-saving effect of current equipment energy consumption and reserved energy consumption, and carbon asset management: the method comprises the data display of the saved electric energy, the saved coal and the saved carbon emission when the equipment is used;

s62, operation data and operation and maintenance data, operation history: checking all operation data of the platform, and information such as instructions, states, data, operation time and the like of the operated equipment, quickly inquiring by recording equipment states, operation time, protocols and equipment numbers, and simultaneously clearing all historical records;

and S7, judging whether the user wants to operate, if so, clicking a corresponding button to perform related operation, if not, judging whether N is less than or equal to 30 by the system, if not, automatically recording related data by the system, adding one to the value of N, turning to S7, if N is more than 30, automatically reading the meter and performing a ring ratio, simultaneously returning the value of N to zero, and returning to S7.

Preferably, the intelligent lighting platform in step S1 includes an operation state, a management center, an operation and maintenance center, a control center and a data center;

the running state comprises a device state, a single lamp state and a bright spot rate;

the management center comprises equipment management, single lamp management, electric meter management, system setting, life cycle and user management;

the operation and maintenance center comprises alarm setting and an alarm list;

the control center comprises centralized control, centralized setting, single lamp control and single lamp setting;

the data center comprises energy consumption data, operation data and operation and maintenance data.

Preferably, the device status includes device name, device group, control mode, voltage and power;

the single lamp state comprises a single lamp address, a lamp post number, a mode, voltage, a power supply, kilometer factors, temperature, lamp turn-on times, alarms, electric energy, leakage current, lamp turn-on time, single lamp power and updating time;

the lighting rate comprises a single-lamp lighting rate and an equipment lighting rate.

Preferably, the device management includes ID, site name, site number, device model, device group, status, installation location, IP, and connection time;

the single lamp management comprises a single lamp address, a lamp post number, a mode, voltage and a power supply;

the electric meter management comprises equipment name, electric meter model, electric meter number, meter reading protocol, original reference power, charge rate, original load and new load;

the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

the lifecycle includes site name, site number, equipment group, purchase date, design lifetime, elapsed time, and remaining lifetime.

Preferably, the alarm list comprises alarms to be processed, processed alarms and alarm statistics;

the alarm setting comprises switch abnormity, equipment offline, system fault, voltage abnormity, current abnormity, external control abnormity, illegal door opening, lamp power failure, lamp fault, output feedback abnormity, temperature abnormity, cable anti-theft, water immersion, electric leakage and single lamp offline alarm.

Preferably, the centralized control comprises a control mode and a manual control;

the centralized setting comprises tenth control, light control setting and longitude and latitude setting;

the single lamp control comprises a single lamp manual control mode and a single lamp control mode;

the single lamp settings include single lamp grouping and single lamp brightness settings.

Preferably, the energy consumption data comprises an energy consumption report, an energy saving comparison, a power trend, energy consumption monitoring and carbon assets;

the operational data and the operation and maintenance data include operational history.

Preferably, in the step S7, the information after the automatic loop ratio and the automatic meter reading are automatically uploaded.

Compared with the prior art, the invention has the beneficial effects that:

1. all operation data of the platform can be checked through operation history, so that a user can conveniently and fully know the information such as instructions, states, data, operation time and the like of the operated equipment, the equipment state, the operation time, the protocol and the equipment number can be input for quick query, the equipment query time is reduced, and all history records can be removed after the device is damaged and replaced for saving the memory;

2. can accomplish energy consumption measurement and the long-range statistical function of checking meter to electric energy metering equipment through energy consumption data, and then can reduce workman's work load, through looking over the ring ratio of electric energy and energy-saving rate, the user can master field device's power consumption information in real time, accomplishes the management and the control to the power consumption plan.

According to the invention, the platform can complete energy consumption metering and remote meter reading statistical functions of the electric energy metering equipment through the energy consumption data, so that the workload of workers can be reduced, a user can master the electricity utilization information of the field equipment in real time by checking the loop ratio of the electric energy to the energy saving rate, the energy consumption of the equipment is adjusted according to actual conditions, and management and control of an electricity utilization plan are completed.

Drawings

FIG. 1 is a schematic structural diagram of a multi-port control method for an intelligent lighting platform according to the present invention;

FIG. 2 is a flowchart illustrating a multi-port control method for an intelligent lighting platform according to the present invention;

fig. 3 is a working flow chart of automatic meter reading in the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings of the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Example one

Referring to fig. 1-3, a multi-port control method for an intelligent lighting platform includes the steps of:

s1, user login: a user enters a website of the lamp networking platform through browsers such as IE, 360 and the like;

s2, operation state:

s21, device status: after logging in the platform, clicking the left navigation bar 'equipment state', entering a page, and displaying a host name, equipment grouping, current, voltage and the like in a list;

s22, single lamp state: clicking the left navigation bar in the single-lamp state, clicking the name of the left equipment in the list after entering the page, and checking the existing state of the single lamp of each host; clicking the history on the right side of the list can check the history of the single-lamp execution command;

s23, lighting ratio: clicking the left navigation bar to turn on the light rate, clicking the name of the left equipment in the list after entering the page, checking the current on-off state of a single lamp under each host, turning off the light grey state and turning on the green state, clicking the left upper equipment light rate in the list, and checking the general view of the single lamp switches under all the hosts;

s3, management center:

s31, equipment management: the user can add the equipment, change the equipment information and inquire the local address of the equipment through equipment management;

s32, single lamp management: the equipment has the functions of single lamp and centralized inspection, and the operation data flow can be increased when the inspection is started;

s33, managing the electric meter: completing configuration of the equipment ammeter, and realizing selection of the type of the ammeter by clicking to update;

s34, system setting: the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

s35, life cycle: the user inputs data to be filled, and the system automatically generates the service life according to the use condition;

s36, user management: user information and login passwords can be modified;

s4, operation and maintenance center:

s41, alarm list: displaying alarm information, alarm processing states and processing time of all equipment;

s42, alarm setting: the alarm equipment and the alarm reason required by the group can be set according to actual requirements;

s5, control center:

s51, centralized control: the user can select the control mode of the host, and can close the control loop and adjust the brightness of the single lamp under the host by clicking the 'manual control' on the on-line switch;

s52, centralized setting: the method comprises the steps of setting timing control parameters, setting longitude and latitude control parameters and setting illuminance control parameters;

s521, timing setting: the timing switch time takes a week as a unit, a user can customize the lamp switching time according to needs and select an action loop, and the time input is based on the quotation marks input by English;

s522, light control setting: under the modes including a light control mode, such as timing light control, comprehensive control and the like, the on-off of an output loop can be controlled according to the brightness of the illumination by setting light control parameters, 2 groups of light on-off time are built in the illumination, and in the illumination time, the equipment is executed according to light control logic, otherwise, the equipment is executed according to other logic, such as timing;

s523, longitude and latitude control: the device can automatically calculate the time for turning on and off the lamp by setting the longitude and latitude parameters, and simultaneously, the system designs a group of lamp-on correction values and lamp-off correction values;

s53, single lamp control: the function of single lamp control can accurately control each lamp, and the single lamp can be finely managed and can be illuminated as required through the realization of the single lamp control;

s54, single lamp setting: the grouping condition of the single lamps under each host can be checked, and the brightness can be adjusted;

s6, data center:

s61, energy consumption data: the platform can accomplish energy consumption measurement and the long-range statistical function of checking meter to electric energy metering equipment, and through energy consumption management function, the user can master field device's power consumption information in real time, accomplishes the management and the control to the power consumption plan, and energy-conserving contrast: energy-saving effect of current equipment energy consumption and reserved energy consumption, and carbon asset management: the method comprises the data display of the saved electric energy, the saved coal and the saved carbon emission when the equipment is used;

s62, operation data and operation and maintenance data, operation history: checking all operation data of the platform, and information such as instructions, states, data, operation time and the like of the operated equipment, quickly inquiring by recording equipment states, operation time, protocols and equipment numbers, and simultaneously clearing all historical records;

and S7, judging whether the user wants to operate, if so, clicking a corresponding button to perform related operation, if not, judging whether N is less than or equal to 30 by the system, if not, automatically recording related data by the system, adding one to the value of N, turning to S7, if N is more than 30, automatically reading the meter and performing a ring ratio, simultaneously returning the value of N to zero, and returning to S7.

Example two

Referring to fig. 1-3, a multi-port control method for an intelligent lighting platform includes the steps of:

s1, user login: a user enters a website of a lamp networking platform through browsers such as IE, 360 and the like, and the intelligent illumination platform comprises an operation state, a management center, an operation and maintenance center, a control center and a data center;

the operation state comprises a device state, a single lamp state and a bright spot rate, wherein the device state comprises a device name, a device group, a control mode, a voltage and a power supply;

the single lamp state comprises a single lamp address, a lamp post number, a mode, voltage, a power supply, kilometer factors, temperature, lamp turn-on times, alarm, electric energy, leakage current, lamp turn-on time, single lamp power and updating time;

the lighting rate comprises a single-lamp lighting rate and an equipment lighting rate;

the management center comprises equipment management, single lamp management, electric meter management, system setting, life cycle and user management, wherein the equipment management comprises ID, site name, site number, equipment model, equipment grouping, state, installation position, IP and connection time;

the single lamp management comprises a single lamp address, a lamp post number, a mode, voltage and a power supply;

the electric meter management comprises equipment name, electric meter model, electric meter number, meter reading protocol, original reference power, charge rate, original load and new load;

the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

the life cycle comprises a site name, a site number, equipment grouping, a purchase date, a design life, used time and remaining life;

the operation and maintenance center comprises alarm setting and an alarm list, wherein the alarm list comprises alarms to be processed, processed alarms and alarm statistics;

the alarm setting comprises switch abnormity, equipment offline, system fault, voltage abnormity, current abnormity, external control abnormity, illegal door opening, lamp power failure, lamp fault, output feedback abnormity, temperature abnormity, cable theft prevention, water immersion, electric leakage and single lamp offline alarm;

the control center comprises centralized control, centralized setting, single lamp control and single lamp setting, wherein the centralized control comprises a control mode and manual control;

the centralized setting comprises tenth control, light control setting and longitude and latitude setting;

the single lamp control comprises a single lamp manual control mode and a single lamp control mode;

the single lamp setting comprises a single lamp group and a single lamp brightness setting;

the data center comprises energy consumption data, operation data and operation and maintenance data, wherein the energy consumption data comprises an energy consumption report, energy saving comparison, a power trend, energy consumption monitoring and carbon assets;

the operation data and the operation and maintenance data comprise operation history;

s2, operation state:

s21, device status: after logging in the platform, clicking the left navigation bar 'equipment state', entering a page, and displaying a host name, equipment grouping, current, voltage and the like in a list;

s22, single lamp state: clicking the left navigation bar in the single-lamp state, clicking the name of the left equipment in the list after entering the page, and checking the existing state of the single lamp of each host; clicking the history on the right side of the list can check the history of the single-lamp execution command;

s23, lighting ratio: clicking the left navigation bar to turn on the light rate, clicking the name of the left equipment in the list after entering the page, checking the current on-off state of a single lamp under each host, turning off the light grey state and turning on the green state, clicking the left upper equipment light rate in the list, and checking the general view of the single lamp switches under all the hosts;

s3, management center:

s31, equipment management: the user can add the equipment, change the equipment information and inquire the local address of the equipment through equipment management;

s32, single lamp management: the equipment has the functions of single lamp and centralized inspection, and the operation data flow can be increased when the inspection is started;

s33, managing the electric meter: completing configuration of the equipment ammeter, and realizing selection of the type of the ammeter by clicking to update;

s34, system setting: the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

s35, life cycle: the user inputs data to be filled, and the system automatically generates the service life according to the use condition;

s36, user management: user information and login passwords can be modified;

s4, operation and maintenance center:

s41, alarm list: displaying alarm information, alarm processing states and processing time of all equipment;

s42, alarm setting: the alarm equipment and the alarm reason required by the group can be set according to actual requirements;

s5, control center:

s51, centralized control: the user can select the control mode of the host, and can close the control loop and adjust the brightness of the single lamp under the host by clicking the 'manual control' on the on-line switch;

s52, centralized setting: the method comprises the steps of setting timing control parameters, setting longitude and latitude control parameters and setting illuminance control parameters;

s521, timing setting: the timing switch time takes a week as a unit, a user can customize the lamp switching time according to needs and select an action loop, and the time input is based on the quotation marks input by English;

s522, light control setting: under the modes including a light control mode, such as timing light control, comprehensive control and the like, the on-off of an output loop can be controlled according to the brightness of the illumination by setting light control parameters, 2 groups of light on-off time are built in the illumination, and in the illumination time, the equipment is executed according to light control logic, otherwise, the equipment is executed according to other logic, such as timing;

s523, longitude and latitude control: the device can automatically calculate the time for turning on and off the lamp by setting the longitude and latitude parameters, and simultaneously, the system designs a group of lamp-on correction values and lamp-off correction values;

s53, single lamp control: the function of single lamp control can accurately control each lamp, and the single lamp can be finely managed and can be illuminated as required through the realization of the single lamp control;

s54, single lamp setting: the grouping condition of the single lamps under each host can be checked, and the brightness can be adjusted;

s6, data center:

s61, energy consumption data: the platform can accomplish energy consumption measurement and the long-range statistical function of checking meter to electric energy metering equipment, and through energy consumption management function, the user can master field device's power consumption information in real time, accomplishes the management and the control to the power consumption plan, and energy-conserving contrast: energy-saving effect of current equipment energy consumption and reserved energy consumption, and carbon asset management: the method comprises the data display of the saved electric energy, the saved coal and the saved carbon emission when the equipment is used;

s62, operation data and operation and maintenance data, operation history: checking all operation data of the platform, and information such as instructions, states, data, operation time and the like of the operated equipment, quickly inquiring by recording equipment states, operation time, protocols and equipment numbers, and simultaneously clearing all historical records;

and S7, judging whether the user wants to operate, if so, clicking a corresponding button to perform related operation, if not, judging whether N is less than or equal to 30 by the system, if not, automatically recording related data by the system, adding one to the numerical value of N, turning to S7, if N is greater than 30, automatically reading the meter and performing a ring ratio, simultaneously returning the numerical value of N to zero, returning to S7, and automatically uploading the information after the automatic ring ratio and the automatic meter reading.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Claims (8)

1. A multi-port control method for an intelligent lighting platform, comprising the steps of:

s1, user login: a user enters a website of the lamp networking platform through browsers such as IE, 360 and the like;

s2, operation state:

s21, device status: after logging in the platform, clicking the left navigation bar 'equipment state', entering a page, and displaying a host name, equipment grouping, current, voltage and the like in a list;

s22, single lamp state: clicking the left navigation bar in the single-lamp state, clicking the name of the left equipment in the list after entering the page, and checking the existing state of the single lamp of each host; clicking the history on the right side of the list can check the history of the single-lamp execution command;

s23, lighting ratio: clicking the left navigation bar to turn on the light rate, clicking the name of the left equipment in the list after entering the page, checking the current on-off state of a single lamp under each host, turning off the light grey state and turning on the green state, clicking the left upper equipment light rate in the list, and checking the general view of the single lamp switches under all the hosts;

s3, management center:

s31, equipment management: the user can add the equipment, change the equipment information and inquire the local address of the equipment through equipment management;

s32, single lamp management: the equipment has the functions of single lamp and centralized inspection, and the operation data flow can be increased when the inspection is started;

s33, managing the electric meter: completing configuration of the equipment ammeter, and realizing selection of the type of the ammeter by clicking to update;

s34, system setting: the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

s35, life cycle: the user inputs data to be filled, and the system automatically generates the service life according to the use condition;

s36, user management: user information and login passwords can be modified;

s4, operation and maintenance center:

s41, alarm list: displaying alarm information, alarm processing states and processing time of all equipment;

s42, alarm setting: the alarm equipment and the alarm reason required by the group can be set according to actual requirements;

s5, control center:

s51, centralized control: the user can select the control mode of the host, and can close the control loop and adjust the brightness of the single lamp under the host by clicking the 'manual control' on the on-line switch;

s52, centralized setting: the method comprises the steps of setting timing control parameters, setting longitude and latitude control parameters and setting illuminance control parameters;

s521, timing setting: the timing switch time takes a week as a unit, a user can customize the lamp switching time according to needs and select an action loop, and the time input is based on the quotation marks input by English;

s522, light control setting: under the modes including a light control mode, such as timing light control, comprehensive control and the like, the on-off of an output loop can be controlled according to the brightness of the illumination by setting light control parameters, 2 groups of light on-off time are built in the illumination, and in the illumination time, the equipment is executed according to light control logic, otherwise, the equipment is executed according to other logic, such as timing;

s523, longitude and latitude control: the device can automatically calculate the time for turning on and off the lamp by setting the longitude and latitude parameters, and simultaneously, the system designs a group of lamp-on correction values and lamp-off correction values;

s53, single lamp control: the function of single lamp control can accurately control each lamp, and the single lamp can be finely managed and can be illuminated as required through the realization of the single lamp control;

s54, single lamp setting: the grouping condition of the single lamps under each host can be checked, and the brightness can be adjusted;

s6, data center:

s61, energy consumption data: the platform can accomplish energy consumption measurement and the long-range statistical function of checking meter to electric energy metering equipment, and through energy consumption management function, the user can master field device's power consumption information in real time, accomplishes the management and the control to the power consumption plan, and energy-conserving contrast: energy-saving effect of current equipment energy consumption and reserved energy consumption, and carbon asset management: the method comprises the data display of the saved electric energy, the saved coal and the saved carbon emission when the equipment is used;

s62, operation data and operation and maintenance data, operation history: checking all operation data of the platform, and information such as instructions, states, data, operation time and the like of the operated equipment, quickly inquiring by recording equipment states, operation time, protocols and equipment numbers, and simultaneously clearing all historical records;

and S7, judging whether the user wants to operate, if so, clicking a corresponding button to perform related operation, if not, judging whether N is less than or equal to 30 by the system, if not, automatically recording related data by the system, adding one to the value of N, turning to S7, if N is more than 30, automatically reading the meter and performing a ring ratio, simultaneously returning the value of N to zero, and returning to S7.

2. The multi-port control method for the intelligent lighting platform as claimed in claim 1, wherein the intelligent lighting platform in step S1 comprises an operation status, a management center, an operation and maintenance center, a control center and a data center;

the running state comprises a device state, a single lamp state and a bright spot rate;

the management center comprises equipment management, single lamp management, electric meter management, system setting, life cycle and user management;

the operation and maintenance center comprises alarm setting and an alarm list;

the control center comprises centralized control, centralized setting, single lamp control and single lamp setting;

the data center comprises energy consumption data, operation data and operation and maintenance data.

3. The multi-port control method for the intelligent lighting platform as recited in claim 2, wherein the device status comprises device name, device group, control mode, voltage and power;

the single lamp state comprises a single lamp address, a lamp post number, a mode, voltage, a power supply, kilometer factors, temperature, lamp turn-on times, alarms, electric energy, leakage current, lamp turn-on time, single lamp power and updating time;

the lighting rate comprises a single-lamp lighting rate and an equipment lighting rate.

4. The multi-port control method for the intelligent lighting platform of claim 2, wherein the device management comprises ID, site name, site number, device model, device group, status, installation location, IP, and connection time;

the single lamp management comprises a single lamp address, a lamp post number, a mode, voltage and a power supply;

the electric meter management comprises equipment name, electric meter model, electric meter number, meter reading protocol, original reference power, charge rate, original load and new load;

the system setting comprises setting the centralized inspection time, the single-lamp inspection time, the illumination value issuing setting, the alarm processing time and the single-lamp alarm setting of the system;

the lifecycle includes site name, site number, equipment group, purchase date, design lifetime, elapsed time, and remaining lifetime.

5. The multi-port control method for the intelligent lighting platform of claim 1, wherein the list of alarms includes pending alarms, processed alarms, and alarm statistics;

the alarm setting comprises switch abnormity, equipment offline, system fault, voltage abnormity, current abnormity, external control abnormity, illegal door opening, lamp power failure, lamp fault, output feedback abnormity, temperature abnormity, cable anti-theft, water immersion, electric leakage and single lamp offline alarm.

6. The multi-port control method for the intelligent lighting platform as claimed in claim 1, wherein the centralized control comprises a control mode and a manual control;

the centralized setting comprises tenth control, light control setting and longitude and latitude setting;

the single lamp control comprises a single lamp manual control mode and a single lamp control mode;

the single lamp settings include single lamp grouping and single lamp brightness settings.

7. The multi-port control method for the intelligent lighting platform as claimed in claim 1, wherein the energy consumption data comprises energy consumption reports, energy saving comparisons, power trends, energy consumption monitoring and carbon assets;

the operational data and the operation and maintenance data include operational history.

8. The multi-port control method for the intelligent lighting platform as claimed in claim 1, wherein the automatic loop ratio and the automatic meter reading information in step S7 are automatically uploaded.

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