CN114399297A - Charging management method, system, electronic equipment and storage medium - Google Patents

Abstract

The application provides a charging management method, a system, an electronic device and a storage medium, which are applied to an energy management platform, wherein the charging management method comprises the following steps: generating a charging scheme according to the actual pricing demand; binding the generated charging scheme with the energy file to be charged to generate a binding relationship, wherein the binding relationship is updated in real time; and inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result. The technical scheme can realize comprehensive charging of various types of energy, binding between the charging scheme and the charged file, and real-time updating of the charging scheme and the binding relation, and solves the technical problems that the charging energy object of the existing energy management platform is single, and when the charging mode of the energy is changed, the charging mode needs to be manually maintained and updated, so that the efficiency of energy rate management is low.

Description

Charging management method, system, electronic equipment and storage medium

Technical Field

The present application relates to the field of energy management, and in particular, to a charging management method, system, electronic device, and computer-readable storage medium.

Background

In energy management, an energy management platform is often used to manage the rate of energy, and the existing rate management usually sets a charging mode for the electricity fee according to fixed time dimensions such as day, month, and quarter, so as to manage the electricity fee.

In the prior art, the rate management of energy is mainly the rate for electric energy, and other types of energy, such as water, natural gas, steam, etc., are not presented in the energy rate management system, and in addition, because the charging mode of energy is changed frequently, the prior art needs to manually maintain and update the charging mode, so that the management efficiency of the energy management platform on the energy rate is reduced.

Disclosure of Invention

An object of the embodiments of the present application is to provide a charging management method, so as to solve the technical problems that an existing energy management platform is single in charging energy object, and when a charging mode of energy is changed, a charging mode needs to be manually maintained and updated, so that efficiency of energy rate management is low.

In order to achieve the above purpose, the technical solutions provided in the embodiments of the present application are as follows:

in a first aspect, an embodiment of the present application provides a charging management method, where the method is applied to an energy management platform, and the charging management method includes: generating a charging scheme according to the actual pricing demand; binding the generated charging scheme with an energy file to be charged to generate a binding relationship, wherein the binding relationship is updated in real time; and inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result. The technical scheme can realize comprehensive charging of various types of energy, complete binding between the charging scheme and the charged files, and realize real-time updating of the charging scheme and the binding relation.

In this embodiment, the charging management method is applied to the energy management platform, and the charging management method performs charging management on the energy management platform, and first generates a charging scheme according to an actual pricing requirement. And then, binding the generated charging scheme with an energy file, wherein the energy file is a file to be charged, and generating a binding relationship after binding, wherein the binding relationship is updated in real time. After the binding relationship is completed, the charging scheme may be changed, so that the charging scheme needs to be updated, the charging scheme of the energy platform is integrally queried every preset time, the effective time and the failure time of the charging scheme in the query result are compared with the current time, and after the comparison is completed, the charging scheme is automatically updated according to the corresponding result.

Further, the generating a charging scheme according to the actual pricing demand includes: matching corresponding charging energy objects according to the charging target energy types; and after the charging energy object is determined, generating the charging scheme according to the selected charging mode.

In this embodiment, a charging scheme is generated according to the actual pricing demand, and first, a corresponding charging energy object is matched according to the type of the charging target energy. And then, after determining the charging energy object, further selecting a charging mode, and finally generating a charging scheme according to the selected charging mode. The technical scheme can realize the generation of the charging scheme.

Further, the target energy types according to the charging include electric energy, water energy, gas energy and heat energy.

In this embodiment, the target energy type includes electric energy, hydraulic energy, gas energy, and heat energy according to the charged target energy type, that is, the charged energy object can charge electric energy consumption, hydraulic energy consumption, gas energy consumption, and heat energy consumption with reference to the above energy types. The technical scheme can realize the classification of the energy types which need to be charged.

Further, after the charging energy object is determined, the charging scheme is generated by matching according to different selected charging modes, including: acquiring energy consumption data from a database, and inquiring the energy consumption at different times in one day according to the energy consumption data; dividing the time of one day into four periods of sharp, peak, flat and valley according to the energy consumption at different times of the day, wherein the fixed time is taken as the minimum unit of the period, and each period consists of a plurality of minimum units; and updating the division of the four periods of the tip, the peak, the flat and the valley according to the change of the energy consumption data.

In this embodiment, in the step of generating the billing scheme, first, data needs to be collected from the database, the data of the usage amount of the energy is collected, and the collected data of the usage amount of the energy is queried to find the usage amount of the energy at different times in a day. After the energy consumption data at different times in a day are acquired, the time of 24 hours in a day can be divided into four time periods of energy consumption, namely a peak time period, a flat time period and a valley time period according to the distribution of the related consumption data, a fixed time is set as a minimum unit of the time periods in the division of the peak time period, the flat time period and the valley time period, and each time period consists of a plurality of minimum units. And when the division of the four time periods of the peak, the flat and the valley is finished, the energy consumption data in the database can be continuously collected, and the division of the four time periods is updated according to the change of the energy consumption data. The technical scheme can realize the division of the energy use time period.

Further, after the charging energy object is determined, according to different charging modes selected, matching and generating the charging scheme includes: time-sharing charging, namely matching different charging unit prices for energy use in different time periods of sharp, peak, flat and valley according to the division of the time periods; step charging, according to the total amount of the used energy, different charging unit prices are matched at different stages of using the total amount of the energy; and commercial billing, matching a constant billing unit price.

In this embodiment, the generation of the charging scheme needs to be selected by a charging method, which is divided into time-sharing charging, step charging, and business charging. The time-sharing charging is that different unit prices are adopted according to different time periods for energy consumption, and different charging unit prices are matched in different time periods according to four time periods of sharp, peak, flat and valley which are divided before. The step charging is charging according to the energy usage by step division, specifically, different unit prices are matched in different energy usage intervals. And realizing step charging. The business charge is to keep a constant charge unit price, and the charge is made at the same unit price regardless of the energy use time and the energy use amount. The technical scheme can realize different charging modes according to different requirements.

Further, the binding the generated charging scheme with the energy file to be charged to generate a binding relationship, wherein the real-time updating of the binding relationship includes: in the binding relationship, each energy file has a charging scheme at the same time; generating a descendant file according to the change of the data record information of the energy file needing to be charged; and the descendant files inherit the binding relationship of the energy files needing to be charged and are the same as the binding relationship of the energy files needing to be charged.

In this embodiment, a binding relationship is formed between the charging scheme and the energy file, and the binding relationship is updated in real time. In the formed binding relationship, each energy file can correspondingly have a charging scheme at the same time. Each energy source to be charged may have a change in the information of the energy source, so that when the information is changed, the energy source file is changed into its descendant file. And the descendant files inherit the binding relationship of the files before updating, namely the descendant files are the same as the binding relationship of the files before updating. The technical scheme can realize the maintenance of the binding relationship when the energy archive is updated, and does not need to reconstruct the binding relationship.

Further, the querying the charging scheme of the energy management platform at preset intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and completing the automatic updating of the charging scheme according to the comparison result includes: inquiring effective time in the charging scheme at the time zero of each day, and setting the charging scheme state with the effective time being the current day as effective; and inquiring the failure time in the charging scheme at the time zero of each day, and setting the state of the charging scheme with the failure time being the current day as failure.

In this embodiment, the current time is compared with the effective time and the ineffective time of the charging scheme, and the automatic updating of the charging scheme is completed. Specifically, at the zero point of each day, the charging scheme is queried once, the effective time and the invalid time in the charging scheme are queried, the effective time and the invalid time are compared with the date of the day, if the date of the day reaches the effective date, the corresponding charging scheme is set to be effective, and if the date of the day reaches the invalid date, the corresponding charging scheme is set to be invalid. The technical scheme can realize the timely update of the effective and invalid charging scheme.

In a second aspect, an embodiment of the present application provides a charging management system, where the charging management system is applied to an energy management platform, and the charging management system includes: the scheme generating module is used for generating a charging scheme according to the actual pricing requirement on a charging scheme making page; the relation binding module is used for binding the established charging scheme with the energy file to be charged to generate a binding relation, wherein the binding relation is updated in real time; and the updating module is used for inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result.

Furthermore, the charging management system is applied to the energy management platform, and firstly generates a charging scheme according to the actual pricing requirement for the charging management of the charging management system on the energy management platform. And then, binding the generated charging scheme with an energy file, wherein the energy file is a file to be charged, and generating a binding relationship after binding, wherein the binding relationship is updated in real time. After the binding relationship is completed, the charging scheme may be changed, so that the charging scheme needs to be updated, the charging scheme of the energy platform is integrally queried every preset time, the effective time and the failure time of the charging scheme in the query result are compared with the current time, and after the comparison is completed, the charging scheme is automatically updated according to the corresponding result.

Furthermore, the charging management system generates a charging scheme according to the actual pricing demand, and firstly, the corresponding charging energy object is matched according to the type of the charging target energy. And then, after determining the charging energy object, further selecting a charging mode, and finally generating a charging scheme according to the selected charging mode. The technical scheme can realize the generation of the charging scheme.

Further, according to the charged target energy type including electric energy, water energy, gas energy and heat energy, that is, the charged energy object can charge electric energy consumption, water energy consumption, gas energy consumption and heat energy consumption with reference to the above energy types. The technical scheme can realize the classification of the energy types which need to be charged.

Further, the billing management system first needs to collect data from the database, collect energy usage data, query the collected energy usage data, and query energy usage at different times of the day. After the energy consumption data at different times in a day are acquired, the time of 24 hours in a day can be divided into four time periods of energy consumption, namely a peak time period, a flat time period and a valley time period according to the distribution of the related consumption data, a fixed time is set as a minimum unit of the time periods in the division of the peak time period, the flat time period and the valley time period, and each time period consists of a plurality of minimum units. And when the division of the four time periods of the peak, the flat and the valley is finished, the energy consumption data in the database can be continuously collected, and the division of the four time periods is updated according to the change of the energy consumption data. The technical scheme can realize the division of the energy use time period.

Further, the charging management system needs to select a charging mode for generating the charging scheme, and the charging mode is divided into time-sharing charging, step charging and commercial charging. The time-sharing charging is that different unit prices are adopted according to different time periods for energy consumption, and different charging unit prices are matched in different time periods according to four time periods of sharp, peak, flat and valley which are divided before. The step charging is charging according to the energy usage by step division, specifically, different unit prices are matched in different energy usage intervals. And realizing step charging. The business charge is to keep a constant charge unit price, and the charge is made at the same unit price regardless of the energy use time and the energy use amount. The technical scheme can realize different charging modes according to different requirements.

Further, the charging management system enables a binding relationship to be formed between the charging scheme and the energy file, and the binding relationship is updated in real time. In the formed binding relationship, each energy file can correspondingly have a charging scheme at the same time. Each energy source to be charged may have a change in the information of the energy source, so that when the information is changed, the energy source file is changed into its descendant file. And the descendant files inherit the binding relationship of the files before updating, namely the descendant files are the same as the binding relationship of the files before updating. The technical scheme can realize the maintenance of the binding relationship when the energy archive is updated, and does not need to reconstruct the binding relationship.

Further, the charging management system compares the current time with the effective time and the ineffective time of the charging scheme to finish the automatic updating of the charging scheme. Specifically, at the zero point of each day, the charging scheme is queried once, the effective time and the invalid time in the charging scheme are queried, the effective time and the invalid time are compared with the date of the day, if the date of the day reaches the effective date, the corresponding charging scheme is set to be effective, and if the date of the day reaches the invalid date, the corresponding charging scheme is set to be invalid. The technical scheme can realize the timely update of the effective and invalid charging scheme.

In a third aspect, an embodiment of the present application provides an electronic device, including: a processor, a memory, and a bus; the processor and the memory are communicated with each other through the bus; the memory stores program instructions executable by the processor, the processor being capable of performing the method as in the first aspect when invoked by the processor.

In a fourth aspect, embodiments of the present application provide a computer-readable storage medium storing computer instructions that cause the computer to perform the method of the first aspect.

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a schematic diagram illustrating steps of a charging management method according to an embodiment of the present application;

fig. 2 is a schematic diagram of a preferred time division provided in the embodiment of the present application;

fig. 3 is a schematic diagram illustrating a charging scheme updating step according to an embodiment of the present application;

fig. 4 is a schematic overall view of a charging management system according to an embodiment of the present application; and

fig. 5 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

Fig. 1 is a schematic diagram illustrating steps of a charging management method according to an embodiment of the present application.

Referring to fig. 1, fig. 1 shows specific steps of a charging management method. In fig. 1, the specific implementation steps of the method include:

step 101: and generating a charging scheme according to the actual pricing demand.

In the specific implementation process of step 101, the energy management platform generates a charging scheme according to the pricing requirement.

Step 102: and binding the generated charging scheme with the energy file to be charged to generate a binding relationship, wherein the binding relationship is updated in real time.

In the specific implementation process of step 102, after the charging scheme is generated, the charging scheme is bound to an energy file, where the energy file refers to a file formed by uniformly storing relevant energy usage data to be charged, and an energy file stores data of a charged energy usage unit. When the binding relationship is generated, the binding relationship is updated with the change.

Step 103: and inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result.

In the specific implementation process of step 103, the data of the energy management platform is queried once at intervals, the current time is compared with the queried data of the energy management platform in the query process, the compared object includes the time of validity and the time of invalidity of the charging scheme in the data of the energy management platform, and after the comparison is completed, the charging scheme is automatically updated according to the comparison result.

Further, in the process of generating the charging scheme according to the actual pricing demand, firstly, the corresponding charging energy object is matched according to the charging target energy type, the charging target energy type is the type of the energy to which the charging is directed, and the charging energy object is determined by taking the type of the energy to which the charging is directed as a reference object. And after the charging energy object is determined, generating a complete charging scheme according to the selected charging mode.

Further, a charging energy object is determined according to the charging target energy type, the charging energy type comprises electric energy, water energy, gas energy and heat energy, and the corresponding charging energy object is matched by distinguishing and confirming the energy before the charging scheme is generated.

Further, after the charging energy object is determined, according to different selected charging modes, the charging scheme is generated in a matching manner on a charging scheme making page according to actual pricing requirements, and a charging scheme is generated, including: acquiring energy consumption data from a database, and inquiring the energy consumption at different times in one day according to the energy consumption data; dividing the time of one day into four periods of sharp, peak, flat and valley according to the energy consumption at different times of the day, wherein the fixed time is taken as the minimum unit of the period, and each period consists of a plurality of minimum units; and updating the division of the four periods of the tip, the peak, the flat and the valley according to the change of the energy consumption data. And when the charging energy object is determined, continuing to generate the charging scheme. Firstly, collecting in a database, wherein the collected object is energy use data, and analyzing the energy use amount at different times in one day according to the collected data. After the energy consumption at different times in a day is analyzed, the time of the day can be further divided into four periods of point, peak, flat and valley, the point period is the period of highest peak power consumption, the peak is the power consumption at the peak power consumption period, the flat period is the power consumption at the flat period, and the valley is the power consumption at the valley power consumption period. The division of the four time periods is done according to the above-mentioned standard, and it should be noted that the division of the time periods needs to be in units of minimum units, to which the time is measured accurately, and each time period is composed of a plurality of minimum units. In a preferred embodiment, the minimum unit is set to 30 minutes, and each time period is an integer multiple of 30 minutes. After the time period is divided for the first time, the division result is not kept constant, the energy management platform collects data in the database at regular time and determines the energy consumption at different time in one day, the energy consumption collected in the database at different time in one day may be changed, and therefore the division of the peak time period, the flat time period and the valley time period determined according to the corresponding data is also updated correspondingly.

Fig. 2 is a schematic diagram of a preferred time interval division provided in the embodiment of the present application.

Referring to fig. 2, fig. 2 shows a preferred time division diagram. In fig. 2, the daily ratio of 0: 00 to 02: 30 is set to a sharp time period, 2: 30 to 07: 30 and 11: 00 to 12: 00 is set as the peak period, 16: 30 to 19: 30 is set as the usual time period, the daily ratio of 07: 30 to 11: 00 and 12: 00 to 16: 30, and 19: 30 to 24: 00 is set to the valley period. According to the time division of fig. 2, 24 hours a day is divided into four energy use periods.

Further, after the charging scheme is generated by matching according to the different selected charging modes after the charging energy object is determined, and the charging scheme is selected by matching according to the different charging modes, the method includes: time-sharing charging, namely matching different charging unit prices for energy use in different time periods of sharp, peak, flat and valley according to the division of the time periods; step charging, according to the total amount of the used energy, different charging unit prices are matched at different stages of using the total amount of the energy; and commercial billing, matching a constant billing unit price. In the step of generating the charging scheme, there are three charging unit price configuration modes, which are time-sharing charging, step charging and business charging. The time-sharing charging is to configure the energy unit prices of different time periods according to the time period division of the peak, flat and valley, in a preferred embodiment, a charging scheme for the electric energy usage is generated, the unit price of the peak time period is set to be 0.528 yuan/degree, the unit price of the peak time period and the unit price of the flat time period are both set to be 0.568 yuan/degree, and the unit price of the valley time period is set to be 0.318 yuan/degree, and the charging scheme under the time-sharing charging is generated through the unit price configuration.

The step charging is charging in different regions according to the total energy consumption within the charging time range, different total amount regions are set, and the unit price of the energy consumption in different regions is different. In a preferred embodiment, different charging scheme configurations are used for the electrical energy. The total amount of power consumption is 0 degree to 2160 degrees, wherein 2160 degrees is not included in the interval, the above is set as the first step, and the charging unit price of power in this interval is 0.573 yuan/degree. When the total power consumption is 2160 to 4800 degrees, wherein 4800 degrees is not included in the interval, the interval is configured as the second step, and the unit price in the interval is 0.623 yuan/degree. When the total power consumption is 4800 deg.C or more, the third step is allocated to this interval, and the unit price in this interval is 0.873 yuan/deg. According to the steps, the charging scheme under the step charging mode is configured and completed.

The commercial charge is maintained at a constant unit price, and in a preferred embodiment, a charge unit price of 2.1 yuan/degree is set.

Further, the binding the generated charging scheme with the energy file to be charged to generate a binding relationship, wherein the real-time updating of the binding relationship includes: in the binding relationship, each energy file has a charging scheme at the same time; generating a descendant file according to the change of the data record information of the energy file needing to be charged; and the descendant files inherit the binding relationship of the energy files needing to be charged and are the same as the binding relationship of the energy files needing to be charged. Each energy file has a corresponding charging scheme, and each energy file has only one charging scheme at the same time, and the energy consumption of the energy file is charged by adopting the charging scheme. The data of the energy source files can be adjusted according to the data of the energy utilization units recorded by the energy source files, namely, the information of the energy source files can be correspondingly changed, and the information of the files is changed, so that the offspring files are formed. The descendant file is only the recorded data information is changed, and the adopted charging scheme is the same as the previous file, so that the descendant file inherits the binding relationship configured by the energy file before the change, and the descendant file is bound with the energy file before the change by the same charging scheme.

Fig. 3 is a schematic diagram of a charging scheme updating step according to an embodiment of the present application.

Referring to fig. 3, fig. 3 shows the steps of charging arrangement update. In step 301, the effective time in the charging scheme is queried at zero time of each day, and the charging scheme state with the effective time being the current day is set to be effective. In step 302, the expiration time in the billing scheme is queried at zero time of day, and the status of the billing scheme with the expiration time of the day is set as invalid.

In a preferred embodiment, a charging scheme of the energy management platform is queried at the time zero of the day of 10 month and 6 days, in the charging scheme, the effective date of a scheme A is 10 month and 6 days, and the failure date of a scheme B is 10 month and 6 days, after the query is finished, the scheme A is set to be in an effective state, the energy file bound with the scheme A starts to be charged according to the method of the scheme A, the scheme B is set to be in a failure state, and the energy file bound with the scheme B is not charged according to the method of the scheme B any more.

Fig. 4 is a schematic overall view of a charging management system according to an embodiment of the present application.

Referring to fig. 4, fig. 4 shows a billing management system provided in the present application, where the billing management system 400 includes: a scheme generation module 401, a relation binding module 402 and an update module 403.

The scenario generation module 401: and generating the charging scheme according to the actual pricing requirement on the charging scheme making page.

The relationship binding module 402: and binding the formulated charging scheme with the energy file to be charged to generate a binding relationship, wherein the binding relationship is updated in real time.

The update module 403: and the charging scheme is used for inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result.

Further, in the process of generating the charging scheme by the scheme generating module 401 according to the actual pricing demand, first, the corresponding charging energy object is matched according to the charging target energy type, the charging target energy type is the type of the energy targeted by charging, and the charging energy object is determined by taking the type of the energy targeted by charging as a reference object. And after the charging energy object is determined, generating a complete charging scheme according to the selected charging mode.

Further, the scheme generating module 401 determines a charging energy object according to the charging target energy type, where the charging energy type includes electric energy, hydraulic energy, gas energy, and heat energy, and matches a corresponding charging energy object by distinguishing and confirming the above energy sources before the charging scheme is generated.

Further, after determining the charging energy object, the scheme generating module 401 generates the charging scheme in a matching manner according to different selected charging modes, and generates the charging scheme according to the actual pricing requirement on a charging scheme making page, including: acquiring energy consumption data from a database, and inquiring the energy consumption at different times in one day according to the energy consumption data; dividing the time of one day into four periods of sharp, peak, flat and valley according to the energy consumption at different times of the day, wherein the fixed time is taken as the minimum unit of the period, and each period consists of a plurality of minimum units; and updating the division of the four periods of the tip, the peak, the flat and the valley according to the change of the energy consumption data. And when the charging energy object is determined, continuing to generate the charging scheme. Firstly, collecting in a database, wherein the collected object is energy use data, and analyzing the energy use amount at different times in one day according to the collected data. After the energy consumption at different times in a day is analyzed, the time of the day can be further divided into four periods of point, peak, flat and valley, the point period is the period of highest peak power consumption, the peak is the power consumption at the peak power consumption period, the flat period is the power consumption at the flat period, and the valley is the power consumption at the valley power consumption period. The division of the four time periods is done according to the above-mentioned standard, and it should be noted that the division of the time periods needs to be in units of minimum units, to which the time is measured accurately, and each time period is composed of a plurality of minimum units. In a preferred embodiment, the minimum unit is set to 30 minutes, and each time period is an integer multiple of 30 minutes. After the time period is divided for the first time, the division result is not kept constant, the energy management platform collects data in the database at regular time and determines the energy consumption at different time in one day, the energy consumption collected in the database at different time in one day may be changed, and therefore the division of the peak time period, the flat time period and the valley time period determined according to the corresponding data is also updated correspondingly.

Further, after determining the charging energy object, the scheme generating module 401, according to the different charging manners selected, matches and generates the charging scheme to determine the charging energy object, and according to the different charging manners, matches and selects the charging scheme, including: time-sharing charging, namely matching different charging unit prices for energy use in different time periods of sharp, peak, flat and valley according to the division of the time periods; step charging, according to the total amount of the used energy, different charging unit prices are matched at different stages of using the total amount of the energy; and commercial billing, matching a constant billing unit price. In the step of generating the charging scheme, there are three charging unit price configuration modes, which are time-sharing charging, step charging and business charging. The time-sharing charging is to configure the energy unit prices of different time periods according to the time period division of the peak, flat and valley, in a preferred embodiment, a charging scheme for the electric energy usage is generated, the unit price of the peak time period is set to be 0.528 yuan/degree, the unit price of the peak time period and the unit price of the flat time period are both set to be 0.568 yuan/degree, and the unit price of the valley time period is set to be 0.318 yuan/degree, and the charging scheme under the time-sharing charging is generated through the unit price configuration.

The step charging is that the scheme generation module 401 charges in different regions according to the total energy consumption in the charging time range, and sets different total amount regions, and the energy consumption unit prices in different regions are different. In a preferred embodiment, different charging scheme configurations are used for the electrical energy. The total amount of power consumption is 0 degree to 2160 degrees, wherein 2160 degrees is not included in the interval, the above is set as the first step, and the charging unit price of power in this interval is 0.573 yuan/degree. When the total power consumption is 2160 to 4800 degrees, wherein 4800 degrees is not included in the interval, the interval is configured as the second step, and the unit price in the interval is 0.623 yuan/degree. When the total power consumption is 4800 deg.C or more, the third step is allocated to this interval, and the unit price in this interval is 0.873 yuan/deg. According to the steps, the charging scheme under the step charging mode is configured and completed.

The business charging is that the scheme generation module 401 controls to maintain a constant unit price, and in a preferred embodiment, 2.1 yuan/degree is set as the charging unit price.

Further, the relationship binding module 402 binds the generated charging scheme with the energy profile that needs to be charged, and generates a binding relationship, where the binding relationship is updated in real time, and includes: in the binding relationship, each energy file has a charging scheme at the same time; generating a descendant file according to the change of the data record information of the energy file needing to be charged; and the descendant files inherit the binding relationship of the energy files needing to be charged and are the same as the binding relationship of the energy files needing to be charged. Each energy file has a corresponding charging scheme, and each energy file has only one charging scheme at the same time, and the energy consumption of the energy file is charged by adopting the charging scheme. The data of the energy source files can be adjusted according to the data of the energy utilization units recorded by the energy source files, namely, the information of the energy source files can be correspondingly changed, and the information of the files is changed, so that the offspring files are formed. The descendant file is only the recorded data information is changed, and the adopted charging scheme is the same as the previous file, so that the descendant file inherits the binding relationship configured by the energy file before the change, and the descendant file is bound with the energy file before the change by the same charging scheme.

The updating module 403 inquires the effective time in the billing scheme at time zero of each day, sets the status of the billing scheme with the effective time as the current day as effective, inquires the failure time in the billing scheme at time zero of each day, and sets the status of the billing scheme with the failure time as the current day as failure.

Referring to fig. 5, fig. 5 is a schematic structural diagram of an electronic device according to an embodiment of the present application. An electronic device 500 provided in an embodiment of the present application includes: a processor 501 and a memory 502, the memory 502 storing machine readable instructions executable by the processor 501, the machine readable instructions when executed by the processor 501 performing the method as above.

For example, the processor 501 of the embodiment of the present application may read the computer program from the memory 502 through the communication bus and execute the computer program to implement the following method: a data management method. In some examples, the processor 501 may also update the configuration item, that is, may perform the following steps: receiving input log data, storing the log data to a high-speed access module, and marking storage time when the log data are stored; judging whether the time length between the current time and the storage time of the log data is greater than a preset threshold value or not, and if so, migrating and storing the log data to a common rate access module; and querying existing log data stored, wherein the existing log data comprises log data stored on the high rate access module and the normal rate access module.

The processor 501 may be an integrated circuit chip having signal processing capabilities. The Processor 501 may be a general-purpose Processor, including a Central Processing Unit (CPU), a Network Processor (NP), and the like; but also Digital Signal Processors (DSPs), Application Specific Integrated Circuits (ASICs), Field-Programmable Gate arrays (FPGAs) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components. Which may implement or perform the various methods, steps, and logic blocks disclosed in the embodiments of the present application. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The Memory 502 may include, but is not limited to, Random Access Memory (RAM), Read Only Memory (ROM), Programmable Read Only Memory (PROM), Erasable Read Only Memory (EPROM), electrically Erasable Read Only Memory (EEPROM), and the like.

It will be appreciated that the configuration shown in FIG. 5 is merely illustrative and that electronic device 500 may include more or fewer components than shown in FIG. 5 or have a different configuration than shown in FIG. 5. The components shown in fig. 5 may be implemented in hardware, software, or a combination thereof. In this embodiment, the electronic device 500 may be, but is not limited to, an entity device such as a desktop, a laptop, a smart phone, an intelligent wearable device, and a vehicle-mounted device, and may also be a virtual device such as a virtual machine. In addition, the electronic device 500 is not necessarily a single device, but may also be a combination of multiple devices, such as a server cluster, and the like. In the embodiment of the present application, a server in a method for photographing a vehicle may be implemented by using the electronic device 500 shown in fig. 5.

Embodiments of the present application further provide a computer-readable storage medium, which includes a computer program stored on the computer-readable storage medium, where the computer program includes program instructions, and when the program instructions are executed by a computer, the computer is capable of executing the steps of the data management method in the foregoing embodiments, for example, including: receiving input log data, storing the log data to a high-speed access module, and marking storage time when the log data are stored; judging whether the time length between the current time and the storage time of the log data is greater than a preset threshold value or not, and if so, migrating and storing the log data to a common rate access module; and querying existing log data stored, wherein the existing log data comprises log data stored on the high rate access module and the normal rate access module.

In the embodiments provided in the present application, it should be understood that the disclosed systems and methods may be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units is only one logical division, and there may be other divisions when actually implemented, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of devices or units through some communication interfaces, and may be in an electrical, mechanical or other form.

In addition, units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

Furthermore, the functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist separately, or two or more modules may be integrated to form an independent part.

In this document, 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.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. A charging management method is applied to an energy management platform and comprises the following steps:

generating a charging scheme according to the actual pricing demand;

binding the generated charging scheme with an energy file to be charged to generate a binding relationship, wherein the binding relationship is updated in real time; and

and inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result.

2. The method of claim 1, wherein generating a billing scheme according to the actual pricing demand comprises:

matching corresponding charging energy objects according to the charging target energy types;

and after the charging energy object is determined, generating the charging scheme according to the selected charging mode.

3. The method of claim 2, wherein the target energy type according to billing comprises electric energy, water energy, gas energy, and heat energy.

4. The method according to claim 2, wherein after determining the charging energy object, the matching generation of the charging scheme according to the different selected charging modes comprises:

acquiring energy consumption data from a database, and inquiring the energy consumption at different times in one day according to the energy consumption data;

dividing the time of one day into four periods of sharp, peak, flat and valley according to the energy consumption at different times of the day, wherein the fixed time is taken as the minimum unit of the period, and each period consists of a plurality of minimum units;

and updating the division of the four periods of the tip, the peak, the flat and the valley according to the change of the energy consumption data.

5. The method according to claim 4, wherein the matching generation of the charging scheme according to the different charging modes after the determination of the charging energy object comprises:

time-sharing charging, namely matching different charging unit prices for energy use in different time periods of sharp, peak, flat and valley according to the division of the time periods;

step charging, according to the total amount of the used energy, different charging unit prices are matched at different stages of using the total amount of the energy; and

business billing, matching a constant billing unit price.

6. The method according to claim 1, wherein the binding the generated charging scheme with the energy profile that needs to be charged generates a binding relationship, and wherein the binding relationship is updated in real time, and the binding relationship comprises:

in the binding relationship, each energy file has a charging scheme at the same time;

generating a descendant file according to the change of the data record information of the energy file needing to be charged;

and the descendant files inherit the binding relationship of the energy files needing to be charged and are the same as the binding relationship of the energy files needing to be charged.

7. The method according to claim 1, wherein the querying the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and completing the automatic updating of the charging scheme according to the comparison result comprises:

inquiring effective time in the charging scheme at the time zero of each day, and setting the charging scheme state with the effective time being the current day as effective;

and inquiring the failure time in the charging scheme at the time zero of each day, and setting the state of the charging scheme with the failure time being the current day as failure.

8. A billing management system, wherein the billing management system is applied to an energy management platform, and the billing management system comprises:

the scheme generating module is used for generating a charging scheme according to the actual pricing requirement on a charging scheme making page;

the relation binding module is used for binding the established charging scheme with the energy file to be charged to generate a binding relation, wherein the binding relation is updated in real time; and

and the updating module is used for inquiring the charging scheme of the energy management platform at preset time intervals, comparing the current time with the effective time and the ineffective time of the charging scheme, and finishing automatic updating of the charging scheme according to the comparison result.

9. An electronic device, comprising: a processor, a memory, and a bus;

the processor and the memory are communicated with each other through the bus;

the memory stores program instructions executable by the processor, the processor invoking the program instructions to perform the method of any one of claims 1-7.

10. A computer-readable storage medium storing computer instructions which, when executed by a computer, cause the computer to perform the method of any one of claims 1-7.

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