CN116415703A

CN116415703A - Method and device for adjusting operation state of power exchange station, electronic equipment and medium

Info

Publication number: CN116415703A
Application number: CN202111672848.5A
Authority: CN
Inventors: 董超华
Original assignee: Aulton New Energy Automotive Technology Co Ltd
Current assignee: Aulton New Energy Automotive Technology Co Ltd
Priority date: 2021-12-31
Filing date: 2021-12-31
Publication date: 2023-07-11

Abstract

The invention discloses a method, a device, electronic equipment and a medium for adjusting the operation state of a power exchange station, wherein the method comprises the following steps: acquiring historical power conversion data of a first power conversion station; determining a power conversion busy time period of the first power conversion station according to the historical power conversion data; adjusting the operation state information of the first power exchange station in the power exchange busy time period; and updating the adjusted operation state information of the power change busy time period and the power change busy time period of the first power change station to a power change user side. The invention can guide the power exchange user terminal to exchange power from the power exchange busy time period to other power exchange stations not in the busy time period, on one hand, the power exchange pressure of the first power exchange station in the busy time period can be relieved, and on the other hand, the utilization rate of the other power exchange stations not in the busy time period can be improved, and further the overall resource utilization rate of the power exchange station is improved.

Description

Method and device for adjusting operation state of power exchange station, electronic equipment and medium

Technical Field

The present invention relates to the field of power conversion, and in particular, to a method and apparatus for adjusting an operation state of a power conversion station, an electronic device, and a medium.

Background

The power exchange station can provide power exchange service for the electric automobile, and along with the increasing electric automobile demand, the power exchange users gradually increase, the queuing quantity of the power exchange vehicles of different power exchange stations in different time periods is unbalanced, the number of the vehicles for power exchange of the power exchange stations is excessive, the queuing is serious, the power exchange experience of a driver is poor, the number of the vehicles for power exchange of the power exchange stations is too small, the utilization efficiency of the power exchange stations is low, and the income of the power exchange stations is less than the operation cost.

Disclosure of Invention

The invention aims to overcome the defects of low utilization efficiency of a power exchange station caused by too many power exchange stations and too few power exchange stations in different time periods, and provides a method, a device, electronic equipment and a medium for adjusting the operation state of the power exchange station, wherein the method, the device and the electronic equipment can guide a user to exchange power from a power exchange busy time period to other power exchange stations which are not in the busy time period so as to improve the experience of the power exchange user and the overall resource utilization rate of the power exchange station.

The invention solves the technical problems by the following technical scheme:

the invention provides a method for adjusting the operation state of a power exchange station, which comprises the following steps:

Acquiring historical power conversion data of a first power conversion station;

determining a power conversion busy time period of the first power conversion station according to the historical power conversion data;

adjusting the operation state information of the first power exchange station in the power exchange busy time period;

and updating the adjusted operation state information of the power change busy time period and the power change busy time period of the first power change station to a power change user side.

According to the invention, the power change busy time period of the first power change station is predicted according to the historical power change data of the first power change station, the operation state information of the power change busy time period is adjusted, and then the adjusted power change busy time period and the operation state information are updated to the power change user terminal, so that the power change user terminal can be guided to change power from the power change busy time period to other power change stations which are not in the busy time period, on one hand, the power change pressure of the first power change station in the busy time period can be relieved, on the other hand, the utilization rate of the other power change stations which are not in the busy time period can be improved, and further the overall resource utilization rate of the power change station is improved.

Preferably, the historical power conversion data comprises the power conversion times of each set time period;

the step of determining the power change busy time period of the first power change station according to the historical power change data comprises the following steps:

And when the power-changing times are greater than or equal to the preset times, taking the corresponding time period as a power-changing busy time period.

According to the invention, whether the power exchange station is in a busy state in different time periods can be effectively obtained according to the power exchange times of the power exchange station in different time periods, specifically, a time period with more power exchange times (namely, a time period with the power exchange times being greater than or equal to the preset times) is taken as a power exchange busy time period, so that the power exchange busy time period is effectively obtained.

Preferably, the step of determining the power conversion busy period of the first power conversion station according to the historical power conversion data comprises the following steps:

calculating the power conversion load rate of each set time period according to the historical power conversion data;

and when the power conversion load rate is larger than or equal to the preset load rate, taking the corresponding time period as a power conversion busy time period.

According to the invention, whether the power exchange station is in a busy state in different time periods can be effectively obtained according to the power exchange load rates of the power exchange station in different time periods, specifically, the time period with high power exchange load rate is taken as a power exchange busy time period (namely, the time period with the power exchange load rate being greater than or equal to the preset load rate), so that the power exchange busy time period is effectively obtained.

Preferably, the historical power conversion data further includes: the number of times of the power conversion service capability of each set time period, the power conversion operation time of each set time period and the number of batteries in the station of each set time period;

the step of determining the power conversion load rate of each set time period according to the historical power conversion data comprises the following steps:

calculating the power conversion load rate of each set time period according to a load rate calculation formula, wherein the load rate calculation formula is as follows:

the power conversion load ratio=the number of power conversion times in the corresponding time period/[ the number of power conversion service capability times in the corresponding time period (the ratio of power conversion operation time in the corresponding time period) ].

According to the invention, the power change times, the power change service capacity, the power change operation time and the number of batteries in the station of the power change stations corresponding to different time periods are comprehensively considered to obtain the power change load rates of the different time periods, and the busyness state of the first power change station in each time period can be more accurately reflected, so that a more accurate power change busyness time period is predicted.

Preferably, the historical power conversion data includes average historical power conversion data in a preset historical time range and corresponding time period.

The invention provides a specific implementation manner of historical battery replacement data, specifically, for example, in a corresponding time period within a preset historical time range: the average power change times, the average power change service capability times, the average power change operation time and the average number of batteries in the station can comprehensively consider the data in the corresponding time period in the historical time range according to the average value of the historical power change data.

Preferably, the operation state information includes power conversion resource settlement information corresponding to the power conversion busy time period.

According to the invention, the battery replacement resource settlement information corresponding to the battery replacement busy time period is used as an implementation mode of the first operation state information, and the battery replacement resource settlement information corresponding to the battery replacement busy time period is sent to the battery replacement user terminal, so that the battery replacement user terminal can be informed of the adjusted battery replacement resource settlement information, the battery replacement user terminal is effectively guided to perform battery replacement to the first battery replacement station when the battery replacement resource settlement information is lower, the battery replacement capacity of the first battery replacement station in the battery replacement busy time period is further slowed down, and the overall resource utilization rate of the battery replacement station is further improved.

Preferably, the step of determining the power conversion busy period of the first power conversion station according to the historical power conversion data further comprises:

Acquiring a preset load rate of the first power exchange station in the busy time period;

and when the power conversion load rate of the first power conversion station is larger than or equal to the preset load rate, executing the step of adjusting the operation state information of the first power conversion station in the power conversion busy time period.

In the invention, after the power change busy time period is calculated, whether the power change load rate of the first power change station in the power change busy time period is overlarge is further judged, if the power change load rate of the first power change station in the power change busy time period is overlarge, the operation state information is adjusted, and if the power change load rate of the first power change station is not overlarge, the operation state information is not adjusted, so that the power change resources of the first power change station can be fully utilized.

Preferably, the step of adjusting the operation information state of the first power exchange station in the power exchange busy period includes the following steps:

acquiring basic power conversion resource settlement information of the first power conversion station;

and calculating the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information of the first power conversion station.

According to the invention, the power conversion resource settlement information in the busy time period can be obtained through calculation according to the basic power conversion resource settlement information corresponding to the first power conversion station, so that the power conversion resource settlement information meets the actual requirements and has practicability.

Preferably, the step of calculating the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information of the first power conversion station includes the following steps:

acquiring a settlement adjustment formula;

calculating the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information by utilizing the settlement adjustment formula;

taking the calculated power conversion resource settlement information as power conversion resource settlement information of the first power conversion station in the power conversion busy time period;

the settlement adjustment formula is as follows:

the power conversion resource settlement information of the busy period=the basic power conversion resource settlement information of the first power conversion station+the basic power conversion resource settlement information of the first power conversion station (the power conversion load rate of the first power conversion station in the busy period-the second preset load rate).

According to the invention, the power conversion price of the first power conversion station in the busy time period is regulated to be high through the settlement regulation formula, so that the power conversion user terminal can be guided to go to the first power conversion station for power conversion in the low-price time period, and the power conversion pressure of the first power conversion station in the power conversion busy time period is further reduced.

Preferably, the operation state information includes the power conversion busy time period and corresponding guiding information, and the guiding information is used for guiding a power conversion user to perform power conversion to other power conversion stations.

In the invention, the following components are added: the power change busy time period and the corresponding guide information are used as a second operation information implementation mode, and the power change user terminal can be guided to perform power change to other power change stations except the first power change station in the power change busy time period through the guide information so as to effectively reduce the power change pressure of the first power change station in the power change busy time period.

Preferably, before the step of updating the adjusted operation state information of the power change busy period and the power change busy period of the first power change station to the power change user side, the step of updating the operation state information of the power change busy period and the power change busy period of the first power change station includes:

acquiring historical power conversion data of a second power conversion station;

determining a power conversion busy time period of the second power conversion station according to the historical power conversion data of the second power conversion station;

when the overlapping time does not exist between the power-exchanging busy time period of the second power-exchanging station and the power-exchanging busy time period of the first power-exchanging station, the corresponding second power-exchanging station is used as a third power-exchanging station;

and the guide information is used for guiding the power conversion user to the third power conversion station for power conversion.

In the invention, the historical power exchanging data of other power exchanging stations (namely the second power exchanging station) except the first power exchanging station is obtained, and the power exchanging busy time periods corresponding to the second power exchanging stations are obtained according to the historical power exchanging data, if the power exchanging busy time periods of the second power exchanging stations and the power exchanging busy time periods of the first power exchanging station do not have the overlapping time, the corresponding second power exchanging station is used as the third power exchanging station, and the power exchanging users are guided to exchange power from the third power exchanging station, so that the resource utilization rate of the third power exchanging station which is not in the power exchanging busy time period can be improved.

Preferably, the step of obtaining the historical power change data of the first power change station further comprises the following steps:

determining a power exchange idle time period of the first power exchange station according to the historical power exchange data;

adjusting the operation state information of the first power exchange station in the power exchange idle time period;

and updating the adjusted power change idle time period and the operation state information of the power change idle time period of the first power change station to a power change user side.

According to the invention, the power change idle time period of the first power change station is predicted according to the historical power change data of the first power change station, the operation state information of the power change idle time period is regulated, and then the regulated power change idle time period and the operation state information are updated to the power change user terminal, so that the power change user terminal can be guided to change power in the power change idle time period, on one hand, the power change pressure of other power change station stations in busy time periods can be relieved, on the other hand, the utilization rate of the power change station in the idle time period can be improved, and further the overall resource utilization rate of the power change station is improved.

The invention also provides an operation state adjusting device of the power exchange station, which comprises a historical data acquisition module, a busy time calculation module, an operation state adjusting module and an operation information updating module;

The historical data acquisition module is used for acquiring historical battery replacement data of the first battery replacement station;

the busy time calculation module is used for determining a power conversion busy time period of the first power conversion station according to the historical power conversion data;

the operation state adjustment module is used for adjusting operation state information of the first power exchange station in the power exchange busy time period;

and the operation information updating module is used for updating the operation state information of the adjusted power change busy time period and the power change busy time period of the first power change station to a power change user side.

and the busy time calculation module is used for taking the corresponding time period as a power-changing busy time period when the power-changing times are greater than or equal to preset times.

Preferably, the busy time calculation module comprises a load rate calculation unit and a busy period determination unit;

the load factor calculation unit is used for calculating the power conversion load factor of each set time period according to the historical power conversion data;

The busy period determining unit is configured to take a corresponding time period as a power-change busy time period when the power-change load rate is greater than or equal to the preset load rate.

the load factor calculation unit is used for calculating the power conversion load factor of each set time period according to a load factor calculation formula, and the load factor calculation formula is as follows:

Preferably, the device for adjusting the operation state of the power exchange station further comprises: the preset load factor acquisition module is further used for calling the preset load factor acquisition module, and the preset load factor acquisition module is used for acquiring the preset load factor of the first power exchange station in the busy time period; and when the power conversion load rate of the first power conversion station is greater than or equal to the preset load rate, calling the operation state adjustment module.

Preferably, the operation state adjustment module comprises a basic settlement information acquisition unit and a busy settlement information calculation unit;

the basic settlement information acquisition unit is used for acquiring basic electricity exchange resource settlement information of the first electricity exchange station;

the busy settlement information calculation unit is used for calculating and obtaining the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information of the first power conversion station.

Preferably, the busy settlement information calculation unit comprises a formula acquisition subunit, a settlement information calculation subunit and a busy settlement calculation subunit;

the formula acquisition subunit is used for acquiring a settlement adjustment formula;

the settlement information calculation subunit is used for calculating the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information by utilizing the settlement adjustment formula;

the busy calculation subunit is configured to use the calculated power conversion resource settlement information as power conversion resource settlement information of the first power conversion station in the power conversion busy time period;

the settlement adjustment formula is as follows:

Preferably, the device for adjusting the operation state of the power exchange station further comprises a power exchange guiding module;

the operation state information comprises the power change busy time period and corresponding guide information, and the guide information is used for guiding the power change user terminal to perform power change to other power change stations.

Preferably, the historical data acquisition module is further used for acquiring historical power conversion data of the second power conversion station;

the busy time calculation module is further used for determining a power conversion busy time period of the second power conversion station according to the historical power conversion data of the second power conversion station;

the power conversion guiding module is used for taking the corresponding second power conversion station as a third power conversion station when the power conversion busy time period of the second power conversion station does not have the coincidence time with the power conversion busy time period of the first power conversion station; and the guide information is used for guiding the power conversion user to the third power conversion station for power conversion.

Preferably, the device for adjusting the operation state of the power exchange station further comprises an idle time calculation module;

the idle time calculation module is used for determining a power exchange idle time period of the first power exchange station according to the historical power exchange data;

the operation state adjustment module is used for adjusting operation state information of the first power exchange station in the power exchange idle time period;

The operation information updating module is used for updating the operation state information of the adjusted power change idle time period and the power change idle time period of the first power change station to a power change user side.

The invention also provides an adjusting device of the operation state of the power exchange station, which is applied to the power exchange user terminal and comprises: the system comprises an operation information receiving module, a power conversion request acquisition module and a display module;

the operation information receiving module is used for receiving operation state information of the power conversion busy time period and the power conversion busy time period of the first power conversion station sent by the power conversion station end, wherein the operation state information is generated according to the adjusted first power conversion station in the power conversion busy time period;

the power change request acquisition module is used for acquiring power change request operation of a first power change station sent by a power change user;

the display module is used for determining that the power change time of the power change request operation is the power change busy time period of the first power change station, and displaying operation state information of the power change busy time period.

The invention also provides an electronic device comprising a memory, a processor and a computer program stored on the memory and capable of running on the processor, wherein the processor realizes the adjustment method of the operation state of the power exchange station when executing the computer program.

The invention also provides a computer-readable storage medium on which a computer program is stored which, when executed by a processor, implements a method of adjusting the operating state of a power exchange station as described above.

The invention has the positive progress effects that: according to the invention, the power change busy time period of the first power change station is predicted according to the historical power change data of the first power change station, the operation state information of the power change busy time period is adjusted, and then the adjusted power change busy time period and the operation state information are updated to the power change user terminal, so that the power change user terminal can be guided to change power from the power change busy time period to other power change stations which are not in the busy time period, on one hand, the power change pressure of the first power change station in the busy time period can be relieved, on the other hand, the utilization rate of the other power change stations which are not in the busy time period can be improved, and further the overall resource utilization rate of the power change station is improved.

The power exchange user side receives a power exchange busy time period and corresponding operation state information of the first power exchange station sent by the power exchange station side, determines that the power exchange time requested by the power exchange user side is in the power exchange busy time period, and can display the adjusted operation state information so as to guide the power exchange user side to exchange power from the power exchange busy time period to other power exchange stations which are not in the busy time period, so that the power exchange time of the power exchange user side can be saved, the queuing phenomenon caused by power exchange to the first power exchange station in the busy time period is avoided, and the user experience degree of the power exchange user side is improved.

Drawings

Fig. 1 is a flowchart of a method for adjusting the operation status of a power exchange station in embodiment 1 of the present invention.

Fig. 2 is a flowchart of an implementation of step 102 in embodiment 1 of the present invention.

Fig. 3 is a flowchart of an implementation of step 103 in embodiment 1 of the present invention.

Fig. 4 is a flowchart of an implementation of step 1032 in embodiment 1 of the present invention.

Fig. 5 is a flowchart of a confirmation method of the third power exchange station in embodiment 1 of the present invention.

Fig. 6 is a flowchart of the operation status update of the idle power exchange station in embodiment 1 of the present invention.

Fig. 7 is a flowchart of a method for adjusting an operation status in embodiment 2 of the present invention.

Fig. 8 is a flowchart of an operation status information obtaining method in a power conversion idle period in embodiment 2 of the present invention.

Fig. 9 is a schematic block diagram of an adjusting device for the operation status of a power exchange station in embodiment 3 of the present invention.

Fig. 10 is a schematic block diagram of an adjusting device for the operation status of the power exchange station in embodiment 4 of the present invention.

Fig. 11 is a schematic block diagram of an electronic device in embodiment 5 of the present invention.

Detailed Description

The invention is further illustrated by means of the following examples, which are not intended to limit the scope of the invention.

Example 1

The embodiment provides a method for adjusting an operation state of a power exchange station, which is applied to a power exchange station end, and can be applied to an operation server platform of the power exchange station end, a PC (personal computer) of the power exchange station end, an intelligent terminal and the like, wherein the operation server platform can be formed by servers or server clusters, as shown in fig. 1, and the method for adjusting the operation state of the power exchange station comprises the following steps:

step 101, acquiring historical power conversion data of a first power conversion station;

step 102, determining a power conversion busy time period of the first power conversion station according to the historical power conversion data.

Step 102 may have a plurality of manners of determining the power-down busy period, and in a specific implementation, step 102 may specifically include: when the number of power exchanging times is larger than or equal to the preset number of times, the corresponding time period is used as a power exchanging busy time period, wherein the preset number of times can be set automatically according to the historical power exchanging condition of the first power exchanging station.

In this way, the historical power conversion data includes the power conversion times of each set time period, specifically, the power conversion times may be average power conversion times of each set time period in the preset historical time range, mode power conversion times of each set time period in the preset historical time range, or other calculation modes comprehensively considering the power conversion times of each set time period in the preset historical time range.

The number of power change can reflect the busy state of the power change station to a certain extent, specifically, the more the number of power change is, the more busy the corresponding power change station is in the time zone, so that according to the number of power change of the power change station in different time zones, whether the power change station is in the busy state in different time zones can be effectively obtained, specifically, the time zone with the more number of power change (namely, the time zone with the number of power change being greater than or equal to the preset number of times) is taken as the power change busy time zone, and the power change busy time zone is effectively obtained.

In another specific implementation, as shown in fig. 2, step 102 may specifically include:

and 1021, calculating the power conversion load rate of each set time period according to the historical power conversion data.

Executing step 1022 when the power conversion load rate is greater than or equal to the preset load rate; when the power conversion load rate is smaller than the preset load rate, step 1023 is executed.

Step 1022, taking the corresponding time period as a power-change busy time period;

step 1023, ending the flow.

The power conversion load rate represents the load condition of the power conversion station, and compared with the power conversion times, the power conversion load rate comprehensively considers various factors of the power conversion station, so that real information which can more accurately reflect whether the power conversion station is busy in each time zone can be obtained, for example, the real information can be obtained through calculation according to historical data, the power conversion load rate is 8:00 to 10:00, the power conversion station A has 10 full batteries, the power conversion station B has 100 full batteries, the corresponding power conversion times of the two are 10 times, if the power conversion busy time zone is confirmed according to the power conversion times, the power conversion busy time zone of the power conversion station A and the power conversion station B are busy time zone or are all not busy time zone in 8:00 to 10:00, that is, the number of full batteries just meets the power conversion times, the power conversion time requirement is the power conversion time zone, the number of the full batteries in the time zone far exceeds the power conversion times, the power conversion times is only one battery, if the full power conversion times are not full time zone is the full, the power conversion times can be calculated according to the specific time zone, the accuracy is obtained, if the power conversion times are different from the predicted, the power conversion times are calculated according to the specific time, and the accuracy is obtained if the power conversion times is calculated according to the data.

In other embodiments, the power conversion load rate may be obtained according to other methods, for example, in a specific implementation manner, step 1021 may specifically calculate the power conversion load rate of each set period according to a load rate calculation formula, where the load rate calculation formula is as follows:

In this case, the historical battery change data acquired in step 101 includes: the number of times of power conversion in each set time period, the number of times of power conversion service capability in each set time period, the power conversion operation time in each set time period and the number of batteries in a station in each set time period.

In this embodiment, the number of power exchanging times, the power exchanging service capability, the power exchanging operation time and the number of batteries in the station of the power exchanging station corresponding to different time periods are comprehensively considered to obtain the power exchanging load rates of different time periods, and the busy state of the first power exchanging station in each time period can be more accurately reflected, so that a more accurate power exchanging busy time period is predicted.

In particular, the power exchange service capability represents the maximum number of vehicles that the first power exchange station can service in a corresponding time period.

The historical power conversion data may include average historical power conversion data in a corresponding time period within a preset historical time range, and specifically includes average historical power conversion data in a corresponding time period within a preset historical time range: average number of battery exchanges, average number of battery exchange service capabilities, average battery exchange operation time, and average number of batteries in the station.

In this embodiment, a specific implementation manner of historical power conversion data is provided, that is, average data in a corresponding time period in a historical time range is preset, and data in the corresponding time period in the historical time range can be comprehensively considered according to the average data.

In a preferred embodiment, step 102 is followed by the further step of:

acquiring a preset load rate of the first power exchange station in a busy time period;

when the power conversion load rate of the first power conversion station is greater than or equal to the preset load rate, step 103 is executed.

Since in some specific cases, although the power exchange station is in the busy period, the load rate of the power exchange station is not substantially up to the load rate of the power exchange station in the busy period, in this embodiment, after determining that the power exchange station is in the busy period, it may be further determined whether the power exchange load rate of the first power exchange station in the power exchange busy period is too large, if the power exchange load rate is too large, the operation state information of step 103 is adjusted, and if the power exchange load rate is not too large, the operation state information may not be adjusted, so that the power exchange resource of the first power exchange station may be fully utilized.

Step 103, adjusting operation state information of the first power exchange station in a power exchange busy time period;

and 104, updating the adjusted operation state information of the power change busy time period and the power change busy time period of the first power change station to a power change user side.

In this embodiment, the power change busy period of the first power change station is predicted according to the historical power change data of the first power change station, after the operation state information of the power change busy period is adjusted, the adjusted power change busy period and operation state information are updated to the power change user terminal, so that the power change user terminal can be guided to change power from the power change busy period to other power change stations not in the busy period, on one hand, the power change pressure of the first power change station in the busy period can be relieved, on the other hand, the utilization rate of other power change stations not in the busy period can be improved, and further the overall resource utilization rate of the power change station is improved.

In this embodiment, a specific implementation manner of the operation status information may be selected according to an actual situation, where in a specific implementation manner of the operation status information, the operation status information includes power conversion resource settlement information, such as a power conversion price, corresponding to a power conversion busy period.

In this manner, as shown in fig. 3, step 103 may specifically include the steps of:

step 1031, acquiring basic power exchange resource settlement information of a first power exchange station;

and step 1032, calculating to obtain the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information of the first power conversion station.

Because the basic electricity-exchanging resource settlement information corresponding to different first electricity-exchanging stations is possibly different, the electricity-exchanging resource settlement information in a busy time period can be obtained through calculation according to the basic electricity-exchanging resource settlement information corresponding to the first electricity-exchanging stations, so that the electricity-exchanging resource settlement information is more in accordance with the actual demands, and the practicability is improved.

Specifically, as shown in fig. 4, step 1032 may calculate, according to the basic power conversion resource settlement information, power conversion resource settlement information by:

step 10321, obtaining a settlement adjustment formula;

step 10322, calculating the power conversion resource settlement information of the busy time period according to the basic power conversion resource settlement information by using a settlement adjustment formula;

step 10323, using the calculated power conversion resource settlement information as power conversion resource settlement information of the first power conversion station in the power conversion busy time period;

wherein, the settlement adjustment formula is as follows:

The power conversion load rate of the first power conversion station in the busy time period can be adjusted according to actual conditions, the power conversion load rate is generally not too high, and therefore the difference between the power conversion resource settlement information of the adjusted busy time period and the power conversion resource settlement information before adjustment is not too large, so that the power conversion user terminal can still go to the first power conversion station in the busy time period for power conversion under special conditions, for example, the battery of the power conversion user terminal is about to run out, the power conversion station closest to the first power conversion station is the power conversion busy time period, other power conversion stations in the non-busy time period are far away from the power conversion user terminal, the residual power of the battery is insufficient to support the power conversion station far away, and therefore the power conversion station capable of bearing the power conversion user terminal is also improved when the power conversion price of each power conversion user terminal is located in the price range of the power conversion user terminal in different busy states by means of guiding the user terminal through fine adjustment of difference price.

In this embodiment, the power exchange price of the first power exchange station in the busy period is adjusted to be high by the settlement adjustment formula, so that the power exchange user terminal can be guided to go to the first power exchange station for power exchange in the low-price period, and the power exchange pressure of the first power exchange station in the power exchange busy period is further reduced.

In this implementation manner, step 104 specifically updates the adjusted power-change-resource settlement information of the power-change busy period and the power-change busy period of the first power-change station to the power-change user terminal.

In this embodiment, the adjusted power conversion resource settlement information of the power conversion user terminal can be notified in this way, so as to effectively direct the power conversion user terminal to go to the first power conversion station for power conversion when the power conversion resource settlement information is low, further reduce the power conversion capability of the first power conversion station in the power conversion busy time period, and further improve the overall resource utilization rate of the power conversion station.

In another implementation manner of the operation state information, the operation state information includes a power change busy time period and corresponding guiding information, where the guiding information is used for guiding a user to perform power change to other power change stations.

In this embodiment: the power change busy time period and the corresponding guide information are used as a second operation information implementation mode, and the power change user terminal can be guided to perform power change to other power change stations except the first power change station in the power change busy time period through the guide information so as to effectively reduce the power change pressure of the first power change station in the power change busy time period.

The specific other power exchange stations can be selected according to actual conditions, for example, the power exchange station closest to the power exchange user can be the power exchange station not in a busy time period, the power exchange station with the lowest basic power exchange resource settlement information can be the power exchange station, and the like. The following further describes the manner of obtaining the third power exchange station by taking other third power exchange stations not in the busy period as an example:

as shown in fig. 5, step 104 further includes:

step 1041, obtaining historical power conversion data of a second power conversion station;

step 1042, determining a power conversion busy period of the second power conversion station according to the historical power conversion data of the second power conversion station: when there is no overlapping time between the power-exchanging busy time period of the second power-exchanging station and the power-exchanging busy time period of the first power-exchanging station, executing step 1043; when there is a coincidence time between the power-down busy period of the second power-down station and the power-down busy period of the first power-down station, step 1044 is performed.

Step 1043, using the corresponding second power exchange station as a third power exchange station;

step 1044, the flow ends.

Specifically, the guiding information specifically refers to guiding information for guiding the power conversion user to perform power conversion to the third power conversion station.

In this embodiment, historical power exchanging data of other power exchanging stations (i.e., second power exchanging stations) except the first power exchanging station is obtained, and power exchanging busy time periods corresponding to the second power exchanging stations are obtained according to the historical power exchanging data, if the power exchanging busy time periods of the second power exchanging stations do not overlap with the power exchanging busy time periods of the first power exchanging stations, the corresponding second power exchanging stations are used as third power exchanging stations, and power exchanging users are guided to the third power exchanging stations to exchange power, so that the resource utilization rate of the third power exchanging stations which are not in the power exchanging busy time periods can be improved.

In a preferred embodiment, as shown in fig. 6, the step 101 may further include the following steps:

step 112, determining a power exchange idle time period of the first power exchange station according to the historical power exchange data.

The determining manner of the power-change idle time period can refer to the determining manner of the power-change busy time period of the power-change busy time. Different from the power-change busy time period, if the power-change idle time period is determined by the power-change times, the step 102 is modified to take the corresponding time period as the power-change idle time when the power-change times are smaller than the preset times; if the power change idle time period is determined by the power change load rate, 1022 is needed to be modified, and when the power change load rate is smaller than the preset load rate, the corresponding time period is used as the power change idle time period.

And 113, adjusting the operation state information of the first power exchange station in the power exchange idle time period.

The implementation of step 113 may refer to the implementation of step 103. Different from the power-change busy time period, if the operation state information includes power-change resource settlement information of the power-change idle time period, the basic power-change resource settlement information is reduced at the moment, and the specific reduced calculation formula can refer to the settlement adjustment formula; if the operation state information comprises a power conversion busy time period and corresponding guide information, the guide information is used for guiding a power conversion user to the power conversion station to convert power.

And 114, updating the adjusted power exchange idle time period and the operation state information of the power exchange idle time period of the first power exchange station to a power exchange user side.

In this embodiment, the power exchange idle period of the first power exchange station is predicted according to the historical power exchange data of the first power exchange station, after the operation state information of the power exchange idle period is adjusted, the adjusted power exchange idle period and operation state information are updated to the power exchange user terminal, so that the power exchange user terminal can be guided to exchange power in the power exchange idle period, on one hand, the power exchange pressure of other power exchange stations in busy periods can be relieved, on the other hand, the utilization rate of the power exchange stations in the idle period can be improved, and further the overall resource utilization rate of the power exchange station is improved.

Example 2

The embodiment also provides a method for adjusting the operation state of the power exchange station, which is applied to a power exchange user terminal and can be applied to electronic equipment such as a vehicle-mounted terminal, a handheld terminal, an intelligent portable device, a microcomputer and the like, as shown in fig. 7, and the method for adjusting the operation state of the power exchange station comprises the following steps:

step 201, receiving operation state information of a power change busy time period and a power change busy time period of a first power change station sent by a power change station end.

The operation state information is operation state information of the first power exchange station after the adjustment of the power exchange busy time period.

In this embodiment, the specific content received by the power conversion client in step 201 is the specific content updated by the power conversion client in step 104 in embodiment 1.

Step 202, obtaining a power change request operation of a first power change station sent by a power change user;

step 203, determining that the power change time of the power change request operation is within the power change busy time period of the first power change station, and displaying operation state information of the power change busy time period.

For example, in a specific scenario, the target information displayed on the power conversion client includes operation status information of power conversion resource settlement information, specifically, a power conversion price, for example: the base electricity exchanging price of the road D site is 0.22 yuan/km in the non-busy time period, and the electricity exchanging price is adjusted to be 0.32/km in the busy time period of 10:00-11:00, so that the busy time period and the adjusted electricity exchanging resource settlement information can be further displayed in other colors or in a high-brightness mode, and the electricity exchanging user side is further reminded.

The target information may further include detailed information of the power exchange station, such as address, business state, business time, whether to stop freely, etc. of the power exchange station; the target station can further comprise battery conditions of the current charging bin of the battery replacement station, such as the number of batteries with different electric quantities, the number of available batteries, the number of batteries to be charged and the like; the target information may also include other price information, such as parking fees, service fees, etc., in addition to the price of the electricity change.

In this embodiment, the information such as the operation state information, the battery exchange station information, the battery charging information and the like is displayed to the battery exchange user through the battery exchange user terminal, so that the detailed information of the battery exchange station can be comprehensively displayed to the battery exchange user, and the use experience of the battery exchange user is further improved.

In this embodiment, the power exchange busy period and the corresponding operation state information of the first power exchange station sent by the power exchange station end are received, and it is determined that the power exchange time requested by the power exchange user end is within the power exchange busy period, the adjusted operation state information can be displayed, so that the power exchange user end is guided to exchange power from the power exchange busy period to other power exchange stations not in the busy period, on one hand, the power exchange time of the power exchange user end can be saved, the queuing phenomenon caused by power exchange to the first power exchange station in the busy period is avoided, on the other hand, the power exchange pressure of the first power exchange station in the busy period can be relieved, in addition, the utilization rate of other power exchange stations not in the busy period can be improved, and further the overall resource utilization rate of the power exchange station is improved.

In a specific implementation, as shown in fig. 8, the adjustment method may further include:

step 211, receiving a power exchange idle time period and operation state information of the power exchange idle time period of the first power exchange station sent by the power exchange station end.

The operation state information is operation state information of the first power exchange station after the adjustment of the power exchange idle time period.

In this embodiment, the specific content received by the power conversion client in step 201 is the specific content updated by the power conversion client in step 114 in embodiment 1.

Step 212, obtaining a power change request operation of a first power change station sent by a power change user;

and 213, determining that the power change time of the power change request operation is within the power change idle time period of the first power change station, and displaying the operation state information of the power change idle time period.

In this embodiment, the power exchange idle time period and the corresponding operation state information of the first power exchange station sent by the power exchange station end are received, and it is determined that the power exchange time requested by the power exchange user end is within the power exchange idle time period, the adjusted operation state information can be displayed, so that the power exchange user end is guided to exchange power from the power exchange idle time period to the power exchange station, on one hand, the power exchange time of the power exchange user end can be saved, the queuing phenomenon caused by the power exchange station going to the busy time period is avoided, on the other hand, the utilization rate of the power exchange station in the idle time period is also improved, and further the overall resource utilization rate of the power exchange station is improved.

Example 3

The embodiment provides an adjustment device for an operation state of a power exchange station, which is applied to a power exchange station end, as shown in fig. 9, and includes a historical data acquisition module 301, a busy time calculation module 302, an operation state adjustment module 303, and an operation information update module 304.

The historical data acquisition module 301 is configured to acquire historical power conversion data of a first power conversion station;

the busy time calculation module 302 is configured to determine a power conversion busy period of the first power conversion station according to the historical power conversion data;

the operation state adjustment module 303 is configured to adjust operation state information of the first power exchange station in the power exchange busy period;

the operation information updating module 304 is configured to update the adjusted operation status information of the power change busy period and the power change busy period of the first power change station to a power change user side.

It should be understood that, the implementation manner of each module may refer to the specific implementation manner and the corresponding technical effect in embodiment 1, and will not be described herein.

Example 4

The embodiment provides an adjustment device for an operation state of a power exchange station, which is applied to a power exchange user side, as shown in fig. 10, and the adjustment device includes: an operation information receiving module 401, a power change request obtaining module 402 and a display module 403.

The operation information receiving module 401 is configured to receive operation status information of the power conversion busy period and the power conversion busy period of the first power conversion station sent by the power conversion station, where the operation status information is generated according to the adjusted first power conversion station in the power conversion busy period;

the power change request acquisition module 402 is configured to acquire a power change request operation of a first power change station sent by a power change user;

the display module 403 is configured to determine that the power change time of the power change request operation is the power change busy period of the first power change station, and display operation status information of the power change busy period.

It should be understood that, the implementation manner of each module may refer to the specific implementation manner and the corresponding technical effect in embodiment 2, and will not be described herein.

Example 5

The present embodiment provides an electronic device, which may be expressed in the form of a computing device (for example, may be a server device), and includes a memory, a processor, and a computer program stored on the memory and capable of running on the processor, where the processor may implement the method for adjusting the operation state of the power exchange station in embodiment 1 or embodiment 2 when executing the computer program, and reference may be made to the specific implementation manner and corresponding technical effects in embodiment 1 or embodiment 2, which are not described herein.

Fig. 11 shows a schematic diagram of the hardware structure of the present embodiment, and as shown in fig. 11, the electronic device 9 specifically includes:

at least one processor 91, at least one memory 92, and a bus 93 for connecting the different system components (including the processor 91 and the memory 92), wherein:

the bus 93 includes a data bus, an address bus, and a control bus.

The memory 92 includes volatile memory such as Random Access Memory (RAM) 921 and/or cache memory 922, and may further include Read Only Memory (ROM) 923.

The memory 92 also includes a program tool 925 having a set (at least one) of program modules 924, such program modules 924 including, but not limited to: an operating system, one or more application programs, other program modules, and program data, each or some combination of which may include an implementation of a network environment.

The processor 91 executes various functional applications and data processing, such as the adjustment method of the operation state of the battery exchange station in embodiment 1 or embodiment 2 of the present invention, by running a computer program stored in the memory 92.

The electronic device 9 may further communicate with one or more external devices 94 (e.g., keyboard, pointing device, etc.). Such communication may occur through an input/output (I/O) interface 95. Also, the electronic device 9 may communicate with one or more networks such as a Local Area Network (LAN), a Wide Area Network (WAN) and/or a public network, such as the Internet, through a network adapter 96. The network adapter 96 communicates with other modules of the electronic device 9 via the bus 93. It should be appreciated that although not shown in the figures, other hardware and/or software modules may be used in connection with the electronic device 9, including but not limited to: microcode, device drivers, redundant processors, external disk drive arrays, RAID (disk array) systems, tape drives, data backup storage systems, and the like.

It should be noted that although several units/modules or sub-units/modules of an electronic device are mentioned in the above detailed description, such a division is merely exemplary and not mandatory. Indeed, the features and functionality of two or more units/modules described above may be embodied in one unit/module according to embodiments of the present application. Conversely, the features and functions of one unit/module described above may be further divided into ones that are embodied by a plurality of units/modules.

Example 6

The present embodiment provides a computer readable storage medium, on which a computer program is stored, where the program when executed by a processor implements the method for adjusting the operation state of the power exchange station in embodiment 1 or embodiment 2, and reference may be made to the specific implementation manner and the corresponding technical effects in embodiment 1 or embodiment 2, which will not be described herein.

More specifically, among others, readable storage media may be employed including, but not limited to: portable disk, hard disk, random access memory, read only memory, erasable programmable read only memory, optical storage device, magnetic storage device, or any suitable combination of the foregoing.

In a possible embodiment, the invention may also be realized in the form of a program product comprising program code for causing a terminal device to carry out the adjustment method for realizing the operating state of the power exchange station in embodiment 1 or embodiment 2, when said program product is run on the terminal device.

Wherein the program code for carrying out the invention may be written in any combination of one or more programming languages, which program code may execute entirely on the user device, partly on the user device, as a stand-alone software package, partly on the user device and partly on the remote device or entirely on the remote device.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the principles and spirit of the invention, but such changes and modifications fall within the scope of the invention.

Claims

1. A method for adjusting the operating status of a power exchange station, the method comprising the steps of:

acquiring historical power conversion data of a first power conversion station;

2. The method for adjusting an operation state of a power exchange station according to claim 1, wherein the historical power exchange data includes a number of power exchange times for each set period of time;

3. The method of adjusting the operational status of a power exchange station of claim 1, wherein said step of determining a power exchange busy period of said first power exchange station based on said historical power exchange data comprises:

4. A method of adjusting the operational status of a power exchange station as defined in claim 3, wherein said historical power exchange data further comprises: the number of times of the power conversion service capability of each set time period, the power conversion operation time of each set time period and the number of batteries in the station of each set time period;

5. The method for adjusting an operating state of a power exchange station according to claim 1, wherein the historical power exchange data includes average historical power exchange data within a preset historical time range and within a corresponding time period.

6. The method for adjusting an operation state of a power exchange station according to claim 1, wherein the operation state information includes power exchange resource settlement information corresponding to the power exchange busy period.

7. The method of claim 6, wherein the step of determining the power-down busy period of the first power-down station based on the historical power-down data further comprises:

8. The method for adjusting the operation status of a power exchange station according to claim 1, wherein the step of adjusting the operation information status of the first power exchange station during the power exchange busy period comprises the steps of:

9. The method of adjusting an operation state of a power exchange station according to claim 8, wherein the step of calculating power exchange resource settlement information of the busy period from the base power exchange resource settlement information of the first power exchange station comprises the steps of:

acquiring a settlement adjustment formula;

The settlement adjustment formula is as follows:

10. A method for adjusting the operating state of a power exchange station according to claim 1, characterized in that,

11. The method for adjusting the operation status of a power exchange station according to claim 10, wherein the step of updating the operation status information of the power exchange busy period and the power exchange busy period of the adjusted first power exchange station to the power exchange user side comprises:

12. The method for adjusting the operation state of a power exchange station according to claim 1, wherein the step of acquiring the historical power exchange data of the first power exchange station further comprises the steps of:

13. The method for adjusting the operation state of the power exchange station is characterized by being applied to a power exchange user side and comprising the following steps of:

receiving a power change busy time period and operation state information of the power change busy time period of a first power change station sent by a power change station end, wherein the operation state information is operation state information of the first power change station after adjustment of the power change busy time period;

acquiring a power change request operation of a first power change station sent by a power change user;

and determining the power change time of the power change request operation within the power change busy time period of the first power change station, and displaying operation state information of the power change busy time period.

14. The device for adjusting the operation state of the power exchange station is characterized by comprising a historical data acquisition module, a busy time calculation module, an operation state adjustment module and an operation information update module;

15. An adjusting device for an operation state of a power exchange station, wherein the adjusting device is applied to a power exchange user terminal, and the adjusting device comprises: the system comprises an operation information receiving module, a power conversion request acquisition module and a display module;

the operation information receiving module is used for receiving a power conversion busy time period of a first power conversion station and operation state information of the power conversion busy time period, which are sent by a power conversion station end, wherein the operation state information is generated according to the adjusted first power conversion station in the power conversion busy time period;

16. An electronic device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, characterized in that the processor implements a method for adjusting the operating state of a power exchange station according to any one of claims 1 to 13 when executing the computer program.

17. A computer-readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements a method of adjusting the operating state of a power exchange station according to any one of claims 1 to 13.