CN113627724A

CN113627724A - Method and device for reasonably distributing electric quantity, storage medium and solar street lamp equipment

Info

Publication number: CN113627724A
Application number: CN202110759197.7A
Authority: CN
Inventors: 雷锡社; 穆彪; 张益玖; 郑雷; 吕子伟
Original assignee: Jiangsu Nengdian S&t Co ltd
Current assignee: Jiangsu Nengdian S&t Co ltd
Priority date: 2021-07-02
Filing date: 2021-07-02
Publication date: 2021-11-09
Anticipated expiration: 2041-07-02
Also published as: CN113627724B

Abstract

The embodiment of the invention discloses a method and a device for reasonably distributing electric quantity, a storage medium and a solar street lamp, wherein the method comprises the following steps: acquiring days N to be homogenized, numbers of all days in the days N to be homogenized and electric quantity to be homogenized of the solar street lamp corresponding to all the numbers; sequentially carrying out accumulation homogenization treatment on the to-be-homogenized electric quantity of each day according to the sequence of the reverse numbers, determining the first homogenized electric quantity of each number corresponding to each accumulation homogenization time, and marking the starting number and the ending number of each accumulation homogenization time; performing over-value prevention processing on each number by using the first number of days corresponding to each accumulated homogenization time and the first homogenized electric quantity of each number in the first number of days, and determining the target homogenized electric quantity corresponding to each number in the days N to be homogenized; and updating the target homogenizing electric quantity to the electric quantity to be homogenized corresponding to each number in the days N to be homogenized, and continuing to execute the steps until N is equal to the preset days by taking N as N + 1. By the method, the electric quantity in each day can be balanced and reasonable, so that electric quantity resources are reasonably distributed.

Description

Method and device for reasonably distributing electric quantity, storage medium and solar street lamp equipment

Technical Field

The invention relates to the technical field of solar power generation, in particular to a method and a device for reasonably distributing electric quantity, a storage medium and solar street lamp equipment.

Background

Solar energy is one of the cleanest energy sources, and is deeply favored by various manufacturing industries by combining the advantages of renewable energy, and the solar power generation technology is pure at present, such as a solar water heater, a solar street lamp and the like.

However, when power is supplied to a load by using solar energy, redundancy exists between power generation amount and power consumption amount, which is particularly expressed in that excessive power generation amount makes the residual power not be reasonably used, which causes resource waste, and therefore an effective means for reasonably planning and using the power is urgently needed.

Disclosure of Invention

The invention mainly aims to provide a method and a device for reasonably distributing electric quantity, a storage medium and solar street lamp equipment, which can solve the problem that the electric quantity is reasonably planned and used by lacking an effective means so as to cause the electric quantity redundancy in the prior art.

In order to achieve the above object, a first aspect of the present invention provides a method for reasonably distributing electric quantity, the method being applied to a solar street lamp, the method comprising:

acquiring days N to be homogenized, numbers of all days in the days N to be homogenized and electric quantity to be homogenized of the solar street lamp corresponding to all the numbers, wherein the numbers are sequenced according to a positive time sequence;

sequentially carrying out accumulation homogenization treatment on the electric quantity to be homogenized corresponding to the serial numbers of the days according to the sequence of reverse serial numbers, determining the first homogenization electric quantity of each serial number corresponding to each accumulation homogenization time, and marking the starting serial number and the ending serial number of each accumulation homogenization time, wherein the starting serial number and the ending serial number correspond to the serial numbers of the days;

performing over-value prevention processing on each number by using a first number of days corresponding to each accumulated homogenization time and a first homogenization electric quantity of each number corresponding to the first number of days, and determining a target homogenization electric quantity corresponding to each number in the days N to be homogenized;

and updating the target homogenization electric quantity to the electric quantity to be homogenized corresponding to each serial number in the days to be homogenized N, setting N as N +1, and continuing to execute the step of acquiring the days to be homogenized N, the serial numbers of each day in the N and the electric quantity to be homogenized corresponding to each serial number until N is equal to a preset number of days.

In a feasible implementation manner, the performing, by using the first number of days corresponding to each accumulated equalization time and the first equalization electric quantity of each number corresponding to the first number of days to perform the over-value prevention processing on each number, and determining the target equalization electric quantity corresponding to each number in the number of days N to be equalized includes:

acquiring each serial number in a second number of days corresponding to the accumulated homogenization times each time and a second homogenization electric quantity corresponding to each serial number, wherein the second number of days is less than or equal to the first number of days;

respectively calculating the sum of each target number in a second day corresponding to each accumulated homogenization time and a second homogenization electric quantity corresponding to each number in the last i numbers corresponding to the target number, and determining the sum of the average values corresponding to the target numbers in each accumulated homogenization time, wherein the target number is the number of any day in the second day;

acquiring the original electric quantity corresponding to each number in the i numbers after the target number in each accumulated homogenization time;

determining a safety threshold corresponding to the target number in each accumulated homogenization time by using the sum of the original electric quantity, a preset maximum battery capacity, a cutting absorption extreme value and a preset safety threshold algorithm;

determining whether the second days have unrepairable days according to the safety threshold corresponding to each target number and the mean sum corresponding to each target number;

and if the number of the days N to be homogenized is not equal to the preset number, determining that the second homogenization quantity is the target homogenization electric quantity corresponding to each number in the days N to be homogenized.

In a feasible implementation manner, the determining whether there are unrepairable days in the second number of days according to the safety threshold corresponding to each target number and the sum of the mean values corresponding to each target number includes:

if the average sum corresponding to any one of the target numbers in the second number of days is greater than the safety threshold, determining that the number of days which cannot be left exists in the second number of days;

and if the sum of the average values corresponding to any one of the target numbers in the second number of days is less than or equal to the safety threshold, determining that no unrepairable days exist in the second number of days.

In one possible implementation, the determining that there are no remaining days in the second number of days further comprises:

marking the average value and the target number corresponding to the safety threshold as the days which cannot be left; determining the target accumulation homogenization times corresponding to the days which cannot be left;

acquiring a third day corresponding to the target accumulation homogenization times, a number of each day corresponding to the third day and a third homogenization electric quantity of each day;

skipping the target number corresponding to the days which cannot be left, continuing to execute the steps of sequentially carrying out accumulation homogenization treatment on the electric quantity to be homogenized corresponding to the number of each day according to the reverse numbering sequence, determining the first homogenization electric quantity of each number corresponding to each accumulation homogenization time, and marking the starting number and the ending number of each accumulation homogenization time.

In a feasible implementation manner, the step of acquiring the number of days to be homogenized N, the number of each day in N, and the electric quantity to be homogenized corresponding to each number further includes:

if the number has the days which cannot be left, and the electric quantity to be homogenized corresponding to the number N is larger than the electric quantity to be homogenized corresponding to the number N-1, making N equal to N +1, and continuing to execute the step of acquiring the number of days to be homogenized N, the number of each day in the days to be homogenized N and the electric quantity to be homogenized of the solar street lamp corresponding to each number;

if the number has the day which cannot be left and the electric quantity to be homogenized corresponding to the number N is less than or equal to the electric quantity to be homogenized corresponding to the number N-1, judging whether the number N-1 is a marked day which cannot be left;

if the number N-1 is a marked day which cannot be remained, making N equal to N +1, and continuing to execute the step of acquiring the number of days to be homogenized N, the number of each day in the number of days to be homogenized N and the electric quantity to be homogenized of the solar street lamp corresponding to each number;

and if the number N-1 is not the marked non-remaining day, continuing to perform the steps of sequentially carrying out accumulation homogenization treatment on the to-be-homogenized electric quantity corresponding to the number of each day according to the reverse number sequence, determining the first homogenization electric quantity of each number corresponding to each accumulation homogenization time, and marking the starting number and the ending number of each accumulation homogenization time.

In a possible implementation manner, the skipping of the target number corresponding to the unremainable day further includes:

acquiring a first electric quantity difference value between the average value and the safety threshold value;

and extracting the first electric quantity difference value from the third homogenized electric quantity corresponding to the non-available day, returning to the third homogenized electric quantity of the number corresponding to the termination number of the target accumulated homogenization times, and obtaining the updated fourth homogenized electric quantity corresponding to the non-available day and the fourth homogenized electric quantity corresponding to the termination number.

In one possible implementation, the determining the target accumulated homogenization times corresponding to the unrepairable days further comprises:

acquiring the original electric quantity of the number corresponding to the non-remained day;

and determining a cutting absorption extreme value corresponding to the target accumulation homogenization times by using the original electric quantity, the preset maximum battery capacity and a preset difference algorithm.

In order to achieve the above object, a second aspect of the present invention provides a device for reasonably distributing electric quantity, the device being applied to a solar street lamp, the device comprising:

a data acquisition module: the number of days N to be homogenized, the number of each day in the days N to be homogenized and the electric quantity to be homogenized of the solar street lamp corresponding to each number are obtained, and the numbers are sorted according to a positive time sequence;

a data homogenizing module: the number-counting and averaging device is used for sequentially carrying out accumulation and averaging processing on the electric quantity to be averaged corresponding to the number of each day according to the sequence of the reverse numbers, determining the first averaged electric quantity of each number corresponding to each accumulation and averaging time, and marking the starting number and the ending number of each accumulation and averaging time, wherein the starting number and the ending number correspond to the number of each day;

the excess value processing module: the number averaging device is used for utilizing the first number of days corresponding to the accumulated averaging times and the first averaging electric quantity of each number corresponding to the first number of days to perform over-value prevention processing on each number, and determining the target averaging electric quantity corresponding to each number in the number N of days to be averaged;

a data updating module: and the step of obtaining the number of days to be homogenized N, the number of each day in the N and the electric quantity to be homogenized corresponding to each number is continuously executed until the number of N is equal to a preset number of days.

To achieve the above object, a third aspect of the present invention provides a computer-readable storage medium storing a computer program, which, when executed by a processor, causes the processor to perform the steps shown in the first aspect and any one of the alternative implementations.

In order to achieve the above object, a fourth aspect of the present invention provides a solar street light device, comprising a memory and a processor, wherein the memory stores a computer program, and the computer program, when executed by the processor, causes the processor to perform the steps of the first aspect and any one of the optional implementations.

The embodiment of the invention has the following beneficial effects:

the invention provides a method for maximizing resource utilization rate, which is applied to a solar street lamp and comprises the following steps: acquiring days N to be homogenized, numbers of all days in the days N to be homogenized and electric quantity to be homogenized of the solar street lamp corresponding to all the numbers, wherein the numbers are sequenced according to a positive time sequence; sequentially carrying out accumulation homogenization treatment on the electric quantity to be homogenized corresponding to the serial numbers of the days according to the sequence of reverse serial numbers, determining the first homogenization electric quantity of each serial number corresponding to each accumulation homogenization time, and marking the starting serial number and the ending serial number of each accumulation homogenization time, wherein the starting serial number and the ending serial number correspond to the serial numbers of the days; performing over-value prevention processing on each number by using a first number of days corresponding to each accumulated homogenization time and a first homogenization electric quantity of each number corresponding to the first number of days, and determining a target homogenization electric quantity corresponding to each number in the days N to be homogenized; and updating the target homogenization electric quantity to the electric quantity to be homogenized corresponding to each serial number in the days to be homogenized N, setting N as N +1, and continuing to execute the step of acquiring the days to be homogenized N, the serial numbers of each day in the N and the electric quantity to be homogenized corresponding to each serial number until N is equal to a preset number of days. The electric quantity to be homogenized in each day in the preset number of days is accumulated and homogenized, and each day is subjected to over-value prevention processing, so that the electric quantity balance of each day is guaranteed, the maximum capacity of the solar street lamp can be prevented from being exceeded, the optimal target homogenized electric quantity among the days is realized, the electric quantity balance and reasonability of each day are achieved, and the electric quantity resources are reasonably distributed.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

FIG. 1 is a flow chart of a method for reasonably distributing electric quantity in an embodiment of the present invention;

FIG. 2 is another flow chart of a method for reasonably distributing power in an embodiment of the present invention;

FIG. 3 is a block diagram of an apparatus for reasonably distributing power according to an embodiment of the present invention;

fig. 4 is a block diagram of a computer device according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the embodiment of the invention, the illumination principle of the solar street lamp is as follows: solar energy absorbed by the solar panel on the daytime is converted into electric energy to be stored in the storage battery, so that the electric energy stored by the storage battery is used for supplying power to the lamp at night, and night illumination is realized.

It can be understood that the generated energy of the solar panel of the same solar street lamp changes along with the change of sunlight, and if the generated energy of the cloudy day is worse than that of the sunny day compared with that of the sunny day, so that the illumination time of the same solar street lamp is different when illumination is performed, the illumination time of one day is too long, the illumination of the other day is too short, and at this time, the unbalanced power utilization is explained. Therefore, in an embodiment of the present invention, an electric quantity distribution method is used to reasonably distribute electric quantity between the electric quantity generated by solar energy corresponding to the current day or the current day and the predicted electric quantity generated by solar energy for the current day or the next days after the current day in a manner of being as balanced as possible. The remaining capacity belonging to the current day is thus distributed to the next days, but the required draw for the capacity of the next days is only available to the respectively adjacent previous day, so that the distribution process starts from the first day and the remaining is carried out subsequently. The description of the embodiments of the present application begins next.

Referring to fig. 1, fig. 1 is a schematic flow chart of a method for reasonably distributing electric quantity in an embodiment of the present invention, and as shown in fig. 1, the method is applied to a solar street lamp, and the method specifically includes the following steps:

101. acquiring days N to be homogenized, numbers of all days in the days N to be homogenized and electric quantity to be homogenized of the solar street lamp corresponding to all the numbers, wherein the numbers are sequenced according to a positive time sequence;

it should be noted that, the number of days to be homogenized is from the current day to the end of the preset number of days, the value of N is minimum 1, maximum is the preset number of days N, and the number of days refers to a time range, and the time range is in days.

The number of each day is the number of each day in the time range corresponding to the number of days to be homogenized N, and the numbers are sorted according to the positive time sequence and can be arranged from 1. Illustratively, if the number of days to be homogenized is 1, the time range is 1 day, and the corresponding number of the day is 1; if the number of days to be homogenized is 2, the time range is 2 days, the number corresponding to the first day is 1, and the number corresponding to the second day is 2; if the number of days to be homogenized is 3, the time range is 3 days, the number of the first day is 1, the number of the second day is 2, and the number of the third day is 3; according to the method, each day in the preset number of days is numbered in advance. The above numbering rules are not limited in this example, and whether the arrangement is started from 0 or from any number can be selected according to actual needs.

It will be appreciated that the appropriate allocation of power is based on the current day, and thus the first of the days to be homogenized is the current day and all days following the second of the days to be homogenized are future days.

Further, the electric quantity to be homogenized corresponding to each day or each number can be represented as the current residual electric quantity corresponding to the current day and the predicted electric energy generation quantity corresponding to the future day.

102. Sequentially carrying out accumulation homogenization treatment on the electric quantity to be homogenized corresponding to the serial numbers of the days according to the sequence of reverse serial numbers, determining the first homogenization electric quantity of each serial number corresponding to each accumulation homogenization time, and marking the starting serial number and the ending serial number of each accumulation homogenization time, wherein the starting serial number and the ending serial number correspond to the serial numbers of the days;

the reverse numbering order is the order starting from the last day of the maximum number of days to be homogenized in each round, i.e. the days to be homogenized, and ending to the current day of the minimum number of days to be homogenized in each round, i.e. the first day.

The accumulation means that the sum of the electric quantity to be homogenized is calculated in each day of addition in the previous day range, the initial day range is one day, and N is N +1 until the accumulated sum range is the number of days to be homogenized.

The homogenization refers to that the summation result is subjected to average calculation in a day range, and the average value of the electric quantity of each day in the day range is obtained.

In summary, each accumulation and homogenization process means that accumulation and homogenization are performed each time. Furthermore, the starting number corresponding to each time of accumulation and homogenization is the last day, and the ending number is changed from N to 1 according to each time of accumulation and homogenization until the ending number is the current day, namely the number 1.

Illustratively, the number of days to be homogenized is 3, the time range is 3 days, the number corresponding to the first day is 1 and the electric quantity to be homogenized is 8, the number corresponding to the second day is 2 and the electric quantity to be homogenized is 8, the number corresponding to the third day is 3 and the electric quantity to be homogenized is 6, and the number corresponding to the fourth day is 4 and the electric quantity to be homogenized is 0; at this time, the reverse order accumulation homogenization is specifically as follows:

the round of reverse order accumulation includes: number of days in the first cumulative homogenization cycle, number 4: the starting number is 4, the end number is 4, and the result of further cumulative averaging is that the first equalized electric quantity of number 4 is 0.

Second cumulative number of homogenizers over the days numbered 4 and 3: the start number is 4 and the end number is 3, and the further cumulative homogenization process is: the sum of the first homogenized electric quantity 0+ the electric quantity 6 to be homogenized is 6, the 6 is evenly divided into a number 4 and a number 3, the result of the accumulation homogenization is that the first homogenized electric quantity of the number 4 is 3, and the first homogenized electric quantity of the number 3 is 3.

Third cumulative number of homogenizers over the number of days numbered 4, numbered 3 and numbered 2: the start number is 4 and the end number is 2, and the further cumulative homogenization process is: the sum 14 of the first homogenized electric quantity 3+ the electric quantity 8 to be homogenized is divided into number 4, number 3 and number 2, the result of the accumulated homogenization is that the first homogenized electric quantity of number 4 is 4.67, the first homogenized electric quantity of number 3 is 4.67, and the first homogenized electric quantity of number 2 is 4.67.

Fourth cumulative number of homogenizers over the number of days numbered 4, numbered 3, numbered 2 and numbered 1: the start number is 4, the end number is 1, and the further cumulative homogenization process is: the sum 22 of the first homogenized electric quantity 4.67+ the electric quantity 8 to be homogenized is divided into number 4, number 3, number 2 and number 1, the result of the cumulative homogenization is that the first homogenized electric quantity of number 4 is 5.5, the first homogenized electric quantity of number 3 is 5.5, the first homogenized electric quantity of number 2 is 5.5, and the first homogenized electric quantity of number 2 is 5.5.

It is understood that the above example is based on the explanation that N is 4, and in fact the initial value of N is 1, that is, the power distribution process of the present application is to perform the reverse numbering sequence accumulation and equalization from the first day (current day) to the next days to realize the reasonable power distribution.

103. Performing over-value prevention processing on each number by using a first number of days corresponding to each accumulated homogenization time and a first homogenization electric quantity of each number corresponding to the first number of days, and determining a target homogenization electric quantity corresponding to each number in the days N to be homogenized;

it will be appreciated that the battery capacity is limited and therefore the first homogenized power needs to be protected against overruns, preventing the first homogenized power from exceeding the bearable range, leading to artificial correction.

The first number of days is equal to or less than the number of days to be homogenized, and the first number of days is the range of days corresponding to each accumulated homogenization. Furthermore, each calculation is carried out according to the previous time, so that when the homogenization electric quantity of each day is subjected to the over-value prevention processing in the previous calculation result, the next calculation can be carried out continuously, and the subsequent calculation is carried out reasonably.

Continuing with the above example, the number of days is 1, the number of days is 4, and the number of days is only required to be processed to prevent the over-value, and the number of days is 0. After treatment, a second cumulative homogenization is performed.

The second adds up the homogenization time, this first day is 2, and the number of days scope is serial number 4 and serial number 3, need all to prevent the excessive value processing to this two serial numbers, promptly, to preventing the excessive value processing for serial number 4 and serial number 3, this time, first homogenization electric quantity is 3. After treatment, a third cumulative homogenization is performed.

The third time of homogenization, the first day of the time is 3, the number of days ranges are numbers 4, 3 and 2, the three numbers of the time need to be processed in an over-limit prevention mode, namely, the numbers 4, 3 and 2 need to be processed in an over-limit prevention mode, and the first homogenization electric quantity is 4.67. After treatment, a fourth cumulative homogenization is performed.

The fourth adds up the homogenization time, and this time the first day is 4, and the day range is serial number 4, serial number 3, serial number 2 and serial number 1, need all to prevent the excessive value processing to this time four serial numbers, promptly, to serial number 4, serial number 3, serial number 2 and serial number 1 prevent the excessive value processing, this time, first homogenization electric quantity is 5.5. After treatment, subsequent accumulation and homogenization are carried out.

And after the overtime prevention processing, the first homogenized electric quantity corresponding to the last time of accumulation is the target homogenized electric quantity.

104. And updating the target homogenization electric quantity to the electric quantity to be homogenized corresponding to each serial number in the days to be homogenized N, setting N as N +1, and continuing to execute the step of acquiring the days to be homogenized N, the serial numbers of each day in the N and the electric quantity to be homogenized corresponding to each serial number until N is equal to a preset number of days.

It can be understood that the reasonable electricity distribution result is dynamically updated in real time along with the number of days to be distributed, the number of electricity to be homogenized, the number of times of accumulative homogenization and the over-value prevention processing, so that the accumulative homogenization result is dynamically updated as the electricity to be homogenized before a new round of calculation is carried out on a new day, and the steps are repeated to start the new round of reasonable electricity distribution of accumulative homogenization until the preset number of days is reached. The calculation result can be calculated in real time according to the dynamically updated homogenized electric quantity, so that the result of reasonable electric quantity distribution is more accurate and credible.

Referring to fig. 2, fig. 2 is another schematic flow chart of a method for reasonably distributing electric quantity according to an embodiment of the present invention, and as shown in fig. 3, the method is applied to a solar street lamp and specifically includes the following steps,

201. acquiring days N to be homogenized, numbers of all days in the days N to be homogenized and electric quantity to be homogenized of the solar street lamp corresponding to all the numbers, wherein the numbers are sequenced according to a positive time sequence;

202. sequentially carrying out accumulation homogenization treatment on the electric quantity to be homogenized corresponding to the serial numbers of the days according to the sequence of reverse serial numbers, determining the first homogenization electric quantity of each serial number corresponding to each accumulation homogenization time, and marking the starting serial number and the ending serial number of each accumulation homogenization time, wherein the starting serial number and the ending serial number correspond to the serial numbers of the days;

it should be noted that steps 201 and 202 shown in fig. 2 are similar to those shown in

steps

101 and 102 in fig. 1, and for avoiding repetition, the description may be specifically made with reference to fig. 1.

203. Acquiring each serial number in a second number of days corresponding to the accumulated homogenization times each time and a second homogenization electric quantity corresponding to each serial number, wherein the second number of days is less than or equal to the first number of days;

the second number of days is less than or equal to the first number of days; the second number of days is the current number of calculated days for each cumulative averaging pass, continuing with the example above, the first number of days for each cumulative averaging pass, including but not limited to the first, second, and third numbers of days for the example above. It is understood that the first days when the number of days to be homogenized increases for each homogenization pass are also dynamically updated, and are not described in detail herein.

And the second number of days is the current calculation number of days, so the second number of days is the first or second or third or fourth corresponding number of days, so as to eventually reach the maximum number of days range corresponding to the first number of days as the over-limit prevention process proceeds.

The second homogenized electric quantity is the first homogenized electric quantity corresponding to each number before the next time of accumulating homogenization is started, and the second homogenized electric quantity is 0 corresponding to the first time by taking the above as an example; 3 of secondary correspondence; three for 4.67 and four for 5.5. It is to be understood that the second equalized electrical quantity is substantially in a different processing or operational phase, and that the difference description is substantially an average value compared to the first equalized electrical quantity.

204. Respectively calculating the sum of each target number in a second day corresponding to each accumulated homogenization time and a second homogenization electric quantity corresponding to each number in the last i numbers corresponding to the target number, and determining the sum of the average values corresponding to the target numbers in each accumulated homogenization time, wherein the target number is the number of any day in the second day;

it should be noted that, the front and/or the back are relative relationships with the target numbers obtained by reference in the order of positive time, where the i-th numbers can be understood as i-th numbers after the target numbers and can also be understood as i-th days after the days corresponding to the target numbers, for example, if the target number is 1, the i-th numbers corresponding to the target numbers in the second day may be numbers 2, 2 and 3, or 2, 3 and i, and the like, and i corresponding to each target number changes correspondingly according to the difference of the second day. But i is an integer and is not negative. The average sum is the sum of the average electric quantity of the target number and the number i after the target number, the average sum is used for determining whether the target number is a day which cannot be left, and the average sum can also be used for indicating whether the average electric quantity in each accumulated average time of the second day is reasonable, so that the condition that the electric quantity is excessive in the dynamic averaging process can be effectively prevented.

Continuing with the above example, the average sum is described as follows:

wherein the first accumulation for homogenization, with a second day of 1, comprises: number 4; further, the start number is 4, and the end number is 4. The result of the first cumulative homogenization is → the second quantity of homogenization electric quantity of number 4 is 0. Further, the target number is 4, and the i-th numbers corresponding to the second day are null, so the sum of the mean values is 0.

A second cumulative number of homogenizes for a second day of 2, comprising: number 4 and number 3; further, the starting number is 4, the ending number is 3, and the result of the second cumulative number of equalization times is → the second equalized electric quantity of the number 4 is 3, and the second equalized electric quantity of the number 3 is 3.

Further, when the target number is 4, the last i numbers corresponding to the second day do not exist, and thus the sum of the average values is 3;

when the target number is 3, the number of the last i corresponding to the second day is 4, and thus the sum of the average values is 6.

A third cumulative number of homogenizes for a second day of 3, comprising: number 4, number 3, and number 2; further, the starting number is 4, the ending number is 2, and the result of the third cumulative number of averaging is → the second averaged electric quantity of number 4 is 4.67, the second averaged electric quantity of number 3 is 4.67, and the second averaged electric quantity of number 2 is 4.67.

Further, when the target number is 4, the last i corresponding to the second day are absent, and thus the sum of the mean values is 4.67;

when the target number is 3, the number of the last i corresponding to the second day is 4, so the sum of the average values is 9.34;

the target number is 2, the last i numbers corresponding to the second day are 3, 4, so the sum of the means is 14.01.

A fourth cumulative number of homogenizes for a second day of 4, comprising: number 4, number 3, number 2, and number 1; further, the starting number is 4, the ending number is 1, and the result of the fourth cumulative number of times of homogenization → the second homogenized electric quantity of number 4 is 5.5, the second homogenized electric quantity of number 3 is 5.5, the second homogenized electric quantity of number 2 is 5.5, and the second homogenized electric quantity of number 2 is 5.5.

Further, when the target number is 4, the last i corresponding to the second day are absent, and thus the sum of the average values is 5.5.

When the target number is 3, the number of the last i corresponding to the second day is 4, and therefore the sum of the average values is 11.

The target number is 2, the last i numbers corresponding to the second day are 3, 4, so the sum of the means is 16.5.

The target number is 1 and the last i numbers corresponding to the second day are 2, 3, 4, so the sum of the means is 22.

205. Acquiring the original electric quantity corresponding to each number in the i numbers after the target number in each accumulated homogenization time;

continuing with step 204 as an example: for the first time of the accumulation and homogenization, only one day is needed, and therefore only the day needs to be judged, and obviously, in the case of only one day, the case of the excess value does not exist, so that the judgment may not be performed, and certainly, the judgment may also be performed, and the description of step 205 is performed by continuing to take the above example as an example, specifically as follows:

exemplary, the first cumulative number of homogenizers, the second day of which is 1, includes: number 4; further, the start number is 4, and the end number is 4. The result of the first cumulative homogenization is- > the second homogenization electrical quantity of number 4 is 0. Further, the target number is 4, and the i-th number corresponding to the second day is also null, so that the original electric quantity corresponding to the i-th number is 0.

A second cumulative number of homogenizes for a second day of 2, comprising: number 4 and number 3; further, the starting number is 4, the ending number is 3, and the result of the second cumulative averaging number is- > the second averaged electric quantity of number 4 is 3, and the second averaged electric quantity of number 3 is 3. Further, when the target number is 4, the last i numbers corresponding to the second day do not exist, and therefore, the original electric quantity of the last i numbers is 0;

when the target number is 3, the i-th number corresponding to the second day is 4, and the i-th original electric quantity is 0 since the i-th original electric quantity is the 4-th original electric quantity.

A third cumulative number of homogenizes for a second day of 3, comprising: number 4, number 3, and number 2; further, the starting number is 4, the ending number is 2, and the result of the third accumulation of the averaging times is- > the second averaged electric quantity of number 4 is 4.67, the second averaged electric quantity of number 3 is 4.67, and the second averaged electric quantity of number 2 is 4.67. Further, when the target number is 4, the last i numbers corresponding to the second day are absent, so that the original electric quantity corresponding to the last i numbers is 0;

when the target number is 3, the number of the last i numbers corresponding to the second day is 4, and therefore the original electric quantity is the original electric quantity with the number of 4, namely 0;

the target number is 2, and the last i numbers corresponding to the second day are 3 and 4, so that the original electric quantities of the numbers 3 and 4 are 6 corresponding to the number 3 and 0 corresponding to the number 4.

A fourth cumulative number of homogenizes for a second day of 4, comprising: number 4, number 3, number 2, and number 1; further, the starting number is 4, the ending number is 1, and the result of the third accumulation of the number of averaging times is- > the second averaged electric quantity of number 4 is 5.5, the second averaged electric quantity of number 3 is 5.5, the second averaged electric quantity of number 2 is 5.5, and the second averaged electric quantity of number 2 is 5.5.

Further, when the target number is 4, the last i corresponding to the second day does not exist, and therefore the original electric quantity corresponding to the last i number is 0.

When the target number is 3, the i-th number corresponding to the second day is 4, and thus the original electric quantity is 0, which is the original electric quantity of the original electric quantity number 4.

The target number is 2, the last i numbers are 3 and 4 corresponding to the second day, so the original electric quantity is the original electric quantity of numbers 3 and 4, namely 6 corresponding to the number 3, and 0 corresponding to the number 4.

The target number is 1, and the last i numbers corresponding to the second day are 2, 3, and 4, so that the original electric quantities are the original electric quantities of numbers 2, 3, and 4, i.e., 8 corresponding to number 2, 6 corresponding to number 3, and 0 corresponding to number 4.

206. Determining a safety threshold corresponding to the target number in each accumulated homogenization time by using the sum of the original electric quantity, a preset maximum battery capacity, a cutting absorption extreme value and a preset safety threshold algorithm;

it should be noted that the preset safety threshold algorithm is as follows:

and adding the original electric quantity of each number in the last i number of the target number, and presetting the maximum value of the battery capacity-the cutting absorption extreme value.

The maximum value of the preset battery capacity is 10; the absorption extreme value of the cutting is an electric quantity value which is generated in real time and updated in real time in the distribution process, and the initial value of the absorption extreme value of the cutting is 0. It can be understood that the term "absorption extremum and the term" absorption extremum "in this document are the same concept, and both refer to an electric quantity value used for calculating the safety threshold value and generating real-time update in the distribution process, and the default initial value is 0.

Continuing with

steps

204, 205 as an example: for the first time, only one day is needed, so that only the day needs to be judged, and obviously, the case of exceeding the value does not exist in the case of only one day, so that the judgment is not needed, and certainly, the judgment can also be carried out, and the explanation is continued by using the above example, and the specific flow is as follows:

the target number is 4, and the number of the last i corresponding to the second day is also null, in which case the sum of the means is 0. Further, the last i numbers are null, and therefore, the original electric quantity corresponding to the last i numbers is 0. Further, the safety threshold is 10.

Twice, there are two days, therefore, two determinations are made:

when the target number is 4, the last i numbers corresponding to the second day do not exist, and thus the average sum is 3. Further, the latter i number does not exist, and thus, the original capacity is 0. Further, the safety threshold is 10.

When the object number is 3, the last i numbers corresponding to the second day are 4, and thus the average sum is 6. Further, the last i numbers are 4, and therefore, the original electric quantity is the original electric quantity of the number 4, that is, 0. Further, the safety threshold is 10.

Three times, three days, therefore, three times:

when the object number is 4, the last i corresponding to the second day is absent, and thus the sum of the means is 4.67. Further, the last i numbers are also null, so the original electric quantity corresponding to the last i numbers is 0. Further, the safety threshold is 10.

When the target number is 3, the last i numbers corresponding to the second day are 4, and thus the sum of the means is 9.34. Further, the last i numbers are 4, and therefore, the original electric quantity is the original electric quantity of the number 4, that is, 0. Further, the safety threshold is 10.

When the target number is 2, the last i numbers corresponding to the second day are 3, 4, so the sum of the means is 14.02. Further, the last i numbers are 3 and 4, so the original electric quantity is the original electric quantity of numbers 3 and 4, i.e. 6 corresponding to number 3, and 0 corresponding to number 4. Further, the safety threshold is 16.

Four times, four days, therefore, four determinations were made:

when the object number is 4, the last i corresponding to the second day does not exist, so the sum of the means is 5.5. Further, the last i numbers are also null, so the original electric quantity corresponding to the last i numbers is 0. Further, the safety threshold is 10.

When the object number is 3, the last i numbers corresponding to the second day are 4, and thus the sum of the mean values is 11. Further, the last i numbers are 4, and therefore, the original electric quantity is the original electric quantity of the number 4, that is, 0. Further, the safety threshold is 10.

When the target number is 2, the last i numbers corresponding to the second day are 3, 4, so the sum of the means is 16.5. Further, the last i numbers are 3 and 4, so the original electric quantity is the original electric quantity of numbers 3 and 4, i.e. 6 corresponding to number 3, and 0 corresponding to number 4. Further, the safety threshold is 16.

When the target number is 1, the last i numbers corresponding to the second day are 2, 3, 4, so the sum of the mean values is 22. Further, the last i numbers are 2, 3 and 4, so the original electric quantity is the original electric quantity of numbers 2, 3 and 4, i.e. 8 corresponding to number 2, 6 corresponding to number 3 and 0 corresponding to number 4. Further, the safety threshold is 24.

207. Determining whether the second days have unrepairable days according to the safety threshold corresponding to each target number and the mean sum corresponding to each target number;

it should be noted that, when allocating electric energy, the remaining electric energy of one day is allocated to the following day, so each time of allocating electric energy is performed between adjacent days, and an unrepairable day means that the previous day cannot be left with more electric energy, and the remaining electric energy will cause the risk of the final electric energy being exceeded after allocation, so the unrepairable day cannot accept the remaining electric energy of the previous day, in order to prevent the occurrence of the excess phenomenon, therefore, each day of accumulating the equalization times each time needs to be judged, and the subsequent steps are processed according to the judgment result, which may specifically refer to the following description of the steps.

Wherein step 207 comprises:

217. if the average sum corresponding to any one of the target numbers in the second number of days is greater than the safety threshold, determining that the number of days which cannot be left exists in the second number of days;

227. and if the sum of the average values corresponding to any one of the target numbers in the second number of days is less than or equal to the safety threshold, determining that no unrepairable days exist in the second number of days.

Continuing with step 206 as an example: for the first time, only one day is needed, so that only the day needs to be judged, and obviously, the case of only one day does not have the condition of excess value, so that the judgment may not be performed, and certainly, the above example can also be judged, and the specific judgment flow of the

step

217 and 227 is as follows:

the homogenization is accumulated for the first time, the target number is 4, and the judgment is as follows: the mean sum 0< safety threshold 10 and is therefore not present.

The second cumulative homogenization pass, two days, therefore, two determinations are made:

when the object number is 4, the following is judged: mean sum 3< safety threshold 10 and therefore does not exist.

When the object number is 3, the mean sum 6< safety threshold 10, and therefore does not exist.

The third cumulative homogenization time, three days, therefore, three determinations were made:

when the object number is 4, the following is judged: mean sum 4.67< safety threshold 10 and therefore is not present.

When the object number is 3, the following is judged: mean sum 9.34< safety threshold 10 and therefore does not exist.

When the object number is 2, the following judgment is made: mean sum 14.02< safety threshold 16 and therefore does not exist.

The fourth cumulative homogenization pass for four days, and therefore four determinations are made:

when the object number is 4, the following is judged: mean sum 5.5< safety threshold 10 and therefore is not present.

When the target number is 3, the following judgment is made: the mean sum 11< safety threshold 10 and, therefore, exists. After that, the judgment is not needed, and the step i and the subsequent steps are executed.

Wherein step 217 is followed by:

i. marking the average value and the target number corresponding to the safety threshold as the days which cannot be left; determining the target accumulation homogenization times corresponding to the days which cannot be left;

it should be noted that the number of the unremainable days is the target number whose mean value and the target number are greater than the safety threshold, and the above description is continued by taking the step 227 as an example: the target number marked as a day not remaining is number 3 and the target cumulative averaging number is the fourth cumulative averaging number.

Further, step i further includes: acquiring the original electric quantity of the number corresponding to the non-remained day; and determining a 'cutting' absorption extreme value corresponding to the target accumulation homogenization times by using the original electric quantity, the preset maximum battery capacity and a preset difference algorithm.

It should be noted that the "grazing" absorption extremum is used to calculate the safety threshold, the default initial value is 0, and when the non-available day is generated, the day is updated according to the preset difference algorithm, so that the subsequent calculation can be performed in order.

Further, the preset difference algorithm is as follows:

the absorption extreme value of the cutting is the original electric quantity of the number corresponding to the preset maximum value of the battery capacity and the number which cannot be remained.

ii. Acquiring a third day corresponding to the target accumulation homogenization times, a number of each day corresponding to the third day and a third homogenization electric quantity of each day;

in addition, when the third day is the number of days corresponding to the target cumulative averaging times when the days which cannot be left are generated, continuing with the above example, when the target cumulative averaging times corresponding to the number 3 of the days which cannot be left is the fourth cumulative averaging times, the third day is 4.

Wherein step iii is preceded by:

acquiring the average value and the electric quantity difference value between the average value and the safety threshold value; and extracting the first electric quantity difference value from the third homogenized electric quantity corresponding to the non-available day, returning the first electric quantity difference value to the third homogenized electric quantity of the number corresponding to the termination number of the target accumulated homogenization times, and updating the fourth homogenized electric quantity corresponding to the non-available day and the fourth homogenized electric quantity corresponding to the termination number.

Further, the third equalization electric quantity refers to an equalization electric quantity corresponding to a target accumulated equalization time for generating the days that cannot remain.

And the fourth homogenized electric quantity is the homogenized electric quantity of each day in the target accumulation homogenization after returning based on the third homogenized electric quantity.

The explanation is continued with the above step i. And if the fourth accumulated equalization time is 4 days, the numbers are 1, 2, 3 and 4, the third equalized electric quantity is 5.5, and if the difference between the average value and the electric quantity and the safety threshold value is 11 to 10 equal to 1, 1 is extracted from the third equalized electric quantity corresponding to the number 3 in the fourth accumulated equalization time, that is, 5.5, and the average value and the safety threshold value are returned to the third equalized electric quantity corresponding to the number 1, that is, 5.5, the fourth equalized electric quantity corresponding to the numbers 4 and 2 is 5.5, the fourth equalized electric quantity corresponding to the number 3 is 4.5, and the fourth equalized electric quantity corresponding to the number 1 is 6.5. And continues with step iii.

And iii, skipping the target number corresponding to the days which cannot be left, continuing to perform the step of sequentially performing accumulation homogenization treatment on the to-be-homogenized electric quantity corresponding to the number of each day according to the reverse number sequence, determining the first homogenization electric quantity of each number corresponding to each accumulation homogenization time, and marking the starting number and the ending number of each accumulation homogenization time.

It can be understood that after the returning, the power amount of each day is not averaged, and therefore, the fourth cumulative averaging is performed again, and this execution needs to skip the target number corresponding to the non-remaining day, i.e. the number 3, to prevent the averaged power amount from exceeding the preset maximum battery capacity value in the power allocation process.

Continuing with the above example, after returning: in the re-reverse order accumulation equalization, the fourth equalized electric quantity of the number 4 and the number 2 is 5.5, the fourth equalized electric quantity of the number 3 is 4.5, and the fourth equalized electric quantity of the number 1 is 6.5.

The re-executed fifth cumulative averaging times starts at 4 and ends at 3; the average charge was 5 per day. Further, the above-mentioned process of preventing the excessive value is repeated, this time, "the cutting" absorbs the extreme value and is 4 in the calculation of the safety threshold, repeat the above-mentioned process of preventing the excessive value, do not need to be repeated here, can obtain this time not exist can not remain the day finally.

Since number 3 is the marked non-remaining day, the amount of power of the previous day cannot be drawn, so number 3 is skipped, i.e. number 2 does not remain to number 3, to prevent number 3 from being exceeded.

Thus, further, the sixth cumulative averaging time is: the beginning is number 2 and the end is number 1; the average charge was 6 per day. Similar to the fifth cumulative homogenization time, the number 2 and the number 1 do not have a date which cannot be left, so that the target homogenization electric quantity is obtained by the process as the number 1: number 6, 2: 6; number 3: 5; number 4: 5. and proceeds to step 209.

Further, step 201 is followed by:

A. if the number has the days which cannot be left, and the electric quantity to be homogenized corresponding to the number N is larger than the electric quantity to be homogenized corresponding to the number N-1, making N equal to N +1, and continuing to execute the step of acquiring the number of days to be homogenized N, the number of each day in the days to be homogenized N and the electric quantity to be homogenized of the solar street lamp corresponding to each number;

it is understood that after the non-remaining day is generated, after N is N +1, the day needs to be skipped to perform the daily accumulation and homogenization processing.

In one possible implementation, assuming that N +1 is 5, continuing with the above example, the amount of electricity to be homogenized for each day is 6 with number 1; the number 2 of the electric quantity to be homogenized is 6; the number 3 of the electric quantity to be homogenized is 5; the number 4 of the electric quantity to be homogenized is 5; the quantity of electricity to be homogenized of number 5 is 8.

Therefore, at this time, the number 5 is 8> the number 4 is 5, and 3 is a day that cannot be left, and therefore, the subsequent accumulative equalization is not performed at this time, and at this time, the target equalization electric quantity for each day is: the target homogenized electric quantity of number 1 is 6; the target homogenized electric quantity of number 2 is 6; the target homogenization electric quantity of number 3 is 5; the target homogenization electric quantity of number 4 is 5; the target homogenization power of number 5 is 8. And let N +1 be 6, and proceed to step 201.

B. If the number has the day which cannot be left and the electric quantity to be homogenized corresponding to the number N is less than or equal to the electric quantity to be homogenized corresponding to the number N-1, judging whether the number N-1 is a marked day which cannot be left;

b01, if the number N-1 is a marked day which cannot be left, making N equal to N +1, and continuing to execute the step of acquiring the number of days to be homogenized N, the number of each day in the number of days to be homogenized N, and the electric quantity to be homogenized of the solar street lamp corresponding to each number;

b02, if the number N-1 is not the marked non-remaining day, continuing to execute the steps of sequentially carrying out accumulation homogenization treatment on the to-be-homogenized electric quantity corresponding to the number of each day according to the reverse number sequence, determining the first homogenization electric quantity of each number corresponding to each accumulation homogenization time, and marking the starting number and the ending number of each accumulation homogenization time.

In one possible implementation, assuming that N +1 is 5, continuing with the above example, the amount of electricity to be homogenized for each day is 6 with number 1; the number 2 of the electric quantity to be homogenized is 6; the number 3 of the electric quantity to be homogenized is 5; the number 4 of the electric quantity to be homogenized is 5; the quantity of electricity to be homogenized of number 5 is 4.

Therefore, at this time, the number 5 electric power is 4< the number 4 electric power is 5, and the number 4 is not the date on which the electric power cannot be left, and therefore, the reverse order accumulation processing can be performed at this time.

The first time of the round is accumulated and homogenized to be the initial number 5 and the end number 5; the first equalized electrical quantity is 4; the day which cannot be remained does not exist after the excessive value prevention treatment.

The second cumulative number of homogenizers, start number 5, end number 4; the first homogenized charge was 4.5; the day which cannot be remained does not exist after the excessive value prevention treatment.

The third cumulative homogenization time, the start number 5 and the end number 3; the first homogenized charge was 4.67; the day which cannot be remained does not exist after the excessive value prevention treatment.

At this time, although the power amount of number 3 is 4.67 smaller than the power amount of number 2 is 6 and the no-remaining day is not generated this time, number 3 has a flag of the no-remaining day, and therefore, number 3 cannot draw power amount one day ahead, and another angle indicates that number 2 cannot remain power amount to number 3. Otherwise, the final power of number 3 after power distribution exceeds the preset maximum battery capacity. Therefore, no subsequent negative order cumulative averaging is performed, at which point the target averaged charge for each day is: the target homogenized electric quantity of number 1 is 6; the target homogenized electric quantity of number 2 is 6; the target homogenized electric quantity of number 3 is 4.67; the target homogenized electric quantity of number 4 is 4.67; the target homogenization capacity of number 5 was 4.67. And let N +1 be 6, and proceed to step 201.

208. If the number of the days N to be homogenized is not equal to the preset number, determining that the second homogenization quantity is the target homogenization electric quantity corresponding to each number in the days N to be homogenized;

it should be noted that, if the days to be averaged up to the accumulated number of days to be averaged reach the number of days to be averaged, the number of days to be averaged is the generation of the non-remaining day, for example, any one of the above numbers 1-4 and 1-5 is assigned to the end, and during the over-value prevention process, no non-remaining day appears in any target number, so the second averaged electric quantity obtained by the current round of assignment is updated to the target averaged electric quantity, and further, if the non-remaining day does not appear, the second averaged electric quantity is the first averaged electric quantity.

209. And updating the target homogenization electric quantity to the electric quantity to be homogenized corresponding to each serial number in the days to be homogenized N, setting N as N +1, and continuing to execute the step of acquiring the days to be homogenized N, the serial numbers of each day in the N and the electric quantity to be homogenized corresponding to each serial number until N is equal to a preset number of days.

It can be understood that, if the preset number of days is 10 days, after each time of the cumulative homogenization, the calculation range of the number of days needs to be updated, and the calculation result is used as the electric quantity to be homogenized of the day corresponding to the number of updated days, where the number N is a new day, and the electric quantity to be homogenized corresponding to the new day is obtained by estimating parameters having influence on the solar electric energy production according to the weather, the related power generation parameters of the solar panel, and the like. The preset number of days may be 10, 20, N, etc., and is not limited herein.

It should be noted that, when the number of days to be homogenized reaches the preset number of days, the final electric quantity of each day, that is, the available electric quantity of the current day, may be obtained according to the calculation result, so as to implement the power supply of the current day according to the homogenized available electric quantity, so as to equalize the power consumption of the current day and the future days.

In this embodiment, the electric quantity is reasonably distributed in units of days, and optionally, the electric quantity reasonable distribution process of the embodiment may also be performed in a subdivision manner, which is not described herein any more, and the above equivalent transformations without creative efforts are all included in the protection scope of this embodiment. Moreover, the actual procedure of executing the rational distribution of the electric quantity is performed from the first day (current day) of the preset number of days, i.e. 1 day to be homogenized, and the present embodiment is to represent all possible variation counts in the rational distribution of the electric quantity, so the number of days to be homogenized is described as 4, but for the sake of making the actual implementation of the present application clearer, some brief descriptions will be briefly made from the actual procedure of executing the rational distribution of the electric quantity, and the following are concrete:

exemplarily, the original power of number 1 is 8; the original electric quantity of the number 2 is 8; the original electric quantity of the number 3 is 6; the original electric quantity of the number 4 is 0; the original electric quantity of the number 5 is 8, and the absorption extreme value of the cutting is an initial value which is 0.

And (3) calculating reasonable distribution of electric quantity:

the round of reverse order accumulation homogenization comprises the following steps: the first accumulation was homogenized for the number of days in the range of number 1: the starting number is 1, the end number is 1, and the result of further cumulative averaging is that the first equalized electric quantity of number 1 is 8. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. The first equalized electric power of number 1 is obtained as 8, and the target equalized electric power thereof is updated.

The calculation result of the round is as follows: the number 1 of the electric quantity to be homogenized is 8; the original electric quantity of the number 2 is 8; the original electric quantity of the number 3 is 6; the original electric quantity of the number 4 is 0; the original electric quantity of the number 5 is 8, and the absorption extreme value of the cutting is an initial value which is 0.

The two rounds of reverse order accumulation homogenization comprise: the number of days is number 1 and number 2, the number of days is averaged for the first time: the starting number is 2 and the ending number is 2, and the result of further cumulative averaging is that the first equalized electric quantity of number 2 is 8. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. Obtaining the first homogenized electric quantity of number 2 as 8;

second cumulative homogenization time: the start number is 2, the end number is 1, and the result of further cumulative averaging is 8 for the first equalized electrical quantity numbers 2 and 1. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. The first equalized electric power of number 2 and number 1 was obtained as 8. The first equalized electric power of number 2 and number 1 is obtained as 8, and the target equalized electric power is updated.

And two rounds of calculation results: the number 1 of the electric quantity to be homogenized is 8; the original electric quantity of the number 2 is 8; the original electric quantity of the number 3 is 6; the original electric quantity of the number 4 is 0; the original electric quantity of the number 5 is 8, and the absorption extreme value of the cutting is an initial value which is 0.

Three rounds of reverse order additive homogenization include: the number of days is number 1, number 2 and number 3, the first time of accumulation and homogenization is as follows: the start number is 3, the end number is 3, and the result of further cumulative averaging is that the first equalized electric quantity of number 3 is 6. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. Obtaining the first homogenized electric quantity of number 3 as 8;

second cumulative homogenization time: the start number is 3, the end number is 2, and the result of further cumulative averaging is the first equalized electric quantity of number 3 and number 2 is 7. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. Obtaining the first homogenized electric quantity of the number 3 and the number 2 as 7;

third cumulative homogenization time: the start number is 3, the end number is 1, and the result of further cumulative averaging is that the first equalized electric quantity of number 3, number 2 and number 1 is 7.33. It can be understood that, it is only necessary to draw power for the previous day following the next day, and therefore, this time, in addition to the cumulative averaging, it can also be understood that the current power difference between the number 1 and the number 2 of the adjacent day is uniformly allocated to each number in the third cumulative averaging time, and further, the excessive value prevention processing is performed, which is not described herein again with reference to the foregoing. And (5) performing overtime prevention treatment. The first equalized electric power of number 3, number 2 and number 1 was 7.33.

The results of the three calculations are: the number 1 of the electric quantity to be homogenized is 7.33; the original electric quantity of the number 2 is 7.33; the original electric quantity of the number 3 is 7.33; the original electric quantity of the number 4 is 0; the original electric quantity of the number 5 is 8, and the absorption extreme value of the cutting is an initial value which is 0.

Four-wheel cumulative averaging comprises: the number of days is number 1, number 2, number 3 and number 4, the homogenization is accumulated for the first time: the starting number is 4, the end number is 4, and the result of further cumulative averaging is that the first equalized electric quantity of number 4 is 0. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. Obtaining the first homogenized electric quantity of the number 4 as 0;

second cumulative homogenization time: the start number is 4, the end number is 3, and the result of further cumulative averaging is that the first equalized electric quantity of numbers 4 and 3 is 3.67. Further, the excessive value prevention processing can be performed by referring to the foregoing description, which is not described herein. And (5) performing overtime prevention treatment. The first equalized electric quantity of the number 4 and the number 3 is 3.67;

third cumulative homogenization time: the start number is 4, the end number is 2, and the result of further cumulative averaging is that the first equalized electric quantity of numbers 4, 3 and 2 is 4.89. It can be understood that, the electric quantity can be drawn only for the previous day following the next day, and therefore, this time, in addition to the cumulative averaging, it can also be understood that the current electric quantity difference between the number 2 and the number 3 of the adjacent day is uniformly distributed to each number in the third cumulative averaging time, and further, the excessive value prevention processing is performed, which is not described herein with reference to the foregoing. And (5) performing overtime prevention treatment. The first equalized electric power of number 3, number 2, and number 1 was obtained to be 4.89.

Fourth cumulative averaging times: the initial number is 4, the end number is 1, and the result of further reverse order accumulation equalization is that the first equalization electric quantity of the numbers 4, 3, 2 and 1 is 5.5. It can be understood that, it is only necessary to draw power for the previous day following the next day, and therefore, this time, in addition to the cumulative averaging, it can also be understood that the current power difference between the number 1 and the number 2 of the adjacent day is uniformly allocated to each number in the third cumulative averaging time, and further, the excessive value prevention processing is performed, which is not described herein again with reference to the foregoing. And (5) performing overtime prevention treatment. The first equalized electric quantity of No. 3, No. 2, and No. 1 was 5.5.

After the over-value prevention processing, the number 3 is marked as the day that cannot remain, and therefore, the difference in the amount of electricity between the average value and the safety threshold needs to be returned from the first equalized amount of electricity of the number 3 to the end number 1.

After returning: the number 1 of the electric quantity to be homogenized is 6.5; the original electric quantity of the number 2 is 5.5; the original electric quantity of the number 3 is 4.5; the original electric quantity of the number 4 is 5.5; the absorption extremum of the "cutting" is: presetting original electric quantity 6 with the maximum battery capacity of 10-number 3 as 4; after returning, the result is not averaged, so the reverse order accumulation homogenization is carried out again, and the number 3 is skipped for the time to carry out the reverse order accumulation homogenization treatment. The following processes are not repeated, and reference may be made to the foregoing.

Referring to fig. 3, fig. 3 is a block diagram of a structure of a device for reasonably distributing electric power according to an embodiment of the present invention, where the device is applied to a solar street lamp, and the device includes:

the data acquisition module 301: the number of days N to be homogenized, the number of each day in the days N to be homogenized and the electric quantity to be homogenized of the solar street lamp corresponding to each number are obtained, and the numbers are sorted according to a positive time sequence;

the data averaging module 302: the number-counting and averaging device is used for sequentially carrying out accumulation and averaging processing on the electric quantity to be averaged corresponding to the number of each day according to the sequence of the reverse numbers, determining the first averaged electric quantity of each number corresponding to each accumulation and averaging time, and marking the starting number and the ending number of each accumulation and averaging time, wherein the starting number and the ending number correspond to the number of each day;

the excess value processing module 303: the number averaging device is used for utilizing the first number of days corresponding to the accumulated averaging times and the first averaging electric quantity of each number corresponding to the first number of days to perform over-value prevention processing on each number, and determining the target averaging electric quantity corresponding to each number in the number N of days to be averaged;

the data update module 304: and the step of obtaining the number of days to be homogenized N, the number of each day in the N and the electric quantity to be homogenized corresponding to each number is continuously executed until the number of N is equal to a preset number of days.

It should be noted that the functions of each module shown in fig. 3 are similar to those shown in each step in fig. 1, and for avoiding repetition, the description may be specifically made with reference to fig. 1 without repeated description.

The embodiment of the invention provides a device for reasonably distributing electric quantity, which is applied to a solar street lamp and comprises: a data acquisition module: the number of days N to be homogenized, the number of each day in the days N to be homogenized and the electric quantity to be homogenized of the solar street lamp corresponding to each number are obtained, and the numbers are sorted according to a positive time sequence; a data homogenizing module: the number-counting and averaging device is used for sequentially carrying out accumulation and averaging processing on the electric quantity to be averaged corresponding to the number of each day according to the sequence of the reverse numbers, determining the first averaged electric quantity of each number corresponding to each accumulation and averaging time, and marking the starting number and the ending number of each accumulation and averaging time, wherein the starting number and the ending number correspond to the number of each day; the excess value processing module: the number averaging device is used for utilizing the first number of days corresponding to the accumulated averaging times and the first averaging electric quantity of each number corresponding to the first number of days to perform over-value prevention processing on each number, and determining the target averaging electric quantity corresponding to each number in the number N of days to be averaged; a data updating module: and the step of obtaining the number of days to be homogenized N, the number of each day in the N and the electric quantity to be homogenized corresponding to each number is continuously executed until the number of N is equal to a preset number of days. The electric quantity to be homogenized in each day in the preset number of days is accumulated and homogenized, and each day is subjected to over-value prevention processing, so that the electric quantity balance of each day is guaranteed, the maximum capacity of the solar street lamp can be prevented from being exceeded, the optimal target homogenized electric quantity among the days is realized, the electric quantity balance and reasonability of each day are achieved, and the electric quantity resources are reasonably distributed.

Fig. 4 shows an internal configuration diagram of a computer device in the embodiment of the present invention. The computer device may specifically be a terminal, and may also be a server. As shown in fig. 4, the computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the memory includes a non-volatile storage medium and an internal memory. The nonvolatile storage medium of the solar street light device stores an operating system and also stores a computer program, and when the computer program is executed by the processor, the processor can realize the age identification method. The internal memory may also have stored therein a computer program that, when executed by the processor, causes the processor to perform a method of apportioning power among the processors. It will be understood by those skilled in the art that the structure shown in fig. 4 is only a block diagram of a part of the structure related to the present application, and does not constitute a limitation of the solar street light device to which the present application is applied, and a specific solar street light device may include more or less components than those shown in the figure, or combine some components, or have a different arrangement of components.

In an embodiment, a solar street light device is proposed, comprising a memory and a processor, the memory storing a computer program which, when executed by the processor, causes the processor to perform any of the steps as shown in fig. 1 and 2.

In one embodiment, a computer-readable storage medium is proposed, in which a computer program is stored, which, when executed by a processor, causes the processor to perform any of the steps as shown in fig. 1 and 2.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a non-volatile computer-readable storage medium, and can include the processes of the embodiments of the methods described above when the program is executed. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A reasonable distribution method of electric quantity is characterized in that the method is applied to a solar street lamp, and comprises the following steps:

2. The method according to claim 1, wherein the determining the target equalization electric quantity corresponding to each number in the days N to be equalized by performing the over-limit prevention processing on each number by using the first equalization electric quantity corresponding to the first number of days corresponding to each accumulated equalization time and the first equalization electric quantity corresponding to each number in the first number of days comprises:

3. The method of claim 2, wherein the determining whether there are any remaining days in the second number of days according to the safety threshold corresponding to each target number and the sum of the mean values corresponding to each target number comprises:

4. The method of claim 3, wherein determining that there are days that remain unremainable in the second number of days is further followed by:

5. The method according to claim 1, wherein the step of obtaining the number of days N to be homogenized, the number of each day in the N, and the amount of electricity to be homogenized corresponding to each number further comprises:

6. The method of claim 4, wherein skipping the target number corresponding to the non-remaining day further comprises:

7. The method of claim 4, wherein determining the target cumulative averaging times for the days not remaining is preceded by:

8. The utility model provides a device of electric quantity rational distribution, its characterized in that, the device is applied to solar street lamp, the device includes:

9. A computer-readable storage medium, in which a computer program is stored which, when being executed by a processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 7.

10. A solar street light device comprising a memory and a processor, characterized in that the memory stores a computer program which, when executed by the processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 7.