CN116605083B - Processing system for carrying out power regulation and control on charging pile - Google Patents

Abstract

The embodiment of the invention relates to a processing system for carrying out power regulation and control on a charging pile, which comprises the following components: the system comprises a transformer, a power regulation platform, a plurality of first charging networks and a plurality of first user APP; each first charging network comprises a first pipe transporting platform, a first circuit breaker and a plurality of first charging piles. The system can regulate and control the power of the charging pile network.

Description

Processing system for carrying out power regulation and control on charging pile

Technical Field

The invention relates to the technical field of data processing, in particular to a processing system for regulating and controlling power of a charging pile.

Background

New energy automobile based on electric energy obtains electric energy through charging pile. For the charging piles installed in civil areas, the electricity utilization paths of the charging piles overlap with the life electricity utilization paths of residents in the areas. In practical application, the problem that the residential life electricity is insufficient in power supply is easily caused if the electricity consumption of the charging pile is not limited in the residential electricity consumption peak period. To solve the power utilization contradiction, the power regulation and control of the charging pile network is needed, and how to regulate the power of the charging pile network is a technical problem to be solved by the invention.

Disclosure of Invention

The invention aims at overcoming the defects of the prior art, and provides a processing system for regulating and controlling power of a charging pile, which comprises the following components: the system comprises a transformer, a power regulation platform, a plurality of first charging networks and a plurality of first user APP; each first charging network comprises a first pipe transporting platform, a first circuit breaker and a plurality of first charging piles; the power regulation and control platform can regulate and control the whole network power according to the collected data of the transformer and each first charging network side and output three power regulation and control modes: the first operation platform can dynamically regulate and control the charging power of each first charging pile of the first charging network in a designated regulation mode. Therefore, the system can achieve the purpose of regulating and controlling the power of the charging pile network.

In order to achieve the above object, an embodiment of the present invention provides a processing system for performing power regulation and control on a charging pile, the system including: the system comprises a transformer, a power regulation platform, a plurality of first charging networks and a plurality of first user APP; each first charging network comprises a first pipe transporting platform, a first circuit breaker and a plurality of first charging piles;

The transformer is connected with an external power supply network through a power line, is also connected with the first circuit breakers of the first charging networks through power lines, and is also connected with the power regulation and control platform through a data line; the transformer is used for taking electricity from the external power supply network through a power line and outputting power to the first circuit breakers of the first charging networks through the power line; the transformer is also used for regularly carrying out data acquisition on the real-time output power of the transformer to obtain corresponding first acquisition data and sending the corresponding first acquisition data to the power regulation platform;

Each first breaker is respectively connected with each first charging pile in the same charging network through a power line, is also connected with the power regulation and control platform through a data line, and is also connected with the first pipe conveying platform in the same charging network through a data line; the first circuit breaker is used for outputting power to the first charging pile through a power line; the first circuit breaker is also used for periodically acquiring data of the real-time output power of the first circuit breaker to obtain corresponding second acquired data and sending the corresponding second acquired data to the power regulation platform;

Each first charging pile is connected with the first pipe conveying platform in the same charging network through a data line; the first charging pile is used for periodically acquiring real-time data of the first charging pile to obtain corresponding third acquired data and sending the corresponding third acquired data to the first pipe conveying platform; the first charging pile is also used for charging the new energy automobile;

Each first pipe transporting platform is connected with the power regulating and controlling platform through a data line and is also connected with each first user APP through a data line; the first management platform is used for updating the working state of a preset charging pile configuration list according to a first operation application sent by each first user APP; the first pipe transporting platform is further used for updating the working state and the real-time charging power of the charging pile configuration list according to the received third acquired data; the first pipe transporting platform is also used for periodically carrying out data acquisition on the total power of network charging requirements to obtain corresponding fourth acquired data and sending the fourth acquired data to the power regulation platform;

The power regulation and control platform is used for storing the first acquired data sent by the transformer into a corresponding first transformer data list; the power regulation and control platform is further used for storing the second acquired data sent by each first circuit breaker into a corresponding first circuit breaker data list; the power regulation and control platform is also used for storing the fourth acquired data sent by each first pipe conveying platform into a corresponding first pipe conveying platform data list; the power regulation and control platform is further used for confirming a corresponding full-network power regulation and control threshold P ₀,P₀＝a*P_max according to a preset rated power P _max of the transformer, wherein a is a preset proportionality coefficient; the power regulation and control platform is further configured to set a preset total network real-time total power parameter P ₁ and a total network available total power parameter P ₂ according to the total network power regulation and control threshold P ₀, the first transformer data list and all the first breaker data lists; the power regulation and control platform is further used for setting a preset total power demand parameter P ₃ of the whole network according to all the first transportation platform data lists; the power regulation and control platform is further used for periodically carrying out full-network power regulation and control processing according to the full-network real-time total power parameter P ₁, the full-network available total power parameter P ₂ and the full-network required total power parameter P ₃ to obtain corresponding network regulation and control instructions and sending the corresponding network regulation and control instructions to each first pipe transportation platform;

The first pipe transporting platform is further used for carrying out network charging power regulation and control processing according to the network regulation and control instruction to generate corresponding charging pile regulation and control instructions and sending the corresponding charging pile regulation and control instructions to each first charging pile; the first charging pile is further used for carrying out charging pile power regulation and control processing according to the charging pile regulation and control instruction.

Preferably, the first collected data includes a first timestamp and a first full-network real-time power P _T,R;

The second acquired data comprises a second timestamp, a first network identifier and a first network real-time power P _N,R;

The third collected data comprises a third timestamp, a first charging pile identifier, a first charging pile type, a first working state and a first real-time charging power P _C,R; the first working state comprises a charging state and an uncharged state; the first charging pile type comprises a direct current type and an alternating current type;

The fourth collected data comprises a fourth timestamp, a second network identifier and a first network demand total power P _Q;

The charging pile configuration list comprises a plurality of charging pile configuration records; the charging pile configuration record comprises a charging pile identification field, a charging pile type field, a working state field, a rated charging power field, a maximum charging power field and a real-time charging power field; the charging pile type field comprises a direct current type and an alternating current type; the working state field comprises a charging state and an uncharged state;

The first operation application comprises a fifth time stamp, a second charging pile identifier and a first application type; the first application type includes a start charge type and a stop charge type.

Preferably, the transformer is specifically configured to periodically measure the real-time output power of the transformer to obtain the corresponding first full-network real-time power P _T,R when the data of the real-time output power of the transformer is acquired to obtain the corresponding first acquired data and the corresponding first acquired data is sent to the power regulation platform; taking the current acquisition time as the corresponding first timestamp; and the first acquired data corresponding to the first timestamp and the first full-network real-time power P _T,R obtained at the present time are sent to the power regulation platform.

Preferably, the first circuit breaker is specifically configured to periodically measure the real-time output power of the first circuit breaker to obtain the corresponding first network real-time power P _N,R when the second data acquired by periodically collecting the real-time output power of the first circuit breaker is sent to the power regulation platform; extracting a locally preset charging network identification parameter to serve as a corresponding first network identification; and taking the current acquisition time as the corresponding second time stamp; and the second acquired data corresponding to the second timestamp, the first network identifier and the first network real-time power P _N,R which are obtained at the present time are sent to the power regulation platform.

Preferably, the first charging pile is specifically configured to identify, when the third collected data obtained by periodically collecting real-time data of the first charging pile is sent to the first pipe conveying platform, whether the first charging pile is currently in a charging state, if so, set the corresponding first working state as a charging state, and if not, set the corresponding first working state as an uncharged state; when the first working state is a charging state, measuring the real-time output power of the device to obtain the corresponding first real-time charging power P _C,R; setting the corresponding first real-time charging power P _C,R to 0 when the first working state is an uncharged state; extracting a locally preset charging pile identification parameter and a charging pile type parameter to serve as the corresponding first charging pile identification and first charging pile type; and taking the current acquisition time as the corresponding third timestamp; the third acquired data corresponding to the third timestamp, the first charging pile identifier, the first charging pile type, the first working state and the first real-time charging power P _C,R are formed and sent to the power regulation platform;

The first charging pile is specifically configured to extract a local preset maximum charging power parameter of the charging pile as a corresponding current charging power threshold when the new energy automobile is charged, and control real-time charging power to be below the current charging power threshold when the new energy automobile is charged.

Preferably, each first user APP is configured to use, when a user selects one of the first charging piles to operate, the currently selected first charging pile as a corresponding current charging pile; identifying the charging pile identification information of the current charging pile by a preset charging pile identification mode to obtain a corresponding second charging pile identification; extracting the operation mode of the charging pile selected by the user at present as a corresponding first mode; the first mode is identified, if the first mode is a charging operation mode, the corresponding first application type is set to be a starting charging type, and if the first mode is a stopping charging operation mode, the corresponding first application type is set to be a stopping charging type; and taking the current operation time as the corresponding fifth timestamp; and the fifth timestamp, the second charging pile identifier and the first application type obtained by the current operation form a corresponding first operation application to be sent to the first pipe transporting platform.

Preferably, the first pipe transporting platform is specifically configured to extract, when the working state update process is performed on a preset charging pile configuration list according to the first operation application sent by each first user APP, the second charging pile identifier and the first application type from the first operation application received at the present time as corresponding current charging pile identifier and current application type; and taking the charging pile configuration record matched with the current charging pile identifier in the charging pile configuration list as a corresponding current charging pile configuration record; the current application type is identified, if the current application type is a start charging type, the working state field of the current charging pile configuration record is set to be in a charging state, and if the current application type is a stop charging type, the working state field of the current charging pile configuration record is set to be in an uncharged state;

The first pipe transporting platform is specifically configured to use the third acquired data received latest as corresponding current third acquired data when the charging pile configuration list is subjected to working state and real-time charging power update processing according to the received third acquired data; extracting the first charging pile identifier, the first charging pile type, the first working state and the first real-time charging power P _C,R of the current third acquired data as corresponding current charging pile identifier, current charging pile type, current working state and current real-time charging power; the charging pile configuration record in the charging pile configuration list, wherein the charging pile identification field is matched with the current charging pile identification, and the charging pile type field is matched with the current charging pile type, is used as a corresponding current charging pile configuration record; setting the working state field and the real-time charging power field of the current charging pile configuration record to be the corresponding current working state and current real-time charging power;

The first pipe transporting platform is specifically configured to record the charging pile configuration record with the working state field being a charging state in the charging pile configuration list as a corresponding requirement record when the fourth acquired data obtained by periodically acquiring the total power of network charging requirements is sent to the power regulating platform; extracting the maximum charging power field of each requirement record to serve as corresponding required charging power; and performing sum calculation on all the obtained required charging power to obtain a corresponding first power sum s ₁; and taking the first power sum s ₁ as the corresponding first network demand total power P _Q; extracting a locally preset charging network identification parameter to serve as a corresponding second network identification; and taking the current acquisition time as the corresponding fourth timestamp; and the fourth timestamp, the second network identifier and the total power P _Q of the first network demand which are obtained at present form corresponding fourth acquisition data to be sent to the power regulation platform.

Preferably, the power regulation and control platform is specifically configured to extract the first acquired data with the latest time in the first transformer data list as corresponding latest first acquired data when the preset full-network real-time total power parameter P ₁ and the full-network available total power parameter P ₂ are set according to the full-network power regulation and control threshold P ₀, the first transformer data list and all the first breaker data lists, and set the full-network real-time total power parameter P ₁ based on the first full-network real-time power P _T,R of the latest first acquired data; extracting the first network real-time power P _N,R of the second acquired data with the latest time in each first breaker data list as corresponding first real-time power, summing all the first real-time power to obtain corresponding second total power s ₂, and setting the total network available total power parameter P ₂ according to the total network power regulation threshold P ₀, the total network real-time total power parameter P ₁ and the second total power s ₂, and P ₂＝P₀-(P₁-s₂);

The power regulation and control platform is specifically configured to extract, as a corresponding first required total power, the first network required total power P _Q of the fourth collected data with the latest time in each first pipe transportation platform data list when the preset total network required total power parameter P ₃ is set according to all the first pipe transportation platform data lists; and performing total calculation on all the first required total power to obtain a corresponding third total power s ₃; and setting the total power demand parameter P ₃ of the whole network according to the third total power s ₃, and P ₃＝s₃.

Preferably, the power regulation and control platform is specifically configured to identify, when the network regulation and control instruction corresponding to the network regulation and control instruction obtained by performing the whole network power regulation and control process on the whole network real-time total power parameter P ₁, the whole network available total power parameter P ₂, and the whole network required total power parameter P ₃, whether the whole network required total power parameter P ₃ is smaller than the whole network available total power parameter P ₂ or not at regular intervals; if the total power parameter P ₃ of the whole network demand is smaller than the total power parameter P ₂ of the whole network, setting the corresponding regulation mode parameter as a full-load regulation mode; if the total network demand total power parameter P ₃ is greater than or equal to the total network available total power parameter P ₂, identifying whether the total network real-time total power parameter P ₁ is less than the total network available total power parameter P ₂, if the total network real-time total power parameter P ₁ is less than the total network available total power parameter P ₂, setting the corresponding regulation mode parameter as an uplink regulation mode, and if the total network real-time total power parameter P ₁ is greater than or equal to the total network available total power parameter P ₂, setting the corresponding regulation mode parameter as a downlink regulation mode;

when the regulation mode parameter is a full-load regulation mode, setting a previous local preset regulation mode as the full-load regulation mode; the network regulation and control instructions carrying the regulation and control mode parameters are sent to the first pipe transportation platforms of the first charging networks;

When the regulation mode parameter is an uplink regulation mode, setting the locally preset previous regulation mode as an uplink regulation mode; extracting the total power P _Q of the first network demand of the fourth acquired data with the latest time in each first pipe transporting platform data list as corresponding first network demand power P _Q,i, wherein the network index i is an integer larger than 0; calculating a corresponding first network maximum up-regulation total power P _u,i,P_u,i＝P₂*(P_Q,i/P₃ based on each of the first network required power P _Q,i, the total network required total power parameter P ₃ and the total network available total power parameter P ₂; the network regulation and control instruction carrying the regulation and control mode parameters and the maximum up-regulation total power P _u,i of the first network is sent to the first pipe conveying platform of each corresponding first charging network;

When the regulation mode parameter is a downlink regulation mode, calculating the absolute difference between the total network real-time total power parameter P ₁ and the total network available total power parameter P ₂ to obtain a corresponding current downlink regulation power sum P ₄; extracting the local preset previous regulation and control mode to serve as a corresponding previous mode; setting the previous regulation mode as a downlink regulation mode after the previous mode is obtained; and identifying the previous pattern; if the previous mode is a full-load regulation mode, extracting the first network real-time power P _N,R of the second acquired data with the latest time in each first breaker data list as corresponding first network real-time power P _N,i, calculating corresponding first network minimum down-regulating total power P _d,i,P_d,i＝P₄*(P_N,i/P₁ based on each first network real-time power P _N,i, the whole network real-time total power parameter P ₁ and the current down-regulating total power P ₄), and sending the network regulation instruction carrying the regulation mode parameter and the first network minimum down-regulating total power P _d,i to the corresponding first pipe-transporting platform of each first charging network; if the previous mode is not the full-load regulation mode, extracting the first network demand total power P _Q of the fourth collected data with the latest time in each first pipe transporting platform data list as the corresponding first network demand power P _Q,i, calculating the corresponding first network minimum down-regulating total power P _d,i,P_d,i＝P₄*(P_N,i/P₃ based on each first network demand power P _Q,i, the total network demand total power parameter P ₃ and the current down-regulating power sum P ₄, and sending the network regulation instruction carrying the regulation mode parameter and the first network minimum down-regulating total power P _d,i to the first pipe transporting platform of each corresponding first charging network.

Preferably, the first pipe transporting platform is specifically configured to, when the network charging power regulation and control processing is performed according to the network regulation and control instruction to generate a corresponding charging pile regulation and control instruction, send the corresponding charging pile regulation and control instruction to each first charging pile, take the currently received network regulation and control instruction as a corresponding current network regulation and control instruction; extracting the regulation mode parameters from the current network regulation instruction to serve as corresponding charging pile regulation mode parameters;

Counting the number of the charging pile configuration records in the charging pile configuration list to obtain a corresponding first record total number;

Recording the charging pile configuration record with the charging pile type field being of a direct current type and the working state field being of a charging state in the charging pile configuration list as a corresponding direct current charging pile record, and calculating the sum of the maximum charging power fields of all the direct current charging pile records to obtain a corresponding first direct current power sum; recording the charging pile configuration records with the charging pile type field being an alternating current type and the working state field being a charging state in the charging pile configuration list as corresponding alternating current charging pile records, and calculating the sum of the maximum charging power fields of all the alternating current charging pile records to obtain corresponding first alternating current power sum;

traversing each charging pile configuration record of the charging pile configuration list; the charging pile configuration record of the current traversal is used as a corresponding current configuration record, and the first charging pile corresponding to the current configuration record is used as a corresponding current charging pile; identifying the regulation and control mode parameters of the charging pile;

if the charging pile regulation and control mode parameter is a full-load regulation and control mode, setting the maximum charging power field of the current configuration record as the corresponding rated charging power field; extracting the set maximum charging power field as a corresponding charging pile power configuration parameter; transmitting the charging pile regulation and control instruction carrying the charging pile power configuration parameters to the current charging pile;

If the charging pile regulation and control mode parameter is an uplink regulation and control mode, extracting the rated charging power field and the maximum charging power field of the current configuration record as corresponding current rated power and power before uplink regulation; extracting the corresponding maximum up-regulating total power P _u,i of the first network from the current network regulation and control instruction as the corresponding current maximum up-regulating total power; and performing downward rounding on the quotient of the current maximum upregulation total power divided by the total number of the first records to obtain corresponding average upregulation power; adding the power before up-regulation and the average power after up-regulation to obtain corresponding power after up-regulation; and identifying whether the up-regulated power exceeds the corresponding current rated power; if yes, setting the maximum charging power field of the current configuration record as the corresponding current rated power; if not, setting the maximum charging power field of the current configuration record as the corresponding power after the up-regulation; extracting the set maximum charging power field to serve as a corresponding charging pile power configuration parameter; transmitting the charging pile regulation and control instruction carrying the charging pile power configuration parameters to the current charging pile;

If the charging pile regulation and control mode parameter is a downlink regulation and control mode, extracting the maximum charging power field of the current configuration record as corresponding power before downlink regulation; extracting the corresponding minimum down-regulating total power P _d,i of the first network from the current network regulation and control instruction as the corresponding current minimum down-regulating total power; performing AC/DC down-regulation proportion estimation processing according to the first AC power sum, the first DC power sum and the current minimum down-regulation total power to obtain corresponding current AC down-regulation proportion and current DC down-regulation proportion; identifying whether the current configuration record is recorded as the corresponding alternating current charging pile record or the direct current charging pile record; if the current configuration record is recorded as the corresponding ac charging pile record, calculating corresponding first power after downregulation=power before downregulation (1-current ac downregulation ratio) according to the power before downregulation and the current ac downregulation ratio, setting the maximum charging power field of the current configuration record as the corresponding first power after downregulation, extracting the set maximum charging power field as the corresponding charging pile power configuration parameter, and sending the charging pile regulation instruction carrying the charging pile power configuration parameter to the current charging pile; if the current configuration record is recorded as the corresponding direct current charging pile record, calculating corresponding second power after downregulation=power before downregulation (1-current direct current downregulation ratio) according to the power before downregulation and the current direct current downregulation ratio when the current direct current downregulation ratio is not 0, setting the maximum charging power field of the current configuration record as the corresponding second power after downregulation, extracting the set maximum charging power field as the corresponding charging pile power configuration parameter, and sending the charging pile regulation instruction carrying the charging pile power configuration parameter to the current charging pile.

Further, the first pipe transporting platform is specifically configured to, when the ac-dc down-regulation proportion is estimated according to the first ac power sum, the first dc power sum, and the current minimum down-regulation total power to obtain a corresponding current ac-dc down-regulation proportion and a corresponding current dc-dc down-regulation proportion,

Step 111, extracting a first downregulation ratio of a preset first downregulation ratio sequence as a corresponding first alternating current downregulation ratio; extracting a first second downregulation proportion of a preset second downregulation proportion sequence to serve as a corresponding first direct-current downregulation proportion; the first downregulation proportion sequence comprises a plurality of first downregulation proportions, and each first downregulation proportion is a percentage value with a value larger than 0 but smaller than 1; the second downregulation proportion sequence comprises a plurality of second downregulation proportions, wherein a first second downregulation proportion is 0%, and all the second downregulation proportions except the first second downregulation proportion are percentage values with values larger than 0 and smaller than 1;

Step 112, taking the product of the first ac down-regulation ratio and the first ac power sum as the corresponding first ac down-regulation power; identifying whether the first alternating current down-regulating power is smaller than the current minimum down-regulating total power; if yes, extracting the next second downregulation proportion in the second downregulation proportion sequence as a new first direct current downregulation proportion, and turning to step 113; if not, go to step 114;

Step 113, taking the product of the first direct current down-regulation ratio and the first direct current power sum as a corresponding first direct current down-regulation power; taking the sum of the first AC down-regulating power and the first DC down-regulating power as the corresponding first AC down-regulating power sum; identifying whether the sum of the first alternating current-direct current down-regulating power is smaller than the current minimum down-regulating total power; if yes, extracting the next first downturn ratio in the first downturn ratio sequence as a new first alternating current downturn ratio, and returning to step 112; if not, go to step 114;

And 114, outputting the current latest first alternating current down-regulation proportion and the first direct current down-regulation proportion as the corresponding current alternating current down-regulation proportion and the current direct current down-regulation proportion.

Preferably, the first charging pile is specifically configured to extract, when the charging pile power regulation and control process is performed according to the charging pile regulation and control instruction, the charging pile power configuration parameter from the currently received charging pile regulation and control instruction as a corresponding current configuration parameter; and setting the local preset maximum charging power parameter of the charging pile as the corresponding current configuration parameter.

The embodiment of the invention provides a processing system for regulating and controlling power of a charging pile, which comprises the following steps: the system comprises a transformer, a power regulation platform, a plurality of first charging networks and a plurality of first user APP; each first charging network comprises a first pipe transporting platform, a first circuit breaker and a plurality of first charging piles; the power regulation and control platform can regulate and control the whole network power according to the collected data of the transformer and each first charging network side and output three power regulation and control modes: the first operation platform can dynamically regulate and control the charging power of each first charging pile of the first charging network in a designated regulation mode. Therefore, the system provided by the invention realizes the function of regulating and controlling the power of the charging pile network.

Drawings

Fig. 1 is a schematic structural diagram of a processing system for power regulation of a charging pile according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The embodiment of the invention provides a processing system for power regulation and control of a charging pile, as shown in fig. 1, which is a schematic structural diagram of the processing system for power regulation and control of a charging pile, and mainly comprises: the power control system comprises a transformer 1, a power control platform 2, a plurality of first charging networks 3 and a plurality of first user APP4; each first charging network 3 comprises a first pipe handling platform 31, a first circuit breaker 32 and a plurality of first charging piles 33.

A transformer 1

The transformer 1 is connected to an external power supply network via a power line, to the first circuit breakers 32 of the respective first charging networks 3 via power lines, and to the power conditioning platform 2 via data lines.

The transformer 1 in the embodiment of the invention is an intelligent transformer with the functions of power consumption analysis and data acquisition, and can also be a conventional transformer externally connected with a power consumption analysis module and a data acquisition module.

The transformer 1 is used to take power from an external power supply network through a power line and to output power to the first circuit breaker 32 of each first charging network 3 through the power line.

The transformer 1 is also used for regularly carrying out data acquisition on the real-time output power of the transformer to obtain corresponding first acquisition data and sending the corresponding first acquisition data to the power regulation and control platform 2;

The first collected data includes a first timestamp and a first full-network real-time power P _T,R.

In a specific implementation manner of the embodiment of the present invention, the transformer 1 is specifically configured to periodically measure the real-time output power of itself to obtain the corresponding first full-network real-time power P _T,R when periodically acquiring the data of the real-time output power of itself to obtain the corresponding first acquired data and sending the corresponding first acquired data to the power regulation platform 2; taking the current acquisition time as a corresponding first timestamp; and the corresponding first acquired data consisting of the first timestamp obtained at present and the first full-network real-time power P _T,R is sent to the power regulation and control platform 2.

(Two) first charging network 3

Each first breaker 32 is connected with each first charging pile 33 in the same charging network through a power line, is connected with the power regulation and control platform 2 through a data line, and is connected with the first pipe conveying platform 31 in the same charging network through a data line.

Here, the first circuit breaker 32 in the embodiment of the present invention is an intelligent circuit breaker with the functions of power consumption analysis and data acquisition, and may be a conventional circuit breaker externally connected with a power consumption analysis module and a data acquisition module.

The first circuit breaker 32 is used for power output to the first charging pile 33 through a power line.

The first circuit breaker 32 is further configured to periodically perform data acquisition on the real-time output power of the first circuit breaker to obtain corresponding second acquired data, and send the corresponding second acquired data to the power regulation platform 2;

The second collected data includes a second timestamp, a first network identifier, and a first network real-time power P _N,R.

In another specific implementation manner of the embodiment of the present invention, the first circuit breaker 32 is specifically configured to periodically measure the real-time output power of itself to obtain the corresponding first network real-time power P _N,R when periodically performing data acquisition on the real-time output power of itself to obtain corresponding second acquired data to send the second acquired data to the power regulation platform 2; extracting a locally preset charging network identification parameter to serve as a corresponding first network identification; and taking the current acquisition time as a corresponding second timestamp; and the second acquired data corresponding to the second timestamp, the first network identifier and the first network real-time power P _N,R obtained at the present time are sent to the power regulation platform 2.

Each first charging pile 33 is connected to a first pipe platform 31 in the same charging network by a data line.

Here, the first charging pile 33 in the embodiment of the present invention is an intelligent charging pile with data analysis, data acquisition and charging functions, and the types of the first charging pile 33 are two: alternating current fills electric pile and direct current fills electric pile.

The first charging pile 33 is configured to periodically perform real-time data acquisition on the first charging pile to obtain corresponding third acquired data, and send the third acquired data to the first pipe conveying platform 31;

The third collected data comprises a third timestamp, a first charging pile identifier, a first charging pile type, a first working state and a first real-time charging power P _C,R; the first operating state includes a charged state and an uncharged state; the first charging pile type includes a direct current type and an alternating current type.

In another specific implementation manner of the embodiment of the present invention, the first charging pile 33 is specifically configured to, when sending the third collected data obtained by periodically collecting the real-time data of itself to the first pipe transporting platform 31, periodically identify whether the first charging pile is currently in a charging state, if so, set the corresponding first working state to be a charging state, and if not, set the corresponding first working state to be an uncharged state; when the first working state is a charging state, measuring the real-time output power of the power supply to obtain corresponding first real-time charging power P _C,R; setting the corresponding first real-time charging power P _C,R to 0 when the first working state is an uncharged state; extracting a locally preset charging pile identification parameter and a charging pile type parameter to serve as a corresponding first charging pile identification and a first charging pile type; and taking the current acquisition time as a corresponding third timestamp; and the third acquired data corresponding to the third timestamp, the first charging pile identifier, the first charging pile type, the first working state and the first real-time charging power P _C,R are formed and sent to the power regulation and control platform 2.

The first charging pile 33 is also used for charging the new energy automobile.

In another specific implementation manner of the embodiment of the present invention, the first charging pile 33 is specifically configured to extract a local preset maximum charging power parameter of the charging pile as a corresponding current charging power threshold when the new energy automobile is charged, and control the real-time charging power to be below the current charging power threshold when the new energy automobile is charged.

Here, each first charging pile 33 according to the embodiment of the present invention locally stores a charging pile maximum charging power parameter, which is used to limit the real-time charging power.

Each first pipe carrying platform 31 is connected with the power regulation and control platform 2 through a data line, and is also connected with each first user APP4 through a data line.

The first management platform 31 is configured to update a preset charging pile configuration list according to a first operation application sent by each first user APP 4;

the first operation application comprises a fifth time stamp, a second charging pile identifier and a first application type; the first application type includes a start charge type and a stop charge type.

Here, it should be noted that, when the user selects one first charging pile 33 to operate, each first user APP4 uses the currently selected first charging pile 33 as the corresponding current charging pile; identifying the charging pile identification information of the current charging pile by a preset charging pile identification mode to obtain a corresponding second charging pile identification; extracting the operation mode of the charging pile selected by the user at present as a corresponding first mode; the first mode is identified, if the first mode is a charging operation mode, the corresponding first application type is set as a starting charging type, and if the first mode is a stopping charging operation mode, the corresponding first application type is set as a stopping charging type; and taking the current operation time as a corresponding fifth timestamp; and a corresponding first operation application composed of the fifth timestamp obtained by the current operation, the second charging pile identifier and the first application type is sent to the first pipe transporting platform 31.

It should be further noted that, the charging pile configuration list in the embodiment of the present invention includes a plurality of charging pile configuration records, where each charging pile configuration record corresponds to one first charging pile 33; the charging pile configuration record comprises a charging pile identification field, a charging pile type field, a working state field, a rated charging power field, a maximum charging power field and a real-time charging power field; the charging pile type field comprises a direct current type and an alternating current type; the operating state field includes a charged state and an uncharged state.

In another specific implementation manner of the embodiment of the present invention, the first pipe transporting platform 31 is specifically configured to extract, when a preset charging pile configuration list is subjected to a working state update process according to a first operation application sent by each first user APP4, a second charging pile identifier and a first application type from a first operation application received at the present time as corresponding current charging pile identifier and current application type; taking a charging pile configuration record matched with the current charging pile identification in the charging pile configuration list as a corresponding current charging pile configuration record; and identifying the current application type, if the current application type is a start charging type, setting the working state field of the current charging pile configuration record as a charging state, and if the current application type is a stop charging type, setting the working state field of the current charging pile configuration record as an uncharged state.

The first pipe transporting platform 31 is further configured to update the working state and the real-time charging power of the charging pile configuration list according to the received third collected data.

In another specific implementation manner of the embodiment of the present invention, the first pipe transporting platform 31 is specifically configured to use the latest received third collected data as the corresponding current third collected data when the working state and the real-time charging power update processing are performed on the charging pile configuration list according to the received third collected data; extracting a first charging pile identifier, a first charging pile type, a first working state and a first real-time charging power P _C,R of the current third acquired data as corresponding current charging pile identifier, current charging pile type, current working state and current real-time charging power; and taking a charging pile configuration record in which a charging pile identification field in the charging pile configuration list is matched with the current charging pile identification and a charging pile type field is matched with the current charging pile type as a corresponding current charging pile configuration record; and setting the working state field and the real-time charging power field of the current charging pile configuration record as the corresponding current working state and current real-time charging power.

The first pipe transporting platform 31 is further configured to periodically perform data acquisition on the total power of the network charging demand, so as to obtain corresponding fourth acquired data, and send the fourth acquired data to the power regulation and control platform 2;

The fourth collected data includes a fourth timestamp, a second network identifier, and a total power of first network requirements P _Q.

In another specific implementation manner of the embodiment of the present invention, the first pipe transporting platform 31 is specifically configured to record, as a corresponding requirement record, a charging pile configuration record in which a working state field in the charging pile configuration list is a charging state when data acquisition is performed on total power of network charging requirements at regular intervals to obtain corresponding fourth acquisition data and the fourth acquisition data is sent to the power regulating platform 2; extracting the maximum charging power field of each requirement record as corresponding required charging power; and performing sum calculation on all the obtained required charging power to obtain a corresponding first power sum s ₁; and taking the first power sum s ₁ as the corresponding first network demand total power P _Q; extracting a locally preset charging network identification parameter to serve as a corresponding second network identification; and taking the current acquisition time as a corresponding fourth timestamp; and the fourth acquired data corresponding to the fourth timestamp, the second network identifier and the total power P _Q of the first network requirement are formed by the fourth timestamp, the second network identifier and the total power P _Q of the first network requirement, and are sent to the power regulation platform 2.

(III) Power Conditioning platform 2

The power regulation and control platform 2 is used for storing the first acquired data sent by the transformer 1 into a corresponding first transformer data list. The power regulation platform 2 is further configured to store the second collected data sent by each first circuit breaker 32 into a corresponding first circuit breaker data list. The power regulation and control platform 2 is further configured to store fourth collected data sent by each first pipe transportation platform 31 into a corresponding first pipe transportation platform data list.

The power regulation platform 2 is further configured to confirm the corresponding full-network power regulation threshold P ₀ according to the preset rated power P _max of the transformer 1,

Wherein P ₀＝a*P_max, a is a preset scaling factor.

Here, the proportionality coefficient a may be set to 80% in a conventional case.

The power regulation platform 2 is further configured to set a preset total network real-time total power parameter P ₁ and a total network available total power parameter P ₂ according to the total network power regulation threshold P ₀, the first transformer data list and all the first breaker data lists.

In another specific implementation manner of the embodiment of the present invention, the power regulation platform 2 is specifically configured to, when the preset total network real-time total power parameter P ₁ and the total network available total power parameter P ₂ are set according to the total network power regulation threshold P ₀, the first transformer data list and all the first breaker data lists:

Step A1, extracting first acquired data with the latest time in a first transformer data list as corresponding latest first acquired data, and setting a whole-network real-time total power parameter P ₁ based on a first whole-network real-time power P _T,R of the latest first acquired data;

And step A2, extracting the first network real-time power P _N,R of the second acquired data with the latest time in each first breaker data list as corresponding first real-time power, summing all the first real-time power to obtain corresponding second total power s ₂, and setting the total network available total power parameter P ₂ according to the total network power regulation threshold P ₀, the total network real-time total power parameter P ₁ and the second total power s ₂, and P ₂＝P₀-(P₁-s₂).

The power regulation and control platform 2 is further configured to set a preset total power demand parameter P ₃ of the whole network according to all the first management platform data lists.

In another specific implementation manner of the embodiment of the present invention, the power regulation platform 2 is specifically configured to, when the preset total power required parameter P ₃ of the whole network is set according to all the first pipe transportation platform data lists:

Step B1, extracting the first network demand total power P _Q of the fourth acquired data with the latest time in each first transportation platform data list as corresponding first demand total power;

step B2, performing total calculation on the total power of all the first requirements to obtain corresponding third total power s ₃; and setting the total power demand parameter P ₃ of the whole network according to the third total power s ₃, and P ₃＝s₃.

The power regulation and control platform 2 is further configured to perform full-network power regulation and control processing periodically according to the full-network real-time total power parameter P ₁, the full-network available total power parameter P ₂, and the full-network required total power parameter P ₃, so as to obtain a corresponding network regulation and control instruction, and send the corresponding network regulation and control instruction to each first pipe transportation platform 31.

In another specific implementation manner of the embodiment of the present invention, the power regulation platform 2 is specifically configured to, when performing the whole network power regulation processing according to the whole network real-time total power parameter P ₁, the whole network available total power parameter P ₂, and the whole network required total power parameter P ₃ to obtain the corresponding network regulation instruction, send the network regulation instruction to each first pipe transport platform 31:

Step C1, periodically identifying whether the total power parameter P ₃ required by the whole network is smaller than the total power parameter P ₂ available by the whole network;

if the total power parameter P ₃ of the whole network demand is smaller than the total power parameter P ₂ of the whole network, setting the corresponding regulation mode parameter as a full-load regulation mode;

If the total network demand total power parameter P ₃ is greater than or equal to the total network available total power parameter P ₂, identifying whether the total network real-time total power parameter P ₁ is smaller than the total network available total power parameter P ₂, setting a corresponding regulation mode parameter as an uplink regulation mode if the total network real-time total power parameter P ₁ is smaller than the total network available total power parameter P ₂, and setting a corresponding regulation mode parameter as a downlink regulation mode if the total network real-time total power parameter P ₁ is greater than or equal to the total network available total power parameter P ₂;

Step C2, when the regulation mode parameter is a full-load regulation mode, setting a previous local preset regulation mode as the full-load regulation mode; and sends the network regulation and control instruction carrying the regulation and control mode parameters to the first pipe conveying platform 31 of each first charging network 3;

Step C3, when the regulation mode parameter is an uplink regulation mode, setting a locally preset previous regulation mode as the uplink regulation mode; extracting the first network demand total power P _Q of the fourth acquired data with the latest time in each first transport management platform data list as corresponding first network demand power P _Q,i, wherein the network index i is an integer greater than 0; and calculating a corresponding first network maximum up-regulation total power P _u,i,P_u,i＝P₂*(P_Q,i/P₃ based on each first network required power P _Q,i, the total network required total power parameter P ₃ and the total network available total power parameter P ₂); the network regulation and control instruction carrying the regulation and control mode parameters and the maximum up-regulation total power P _u,i of the first network is sent to the first pipe conveying platform 31 of each corresponding first charging network 3;

Step C4, when the regulation mode parameter is a downlink regulation mode, calculating the absolute difference between the total network real-time total power parameter P ₁ and the total network available total power parameter P ₂ to obtain a corresponding current downlink regulation power sum P ₄; extracting a local preset previous regulation mode to serve as a corresponding previous mode; setting the previous regulation mode as a downlink regulation mode after the previous mode is obtained; and identifying the previous mode;

If the previous mode is the full-load regulation mode, extracting the first network real-time power P _N,R of the second acquired data with the latest time in each first breaker data list as corresponding first network real-time power P _N,i, calculating corresponding first network minimum down-regulation total power P _d,i,P_d,i＝P₄*(P_N,i/P₁ based on each first network real-time power P _N,i, the total network real-time total power parameter P ₁ and the current down-regulation power sum P ₄), and sending a network regulation instruction carrying the regulation mode parameter and the first network minimum down-regulation total power P _d,i to the first pipe-conveying platform 31 of each corresponding first charging network 3;

If the previous mode is not the full-load regulation mode, extracting the first network demand total power P _Q of the fourth acquired data with the latest time in the data list of each first pipe transporting platform as corresponding first network demand power P _Q,i, calculating the corresponding first network minimum downregulating total power P _d,i,P_d,i＝P₄*(P_N,i/P₃ based on each first network demand power P _Q,i, the total network demand total power parameter P ₃ and the current downregulating power sum P ₄), and sending a network regulation instruction carrying the regulation mode parameter and the first network minimum downregulating total power P _d,i to the first pipe transporting platform 31 of each corresponding first charging network 3.

Correspondingly, after the first pipe transporting platform 31 of each first charging network 3 receives the network regulation and control instruction issued by the power regulation and control platform 2, the first pipe transporting platform 31 is further configured to perform network charging power regulation and control processing according to the network regulation and control instruction to generate a corresponding charging pile regulation and control instruction, and send the charging pile regulation and control instruction to each first charging pile 33.

In another specific implementation manner of the embodiment of the present invention, the first pipe transporting platform 31 is specifically configured to, when performing network charging power regulation processing according to the network regulation command to generate a corresponding charging pile regulation command, send the charging pile regulation command to each first charging pile 33:

Step D1, taking the currently received network regulation instruction as a corresponding current network regulation instruction; extracting a regulation mode parameter from the current network regulation instruction as a corresponding charging pile regulation mode parameter;

Step D2, counting the number of the charging pile configuration records in the charging pile configuration list to obtain a corresponding first record total number;

Step D3, recording a charging pile configuration record with a charging pile type field of a direct current type and a working state field of a charging state in a charging pile configuration list as a corresponding direct current charging pile record, and carrying out sum calculation on the maximum charging power fields of all the direct current charging pile records to obtain a corresponding first direct current power sum; recording a charging pile configuration record with the charging pile type field being an alternating current type and the working state field being a charging state in a charging pile configuration list as a corresponding alternating current charging pile record, and performing sum calculation on the maximum charging power field of all the alternating current charging pile records to obtain a corresponding first alternating current power sum;

step D4, traversing each charging pile configuration record of the charging pile configuration list; and traversing, taking the configuration record of the charging pile which is traversed currently as a corresponding current configuration record, and taking the first charging pile 33 corresponding to the current configuration record as a corresponding current charging pile; identifying the regulation and control mode parameters of the charging pile;

If the regulation and control mode parameter of the charging pile is the full-load regulation and control mode, setting the maximum charging power field of the current configuration record as a corresponding rated charging power field; extracting the set maximum charging power field as a corresponding charging pile power configuration parameter; transmitting a charging pile regulation and control instruction carrying the charging pile power configuration parameters to the current charging pile;

If the charging pile regulation and control mode parameter is an uplink regulation and control mode, extracting a rated charging power field and a maximum charging power field of the current configuration record as corresponding current rated power and power before uplink regulation; extracting the corresponding maximum up-regulating total power P _u,i of the first network from the current network regulation instruction as the corresponding current maximum up-regulating total power; and performing downward rounding on the quotient of the current maximum upward power divided by the total number of the first records to obtain corresponding average upward power; adding the power before the up-regulation and the average up-regulation power to obtain corresponding power after the up-regulation; and identifying whether the power after the up-regulation exceeds the corresponding current rated power; if yes, setting the maximum charging power field of the current configuration record as the corresponding current rated power; if not, setting the maximum charging power field of the current configuration record as the corresponding power after the up-regulation; extracting the set maximum charging power field as a corresponding charging pile power configuration parameter; transmitting a charging pile regulation and control instruction carrying the charging pile power configuration parameters to the current charging pile;

If the charging pile regulation and control mode parameter is a downlink regulation and control mode, extracting a maximum charging power field of the current configuration record as corresponding power before downregulation; extracting the corresponding minimum down-regulating total power P _d,i of the first network from the current network regulation instruction as the corresponding current minimum down-regulating total power; performing AC/DC down-regulation proportion estimation processing according to the first AC power sum, the first DC power sum and the current minimum down-regulation total power to obtain corresponding current AC down-regulation proportion and current DC down-regulation proportion; and identifying whether the current configuration record is recorded as a corresponding alternating current charging pile record or direct current charging pile record; if the current configuration record is recorded as the corresponding alternating current charging pile record, calculating corresponding first down-regulated power=down-regulated power (1-current alternating current down-regulated proportion) according to the down-regulated power and the current alternating current down-regulated proportion, setting the maximum charging power field of the current configuration record as the corresponding first down-regulated power, extracting the set maximum charging power field as a corresponding charging pile power configuration parameter, and sending a charging pile regulation instruction carrying the charging pile power configuration parameter to the current charging pile; if the current configuration record is recorded as the corresponding direct current charging pile record, when the current direct current down-regulation proportion is not 0, calculating corresponding second down-regulation post power=down-regulation pre-power (1-current direct current down-regulation proportion) according to the down-regulation pre-power and the current direct current down-regulation proportion, setting the maximum charging power field of the current configuration record as the corresponding second down-regulation post-power, extracting the set maximum charging power field as the corresponding charging pile power configuration parameter, and sending a charging pile regulation instruction carrying the charging pile power configuration parameter to the current charging pile.

In another specific implementation manner of the embodiment of the present invention, the first pipe transporting platform 31 is specifically configured to, when performing ac-dc down-regulation proportion estimation processing according to the first ac power sum, the first dc power sum, and the current minimum down-regulation total power to obtain the corresponding current ac-dc down-regulation proportion and the current dc-dc down-regulation proportion:

Step E1, extracting a first downregulation proportion of a preset first downregulation proportion sequence to serve as a corresponding first alternating current downregulation proportion; extracting a first second downregulation proportion of a preset second downregulation proportion sequence to serve as a corresponding first direct-current downregulation proportion;

The first downregulation proportion sequence comprises a plurality of first downregulation proportions, and each first downregulation proportion is a percentage value with a value larger than 0 but smaller than 1; the second down-regulating proportion sequence comprises a plurality of second down-regulating proportions, wherein the first second down-regulating proportion is 0%, and all the second down-regulating proportions except the first second down-regulating proportion are percentage values with values larger than 0 and smaller than 1;

E2, taking the product of the first AC down-regulating proportion and the sum of the first AC power as the corresponding first AC down-regulating power; identifying whether the first alternating current down-regulating power is smaller than the current minimum down-regulating total power; if yes, extracting the next second down-regulation proportion in the second down-regulation proportion sequence to be used as a new first direct-current down-regulation proportion, and turning to the step E3; if not, turning to the step E4;

step E3, taking the product of the first direct current down-regulating proportion and the sum of the first direct current power as the corresponding first direct current down-regulating power; taking the sum of the first AC-DC down-regulating power and the first DC-DC down-regulating power as the corresponding sum of the first AC-DC down-regulating power; identifying whether the sum of the first AC/DC down-regulating power is smaller than the current minimum down-regulating total power; if yes, extracting the next first downregulation proportion in the first downregulation proportion sequence to be used as a new first alternating current downregulation proportion, and returning to the step E2; if not, turning to the step E4;

And E4, taking the current latest first AC down-regulation proportion and the first DC down-regulation proportion as corresponding current AC down-regulation proportion and current DC down-regulation proportion to output.

Correspondingly, after each first charging pile 33 receives the charging pile regulation command issued by the first pipe conveying platform 31, the first charging pile 33 is further configured to perform charging pile power regulation processing according to the charging pile regulation command. In another specific implementation manner of the embodiment of the present invention, the first charging pile 33 is specifically configured to extract, when performing a charging pile power regulation process according to a charging pile regulation command, a charging pile power configuration parameter from a currently received charging pile regulation command as a corresponding current configuration parameter; and setting the local preset maximum charging power parameter of the charging pile as the corresponding current configuration parameter.

In addition, the power regulation platform 2 in the system of the embodiment of the present invention may have a disconnection or downtime in the actual operation, and when this occurs, the system of the embodiment of the present invention further designs two sets of corresponding emergency power consumption adjustment processing flows for each first pipe transportation platform 31:

The emergency power consumption adjustment processing flow comprises the following steps: each first pipe carrying platform 31 is further used for periodically checking the communication state with the power regulation platform 2, and once the communication interruption with the power regulation platform 2 is found, traversing the charging pile configuration records with each working state field being the charging state in the charging pile configuration list immediately; and traversing, taking the configuration record of the charging pile which is traversed currently as a corresponding current record, and taking a first charging pile 33 corresponding to the current record as a corresponding current charging pile; setting the maximum charging power field of the current record to be half of the corresponding rated charging power field; extracting the set maximum charging power field as a corresponding charging pile power configuration parameter; transmitting a charging pile regulation and control instruction carrying the charging pile power configuration parameter to a current charging pile;

the other set of emergency power consumption adjustment processing flow is as follows: each first pipe-transporting platform 31 is further used for timing the interruption time after confirming the communication interruption with the power regulation platform 2, and immediately sending a full-network circuit-breaking instruction to the first circuit breaker 32 once the interruption time exceeds a preset time threshold; correspondingly, each first breaker 32 is further configured to immediately disconnect the power lines of all the first charging piles 33 connected to itself when receiving the network-wide breaking command sent by the first pipe-handling platform 31, and reclose the power lines of all the first charging piles 33 connected to itself after stopping the power supply for a specified period of time.

In addition, in the system of the embodiment of the present invention, the first pipe transporting platform 31 of each first charging network 3 may also have a condition of failed regulation and control in actual operation, and when this occurs, the system of the embodiment of the present invention also designs a set of corresponding emergency power consumption adjustment processing flows for each first pipe transporting platform 31, that is: each first pipe transporting platform 31 is further configured to, after sending a charging pile regulation command to any first charging pile 33, take a charging pile power configuration parameter in the current charging pile regulation command as a corresponding first power; and storing a specified number of third acquired data subsequently uploaded by the current first charging pile 33 into the first data set; extracting each first real-time charging power P _C,R in the first data set as corresponding second power; identifying whether all the second power exceeds the first power, if so, taking the charging pile identification of the current first charging pile 33 as a corresponding first power-off charging pile identification, and sending a charging pile breaking instruction carrying the first power-off charging pile identification to the first circuit breaker 32; correspondingly, each first breaker 32 is further configured to extract a corresponding first outage charging pile identifier from the charging pile identifier when receiving a charging pile breaking instruction sent by the first pipe conveying platform 31, take a first charging pile 33 corresponding to the first outage charging pile identifier as a corresponding current outage charging pile, disconnect a power line of the current outage charging pile, and reclose the power line of the current outage charging pile after stopping power supply for a specified period of time.

It should be further noted that, in the embodiment of the present invention, any data line includes a wired communication data line and wireless communication data; the power line mentioned in the embodiment of the invention is a power supply line in a conventional power supply network.

The embodiment of the invention provides a processing system for regulating and controlling power of a charging pile, which comprises the following steps: the system comprises a transformer, a power regulation platform, a plurality of first charging networks and a plurality of first user APP; each first charging network comprises a first pipe transporting platform, a first circuit breaker and a plurality of first charging piles; the power regulation and control platform can regulate and control the whole network power according to the collected data of the transformer and each first charging network side and output three power regulation and control modes: the first operation platform can dynamically regulate and control the charging power of each first charging pile of the first charging network in a designated regulation mode. Therefore, the system provided by the invention realizes the function of regulating and controlling the power of the charging pile network.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative elements and steps are described above generally in terms of function in order to clearly illustrate the interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied in hardware, in a software module executed by a processor, or in a combination of the two. The software modules may be disposed in Random Access Memory (RAM), memory, read Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

The foregoing description of the embodiments has been provided for the purpose of illustrating the general principles of the invention, and is not meant to limit the scope of the invention, but to limit the invention to the particular embodiments, and any modifications, equivalents, improvements, etc. that fall within the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims (12)

1. A processing system for power regulation of a charging pile, the system comprising: the system comprises a transformer, a power regulation platform, a plurality of first charging networks and a plurality of first user APP; each first charging network comprises a first pipe transporting platform, a first circuit breaker and a plurality of first charging piles;

The transformer is connected with an external power supply network through a power line, is also connected with the first circuit breakers of the first charging networks through power lines, and is also connected with the power regulation and control platform through a data line; the transformer is used for taking electricity from the external power supply network through a power line and outputting power to the first circuit breakers of the first charging networks through the power line; the transformer is also used for regularly carrying out data acquisition on the real-time output power of the transformer to obtain corresponding first acquisition data and sending the corresponding first acquisition data to the power regulation platform;

Each first breaker is respectively connected with each first charging pile in the same charging network through a power line, is also connected with the power regulation and control platform through a data line, and is also connected with the first pipe conveying platform in the same charging network through a data line; the first circuit breaker is used for outputting power to the first charging pile through a power line; the first circuit breaker is also used for periodically acquiring data of the real-time output power of the first circuit breaker to obtain corresponding second acquired data and sending the corresponding second acquired data to the power regulation platform;

Each first charging pile is connected with the first pipe conveying platform in the same charging network through a data line; the first charging pile is used for periodically acquiring real-time data of the first charging pile to obtain corresponding third acquired data and sending the corresponding third acquired data to the first pipe conveying platform; the first charging pile is also used for charging the new energy automobile;

Each first pipe transporting platform is connected with the power regulating and controlling platform through a data line and is also connected with each first user APP through a data line; the first management platform is used for updating the working state of a preset charging pile configuration list according to a first operation application sent by each first user APP; the first pipe transporting platform is further used for updating the working state and the real-time charging power of the charging pile configuration list according to the received third acquired data; the first pipe transporting platform is also used for periodically carrying out data acquisition on the total power of network charging requirements to obtain corresponding fourth acquired data and sending the fourth acquired data to the power regulation platform;

The power regulation and control platform is used for storing the first acquired data sent by the transformer into a corresponding first transformer data list; the power regulation and control platform is further used for storing the second acquired data sent by each first circuit breaker into a corresponding first circuit breaker data list; the power regulation and control platform is also used for storing the fourth acquired data sent by each first pipe conveying platform into a corresponding first pipe conveying platform data list; the power regulation and control platform is further used for confirming a corresponding full-network power regulation and control threshold P ₀,P₀＝a*P_max according to a preset rated power P _max of the transformer, wherein a is a preset proportionality coefficient; the power regulation and control platform is further configured to set a preset total network real-time total power parameter P ₁ and a total network available total power parameter P ₂ according to the total network power regulation and control threshold P ₀, the first transformer data list and all the first breaker data lists; the power regulation and control platform is further used for setting a preset total power demand parameter P ₃ of the whole network according to all the first transportation platform data lists; the power regulation and control platform is further used for periodically carrying out full-network power regulation and control processing according to the full-network real-time total power parameter P ₁, the full-network available total power parameter P ₂ and the full-network required total power parameter P ₃ to obtain corresponding network regulation and control instructions and sending the corresponding network regulation and control instructions to each first pipe transportation platform;

The first pipe transporting platform is further used for carrying out network charging power regulation and control processing according to the network regulation and control instruction to generate corresponding charging pile regulation and control instructions and sending the corresponding charging pile regulation and control instructions to each first charging pile; the first charging pile is further used for carrying out charging pile power regulation and control processing according to the charging pile regulation and control instruction.

2. The processing system for power conditioning of a charging pile according to claim 1, wherein,

The first acquired data comprises a first timestamp and a first whole network real-time power P _T,R;

The second acquired data comprises a second timestamp, a first network identifier and a first network real-time power P _N,R;

The third collected data comprises a third timestamp, a first charging pile identifier, a first charging pile type, a first working state and a first real-time charging power P _C,R; the first working state comprises a charging state and an uncharged state; the first charging pile type comprises a direct current type and an alternating current type;

The fourth collected data comprises a fourth timestamp, a second network identifier and a first network demand total power P _Q;

The charging pile configuration list comprises a plurality of charging pile configuration records; the charging pile configuration record comprises a charging pile identification field, a charging pile type field, a working state field, a rated charging power field, a maximum charging power field and a real-time charging power field; the charging pile type field comprises a direct current type and an alternating current type; the working state field comprises a charging state and an uncharged state;

The first operation application comprises a fifth time stamp, a second charging pile identifier and a first application type; the first application type includes a start charge type and a stop charge type.

3. The processing system for power conditioning of a charging pile according to claim 2, wherein,

The transformer is specifically configured to periodically measure the real-time output power of the transformer to obtain the corresponding first full-network real-time power P _T,R when the data of the real-time output power of the transformer is acquired to obtain corresponding first acquired data and the corresponding first acquired data is sent to the power regulation platform; taking the current acquisition time as the corresponding first timestamp; and the first acquired data corresponding to the first timestamp and the first full-network real-time power P _T,R obtained at the present time are sent to the power regulation platform.

4. The processing system for power conditioning of a charging pile according to claim 2, wherein,

The first circuit breaker is specifically configured to periodically measure the real-time output power of the first circuit breaker to obtain the corresponding first network real-time power P _N,R when the second collected data obtained by periodically collecting the real-time output power of the first circuit breaker is sent to the power regulation platform; extracting a locally preset charging network identification parameter to serve as a corresponding first network identification; and taking the current acquisition time as the corresponding second time stamp; and the second acquired data corresponding to the second timestamp, the first network identifier and the first network real-time power P _N,R which are obtained at the present time are sent to the power regulation platform.

5. The processing system for power conditioning of a charging pile according to claim 2, wherein,

The first charging pile is specifically configured to identify, when the third collected data obtained by periodically collecting real-time data of the first charging pile is sent to the first pipe transporting platform, whether the first charging pile is currently in a charging state or not, if so, set the corresponding first working state as a charging state, and if not, set the corresponding first working state as an uncharged state; when the first working state is a charging state, measuring the real-time output power of the device to obtain the corresponding first real-time charging power P _C,R; setting the corresponding first real-time charging power P _C,R to 0 when the first working state is an uncharged state; extracting a locally preset charging pile identification parameter and a charging pile type parameter to serve as the corresponding first charging pile identification and first charging pile type; and taking the current acquisition time as the corresponding third timestamp; the third acquired data corresponding to the third timestamp, the first charging pile identifier, the first charging pile type, the first working state and the first real-time charging power P _C,R are formed and sent to the power regulation platform;

The first charging pile is specifically configured to extract a local preset maximum charging power parameter of the charging pile as a corresponding current charging power threshold when the new energy automobile is charged, and control real-time charging power to be below the current charging power threshold when the new energy automobile is charged.

6. The processing system for power conditioning of a charging pile according to claim 2, wherein,

Each first user APP is configured to, when a user selects one of the first charging piles to operate, use the currently selected first charging pile as a corresponding current charging pile; identifying the charging pile identification information of the current charging pile by a preset charging pile identification mode to obtain a corresponding second charging pile identification; extracting the operation mode of the charging pile selected by the user at present as a corresponding first mode; the first mode is identified, if the first mode is a charging operation mode, the corresponding first application type is set to be a starting charging type, and if the first mode is a stopping charging operation mode, the corresponding first application type is set to be a stopping charging type; and taking the current operation time as the corresponding fifth timestamp; and the fifth timestamp, the second charging pile identifier and the first application type obtained by the current operation form a corresponding first operation application to be sent to the first pipe transporting platform.

7. The processing system for power conditioning of a charging pile according to claim 2, wherein,

The first management platform is specifically configured to extract, when the working state update process is performed on a preset charging pile configuration list according to a first operation application sent by each first user APP, the second charging pile identifier and the first application type from the first operation application received at the present time as corresponding current charging pile identifier and current application type; and taking the charging pile configuration record matched with the current charging pile identifier in the charging pile configuration list as a corresponding current charging pile configuration record; the current application type is identified, if the current application type is a start charging type, the working state field of the current charging pile configuration record is set to be in a charging state, and if the current application type is a stop charging type, the working state field of the current charging pile configuration record is set to be in an uncharged state;

The first pipe transporting platform is specifically configured to use the third acquired data received latest as corresponding current third acquired data when the charging pile configuration list is subjected to working state and real-time charging power update processing according to the received third acquired data; extracting the first charging pile identifier, the first charging pile type, the first working state and the first real-time charging power P _C,R of the current third acquired data as corresponding current charging pile identifier, current charging pile type, current working state and current real-time charging power; the charging pile configuration record in the charging pile configuration list, wherein the charging pile identification field is matched with the current charging pile identification, and the charging pile type field is matched with the current charging pile type, is used as a corresponding current charging pile configuration record; setting the working state field and the real-time charging power field of the current charging pile configuration record to be the corresponding current working state and current real-time charging power;

The first pipe transporting platform is specifically configured to record the charging pile configuration record with the working state field being a charging state in the charging pile configuration list as a corresponding requirement record when the fourth acquired data obtained by periodically acquiring the total power of network charging requirements is sent to the power regulating platform; extracting the maximum charging power field of each requirement record to serve as corresponding required charging power; and performing sum calculation on all the obtained required charging power to obtain a corresponding first power sum s ₁; and taking the first power sum s ₁ as the corresponding first network demand total power P _Q; extracting a locally preset charging network identification parameter to serve as a corresponding second network identification; and taking the current acquisition time as the corresponding fourth timestamp; and the fourth timestamp, the second network identifier and the total power P _Q of the first network demand which are obtained at present form corresponding fourth acquisition data to be sent to the power regulation platform.

8. The processing system for power conditioning of a charging pile according to claim 2, wherein,

The power regulation and control platform is specifically configured to extract the first acquired data with the latest time in the first transformer data list as corresponding latest first acquired data when the preset full-network real-time total power parameter P ₁ and the full-network available total power parameter P ₂ are set according to the full-network power regulation and control threshold P ₀, the first transformer data list and all the first breaker data lists, and set the full-network real-time total power parameter P ₁ based on the first full-network real-time power P _T,R of the latest first acquired data; extracting the first network real-time power P _N,R of the second acquired data with the latest time in each first breaker data list as corresponding first real-time power, summing all the first real-time power to obtain corresponding second total power s ₂, and setting the total network available total power parameter P ₂ according to the total network power regulation threshold P ₀, the total network real-time total power parameter P ₁ and the second total power s ₂, and P ₂＝P₀-(P₁-s₂);

The power regulation and control platform is specifically configured to extract, as a corresponding first required total power, the first network required total power P _Q of the fourth collected data with the latest time in each first pipe transportation platform data list when the preset total network required total power parameter P ₃ is set according to all the first pipe transportation platform data lists; and performing total calculation on all the first required total power to obtain a corresponding third total power s ₃; and setting the total power demand parameter P ₃ of the whole network according to the third total power s ₃, and P ₃＝s₃.

9. The processing system for power conditioning of a charging pile according to claim 2, wherein,

The power regulation and control platform is specifically configured to identify, when the network regulation and control instruction is sent to each first pipe transportation platform according to the network real-time total power parameter P ₁, the network available total power parameter P ₂ and the network required total power parameter P ₃, whether the network required total power parameter P ₃ is smaller than the network available total power parameter P ₂; if the total power parameter P ₃ of the whole network demand is smaller than the total power parameter P ₂ of the whole network, setting the corresponding regulation mode parameter as a full-load regulation mode; if the total network demand total power parameter P ₃ is greater than or equal to the total network available total power parameter P ₂, identifying whether the total network real-time total power parameter P ₁ is less than the total network available total power parameter P ₂, if the total network real-time total power parameter P ₁ is less than the total network available total power parameter P ₂, setting the corresponding regulation mode parameter as an uplink regulation mode, and if the total network real-time total power parameter P ₁ is greater than or equal to the total network available total power parameter P ₂, setting the corresponding regulation mode parameter as a downlink regulation mode;

when the regulation mode parameter is a full-load regulation mode, setting a previous local preset regulation mode as the full-load regulation mode; the network regulation and control instructions carrying the regulation and control mode parameters are sent to the first pipe transportation platforms of the first charging networks;

When the regulation mode parameter is an uplink regulation mode, setting the locally preset previous regulation mode as an uplink regulation mode; extracting the total power P _Q of the first network demand of the fourth acquired data with the latest time in each first pipe transporting platform data list as corresponding first network demand power P _Q,i, wherein the network index i is an integer larger than 0; calculating a corresponding first network maximum up-regulation total power P _u,i,P_u,i＝P₂*(P_Q,i/P₃ based on each of the first network required power P _Q,i, the total network required total power parameter P ₃ and the total network available total power parameter P ₂; the network regulation and control instruction carrying the regulation and control mode parameters and the maximum up-regulation total power P _u,i of the first network is sent to the first pipe conveying platform of each corresponding first charging network;

When the regulation mode parameter is a downlink regulation mode, calculating the absolute difference between the total network real-time total power parameter P ₁ and the total network available total power parameter P ₂ to obtain a corresponding current downlink regulation power sum P ₄; extracting the local preset previous regulation and control mode to serve as a corresponding previous mode; setting the previous regulation mode as a downlink regulation mode after the previous mode is obtained; and identifying the previous pattern; if the previous mode is a full-load regulation mode, extracting the first network real-time power P _N,R of the second acquired data with the latest time in each first breaker data list as corresponding first network real-time power P _N,i, calculating corresponding first network minimum down-regulating total power P _d,i,P_d,i＝P₄*(P_N,i/P₁ based on each first network real-time power P _N,i, the whole network real-time total power parameter P ₁ and the current down-regulating total power P ₄), and sending the network regulation instruction carrying the regulation mode parameter and the first network minimum down-regulating total power P _d,i to the corresponding first pipe-transporting platform of each first charging network; if the previous mode is not the full-load regulation mode, extracting the first network demand total power P _Q of the fourth collected data with the latest time in each first pipe transporting platform data list as the corresponding first network demand power P _Q,i, calculating the corresponding first network minimum down-regulating total power P _d,i,P_d,i＝P₄*(P_N,i/P₃ based on each first network demand power P _Q,i, the total network demand total power parameter P ₃ and the current down-regulating power sum P ₄, and sending the network regulation instruction carrying the regulation mode parameter and the first network minimum down-regulating total power P _d,i to the first pipe transporting platform of each corresponding first charging network.

10. The processing system for power conditioning of a charging pile according to claim 9, wherein,

The first management platform is specifically configured to, when the network charging power regulation and control processing is performed according to the network regulation and control instruction to generate a corresponding charging pile regulation and control instruction, send the corresponding charging pile regulation and control instruction to each first charging pile, and take the network regulation and control instruction received at present as a corresponding current network regulation and control instruction; extracting the regulation mode parameters from the current network regulation instruction to serve as corresponding charging pile regulation mode parameters;

Counting the number of the charging pile configuration records in the charging pile configuration list to obtain a corresponding first record total number;

Recording the charging pile configuration record with the charging pile type field being of a direct current type and the working state field being of a charging state in the charging pile configuration list as a corresponding direct current charging pile record, and calculating the sum of the maximum charging power fields of all the direct current charging pile records to obtain a corresponding first direct current power sum; recording the charging pile configuration records with the charging pile type field being an alternating current type and the working state field being a charging state in the charging pile configuration list as corresponding alternating current charging pile records, and calculating the sum of the maximum charging power fields of all the alternating current charging pile records to obtain corresponding first alternating current power sum;

traversing each charging pile configuration record of the charging pile configuration list; the charging pile configuration record of the current traversal is used as a corresponding current configuration record, and the first charging pile corresponding to the current configuration record is used as a corresponding current charging pile; identifying the regulation and control mode parameters of the charging pile;

if the charging pile regulation and control mode parameter is a full-load regulation and control mode, setting the maximum charging power field of the current configuration record as the corresponding rated charging power field; extracting the set maximum charging power field as a corresponding charging pile power configuration parameter; transmitting the charging pile regulation and control instruction carrying the charging pile power configuration parameters to the current charging pile;

If the charging pile regulation and control mode parameter is an uplink regulation and control mode, extracting the rated charging power field and the maximum charging power field of the current configuration record as corresponding current rated power and power before uplink regulation; extracting the corresponding maximum up-regulating total power P _u,i of the first network from the current network regulation and control instruction as the corresponding current maximum up-regulating total power; and performing downward rounding on the quotient of the current maximum upregulation total power divided by the total number of the first records to obtain corresponding average upregulation power; adding the power before up-regulation and the average power after up-regulation to obtain corresponding power after up-regulation; and identifying whether the up-regulated power exceeds the corresponding current rated power; if yes, setting the maximum charging power field of the current configuration record as the corresponding current rated power; if not, setting the maximum charging power field of the current configuration record as the corresponding power after the up-regulation; extracting the set maximum charging power field to serve as a corresponding charging pile power configuration parameter; transmitting the charging pile regulation and control instruction carrying the charging pile power configuration parameters to the current charging pile;

If the charging pile regulation and control mode parameter is a downlink regulation and control mode, extracting the maximum charging power field of the current configuration record as corresponding power before downlink regulation; extracting the corresponding minimum down-regulating total power P _d,i of the first network from the current network regulation and control instruction as the corresponding current minimum down-regulating total power; performing AC/DC down-regulation proportion estimation processing according to the first AC power sum, the first DC power sum and the current minimum down-regulation total power to obtain corresponding current AC down-regulation proportion and current DC down-regulation proportion; identifying whether the current configuration record is recorded as the corresponding alternating current charging pile record or the direct current charging pile record; if the current configuration record is recorded as the corresponding ac charging pile record, calculating corresponding first power after downregulation=power before downregulation (1-current ac downregulation ratio) according to the power before downregulation and the current ac downregulation ratio, setting the maximum charging power field of the current configuration record as the corresponding first power after downregulation, extracting the set maximum charging power field as the corresponding charging pile power configuration parameter, and sending the charging pile regulation instruction carrying the charging pile power configuration parameter to the current charging pile; if the current configuration record is recorded as the corresponding direct current charging pile record, calculating corresponding second power after downregulation=power before downregulation (1-current direct current downregulation ratio) according to the power before downregulation and the current direct current downregulation ratio when the current direct current downregulation ratio is not 0, setting the maximum charging power field of the current configuration record as the corresponding second power after downregulation, extracting the set maximum charging power field as the corresponding charging pile power configuration parameter, and sending the charging pile regulation instruction carrying the charging pile power configuration parameter to the current charging pile.

11. The processing system for power conditioning of a charging pile according to claim 10, wherein,

The first pipe transporting platform is specifically configured to perform ac/dc down-regulation proportion estimation processing according to the first ac power sum, the first dc power sum and the current minimum down-regulation total power to obtain a corresponding current ac/dc down-regulation proportion and a corresponding current dc/dc down-regulation proportion,

Step 111, extracting a first downregulation ratio of a preset first downregulation ratio sequence as a corresponding first alternating current downregulation ratio; extracting a first second downregulation proportion of a preset second downregulation proportion sequence to serve as a corresponding first direct-current downregulation proportion; the first downregulation proportion sequence comprises a plurality of first downregulation proportions, and each first downregulation proportion is a percentage value with a value larger than 0 but smaller than 1; the second downregulation proportion sequence comprises a plurality of second downregulation proportions, wherein a first second downregulation proportion is 0%, and all the second downregulation proportions except the first second downregulation proportion are percentage values with values larger than 0 and smaller than 1;

Step 112, taking the product of the first ac down-regulation ratio and the first ac power sum as the corresponding first ac down-regulation power; identifying whether the first alternating current down-regulating power is smaller than the current minimum down-regulating total power; if yes, extracting the next second downregulation proportion in the second downregulation proportion sequence as a new first direct current downregulation proportion, and turning to step 113; if not, go to step 114;

Step 113, taking the product of the first direct current down-regulation ratio and the first direct current power sum as a corresponding first direct current down-regulation power; taking the sum of the first AC down-regulating power and the first DC down-regulating power as the corresponding first AC down-regulating power sum; identifying whether the sum of the first alternating current-direct current down-regulating power is smaller than the current minimum down-regulating total power; if yes, extracting the next first downturn ratio in the first downturn ratio sequence as a new first alternating current downturn ratio, and returning to step 112; if not, go to step 114;

And 114, outputting the current latest first alternating current down-regulation proportion and the first direct current down-regulation proportion as the corresponding current alternating current down-regulation proportion and the current direct current down-regulation proportion.

12. The processing system for power conditioning of a charging pile according to claim 10, wherein,

The first charging pile is specifically configured to extract, when the charging pile power regulation and control processing is performed according to the charging pile regulation and control instruction, the charging pile power configuration parameter from the currently received charging pile regulation and control instruction as a corresponding current configuration parameter; and setting the local preset maximum charging power parameter of the charging pile as the corresponding current configuration parameter.