CN112684397A

CN112684397A - Electric energy meter operation error monitoring method and system based on high-frequency HPLC (high Performance liquid chromatography) data

Info

Publication number: CN112684397A
Application number: CN202011313973.2A
Authority: CN
Inventors: 周玉; 黄奇峰; 邵雪松; 蔡奇新; 陈霄; 季欣荣; 李悦; 徐鸣飞; 易永仙
Original assignee: State Grid Jiangsu Electric Power Co ltd Marketing Service Center; State Grid Jiangsu Electric Power Co Ltd
Current assignee: State Grid Jiangsu Electric Power Co ltd Marketing Service Center; State Grid Jiangsu Electric Power Co Ltd
Priority date: 2020-11-20
Filing date: 2020-11-20
Publication date: 2021-04-20
Anticipated expiration: 2040-11-20
Also published as: CN112684397B

Abstract

The application provides an electric energy meter operation error monitoring method and system based on high-frequency HPLC data acquisition, and relates to the technical field of electric power. In the method, firstly, total meter power consumption and sub-meter power consumption obtained by respectively acquiring a total electric energy meter of a station area and a differential electric energy meter of a target station area by a plurality of HPLC devices in a current time period are obtained; secondly, obtaining line loss electric quantity corresponding to the sub-meter electric quantity based on a predetermined electric quantity corresponding relation and the sub-meter electric quantity for each sub-meter electric quantity; then, calculating to obtain total operation error data of the plurality of station-distinguished electric energy meters based on the station area total meter electricity consumption, the sub-meter electricity consumption and the line loss electricity; and finally, determining the operation error data of each station distinguishing electric energy meter based on the total operation error data and the predetermined error proportion information. Based on the method, the problem that the operation error of the station-specific electric energy meter is difficult to effectively monitor in the prior art can be solved.

Description

Electric energy meter operation error monitoring method and system based on high-frequency HPLC (high Performance liquid chromatography) data

Technical Field

The application relates to the technical field of electric power, in particular to an electric energy meter operation error monitoring method and system based on high-frequency HPLC (high performance liquid chromatography) data acquisition.

Background

In the field of power technology, a district refers to a power supply range or area of a transformer in a power system, wherein an electric energy meter for measuring total power consumption in the power supply range may be referred to as a district total electric energy meter, and one district may include a plurality of electric energy meters for measuring power consumption of each user, which may be referred to as a district division electric energy meter.

The inventor researches and discovers that each station distinguishing electric energy meter generates certain operation errors after being put into use, and therefore the operation errors need to be monitored. However, the prior art has the problem that the operation error of the station distinguishing electric energy meter is difficult to be effectively monitored.

Disclosure of Invention

In view of this, an object of the present application is to provide a method and a system for monitoring an operation error of an electric energy meter based on HPLC high frequency acquisition data, so as to solve the problem in the prior art that it is difficult to effectively monitor the operation error of a station-specific electric energy meter.

In order to achieve the above purpose, the embodiment of the present application adopts the following technical solutions:

a method and a system for monitoring running errors of an electric energy meter based on high-frequency HPLC data acquisition are applied to a computing platform in an electric energy meter running error monitoring system, wherein the monitoring system further comprises an HPLC device in communication connection with the computing platform, and the method comprises the following steps:

acquiring total table electricity consumption and sub-table electricity consumption obtained by respectively acquiring a total table electricity consumption and a sub-table electricity consumption of a target table area by a plurality of HPLC (high performance liquid chromatography) devices in the current time period, wherein the total table area electricity consumption is one, and the sub-table area electricity consumption is a plurality of;

aiming at the sub-meter power consumption of each station distinguishing electric energy meter, obtaining the line loss electric quantity corresponding to the sub-meter power consumption based on the predetermined electric quantity corresponding relation and the sub-meter power consumption;

calculating to obtain total operation error data of the plurality of station-distinguished electric energy meters based on the station-district general meter electricity consumption, the sub-meter electricity consumption and the line loss electricity;

and determining the operation error data of each station distinguishing electric energy meter based on the total operation error data and the error proportion information determined for each station distinguishing electric energy meter in advance.

On the basis of the above embodiment, the application further provides an electric energy meter operation error monitoring system, which includes an HPLC device and a computing platform in communication connection with the HPLC;

wherein the computing platform comprises:

a memory for storing a computer program;

and the processor is connected with the memory and is used for executing a computer program to realize the electric energy meter operation error monitoring method based on the HPLC high-frequency collected data.

The utility model provides an electric energy meter running error monitoring method and system based on HPLC high frequency data collection, gather district total electric energy meter and platform differentiation electric energy meter respectively through HPLC equipment, can obtain corresponding total table power consumption and branch table power consumption, then, obtain the line loss electric quantity that this branch table power consumption corresponds based on predetermined electric quantity corresponding relation and this branch table power consumption, thereby can combine this total table power consumption to obtain the total running error data that the platform differentiates the electric energy meter, make can be based on the error proportion information of confirming, confirm the running error data that each platform differentiates the electric energy meter. Therefore, the operation error of the power meter in the transformer area can be effectively monitored, and the problem that the operation error of the power meter in the transformer area is difficult to effectively monitor in the prior art is solved.

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

Drawings

Fig. 1 is a block diagram of a computing platform in an electric energy meter operation error monitoring system according to an embodiment of the present application.

Fig. 2 is a schematic flow chart illustrating steps included in a method for monitoring an operation error of an electric energy meter based on HPLC high-frequency collected data according to an embodiment of the present disclosure.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all the embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The embodiment of the application provides an electric energy meter operation error monitoring system which comprises a plurality of HPLC (high speed power line carrier) devices and a computing platform in communication connection with each HPLC device.

The HPLC equipment is provided with a carrier chip and a main control chip, can be installed on a total electric energy meter and a station distinguishing electric energy meter in a station area, and can be operated independently of the total electric energy meter and the station distinguishing electric energy meter in the station area.

Also, as shown in FIG. 1, a computing platform may include a memory and a processor.

In detail, the memory and the processor are electrically connected directly or indirectly to realize data transmission or interaction. For example, they may be electrically connected to each other via one or more communication buses or signal lines. The memory can have stored therein at least one software function (computer program) which can be present in the form of software or firmware. The processor can be used for executing the executable computer program stored in the memory, so as to implement the electric energy meter operation error monitoring method based on the HPLC high-frequency collected data provided by the embodiment of the application.

Alternatively, the Memory may be, but is not limited to, a Random Access Memory (RAM), a Read Only Memory (ROM), a Programmable Read-Only Memory (PROM), an Erasable Read-Only Memory (EPROM), an electrically Erasable Read-Only Memory (EEPROM), and the like.

Also, the Processor may be a general-purpose Processor including a Central Processing Unit (CPU), a Network Processor (NP), a System on Chip (SoC), and the like; but may also be a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other programmable logic device, discrete gate or transistor logic device, discrete hardware components.

With reference to fig. 2, an embodiment of the present application further provides an electric energy meter operation error monitoring method based on HPLC high-frequency acquired data, which is applicable to a computing platform of the electric energy meter operation error monitoring system. The method steps defined by the relevant flow of the electric energy meter operation error monitoring method based on the HPLC high-frequency collected data can be realized by a computing platform of the electric energy meter operation error monitoring system.

The specific process shown in FIG. 2 will be described in detail below.

Step S110, acquiring total meter electricity consumption and sub meter electricity consumption obtained by respectively acquiring the total electric energy meter of the station area and the differential electric energy meter of the target station area by a plurality of HPLC devices in the current time period.

In this embodiment, the computing platform may acquire, in a current period (that is, a target period from a current time to a previous time, such as a day or a month), a plurality of HPLC devices respectively acquire a target station area (a station area refers to a power supply range or an area of a transformer in an electric power system, an electric energy meter for measuring a total electric energy consumption in the power supply range may be referred to as a station area total electric energy meter, and one station area may further include a plurality of electric energy meters in addition to the station area total electric energy meter, which may be referred to as station distinguishing electric energy meters), and a station area total electric energy meter (which may be periodically corrected or replaced to ensure that measured data has higher accuracy) and a total electric energy consumption meter electric energy consumption obtained by the station distinguishing electric energy meter (that is, an electric energy consumption increment of the station area total electric energy meter in the current period) and a sub-meter electric energy consumption (that is, an electric energy consumption increment of the station area electric energy meter in the current period) may be acquired by.

The total electric energy meter of the station area is one, and the station area electric energy meters are multiple.

And step S120, distinguishing the sub-meter power consumption of the electric energy meter for each station, and obtaining the line loss electric quantity corresponding to the sub-meter power consumption based on the predetermined electric quantity corresponding relation and the sub-meter power consumption.

In this embodiment, after obtaining the sub-meter power consumption based on step S110, the computing platform may obtain, for each station, the sub-meter power consumption of the electric energy meter, and obtain, based on the predetermined power correspondence and the sub-meter power consumption, the line loss electric quantity corresponding to the sub-meter power consumption (considering that different stations have different line lengths between the different station-specific electric energy meters and the total station electric energy meter, so that the line loss electric quantities may be different even under the same power consumption, and therefore, the line loss electric quantities need to be calculated respectively by combining the corresponding line lengths).

The electric quantity correspondence may be calculated based on simulation (simulating an operating environment of the target distribution area) of the target distribution area.

And step S130, calculating to obtain total operation error data of the plurality of station-specific electric energy meters based on the station-specific total meter electricity consumption, the sub-meter electricity consumption and the line loss electricity quantity.

In this embodiment, after obtaining the line power consumption based on step S120, the computing platform may calculate, based on the line power consumption, and by combining the total power consumption of the distribution area and the power consumption of the sub-meters, total operation error data of the plurality of distribution area electric energy meters.

That is, the total power consumption of the station area, the sum of the power consumptions of the plurality of branch meters, minus the total operation error data of the plurality of line loss power = the plurality of station branch power meters.

And step S140, determining the operation error data of each station distinguishing electric energy meter based on the total operation error data and the error proportion information determined for each station distinguishing electric energy meter in advance.

In this embodiment, after obtaining the total operation error data based on step S130, the computing platform may determine the operation error data of each station-specific electric energy meter based on the total operation error data by combining the error ratio information determined in advance for each station-specific electric energy meter.

Based on the method, the operation error of the electric energy meter can be effectively monitored on the basis of not depending on the actual detection of the detection personnel, so that the problem that the operation error of the electric energy meter is difficult to effectively monitor due to the fact that the detection personnel are required to actually detect the operation error in the prior art is solved.

It should be noted that, in step S140, a specific manner for determining the operation error data of each station for distinguishing the electric energy meters is not limited, and may be selected according to actual application requirements.

For example, in an alternative example, to improve the accuracy of the determined operational error data, step S140 may include the steps of:

a first step of obtaining error ratio history information of each station differentiated electric energy meter in a history time period adjacent to the current time period (for example, if the current time period is 4/18/2020, then an adjacent history time period is 4/17/2020), wherein the time length of the history time period is the same as that of the current time period, the end point of the history time period is the start point of the current time period, and if the history time period is a first history time period, the corresponding error ratio history information is obtained based on measurement;

secondly, segmenting the current time interval according to a preset time length (such as one hour) to obtain a plurality of time segments, and forming a time segment sequence according to the time sequence relation based on the time segments, wherein the end point of the previous time segment in two adjacent time segments is coincided with the start point of the next time segment;

thirdly, acquiring sub-meter sub-electricity consumption of each station distinguishing electric energy meter in the time segment aiming at each time segment in the time segment sequence;

fourthly, distinguishing the electric energy meters for each station, and forming a sub-electric quantity sequence of the distinguishing electric energy meters (such as 0-1 hour of sub-meter sub-electric quantity, 1-2 hours of sub-meter sub-electric quantity, 2-3 hours of sub-meter sub-electric quantity and 3-4 hours of sub-meter sub-electric quantity) according to the time sequence on the basis of a plurality of sub-meter sub-electric quantities corresponding to the distinguishing electric energy meters;

fifthly, for each sub-power consumption sequence, screening each sub-meter sub-power consumption in the sub-power consumption sequence based on a preset abnormal data screening rule (so that the interference of abnormal data can be avoided), and forming a sub-power consumption target sequence corresponding to the sub-power consumption sequence after replacing the screened sub-meter sub-power consumption by the sub-meter preset sub-power consumption;

sixthly, updating the error proportion history information based on each sub-power consumption target sequence (for example, updating the error proportion history information based on proportion information between average values of sub-power consumption of sub-meters included in each sub-power consumption target sequence, where the proportion information between 4 average values is 5%, 30%, 40%, 25%, 4 error proportion history information is 25%, and 25%, respectively, and the corresponding 4 error proportion information is 15%, 27.5%, 32.5%, and 25%, respectively, that is, updating is implemented by means of average value calculation), so as to obtain error proportion information of each electric energy meter for station differentiation;

and seventhly, determining the operation error data of each station distinguishing electric energy meter based on the error proportion information and the total operation error data.

Optionally, in the above example, the specific manner of performing the screening process is not limited, and may be selected according to the actual application requirement.

For example, in an alternative example, the screening process may be performed based on the following steps:

firstly, screening and eliminating sub-meter sub-electricity consumption with preset identification from the sub-electricity consumption sequence to obtain a sub-electricity consumption to-be-interpolated sequence, wherein the preset identification is generated after operation error correction processing is carried out on the distinguishing electric energy meter in a time segment of the corresponding sub-meter sub-electricity consumption (if the sub-meter sub-electricity consumption with the preset identification does not exist, the sub-electricity consumption sequence can be directly used as a sub-electricity consumption target sequence);

secondly, determining the relation between the sub-meter electricity consumption and the (adjacent) former sub-meter electricity consumption and the relation between the sub-meter electricity consumption and the (adjacent) latter sub-meter electricity consumption for each sub-meter electricity consumption which is screened and excluded;

thirdly, for each sub-meter sub-electricity consumption which is screened and eliminated, if the difference value between the sub-meter sub-electricity consumption and the previous sub-meter sub-electricity consumption is not larger than a preset threshold value (which can be set according to the precision requirement, the higher the precision requirement is, the smaller the preset threshold value is), or the difference value between the sub-meter sub-electricity consumption and the next sub-meter sub-electricity consumption is not larger than the preset threshold value, determining a sub-meter preset sub-electricity consumption to replace the sub-meter sub-electricity consumption based on a first preset rule;

fourthly, for each sub-meter sub-electricity consumption which is screened and excluded, if the difference value between the sub-meter sub-electricity consumption and the previous sub-meter sub-electricity consumption is larger than the preset threshold value, and the difference value between the sub-meter sub-electricity consumption and the next sub-meter sub-electricity consumption is larger than the preset threshold value, determining a sub-meter preset sub-electricity consumption to replace the sub-meter sub-electricity consumption based on a second preset rule;

and fifthly, forming a corresponding sub-power consumption target sequence based on each sub-power consumption not screened and excluded in the sub-power consumption sequence and each determined preset sub-power consumption of the sub-tables.

It is understood that, in the above example, the specific manner of determining one sub-table preset sub-power consumption to perform replacement processing on the sub-table sub-power consumption based on the first preset rule is not limited, and may be selected according to actual application requirements.

For example, in an alternative example, the sub-table sub-power usage may be replaced based on determining a sub-table preset sub-power usage by:

firstly, the average power consumption of the previous sub-meter power consumption and the next sub-meter power consumption of the sub-meters power consumption which are screened and excluded can be calculated; and secondly, taking the average power consumption as a sub-table preset sub-power consumption, and replacing the sub-table power consumption which is screened and eliminated through the sub-table preset sub-power consumption.

It is understood that, in the above example, the specific manner of determining one sub-table preset sub-power consumption to perform replacement processing on the sub-table sub-power consumption based on the second preset rule is not limited, and may be selected according to actual application requirements.

For example, in an alternative example, in particular, in order to guarantee the effectiveness of replacement, the sub-table sub-power consumption may be subjected to replacement processing based on the sub-table preset sub-power consumption determined by the following steps:

determining a sequence segment including the sub-meter sub-electricity consumption in the sub-electricity consumption sequence in which the sub-meter sub-electricity consumption which is excluded from the screening is located, wherein the sequence segment includes a first number (which can be configured based on accuracy requirements, and the value of the first number can be larger as the accuracy requirements are higher) of sub-meter sub-electricity consumptions, and the first number of sub-meter sub-electricity consumptions are continuous in time;

secondly, acquiring a sub-power consumption history sequence formed by the station distinguishing electric energy meter corresponding to the sub-power consumption of the selected excluded sub-meter in the adjacent historical time period, wherein the historical time period is divided into a plurality of historical time segments based on the preset time length, and the sub-power consumption history sequence is formed based on the historical sub-meter sub-power consumption of the plurality of historical time segments;

performing sliding window processing on the sub power consumption historical sequences according to the first quantity to obtain a plurality of historical sub sequences, wherein the quantity of the sub power consumption of the historical sub tables included in each historical sub sequence is the first quantity;

fourthly, in the plurality of history subsequences, based on the similarity with the sequence segments (for example, the similarity between the sub-table electricity consumption at the corresponding position and the history sub-table electricity consumption is calculated firstly, and for example, the reciprocal of the difference is used as the similarity, and then the average similarity is calculated), a second number (which can be configured based on the precision requirement, and the higher the precision requirement is, the larger the value of the second number can be) of target history subsequences with the maximum similarity is determined;

fifthly, mapping each historical sub-meter sub-power consumption included by the target historical subsequence based on the historical average power consumption of the historical sub-meter sub-power consumption included by the target historical subsequence to obtain a plurality of historical power consumption identification values included by the target historical subsequence, wherein the historical power consumption identification values corresponding to any two historical sub-meter sub-power consumptions having the same relation with the historical average power consumption (if both the historical sub-meter sub-power consumptions are larger than the historical average power consumption) are the same, and the historical power consumption identification values corresponding to any two historical sub-meter sub-power consumptions having different relations with the historical average power consumption (if one is larger than the historical average power consumption, and the other is not larger than the historical average power consumption) are different;

sixthly, sequencing a plurality of historical power consumption identification values corresponding to the target historical subsequence according to the time sequence relation of the corresponding historical sub-table sub-power consumption for each target historical subsequence to obtain a historical identification value sequence corresponding to the target historical subsequence;

seventhly, calculating a target sequence bit number between each historical identification value sequence and each other historical identification value sequence, wherein the target sequence bit number is a sequence bit number between two historical identification value sequences and has the same historical electricity consumption identification value on a corresponding sequence position (that is, whether the historical electricity consumption identification value of the first position is the same, the historical electricity consumption identification value of the second position is the same, and the historical electricity consumption identification value of the third position is the same or not needs to be determined in each two historical identification value sequences);

an eighth step of, for each of the historical flag sequences, obtaining a variance value for each of the target sequence bit numbers corresponding to the historical flag sequence based on the historical flag sequence (e.g., 3 target sequence bit numbers are 2, and 2, respectively, a corresponding average value is 2, a corresponding variance value is (| 2-2 | plus | 2-2 |)/3 =0, 3 target sequence bit numbers are 1, 2, and 9, respectively, a corresponding average value is 4, and a corresponding variance value is (| 1-4 | plus | 2-4 | plus | 9-4 |)/3 = 3.33);

a ninth step of determining a target historical identification value sequence from the plurality of historical identification value sequences based on the magnitude relation of the discrete degree values, wherein the target historical identification value sequence is the historical identification value sequence with the minimum discrete degree value in the plurality of historical identification value sequences;

tenth, based on the positions (positions in time sequence) of the sub-meter power consumption which is excluded from screening in the sequence segments, determining the historical sub-meter power consumption at the corresponding position in the target historical sub-sequence corresponding to the target historical identification value sequence;

and step eleven, taking the historical sub-meter sub-electricity consumption at the corresponding position as a sub-meter preset sub-electricity consumption, and replacing the sub-meter sub-electricity consumption which is screened and eliminated based on the sub-meter preset sub-electricity consumption.

For another example, in an alternative example, in order to ensure the effectiveness of replacement and take into account the efficiency of the overall calculation, the sub-table sub-power consumption may be replaced based on the following steps:

substep 1, obtaining a plurality of sub-power consumption history sequences formed by a station distinguishing electric energy meter corresponding to the sub-power consumption of the selected and excluded sub-power consumption in a plurality of history periods (which may be a plurality of adjacent history periods), wherein each history period is divided into a plurality of history time segments based on the preset time length, and each sub-power consumption history sequence is formed based on the sub-power consumption of the corresponding history sub-power consumption of the plurality of history time segments;

substep 2, determining a target sub-power consumption history sequence with the maximum similarity to the sub-power consumption sequence where the sub-power consumption of the selected and excluded sub-meter is located in the plurality of sub-power consumption history sequences;

and substep 3, determining a historical sub-meter sub-power consumption as a sub-meter preset sub-power consumption based on a plurality of historical sub-meter sub-power consumptions included in the target sub-power consumption historical sequence, and replacing the sub-meter sub-power consumption which is screened and eliminated based on the sub-meter preset sub-power consumption.

In the above example, the specific manner of determining the historical sub-meter sub-power consumption as the preset sub-power consumption of the sub-meter based on the sub-step 3 is not limited, and may be selected according to the actual application requirement.

For example, in an alternative example, to ensure the efficiency of the overall calculation, sub-step 3 may comprise the following steps:

firstly, determining time segments corresponding to the sub-meter electricity consumption which is excluded by screening;

secondly, determining a corresponding historical time segment based on the time segment (for example, when the time segment is 9-10 of 5, 8 and 7 days of 2020, the historical time segment may be 9-10 of 5, 7 and 7 days of 2020), and obtaining a historical sub-meter sub-electricity consumption corresponding to the historical time segment from a plurality of historical sub-meter sub-electricity consumptions included in the historical sequence of the target sub-electricity consumption;

and then, taking the obtained historical sub-meter electricity consumption as a sub-meter preset sub-electricity consumption, and replacing the sub-meter electricity consumption which is screened and eliminated on the basis of the sub-meter preset sub-electricity consumption.

For another example, in another alternative example, to ensure the validity of the replacement, sub-step 3 may comprise the following steps:

firstly, reordering a plurality of historical sub-table sub-electricity consumptions included in the target sub-electricity consumption historical sequence according to the descending order;

secondly, according to the sequence from big to small, reordering the sub-electricity consumption of the sub-meter included in the sub-electricity consumption sequence where the sub-electricity consumption of the sub-meter which is excluded by screening is located;

then, based on the position of the sorted and excluded sub-meter electricity consumption after reordering, determining the historical sub-meter electricity consumption at the corresponding position in the reordered historical sequence of the target sub-electricity consumption (if the position of the sorted and excluded sub-meter electricity consumption after reordering is the fifth, determining the fifth historical sub-meter electricity consumption in the reordered historical sequence of the target sub-electricity consumption);

and finally, taking the historical sub-meter sub-electricity consumption at the corresponding position as a sub-meter preset sub-electricity consumption, and replacing the sub-meter sub-electricity consumption which is filtered and eliminated on the basis of the sub-meter preset sub-electricity consumption.

Further, considering that in the above example, the maximum similarity needs to be determined when performing sub-step 2, the method may further include the step of calculating the similarity between the historical sequence of the sub power consumption amount and the sequence of the sub power consumption amount where the sub-table sub power consumption amount is excluded from being filtered. Wherein, based on different requirements, the step may include different examples, and in the present embodiment, the following three examples are provided.

In a first example, the following sub-steps may be included:

substep 11, regarding each sub-meter sub-electricity consumption in the sub-electricity consumption sequence in which the sub-meter sub-electricity consumption is excluded from the screening, taking the sub-meter sub-electricity consumption and each sub-meter sub-electricity consumption after the sub-meter sub-electricity consumption as a target comparison sequence of the sub-meter sub-electricity consumption (a plurality of target comparison sequences can be obtained, and the sub-meter sub-electricity consumption included in each target comparison sequence is different in quantity);

substep 12, calculating an electric quantity ratio between the sub-meter sub-electric quantity of the corresponding position (the position is a sequential position in the sequence) in the target comparison sequence and the sub-electric quantity of the sub-meter in the historical sequence of the sub-electric quantity, and obtaining an electric quantity ratio set corresponding to the target comparison sequence;

substep 13, regarding each electric quantity ratio in each electric quantity ratio set, taking the electric quantity ratio and each previous electric quantity ratio of the electric quantity ratio in the corresponding electric quantity ratio set as a ratio sequence corresponding to the electric quantity ratio (each electric quantity ratio set corresponds to at least one ratio sequence);

substep 14, calculating an average value of the electric quantity ratios in each ratio sequence respectively to obtain a ratio average value corresponding to each ratio sequence;

substep 15, determining a maximum ratio average value in the ratio average values of each ratio sequence corresponding to each electric quantity ratio set, and taking the maximum ratio average value as a target ratio average value of the electric quantity ratio set;

substep 16, sorting the target ratio average values according to a sequence of big first and small second to obtain an average value sequence, and obtaining target ratio average values in a preset number (which can be configured according to the precision requirement, and the preset number can be larger if the precision is higher) in the average value sequence;

substep 17, for each target ratio average value of the preset number of target ratio average values, determining the number (e.g. 2, 3, 8, etc.) of the power ratio values in the power ratio set corresponding to the target ratio average value, and determining a first weight coefficient of the target ratio average value based on the number, wherein the number and the first weight coefficient have a positive correlation (that is, the larger the number of the power ratio values in a power ratio set is, the larger the corresponding first weight coefficient is);

substep 18, calculating, for each first weight coefficient, a product of the first weight coefficient and a target ratio average value corresponding to the first weight coefficient, and taking the product as a similarity between a target comparison sequence corresponding to the target ratio average value and the sub-power consumption history sequence;

and a substep 19 of determining a target comparison sequence with the maximum similarity, and taking the similarity of the target comparison sequence as the similarity between the sub power consumption sequence and the sub power consumption history sequence.

In a second example, the following sub-steps may be included:

substep 21, regarding each sub-meter sub-electricity consumption in the sub-electricity consumption sequence where the sub-meter sub-electricity consumption which is excluded by screening is located, taking the sub-meter sub-electricity consumption and each sub-meter sub-electricity consumption behind the sub-meter sub-electricity consumption as a target comparison sequence of the sub-meter sub-electricity consumption;

substep 22, calculating an electric quantity ratio between the sub-meter sub-electric quantity and the historical sub-meter sub-electric quantity at corresponding positions in the target comparison sequence and the sub-electric quantity historical sequence aiming at each target comparison sequence corresponding to the sub-electric quantity sequence, and obtaining an electric quantity ratio set corresponding to the target comparison sequence;

substep 23, regarding each electric quantity ratio in each electric quantity ratio set, taking the electric quantity ratio and each previous electric quantity ratio of the electric quantity ratio in the corresponding electric quantity ratio set as a ratio sequence corresponding to the electric quantity ratio;

substep 24, respectively calculating an average value of the electric quantity ratios in each ratio sequence to obtain a ratio average value corresponding to each ratio sequence;

substep 25, determining a maximum ratio average value in the ratio average values of each ratio sequence corresponding to each electric quantity ratio set, and taking the maximum ratio average value as a target ratio average value of the electric quantity ratio set;

a substep 26 of comparing, for each adjacent (temporal) two of the target comparison sequences, two target ratio averages respectively corresponding to the two target comparison sequences;

a substep 27, if the average difference between the two target ratio averages is smaller than the target difference (configured based on the precision requirement, if the precision requirement is higher, the target difference may be larger), setting a second weight coefficient for the larger one of the two target ratio averages, wherein the second weight coefficient is smaller than 1 and has a negative correlation with the target difference (that is, the larger the target difference, the smaller the second weight coefficient);

substep 28, for each second weight coefficient, performing update processing on the corresponding target ratio average value based on the second weight coefficient (i.e. performing product on the second weight coefficient and the corresponding target ratio average value to realize update processing), so as to obtain an updated target ratio average value;

and a substep 29 of determining a maximum target ratio average value and taking the maximum target ratio average value as the similarity between the sub power consumption sequence and the sub power consumption history sequence.

In the third example, in order to sufficiently ensure that the calculated similarity has high reliability, in particular, the following sub-steps may be included:

substep 30, regarding each sub-meter sub-electricity consumption in the sub-electricity consumption sequence where the sub-meter sub-electricity consumption which is excluded by screening is located, taking the sub-meter sub-electricity consumption and each sub-meter sub-electricity consumption behind the sub-meter sub-electricity consumption as a target comparison sequence of the sub-meter sub-electricity consumption;

substep 31, calculating an electric quantity ratio between the sub-meter sub-electric quantity and the historical sub-meter sub-electric quantity at the corresponding position in the target comparison sequence and the sub-electric quantity historical sequence aiming at each target comparison sequence corresponding to the sub-electric quantity sequence, and obtaining an electric quantity ratio set corresponding to the target comparison sequence;

substep 32, regarding each electric quantity ratio in each electric quantity ratio set, taking the electric quantity ratio and each previous electric quantity ratio of the electric quantity ratio in the corresponding electric quantity ratio set as a ratio sequence corresponding to the electric quantity ratio;

substep 33, calculating an average value of the electric quantity ratios in each ratio sequence respectively to obtain a ratio average value corresponding to each ratio sequence;

substep 34, determining a maximum ratio average value in the ratio average values of each ratio sequence corresponding to each electric quantity ratio set, and taking the maximum ratio average value as a target ratio average value of the electric quantity ratio set;

substep 35, sorting the target ratio average values according to a sequence of first big and second small to obtain an average value sequence, and obtaining the target ratio average values of a preset number in the average value sequence;

substep 36, determining, for each target ratio average value of the preset number of target ratio average values, the number of the power ratio values in the power ratio set corresponding to the target ratio average value, and determining a first weight coefficient of the target ratio average value based on the number, where the number and the first weight coefficient have a positive correlation;

substep 37, calculating, for each first weight coefficient, a product of the first weight coefficient and a target ratio average value corresponding to the first weight coefficient, and taking the product as a similarity between a target comparison sequence corresponding to the target ratio average value and the sub-power consumption history sequence;

substep 38, determining a target comparison sequence with the maximum similarity number;

and a substep 39 of determining a target comparison sequence with the largest quantity of sub-table sub-electricity consumptions included in the target quantity target comparison sequences, and taking the similarity of the target comparison sequence as the similarity between the sub-electricity consumption sequence and the sub-electricity consumption history sequence.

To sum up, the utility model provides an electric energy meter running error monitoring method and system based on HPLC high frequency data collection distinguishes the electric energy meter through HPLC equipment to the total electric energy meter in platform district and platform respectively and gathers, can obtain corresponding total table power consumption and branch table power consumption, then, obtain the line loss electric quantity that this branch table power consumption corresponds based on predetermined electric quantity corresponding relation and this branch table power consumption, thereby can combine this total table power consumption to obtain the total running error data that the platform distinguishes the electric energy meter, make can distinguish the running error data of electric energy meter based on definite error proportion information, confirm each platform. Therefore, the operation error of the power meter in the transformer area can be effectively monitored, and the problem that the operation error of the power meter in the transformer area is difficult to effectively monitor in the prior art is solved.

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

Claims

1. a kind of electric energy meter operating error monitoring method based on HPLC high frequency acquisition data, it is characterized in that, be applied to the computing platform in the electric energy meter operating error monitoring system, wherein, this monitoring system also comprises the HPLC that is communicatively connected with this computing platform device, the method includes:

Obtain the total meter electricity consumption and sub-meter electricity consumption obtained by multiple HPLC equipments in the target station area respectively collecting the total electricity meter of the station area and the electricity meter of the station area. The station distinguishes the electric energy meter into multiple;

Distinguish the sub-meter power consumption of the electric energy meter for each of the stations, and obtain the line power consumption corresponding to the sub-meter power consumption based on the predetermined power correspondence relationship and the sub-meter power consumption;

Based on the electricity consumption of the total meter in the station area, the electricity consumption of the sub-meters and the power consumption of the line, the total operation error data of a plurality of the station-specific electric energy meters are calculated and obtained;

Based on the total operation error data and the error ratio information determined in advance for each station-distinguished electric energy meter, the operation error data of each of the station-distinguished electric energy meters is determined.

2. the electric energy meter operation error monitoring method based on HPLC high-frequency acquisition data according to claim 1, is characterized in that, described based on described total operation error data and the error proportion information determined in advance for each station to distinguish electric energy meters , the step of determining the running error data of the electric energy meter for each said station includes:

Acquire the historical information of the error ratio of each of the station-distinguished electric energy meters in a historical period adjacent to the current period, wherein the historical period is the same as the current period, and the end point of the historical period is the current period The starting point of , and if the historical period is the first historical period, the corresponding historical information of the error ratio is obtained based on the measurement;

The current time period is divided according to the preset time length to obtain multiple time segments, and a time segment sequence is formed based on the multiple time segments according to the time sequence, wherein the time segment of the previous time segment in the two adjacent time segments is The end point coincides with the start point of the next time segment;

For each time segment in the time segment sequence, obtain the sub-meter sub-meter power consumption of each of the station-distinguished electric energy meters in the time segment;

For each of the station-distinguished electric energy meters, the sub-meter electricity consumption sequence of the station-distinguished electric energy meter is formed in a chronological order based on the plurality of sub-meter sub-electrical power consumption corresponding to the station-distinguished electric energy meter;

For each sub-sequence of electricity consumption, screen each sub-meter sub-consumption in the sub-consumption sequence based on a preset abnormal data screening rule, and screen out the sub-meter sub-consumption of electricity. After the sub-meter preset sub-power consumption is replaced by the sub-meter, the sub-power consumption target sequence corresponding to the sub-power consumption sequence is formed;

updating the error ratio history information based on each of the sub-electricity consumption target sequences, to obtain error ratio information of each of the station-distinguished electric energy meters;

Based on the error ratio information and the total operating error data, operating error data for each of the station-distinguished electric energy meters is determined.

3. The method for monitoring the operation error of electric energy meters based on HPLC high-frequency acquisition data according to claim 2, wherein the method for monitoring each sub-meter in the sub-electricity consumption sequence based on a preset abnormal data screening rule The sub-meter electricity consumption is screened, and after the sub-meter sub-meter electricity consumption screened out is replaced by the sub-meter preset sub-meter electricity consumption, the steps of forming the sub-meter electricity consumption target sequence corresponding to the sub-meter electricity consumption sequence, include:

From the sub-power consumption sequence, the sub-meter sub-power consumption with a preset identifier is screened and excluded to obtain a sub-meter power consumption sequence to be interpolated, wherein the preset identifier is based on the corresponding sub-meter sub-power consumption Generated after performing running error correction processing on the station-distinguished electric energy meter within the time segment;

For each sub-meter sub-meter power consumption that is screened and excluded, determine the relationship between the sub-meter sub-meter sub-meter sub-meter power consumption and the previous sub-meter sub-sub-meter power consumption, and the relationship with the next sub-meter sub-sub-meter power consumption;

For each sub-meter sub-meter power consumption that is screened out, if the difference between the sub-meter sub-meter sub-meter sub-meter power consumption and the previous sub-meter sub-meter sub-power consumption is not greater than the preset threshold, or the sub-meter sub-meter sub-meter power consumption If the difference between the power consumption of the next sub-meter and the sub-meter is not greater than the preset threshold, then determine a sub-meter preset sub-power consumption based on the first preset rule to perform replacement processing on the sub-meter sub-power consumption;

For each sub-meter sub-meter power consumption that is screened and excluded, if the difference between the sub-meter sub-meter sub-meter power consumption and the previous sub-meter sub-meter sub-power consumption value is greater than the preset threshold, and the sub-meter sub-meter power consumption If the difference between the power consumption of the next sub-meter and the sub-meter is greater than the preset threshold, then determine a sub-meter preset sub-power consumption based on the second preset rule to perform replacement processing on the sub-meter sub-power consumption;

Based on each sub-meter sub-consumption that is not screened and excluded in the sub-consumption sequence and each sub-meter preset sub-consumption determined, a corresponding sub-consumption target sequence is formed.

4. The method for monitoring the operation error of an electric energy meter based on HPLC high-frequency acquisition data according to claim 3, wherein the described power consumption of a sub-meter preset sub-meter is determined based on the first preset rule to this sub-meter sub-meter. The steps of using electricity for replacement processing include:

Calculate the average electricity consumption of the electricity consumption of the former sub-meter and the latter sub-meter of the electricity consumption of the excluded sub-meter;

The average power consumption is used as a sub-meter preset sub-power consumption, and the screened and excluded sub-meter sub-power consumption is replaced by the sub-meter preset sub-power consumption.

5. The method for monitoring the operation error of an electric energy meter based on HPLC high-frequency acquisition data according to claim 3, wherein the described power consumption of a sub-meter preset sub-meter is determined based on the second preset rule to this sub-meter sub-meter. The steps of using electricity for replacement processing include:

Obtain a plurality of sub-power consumption history sequences formed by the sub-meter and sub-power consumption corresponding to the sub-meters that are excluded from the screening and formed in a plurality of historical periods, wherein each historical period is divided based on the preset time length is a plurality of historical time segments, each of the sub-power consumption history sequences is formed based on the historical sub-table sub-power consumption of the corresponding multiple historical time segments;

From the plurality of sub-meter power consumption history sequences, determine the target sub-meter power consumption history sequence that has the greatest similarity with the sub-meter power consumption sequence where the screened and excluded sub-meter power consumption is located;

Based on a plurality of historical sub-meter sub-consumptions included in the target sub-meter power consumption history sequence, one historical sub-meter sub-consumption is determined as the sub-meter preset sub-consumption, and the sub-meter preset sub-consumption is based on the sub-meter The power consumption is to replace the power consumption of the sub-meters excluded by the screening.

6. The method for monitoring the operation error of an electric energy meter based on HPLC high-frequency acquisition data according to claim 5, wherein the described power consumption of a sub-meter preset sub-meter is determined based on the second preset rule to this sub-meter sub-meter. The steps of using electricity for replacement processing also include:

The step of calculating the similarity between the sub-consumption historical sequence and the sub-consumption sequence where the sub-meter sub-consumption that has been screened and excluded is located, the step includes:

For each sub-meter sub-power consumption in the sub-meter sub-power consumption sequence where the sub-meter sub-power consumption that has been screened and excluded is located, the sub-meter sub-meter power consumption and each subsequent sub-meter sub-power consumption of the sub-meter sub-consumption The electricity consumption of a sub-meter is used as the target comparison sequence of the electricity consumption of the sub-meter;

For each target comparison sequence corresponding to the sub-power consumption sequence, calculate the difference between the target comparison sequence and the sub-meter sub-power consumption and historical sub-meter sub-power consumption at the corresponding position in the sub-power consumption historical sequence to obtain the set of power ratios corresponding to the target comparison sequence;

For each power ratio in each of the power ratio sets, the power ratio and each power ratio before the power ratio in the corresponding power ratio set are used as the ratio sequence corresponding to the power ratio;

Calculate the average value of the electricity ratio in each of the ratio series respectively, and obtain the average value of the ratio corresponding to each ratio series;

For each of the power ratio sets, determine the maximum ratio average value in the ratio average values of each ratio sequence corresponding to the power ratio set, and use the maximum ratio average value as the target ratio average value of the power ratio set;

Sorting the average value of the target ratios in the order of the largest and the smallest to obtain an average value sequence, and obtain the average value of the target ratios located in the first preset number in the average value sequence;

For each target ratio average value in the preset number of target ratio average values, determine the number of power ratio values in the power ratio value set corresponding to the target ratio average value, and determine the first average value of the target ratio value based on the number. a weight coefficient, wherein the quantity has a positive correlation with the first weight coefficient;

For each of the first weight coefficients, calculate the product of the first weight coefficient and the target ratio average value corresponding to the first weight coefficient, and use the product as the target comparison sequence corresponding to the target ratio average value and the sub- Similarity between historical series of electricity consumption;

Determine the target comparison sequence with the largest similarity, and use the similarity of the target comparison sequence as the similarity between the sub-electricity consumption sequence and the sub-electricity consumption history sequence.

7. The method for monitoring the operation error of an electric energy meter based on HPLC high-frequency acquisition data according to claim 5, wherein the described power consumption of a sub-meter preset sub-meter is determined based on the second preset rule to this sub-meter sub-meter. The steps of using electricity for replacement processing also include:

For each adjacent two target comparison sequences, compare the average value of the two target ratios corresponding to the two target comparison sequences respectively;

If the average difference between the two target ratio averages is smaller than the target difference, a second weight coefficient is set for the larger one of the two target ratio averages, wherein the The second weight coefficient is less than 1 and has a negative correlation with the target difference;

For each of the second weight coefficients, update the corresponding target ratio average value based on the second weight coefficient to obtain an updated target ratio average value;

The maximum average value of target ratio is determined, and the maximum average value of target ratio is used as the similarity between the sub-electricity consumption sequence and the sub-electricity consumption historical sequence.

8. The method for monitoring operation error of an electric energy meter based on HPLC high-frequency acquisition data according to claim 5, wherein the multiple historical sub-meter sub-meter power consumption included in the target sub-meter power consumption historical sequence , determining a historical sub-meter sub-power consumption as the sub-meter preset sub-power consumption, and performing replacement processing on the sub-meter sub-power consumption that has been screened and excluded based on the sub-meter preset sub-power consumption, include:

Determine the time segment corresponding to the sub-meter power consumption that is excluded from the screening;

Determine the corresponding historical time segment based on the time segment, and obtain a historical sub-meter sub-meter power consumption corresponding to the historical time segment from the multiple historical sub-meter sub-meter power consumption included in the target sub-meter power consumption history sequence quantity;

Taking the acquired historical sub-meter sub-power consumption as sub-meter preset sub-power consumption, and performing replacement processing on the screened and excluded sub-meter sub-power consumption based on the sub-meter preset sub-power consumption .

9. The method for monitoring the operation error of an electric energy meter based on HPLC high-frequency acquisition data according to claim 5, wherein the multiple historical sub-meter sub-meter power consumption included in the target sub-meter power consumption historical sequence Steps of determining a historical sub-meter sub-power consumption as a sub-meter preset sub-power consumption, and performing replacement processing on the screened and excluded sub-meter sub-power consumption based on the sub-meter preset sub-power consumption, include:

Reordering the multiple historical sub-meter sub-power consumption included in the target sub-sub-power consumption historical sequence in descending order;

Re-ordering the multiple sub-meter sub-power consumptions included in the sub-meter sub-power consumption sequence where the sub-meter sub-power consumption that has been screened and excluded is located in descending order;

Based on the reordered positions of the sub-meter sub-meter power consumption that have been screened out, determine the historical sub-meter sub-meter sub-power consumption of the corresponding position in the reordered historical sequence of the target sub-meter power consumption;

Taking the historical sub-meter sub-power consumption of the corresponding location as the sub-meter preset sub-power consumption, and performing replacement processing on the screened and excluded sub-meter sub-power consumption based on the sub-meter preset sub-power consumption .

10. An electric energy meter running error monitoring system, characterized in that, comprising HPLC equipment and a computing platform communicatively connected with the HPLC, wherein the computing platform comprises:

memory for storing computer programs;

A processor connected with the memory is used for executing a computer program to implement the method for monitoring the running error of an electric energy meter based on high-frequency HPLC data collected in any one of claims 1-9.