CN114611966A - Intelligent quantitative evaluation method for power transmission and transformation operation safety of smart power grid power system - Google Patents
Intelligent quantitative evaluation method for power transmission and transformation operation safety of smart power grid power system Download PDFInfo
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Abstract
The invention discloses an intelligent assessment method for power transmission and transformation operation safety quantification of a smart grid power system. The intelligent power transmission and transformation operation safety quantitative evaluation method for the smart power grid power system comprises the following steps: extracting basic information corresponding to the associated power transmission line; dividing the associated transmission line into transmission line sections according to a preset interval, and detecting line state parameters and power parameters corresponding to the transmission line sections; extracting historical meteorological information corresponding to the position of the area where the associated power transmission line is located; processing and analyzing the line state parameters, the electric power parameters and the historical meteorological information corresponding to the associated power transmission lines, and performing power transmission and transformation operation safety assessment on the power system to be monitored; the problem of the concrete general nature of current aassessment mode is solved, realized the pertinence aassessment to overhead transmission line operation safety, ensured accurate nature, rationality and the referential of electric power system transmission and transformation operation safety assessment result.
Description
Technical Field
The invention belongs to the field of power grid operation management, and relates to an intelligent power grid power system power transmission and transformation operation safety quantitative evaluation method.
Background
In recent years, the demand of people for electric energy in production and life is continuously increased, which also puts higher requirements on the safe and stable operation of an electric power system, the overhead transmission line is used as a common mode of long-distance power transmission and transformation in the electric power system, the operation safety and the operation stability of the overhead transmission line directly determine the safety and the stability of the power transmission and transformation operation of the electric power system to a great extent, and in order to reduce the potential safety hazard in the power transmission and transformation operation process of the electric power system, the power transmission and transformation operation safety corresponding to the overhead transmission line of the electric power system needs to be evaluated.
At present, the safety assessment of the power transmission and transformation operation of the power system is mainly based on two modes, one mode is based on benchmark risk assessment, the other mode is based on risk assessment, the risk is comprehensively assessed by analyzing the risk hazard and the risk occurrence probability, and then the risk level is determined, and obviously, the two modes have the following problems:
1. the overhead transmission line is used as a main link for connecting a power transmission system and a power distribution system in a power system, and the importance of the overhead transmission line is self-evident, the current modes for evaluating the safety of the power transmission and transformation operation of the power system are general evaluation, the overhead transmission line is not subjected to targeted evaluation, the accuracy of the evaluation result of the safety of the power transmission and transformation operation of the power system cannot be guaranteed, meanwhile, the two current modes need huge data bases, the calculation engineering quantity is large, and large errors are easy to generate in the evaluation process;
2. the two current evaluation modes are based on the probability and the influence degree corresponding to the risk event of the power system, the general operation safety evaluation of the power system is mainly realized, the operation safety state of the power system in the associated power transmission line cannot be highlighted, and then the accurate and efficient analysis of the power transmission line cannot be realized, and meanwhile, the two current modes also cannot provide reliable and powerful data reference for the development of the power system in the operation and maintenance work of the overhead power transmission line.
Disclosure of Invention
In view of the above, in order to solve the problems in the background art, an intelligent assessment method for the power transmission and transformation operation safety quantification of the smart grid power system is provided, so that the intelligent assessment of the power transmission and transformation operation safety of the power system is realized;
the purpose of the invention can be realized by the following technical scheme:
the invention provides a smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method, which comprises the following steps:
s1, acquiring a relevant power transmission line corresponding to the power system to be monitored, and extracting basic information corresponding to the relevant power transmission line;
step S2, dividing the associated transmission line into transmission line sections according to a preset interval, and detecting line states corresponding to the transmission line sections in the associated transmission line;
wherein, step S2 specifically includes the following steps:
step S21, counting each electric pole corresponding to each electric transmission line section in the associated electric transmission line, and detecting the state corresponding to each electric pole;
step S22, counting each corresponding lead and each pull wire in each transmission line section in the associated transmission line, and detecting the state corresponding to each lead and each pull wire;
step S23, counting each corresponding line element in each transmission line section in the associated transmission line, obtaining the type corresponding to each line element, and further detecting the state corresponding to each line element in each type;
step S3, detecting the electric power parameters corresponding to the associated electric transmission line, and acquiring the numerical values corresponding to the electric power parameters in the associated electric transmission line;
step S4, performing preliminary processing on each line state corresponding to each transmission line section in the associated transmission line and each power parameter corresponding to each transmission line section in the associated transmission line;
step S5, extracting the area position of the associated power transmission line from the basic information corresponding to the associated power transmission line, and extracting historical meteorological information corresponding to the area position of the associated power transmission line from an area meteorological database, wherein the historical meteorological information comprises the frequency of occurrence of historical severe weather and the corresponding severe grade of the historical severe weather each time;
step S6, further analyzing the line state corresponding to the associated power transmission line, the primary processing result of each power parameter corresponding to the associated power transmission line and the historical meteorological information corresponding to the area position of the associated power transmission line, and evaluating the power transmission and transformation operation safety of the power system to be monitored;
and S7, sending the evaluation result of the power transmission and transformation operation safety of the power system to be monitored to the operation and maintenance manager corresponding to the power system to be monitored.
As a preferred scheme, the basic information corresponding to the associated power transmission line includes a region position to which the associated power transmission line corresponds, insulator string information, hardware fitting information, and transformer information included in the associated power transmission line.
As a preferred scheme, the insulator string information included in the associated transmission line is the number of insulator strings and the number of insulators included in each insulator string, the hardware fitting information included in the associated transmission line is the number of hardware fittings, and the transformer information included in the associated transmission line is the number of transformers.
Preferably, the specific implementation process of detecting the state corresponding to each electric pole in step S21 includes the following steps:
numbering each transmission line section in the associated transmission lines, and sequentially marking the transmission line sections as 1,2,. i,. n;
marking each electric pole in each transmission line section in the associated transmission line as Gi rR is a pole number, r is 1,2,.. k, i is a transmission line section number, and i is 1,2,.. n;
and acquiring images of the electric poles by using the first cameras at the positions of the electric poles in the electric transmission line sections in the associated electric transmission line, acquiring the images corresponding to the electric poles in the electric transmission line sections in the associated electric transmission line, and acquiring the corresponding states of the electric poles in the electric transmission line sections in the associated electric transmission line.
Preferably, the specific detection process of the state corresponding to each lead and each pull wire in step S22 is as follows: marking each corresponding lead in each transmission line section in the associated transmission line as X according to each corresponding lead and each corresponding pull wire in each transmission line section in the associated transmission linei tMarking each corresponding stay wire in each transmission line section in the associated transmission line as Li dT denotes a wire number, t 1,2,.. h, d denotes a stay wire number, and d 1,2The machine carries out along-the-way shooting on the wires and the stay wires in the power transmission line sections of the machine to obtain wire images and stay wire images corresponding to the power transmission line sections in the associated power transmission line, and further obtains wire states and stay wire states corresponding to the power transmission line sections in the associated power transmission line.
As a preferable scheme, the type corresponding to each line element in the step S23 specifically includes an insulator string and a hardware, and the specific state detection process includes the following steps:
comparing the types of the corresponding line elements in each transmission line section in the associated transmission line with each other, respectively screening out the number of the corresponding insulator strings and the number of the corresponding hardware fittings in each transmission line section in the associated transmission line, and obtaining the corresponding insulator strings and the corresponding hardware fittings in each transmission line section in the associated transmission line;
marking each insulator chain and each hardware fitting corresponding to each transmission line section in the associated transmission line as Ji sAnd Yi uS is an insulator string number, s is 1,2,.. g, u is an armour clamp number, and u is 1,2,... v;
detecting the surface equivalent salt-attached density of the associated transmission line by using an insulator salt density tester carried by each insulator string in each transmission line section in the associated transmission line so as to obtain the surface equivalent salt-attached density corresponding to each insulator string in each transmission line section in the associated transmission line, and simultaneously collecting the insulation resistance of each insulator in the insulator string by using an insulation resistance instrument carried by each insulator string in each transmission line section in the associated transmission line so as to obtain the insulation resistance corresponding to each insulator in each insulator string in each transmission line section in the associated transmission line;
and detecting the temperature of each hardware in each transmission line section in the associated transmission line according to a preset acquisition time interval by using a temperature sensor carried by each hardware in each transmission line section in the associated transmission line, and acquiring the temperature corresponding to each hardware in each acquisition time interval in each transmission line section in the associated transmission line.
As a preferred scheme, each power parameter corresponding to the associated power transmission line in step S3 is a conductor power parameter and a transformer power parameter, and the specific detection process is as follows:
selecting power detection points of all the wires in all the transmission line sections in the associated transmission line according to the corresponding wires in all the transmission line sections in the associated transmission line, laying power detection equipment at the selected power monitoring points, detecting power parameters of all the wires by using the power detection equipment in all the power detection point positions of all the wires in all the transmission line sections in the associated transmission line according to preset detection time points, and acquiring power parameters of all the wires corresponding to all the detection time points of all the power detection point positions of all the wires in all the transmission line sections in the associated transmission line, wherein the power parameters of the wires comprise wire operating current and wire operating voltage;
extracting the corresponding transformers in each transmission line section in the associated transmission line according to the number of the corresponding transformers in the associated transmission line and the corresponding positions of the transformers, detecting discharge signals of the ultrahigh frequency sensors carried by the transformers in each transmission line section in the associated transmission line according to a preset acquisition time period, and acquiring the discharge signal values of the transformers in each transmission line section in the associated transmission line corresponding to each acquisition time period.
As a preferable scheme, the specific processing procedure of performing preliminary processing on each line state corresponding to each transmission line segment in the associated transmission line and each power state corresponding to each transmission line segment in the associated transmission line in step S4 is as follows:
firstly, according to each line state corresponding to each transmission line section in the associated transmission line, performing state confirmation on each line state to obtain state types corresponding to each electric pole, each lead, each pull wire and each line element in each type in each transmission line section in the associated transmission line;
secondly, according to the running current and running voltage of each power detection point on each conductor in each transmission line section in the associated transmission line corresponding to each detection time point, calculating the average running current and average running voltage corresponding to each conductor in each transmission line section in the associated transmission line by using an average value calculation method, and respectively expressing the average running current and average running voltage as Vi tAnd Ai tSimultaneously according to each transmission in the associated transmission lineThe discharge signal value corresponding to each transformer in each acquisition time period in the power line section is screened out, and the maximum discharge signal value corresponding to each transformer in each power line section in the associated line is marked as Bi jJ denotes a transformer number, and j is 1, 2.
As a preferred scheme, the specific analysis process of further analyzing the line state corresponding to the associated power transmission line, the preliminary processing result of each power parameter corresponding to the associated power transmission line, and the historical meteorological information corresponding to the regional location where the associated power transmission line is located in step S6 includes the following steps:
acquiring state types corresponding to each electric pole, each lead, each stay wire and each line element in each transmission line section in the associated transmission line, recording the state types as external analysis elements, setting safety influence weights of the external analysis elements, further counting comprehensive safety indexes of the external analysis elements of the associated transmission line, and recording the comprehensive safety indexes as YZ;
obtaining the corresponding numerical value of each power parameter in the associated power transmission line, recording each power parameter as an internal analysis element, and substituting the maximum discharge signal value corresponding to each transformer in each power transmission line section in the associated line, the average running current and the average running voltage corresponding to each lead in each power transmission line section in the associated line into a calculation formulaObtaining safety indexes of internal analysis elements of the associated power transmission line, wherein sigma 1 and sigma 2 are preset weighted values, delta V and delta A respectively represent a preset allowable voltage difference value and a preset allowable current difference value, B ' represents a preset transformer safety discharge signal value, and V ' and A ' are respectively preset standard operating voltage and standard operating current of a lead;
acquiring historical severe weather occurrence times of the area position of the associated power transmission line and severe grades corresponding to severe weather occurrence times, recording the historical severe weather occurrence times of the area position of the associated power transmission line and the severe grades corresponding to severe weather occurrence times as auxiliary analysis elements, calculating the safety index of the auxiliary analysis elements of the associated power transmission line by using a calculation formula, and marking the safety index as FZ;
and substituting the comprehensive safety index YZ of the external analysis element of the associated power transmission line, the safety index NZ of the internal analysis element of the associated power transmission line and the safety index FZ of the auxiliary analysis element of the associated power transmission line into ZQ (lambda 1) YZ + lambda 1 NZ + lambda 3 FZ to obtain the comprehensive safety index of the power transmission and transformation of the power system to be monitored, wherein lambda 1, lambda 2 and lambda 3 respectively represent preset coefficients, and lambda 1+ lambda 2+ lambda 3 is 1.
As a preferred scheme, the specific process of evaluating the power transmission and transformation operation safety of the power system to be monitored in step S6 is as follows: the method comprises the steps of obtaining a comprehensive transmission and transformation safety index of the power system to be monitored, matching and comparing the comprehensive transmission and transformation safety index of the power system to be monitored with safety indexes corresponding to preset safety levels, and comparing the safety levels corresponding to the transmission and transformation of the power system to be monitored, wherein the preset safety levels comprise first-level safety, second-level safety and third-level safety, the first-level safety is greater than the second-level safety and is greater than the third-level safety, if the safety level corresponding to the transmission and transformation of the power system to be monitored reaches the second level or the first level, recording the operation evaluation state of the transmission and transformation of the power system to be monitored as safe, otherwise, recording the operation evaluation state of the transmission and transformation of the power system to be monitored as unsafe.
Compared with the prior art, the invention has the beneficial effects that: according to the intelligent assessment method for the power transmission and transformation operation safety quantification of the smart grid power system, the line states, power parameters and historical meteorological information corresponding to each power transmission line section in the associated power transmission lines are collected, and the power transmission and transformation operation safety assessment of the power system is carried out according to the collected information, so that on one hand, the problem that the current assessment mode is specific and general is solved, the targeted assessment on the operation safety of the overhead power transmission lines is realized, the accuracy of the power transmission and transformation operation safety assessment result of the power system is improved, the assessment workload of the power transmission and transformation operation safety of the power system is effectively reduced, the errors in the assessment process are reduced as much as possible, and the refined and visualized assessment on the power transmission and transformation operation safety of the power system is realized; on the other hand, the operation safety state of the power system associated with the power transmission line is effectively highlighted, the power transmission line is accurately and efficiently analyzed, and reliable and powerful data reference is provided for the power system to develop the operation and maintenance work of the overhead power transmission line to a certain extent.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.
FIG. 1 is a diagram of the steps of the method of the present invention.
Detailed Description
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
Referring to fig. 1, a smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method includes:
s1, acquiring a relevant power transmission line corresponding to the power system to be monitored, and extracting basic information corresponding to the relevant power transmission line;
specifically, the basic information corresponding to the associated power transmission line includes the position of the region to which the associated power transmission line corresponds, insulator string information, hardware fitting information and transformer information included in the associated power transmission line, wherein the insulator string information included in the associated power transmission line includes the number of insulator strings and the number of insulators included in each insulator string, the hardware fitting information included in the associated power transmission line includes the number of hardware fittings, the transformer information included in the associated power transmission line includes the number of transformers, an effective information basis is provided for subsequent analysis of the power system to be monitored by obtaining the basic information corresponding to the associated power transmission line, and an evaluation process of the power transmission and transformation operation safety of the power system to be monitored is promoted.
Step S2, dividing the associated transmission line into transmission line sections according to a preset interval, and detecting the line state corresponding to each transmission line section in the associated transmission line;
wherein, step S2 specifically includes the following steps:
step S21, counting the electric poles corresponding to each electric transmission line section in the associated electric transmission line, and detecting the corresponding state of each electric pole, wherein the specific detection process is as follows:
numbering each transmission line section in the associated transmission line according to a preset sequence, and sequentially marking the transmission line sections as 1,2,. i,. n;
marking each electric pole in each transmission line section in the associated transmission line as Gi rR is a pole number, r is 1,2,.. k, i is a transmission line section number, and i is 1,2,.. n;
and acquiring images of the electric poles by using the first cameras at the positions of the electric poles in the electric transmission line sections in the associated electric transmission line, acquiring the images corresponding to the electric poles in the electric transmission line sections in the associated electric transmission line, and acquiring the corresponding states of the electric poles in the electric transmission line sections in the associated electric transmission line.
Exemplarily, the process of obtaining the state corresponding to each electric pole in each electric transmission line segment in the associated electric transmission line is as follows: according to the image corresponding to each electric pole in each electric transmission line section in the associated electric transmission line, carrying out noise reduction and filtering processing on the image corresponding to each electric pole, carrying out crack contour extraction on the processed image of each electric pole, counting the number of cracks corresponding to each electric pole in each electric transmission line section, obtaining the contour area corresponding to each crack in each electric pole in each electric transmission line section, and further counting the comprehensive crack area corresponding to each electric pole in each electric transmission line section.
Step S22, counting each corresponding lead and each corresponding pull wire in each transmission line section in the associated transmission line, and detecting the state corresponding to each lead and each pull wire, wherein the specific detection process is as follows: marking each corresponding lead in each transmission line section in the associated transmission line as X according to each corresponding lead and each corresponding pull wire in each transmission line section in the associated transmission linei tAssociating pairs in each transmission line section in the transmission lineThe corresponding pull lines are marked as Li dThe unmanned aerial vehicle is used for shooting the wires and the stay wires in the transmission line section along the way to obtain wire images and stay wire images corresponding to the transmission line sections in the associated transmission line, and further obtaining wire states and stay wire states corresponding to the transmission line sections in the associated transmission line.
Exemplarily, obtaining a wire image and a stay wire image corresponding to each transmission line section in the associated transmission line, performing noise reduction and filtering processing on the wire images, importing each wire image in each transmission line section into a third-party website from the processed wire image corresponding to each transmission line section, obtaining an sag value corresponding to each wire in each transmission line section, and simultaneously comparing the processed stay wire image corresponding to each transmission line section with the image corresponding to each stay wire type to obtain the type corresponding to each stay wire;
in a specific embodiment, the pull string types include a full pull string, a broken pull string, a strandwire, and the like.
Step S23, counting each line element corresponding to each transmission line section in the associated transmission line, and obtaining a type corresponding to each line element, and further detecting a state corresponding to each line element in each type, wherein the type corresponding to each line element specifically includes an insulator string and a hardware fitting, and the specific detection process of the state is as follows: comparing the types of the corresponding line elements in each transmission line section in the associated transmission line with each other, and respectively screening out the number of the corresponding insulator strings and the number of the corresponding hardware fittings in each transmission line section in the associated transmission line to obtain the corresponding insulator strings and the corresponding hardware fittings in each transmission line section in the associated transmission line;
marking each insulator chain and each hardware fitting corresponding to each transmission line section in the associated transmission line as Ji sAnd Yi uS is an insulator string number, s is 1,2,.. g, u is an armour clamp number, and u is 1,2,... v;
detecting the surface salt-attached density of the insulator string carried by each insulator string in each transmission line section in the associated transmission line by using an insulator salt density tester carried by each insulator string in each transmission line section in the associated transmission line, further acquiring the surface equivalent salt-attached density corresponding to each insulator string in each transmission line section in the associated transmission line, and simultaneously acquiring the insulation resistance of each insulator in the insulator string by using an insulation resistance instrument carried by each insulator string in each transmission line section in the associated transmission line, so as to acquire the insulation resistance corresponding to each insulator in each insulator string in each transmission line section in the associated transmission line;
and detecting the temperature of each hardware in each transmission line section in the associated transmission line according to a preset acquisition time interval by using a temperature sensor carried by each hardware in each transmission line section in the associated transmission line, and acquiring the temperature corresponding to each hardware in each acquisition time interval in each transmission line section in the associated transmission line.
Step S3, detecting the electric power parameters corresponding to the associated electric transmission line to obtain the numerical values corresponding to the electric power parameters in the associated electric transmission line, wherein the electric power parameters are the electric power parameters of the conductor and the electric power parameters of the transformer, and the specific detection process is as follows:
selecting power detection points of all the wires in all the transmission line sections in the associated transmission line according to the corresponding wires in all the transmission line sections in the associated transmission line, laying power detection equipment at the selected power monitoring points, and detecting power parameters of all the wires by using the power detection equipment in all the power detection point positions of all the wires in all the transmission line sections in the associated transmission line according to preset detection time points, wherein the power parameters of the wires comprise wire running current and wire running voltage;
it should be noted that the power detection device includes a current sensor and a voltage sensor, where the current sensor is used for detecting the operating current of the conductor, and the voltage sensor is used for detecting the operating voltage of the conductor.
Extracting corresponding transformers in each transmission line section in the associated transmission line according to the number of the corresponding transformers in the associated transmission line, detecting discharge signals of the transformers in each transmission line section in the associated transmission line according to a preset acquisition time period by using the ultrahigh frequency sensor carried by each transformer in each transmission line section, and acquiring the discharge signal values of each transformer in each acquisition time period in each transmission line section in the associated transmission line.
Step S4, performing preliminary processing on each line state corresponding to each transmission line section in the associated transmission line and each power parameter corresponding to each transmission line section in the associated transmission line;
specifically, the specific processing procedure of performing preliminary processing on each line state corresponding to each transmission line segment in the associated transmission line and each power state corresponding to each transmission line segment in the associated transmission line is as follows:
firstly, according to each line state corresponding to each transmission line section in the associated transmission line, performing state confirmation on each line state to obtain state types corresponding to each electric pole, each lead, each pull wire and each line element in each type in each transmission line section in the associated transmission line;
in a specific embodiment, the specific process of preprocessing each line status and confirming each line status includes the following steps:
f1, comparing the number of cracks and the comprehensive crack area corresponding to each electric pole in each transmission line section with the number of standard cracks and the standard comprehensive crack area corresponding to a preset electric pole damage state, if the number of cracks and the average crack area corresponding to a certain electric pole are both larger than or equal to the preset value, recording the state type corresponding to the electric pole as a damage state, and otherwise, recording as a normal state;
f2, comparing the sag value corresponding to each lead in each transmission line section with the sag value corresponding to the preset lead sag abnormal state, if the sag value corresponding to a lead in a certain transmission line section is larger than the preset lead sag value corresponding to the lead sag abnormal state, marking the state type corresponding to the lead in the transmission line section as the abnormal sag state, otherwise, marking as the normal sag state; comparing a certain stay wire type with each stay wire type corresponding to a preset deformation state, recording the stay wire state type as a deformation state if the certain stay wire type is consistent with the stay wire type corresponding to the deformation state, and otherwise, connecting the stay wire state with an undeformed state;
illustratively, the type corresponding to the deformation state of the stay wire comprises loose strands, broken wires, abrasion and the like.
F3, obtaining surface equivalent salt density corresponding to each insulator string in each transmission line section in the associated transmission line, matching and comparing the surface equivalent salt density with a surface salt density value corresponding to each preset pollution state of the insulator string, screening out the pollution state type corresponding to each insulator string in each transmission line section in the associated transmission line, simultaneously obtaining an insulation resistance value corresponding to each insulator string in each transmission line section in the associated transmission line, matching and comparing the insulation resistance value corresponding to each insulator with an insulation resistance value corresponding to a preset insulation abnormal state, and if the insulation resistance value corresponding to an insulator in a certain insulator string conforms to the insulation resistance value corresponding to the preset insulation abnormal state, marking the state type of the insulator in the insulator string as an insulation abnormal state, otherwise, marking as an insulation normal state;
f4, obtaining the temperature corresponding to each hardware in each transmission line section in the associated transmission line in each acquisition time period, obtaining the average temperature corresponding to each hardware in each transmission line section in the associated line by using an average value calculation mode, comparing the average temperature corresponding to each hardware in each transmission line section in the associated line with the preset temperature corresponding to the abnormal state of the hardware, and recording the state type of the hardware as the abnormal state of the temperature if the average temperature corresponding to a certain hardware in a certain transmission line section is greater than or equal to the temperature corresponding to the abnormal state of the hardware, otherwise, recording as the normal state of the temperature.
Secondly, according to the running current and running voltage of each power detection point on each conductor in each transmission line section in the associated transmission line corresponding to each detection time point, calculating the average running current and average running voltage corresponding to each conductor in each transmission line section in the associated transmission line by using an average value calculation method, and respectively expressing the average running current and average running voltage as Vi tAnd Ai tSimultaneously screening out the maximum discharge signal value corresponding to each transformer in each transmission line section in the associated line according to the discharge signal value corresponding to each transformer in each acquisition time period in each transmission line section in the associated transmission line, and marking as Bi jJ denotes a transformer number, and j is 1, 2.
It is noted that in one embodiment, inclement weather includes high winds and rain and snow storms, ice, lightning strikes, and high temperatures, and inclement weather levels include three levels, wherein one level > two levels > three levels.
Step S5, extracting the area position of the associated power transmission line from the basic information corresponding to the associated power transmission line, and extracting historical meteorological information corresponding to the area position of the associated power transmission line from an area meteorological database, wherein the historical meteorological information comprises the frequency of occurrence of historical severe weather and the corresponding severe grade of the historical severe weather each time;
according to the method, the line state, the power parameter and the historical meteorological information corresponding to each power transmission line section in the associated power transmission line are acquired, so that the problem that the current evaluation mode is specific and general is solved, the targeted evaluation on the operation safety of the associated overhead power transmission line of the power system to be monitored is realized, the accuracy of the evaluation result of the power transmission and transformation operation safety of the power system is guaranteed, the evaluation workload of the operation safety of the power transmission and transformation of the power system is effectively reduced, the error in the evaluation process is reduced as much as possible, and the refined and visualized evaluation on the operation safety of the power transmission and transformation of the power system is realized.
Step S6, further analyzing the line state corresponding to the associated power transmission line, the primary processing result of each power parameter corresponding to the associated power transmission line and the historical meteorological information corresponding to the area position of the associated power transmission line, and evaluating the power transmission and transformation operation safety of the power system to be monitored;
it should be noted that the specific analysis process for further analyzing the line state corresponding to the associated power transmission line, the preliminary processing result of each power parameter corresponding to the associated power transmission line, and the historical meteorological information corresponding to the area location where the associated power transmission line is located includes the following steps
1) Acquiring state types corresponding to each electric pole, each lead, each stay wire and each line element in each transmission line section in the associated transmission line, recording the state types as external analysis elements, setting safety influence weights of the external analysis elements, further counting comprehensive safety indexes of the external analysis elements of the associated transmission line, and recording the comprehensive safety indexes as YZ;
illustratively, the specific setting process for setting the security impact weight for each external analysis element includes the following steps:
y1, obtaining state types corresponding to each electric pole in each electric transmission line section in the associated electric transmission line, wherein the state types of the electric poles comprise damage states and normal states, recording the safety influence weight value corresponding to the damage states of the electric poles as alpha, and recording the safety influence weight value corresponding to the normal states of the electric poles as alpha ', and alpha is larger than alpha'.
Y2, obtaining state types corresponding to each lead in each transmission line section in the associated transmission line, wherein the lead state types comprise an abnormal sag state and a normal sag state, recording a safety influence weight value corresponding to the abnormal sag state of the lead as beta, and recording a safety influence weight value corresponding to the normal sag state of the lead as beta ', wherein beta is larger than beta';
y3, obtaining state types corresponding to each stay wire in each transmission line section in the associated transmission line, wherein the state types corresponding to the stay wires comprise a deformation state and an undeformed state, recording the safety influence weight value corresponding to the deformation state of the stay wire as x, and recording the safety influence weight value corresponding to the undeformed state of the stay wire as x ', x is larger than x';
y4, obtaining state types corresponding to insulator strings of each transmission line segment in the associated transmission line, wherein the state types corresponding to the insulator strings comprise a pollution state and an insulation state, the pollution state comprises an uncleaned state, a common pollution state and a serious pollution state, a safety influence weight value corresponding to the uncleaned state is marked as delta 1, a safety influence weight value corresponding to a medium pollution state is marked as delta 1, a safety influence weight value corresponding to the serious pollution state is marked as delta 2, delta 3 is larger than delta 2 and larger than delta 1, the insulation state type comprises an insulation abnormal state and an insulation normal state, the safety influence weight value corresponding to the insulation abnormal state of the insulator in the insulator string is marked as phi, and the safety influence weight value corresponding to the insulation normal state of the insulator in the insulator string is marked as phi ', phi';
y5, obtaining states corresponding to all hardware fittings in all transmission line sections in the associated transmission line, wherein the hardware fitting state types comprise abnormal temperature states and normal temperature states, and recording safety influence weight values corresponding to the abnormal hardware fitting temperature states asRecording the corresponding safety influence weight value of the hardware temperature normal state
In another exemplary embodiment, the specific statistical process of statistically associating the comprehensive safety index of the external analysis element of the power transmission line is as follows:
r1, counting the number of the electric poles in the damage state in each transmission line section in the associated transmission line according to the state type corresponding to each electric pole in each transmission line section in the associated transmission line, and recording the number as k'i;
R2, counting the number of the wires in the abnormal sag state in each transmission line segment in the associated transmission line according to the state type corresponding to each wire in each transmission line segment in the associated transmission line, and recording the number as h'i;
R3, counting the number of pull wires in deformation state in each transmission line segment in the associated transmission line according to the state type corresponding to each pull wire in each transmission line segment in the associated transmission line, and marking as y'i;
R4, respectively counting the number of insulator strings in serious pollution state and the number of insulators in abnormal insulation state in each insulator string in each transmission line section in the associated transmission line according to the pollution state type and the insulation state type corresponding to each insulator string in each transmission line section in the associated transmission line, and recording the number of insulator strings in serious pollution state in each transmission line section as g'iThe number of insulators in an abnormal insulation state in each insulator string in each transmission line section is recorded as pi s;
R5, counting the quantity of hardware fittings in abnormal temperature state in each transmission line section in the associated transmission line according to the state type corresponding to each hardware fitting in each transmission line section in the associated transmission line, and marking the quantity of the hardware fittings as v'i;
R6, calculating the comprehensive safety index of the external analysis elements of the associated transmission line by using a calculation formula, wherein the specific calculation formula isMu 1, mu 2, mu 3 are preset correction factors, kiiRespectively expressed as the number of electric poles, the number of leads, the number of stay wires, the number of insulator strings and the number of hardware fittings corresponding to the ith transmission line section,and the number of insulators corresponding to the s-th insulator string in the ith transmission line section is represented.
2) Obtaining the corresponding numerical value of each power parameter in the associated power transmission line, recording each power parameter as an internal analysis element, and substituting the maximum discharge signal value corresponding to each transformer in each power transmission line section in the associated line, the average running current and the average running voltage corresponding to each lead in each power transmission line section in the associated line into a calculation formulaObtaining safety indexes of internal analysis elements of the associated power transmission line, wherein sigma 1 and sigma 2 are preset weighted values, delta V and delta A respectively represent a preset allowable voltage difference value and a preset allowable current difference value, B ' represents a preset transformer safety discharge signal value, and V ' and A ' are respectively preset standard operating voltage and standard operating current of a lead;
3) acquiring historical severe weather occurrence times of the area where the associated power transmission line is located and severe grades corresponding to severe weather occurrence times, recording the historical severe weather occurrence times of the area where the associated power transmission line is located and the severe grades corresponding to severe weather occurrence times as auxiliary analysis elements, calculating the safety index of the auxiliary analysis elements of the associated power transmission line by using a calculation formula, and marking the safety index as FZ;
in a specific embodiment, the associated power transmission line auxiliary analysis element safety index calculation process includes: comparing the corresponding severe grades of the area position of the associated power transmission line when severe weather occurs at each time, screening out the occurrence times corresponding to each severe grade of the area position of the associated power transmission line, and substituting the historical severe weather occurrence times and the occurrence times corresponding to each severe grade intoIn the method, a safety index of auxiliary analysis elements of the associated power transmission line is obtained, wherein ec represents the occurrence frequency of historical severe weather, yc represents the allowed occurrence frequency corresponding to preset severe weather,is a safety influence coefficient of severe weather, gammaxRepresents the safety influence weight, T, corresponding to the x-th preset severe levelxIndicating the number of occurrences corresponding to the xth severe level, wherein x is a severe level number, and x is w1, w2, w3, w1, w2 and w3 which respectively indicate a primary severe level, a secondary severe level and a tertiary severe level;
in addition, γ isxAnd TxThe values are positive numbers.
4) And substituting the comprehensive safety index YZ of the external analysis element of the associated power transmission line, the safety index NZ of the internal analysis element of the associated power transmission line and the safety index FZ of the auxiliary analysis element of the associated power transmission line into ZQ (lambda 1) YZ + lambda 1 NZ + lambda 3 FZ to obtain the comprehensive safety index of the power transmission and transformation of the power system to be monitored, wherein lambda 1, lambda 2 and lambda 3 respectively represent preset coefficients, and lambda 1+ lambda 2+ lambda 3 is 1.
In one embodiment, it should be noted that, if the safety index of the power system to be monitored is larger, the operation process of the power system to be monitored is safer, and otherwise, the power system to be monitored is more dangerous, and all the safety index formulas mentioned in this embodiment follow the rule.
Specifically, the specific process of evaluating the power transmission and transformation operation safety of the power system to be monitored in step S6 is as follows: the method comprises the steps of obtaining a comprehensive safety index of power transmission and power transformation of the power system to be monitored, matching and comparing the comprehensive safety index of the power transmission and power transformation of the power system to be monitored with safety indexes corresponding to preset safety levels, and comparing the safety levels corresponding to the power transmission and power transformation of the power system to be monitored, wherein the preset safety levels comprise first-level safety, second-level safety and third-level safety, the first-level safety is greater than the second-level safety and greater than the third-level safety, if the safety level corresponding to the power transmission and power transformation of the power system to be monitored reaches the second level or the first level, the operation evaluation state of the power transmission and power transformation of the power system to be monitored is recorded as safe, otherwise, the operation evaluation state of the power transmission and power transformation of the power system to be monitored is recorded as unsafe.
The specific process for evaluating the power transmission and transformation operation safety of the power system to be monitored comprises the following steps: the method comprises the steps of obtaining a comprehensive safety index of power transmission and power transformation of a power system to be monitored, matching and comparing safety indexes corresponding to safety levels preset by the comprehensive safety index of the power transmission and power transformation of the power system to be monitored, and comparing safety levels corresponding to the power transmission and power transformation of the power system to be monitored, wherein the preset safety levels comprise first-level safety, second-level safety and third-level safety, the first-level safety is greater than the second-level safety and greater than the third-level safety, if the safety level corresponding to the power transmission and power transformation of the power system to be monitored reaches the second level or the first level, the operation evaluation state of the power transmission and power transformation of the power system to be monitored is recorded as safe, and if not, the operation evaluation state of the power transmission and power transformation of the power system to be monitored is recorded as unsafe.
According to the embodiment of the invention, the operation safety state of the power transmission and transformation of the power system to be monitored is effectively highlighted by quantitatively evaluating the operation safety of the power transmission and transformation of the power system to be monitored, the accurate and efficient analysis of the power transmission line is realized, and reliable and powerful data reference is further provided for the development of the operation and maintenance work of the power system on the overhead power transmission line to a certain extent.
And step S7, sending the evaluation result of the power transmission and transformation operation safety of the power system to be monitored to the operation and maintenance supervision personnel corresponding to the power system to be monitored.
Specifically, the evaluation result of the operation safety of the power transmission and transformation system to be monitored is sent to the operation and maintenance supervision personnel corresponding to the power system to be monitored, so that the safety level and the operation evaluation state corresponding to the power transmission and transformation system to be monitored are sent to the operation and maintenance supervision personnel corresponding to the power system to be monitored.
The foregoing is merely exemplary and illustrative of the principles of the present invention and various modifications, additions and substitutions of the specific embodiments described herein may be made by those skilled in the art without departing from the principles of the present invention or exceeding the scope of the claims set forth herein.
Claims (10)
1. The intelligent power grid power system power transmission and transformation operation safety quantitative evaluation method is characterized by comprising the following steps:
s1, acquiring a relevant power transmission line corresponding to the power system to be monitored, and extracting basic information corresponding to the relevant power transmission line;
step S2, dividing the associated transmission line into transmission line sections according to a preset interval, and detecting the line state corresponding to each transmission line section in the associated transmission line;
wherein, step S2 specifically includes the following steps:
step S21, counting each electric pole corresponding to each electric transmission line section in the associated electric transmission line, and detecting the state corresponding to each electric pole;
step S22, counting each corresponding lead and each pull wire in each transmission line section in the associated transmission line, and detecting the state corresponding to each lead and each pull wire;
step S23, counting each corresponding line element in each transmission line section in the associated transmission line, obtaining the type corresponding to each line element, and further detecting the state corresponding to each line element in each type;
step S3, detecting the electric power parameters corresponding to the associated electric transmission line, and acquiring the numerical values corresponding to the electric power parameters in the associated electric transmission line;
step S4, performing preliminary processing on each line state corresponding to each transmission line section in the associated transmission line and each power parameter corresponding to each transmission line section in the associated transmission line;
step S5, extracting the area position of the associated power transmission line from the basic information corresponding to the associated power transmission line, and extracting historical meteorological information corresponding to the area position of the associated power transmission line from an area meteorological database, wherein the historical meteorological information comprises the frequency of occurrence of historical severe weather and the corresponding severe grade of the historical severe weather each time;
step S6, further analyzing the line state corresponding to the associated power transmission line, the primary processing result of each power parameter corresponding to the associated power transmission line and the historical meteorological information corresponding to the area position of the associated power transmission line, and evaluating the power transmission and transformation operation safety of the power system to be monitored;
and S7, sending the evaluation result of the power transmission and transformation operation safety of the power system to be monitored to the operation and maintenance manager corresponding to the power system to be monitored.
2. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the basic information corresponding to the associated power transmission line comprises the position of the corresponding region of the associated power transmission line, insulator string information, hardware fitting information and transformer information contained in the associated power transmission line.
3. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the method comprises the steps that insulator string information contained in the associated power transmission line is the number of insulator strings and the number of insulators contained in each insulator string, hardware fitting information contained in the associated power transmission line is the number of hardware fittings, and transformer information contained in the associated power transmission line is the number of transformers.
4. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the specific implementation process of detecting the state corresponding to each electric pole in step S21 includes the following steps:
numbering each transmission line section in the associated transmission lines, and sequentially marking the transmission line sections as 1,2,. i,. n;
will be associated with transmitting powerEach pole in each transmission line section in the line is marked Gi rR is a pole number, r is 1,2,.. k, i is a transmission line section number, and i is 1,2,.. n;
and acquiring images of the electric poles by using the first cameras at the positions of the electric poles in the electric transmission line sections in the associated electric transmission line, acquiring the images corresponding to the electric poles in the electric transmission line sections in the associated electric transmission line, and acquiring the corresponding states of the electric poles in the electric transmission line sections in the associated electric transmission line.
5. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the specific detection process of the state corresponding to each lead and each pull wire in the step S22 is as follows: marking each corresponding lead in each transmission line section in the associated transmission line as X according to each corresponding lead and each corresponding pull wire in each transmission line section in the associated transmission linei tMarking each corresponding stay wire in each transmission line section in the associated transmission line as Li dAnd the unmanned aerial vehicle is used for shooting the wires and the stay wires in the transmission line section along the road to obtain wire images and stay wire images corresponding to the transmission line sections in the associated transmission line, and further obtaining the wire states and the stay wire states corresponding to the transmission line sections in the associated transmission line.
6. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the type corresponding to each line element in the step S23 specifically includes an insulator string and a hardware fitting, and the specific state detection process includes the following steps:
comparing the types of the corresponding line elements in each transmission line section in the associated transmission line with each other, and respectively screening out the number of the corresponding insulator strings and the number of the corresponding hardware fittings in each transmission line section in the associated transmission line to obtain the corresponding insulator strings and the corresponding hardware fittings in each transmission line section in the associated transmission line;
marking each insulator chain and each hardware fitting corresponding to each transmission line section in the associated transmission line as Ji sAnd Yi uS is an insulator string number, s is 1,2,.. g, u is an armour clamp number, and u is 1,2,... v;
detecting the surface equivalent salt-attached density of the associated transmission line by using an insulator salt density tester carried by each insulator string in each transmission line section in the associated transmission line so as to obtain the surface equivalent salt-attached density corresponding to each insulator string in each transmission line section in the associated transmission line, and simultaneously collecting the insulation resistance of each insulator in the insulator string by using an insulation resistance instrument carried by each insulator string in each transmission line section in the associated transmission line so as to obtain the insulation resistance corresponding to each insulator in each insulator string in each transmission line section in the associated transmission line;
and detecting the temperature of each hardware in each transmission line section in the associated transmission line according to a preset acquisition time interval by using a temperature sensor carried by each hardware in each transmission line section in the associated transmission line, and acquiring the temperature corresponding to each hardware in each acquisition time interval in each transmission line section in the associated transmission line.
7. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: in the step S3, the power parameters corresponding to the associated power transmission line are the power parameters of the conductor and the power parameters of the transformer, and the specific detection process is as follows:
selecting power detection points of all the wires in all the transmission line sections in the associated transmission line according to the corresponding wires in all the transmission line sections in the associated transmission line, laying power detection equipment at the selected power monitoring points, detecting power parameters of all the wires by using the power detection equipment in all the power detection point positions of all the wires in all the transmission line sections in the associated transmission line according to preset detection time points, and acquiring power parameters of all the wires corresponding to all the detection time points of all the power detection point positions of all the wires in all the transmission line sections in the associated transmission line, wherein the power parameters of the wires comprise wire operating current and wire operating voltage;
extracting the corresponding transformers in each transmission line section in the associated transmission line according to the number of the corresponding transformers in the associated transmission line and the corresponding positions of the transformers, detecting discharge signals of the ultrahigh frequency sensors carried by the transformers in each transmission line section in the associated transmission line according to a preset acquisition time period, and acquiring the discharge signal values of the transformers in each transmission line section in the associated transmission line corresponding to each acquisition time period.
8. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the specific processing procedure of performing preliminary processing on each line state corresponding to each transmission line segment in the associated transmission line and each power state corresponding to each transmission line segment in the associated transmission line in step S4 is as follows:
firstly, according to each line state corresponding to each transmission line section in the associated transmission line, performing state confirmation on each line state to obtain state types corresponding to each electric pole, each lead, each pull wire and each line element in each type in each transmission line section in the associated transmission line;
secondly, according to the running current and running voltage of each power detection point on each conductor in each transmission line section in the associated transmission line corresponding to each detection time point, calculating the average running current and average running voltage corresponding to each conductor in each transmission line section in the associated transmission line by using an average value calculation method, and respectively expressing the average running current and average running voltage as Vi tAnd Ai tSimultaneously screening out the maximum discharge signal value corresponding to each transformer in each transmission line section in the associated line according to the discharge signal value corresponding to each transformer in each acquisition time period in each transmission line section in the associated transmission line, and marking as Bi jJ denotes a transformer number, and j is 1, 2.
9. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the specific analysis process of further analyzing the line state corresponding to the associated power transmission line, the preliminary processing result of each power parameter corresponding to the associated power transmission line, and the historical meteorological information corresponding to the area position where the associated power transmission line is located in step S6 includes the following steps:
acquiring state types corresponding to each electric pole, each lead, each stay wire and each line element in each transmission line section in the associated transmission line, recording the state types as external analysis elements, setting safety influence weights of the external analysis elements, further counting comprehensive safety indexes of the external analysis elements of the associated transmission line, and recording the comprehensive safety indexes as YZ;
obtaining the corresponding numerical value of each power parameter in the associated power transmission line, recording each power parameter as an internal analysis element, and substituting the maximum discharge signal value corresponding to each transformer in each power transmission line section in the associated line, the average running current and the average running voltage corresponding to each lead in each power transmission line section in the associated line into a calculation formulaObtaining safety indexes of internal analysis elements of the associated power transmission line, wherein sigma 1 and sigma 2 are preset weighted values, delta V and delta A respectively represent a preset allowable voltage difference value and a preset allowable current difference value, B ' represents a preset transformer safety discharge signal value, and V ' and A ' are respectively preset standard operating voltage and standard operating current of a lead;
acquiring historical severe weather occurrence times of the area where the associated power transmission line is located and severe grades corresponding to severe weather occurrence times, recording the historical severe weather occurrence times of the area where the associated power transmission line is located and the severe grades corresponding to severe weather occurrence times as auxiliary analysis elements, calculating the safety index of the auxiliary analysis elements of the associated power transmission line by using a calculation formula, and marking the safety index as FZ;
and substituting the comprehensive safety index YZ of the external analysis element of the associated power transmission line, the safety index NZ of the internal analysis element of the associated power transmission line and the safety index FZ of the auxiliary analysis element of the associated power transmission line into ZQ (lambda 1) YZ + lambda 1 NZ + lambda 3 FZ to obtain the comprehensive safety index of the power transmission and transformation of the power system to be monitored, wherein lambda 1, lambda 2 and lambda 3 respectively represent preset coefficients, and lambda 1+ lambda 2+ lambda 3 is 1.
10. The smart grid power system power transmission and transformation operation safety quantitative intelligent evaluation method as claimed in claim 1, wherein: the specific process of evaluating the power transmission and transformation operation safety of the power system to be monitored in the step S6 is as follows: the method comprises the steps of obtaining a comprehensive safety index of power transmission and power transformation of the power system to be monitored, matching and comparing the comprehensive safety index of the power transmission and power transformation of the power system to be monitored with safety indexes corresponding to preset safety levels, and comparing the safety levels corresponding to the power transmission and power transformation of the power system to be monitored, wherein the preset safety levels comprise first-level safety, second-level safety and third-level safety, the first-level safety is greater than the second-level safety and greater than the third-level safety, if the safety level corresponding to the power transmission and power transformation of the power system to be monitored reaches the second level or the first level, the operation evaluation state of the power transmission and power transformation of the power system to be monitored is recorded as safe, otherwise, the operation evaluation state of the power transmission and power transformation of the power system to be monitored is recorded as unsafe.
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