Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
An embodiment of the present invention provides a method for evaluating operation quality of a power transformation device, and specifically, as shown in fig. 1, the method for evaluating operation quality of a power transformation device includes:
and step S1, acquiring the operation parameters of the substation equipment.
Illustratively, the operation parameters of the power transformation device include the total number of on-grid devices of the power transformation device, the total number of on-grid devices of the power transformation device provided by a certain supplier, the total number of device failures of the power transformation device provided by a certain supplier, the total number of the power transformation devices provided by a certain supplier without failures, and the like, and those skilled in the art can obtain the operation parameters according to requirements in an actual evaluation process.
And step S2, obtaining an efficiency index EOE of the power transformation equipment, a risk index ROE of the power transformation equipment and a cost index COE of the power transformation equipment according to the operation parameters.
Step S3, obtaining an operation quality index EQE of the power transformation device according to the efficiency index EOE, the risk index ROE, and the cost index COE, where EQE is EOE + ROE + COE.
In the technical scheme of this embodiment, after the operation parameters of the power transformation equipment are obtained, according to the operation parameters, the efficiency index EOE, the risk index ROE and the cost index COE of the power transformation equipment can be obtained, and then, the operation quality index EQE for evaluating the operation quality of the power transformation equipment is finally obtained by integrating the efficiency index EOE, the risk index ROE and the cost index COE, so that when the operation quality of the power transformation equipment is evaluated, the operation quality of the power transformation equipment is more comprehensively evaluated by considering not only the efficiency index but also the risk index and the cost index of the power transformation equipment, and further, a worker can conveniently make an operation and maintenance plan for the power transformation equipment provided by different suppliers, and can also provide guidance for the type selection of the power transformation equipment.
Alternatively, the performance index EOE in step S2 may include a plurality of scores of the power transformation equipment in terms of performance, and similarly, the risk index ROE and the cost index COE may also include a plurality of scores of the power transformation equipment in terms of risk and cost, respectively. For the convenience of understanding and implementation of those skilled in the art, the following embodiments of the present invention will provide specific contents of the above-mentioned performance index EOE, risk index ROE and cost index COE.
First, the performance indicator EOE may include an equipment inventory fraction EI of the power transformation equipment.
Illustratively, the specific steps of obtaining the device holding quantity fraction EI include:
basic EI of equipment inventory for acquiring power transformation equipmentb。
Device capacity full-scale EI for acquiring power transformation devicef。
It should be noted that, those skilled in the art can set the equipment holding amount of the power transformation equipment according to the actual situation to be substantially EIbAnd full-load EI of equipment inventory of power transformation equipmentfThe specific values of (b) are not intended to limit the scope of the present invention.
Acquiring the total number N of the transformer equipment in the network provided by the ith supplieri。
According to the total number N of the transformer equipment provided by the ith supplieriObtaining the maximum value N of the total number of the transformer equipment in the network provided by the suppliermaxWherein N ismax=max(Ni)。
Substantially dividing EI according to equipment holding quantitybFull-scale EI of equipment holding amountfAnd the total number N of the transformer equipments provided by the ith supplieriAnd the maximum total number of the power transformation equipment provided by the supplierValue NmaxAnd obtaining a device holding quantity fraction EI, wherein,
in addition, the performance index EOE may further include a technical support fraction TS of the power transformation equipment and a unit complaint fraction OC of the power transformation equipment, where the performance index EOE of the power transformation equipment is EI + TS-OC.
Illustratively, the specific step of obtaining the technical support score TS includes:
obtaining technical support base score T of power transformation equipmentb。
Acquiring technical support full score T of power transformation equipmentf。
Obtaining a number n of scoring reports for technical support of a provider on a substation devicek。
Obtaining the grade t of the technical support of the supplier to the power transformation equipment in the ith grade reporti,tiIs 20.
Scoring T according to a technical support basisbTechnical support full score TfThe number n of rating reports for the technical support of the power transformation equipment by the supplierkAnd a rating t of technical support of the power transformation equipment by the supplieriA technical support score, TS, is obtained, wherein,
when n iskWhen equal to 0, TS equal to Tb;
When n iskWhen the signal is not equal to 0, the signal is transmitted,
illustratively, the specific step of obtaining the complaint score OC of the running unit includes:
obtaining the major complaint times n of the power transformation equipment within the complaint validity period1General complaint times n of power transformation equipment2And the number n of slight complaints of the power transformation equipment3。
According to the number of major complaints n1General number of complaints n2And the number of slight complaints n3Obtaining a unit complaint score OC of 4 × n1+2×n2+1×n3。
The efficiency index EOE of the power transformation equipment is determined through the three aspects, the comprehensiveness of the obtained efficiency index EOE can be improved, and therefore the comprehensiveness of the operation quality index EQE of the operation quality of the power transformation equipment is improved.
The risk index ROE may include an equipment failure score EF of the power transformation equipment, an equipment state score ES of the power transformation equipment, and a batch defect score BD of the power transformation equipment.
Illustratively, the specific steps of obtaining the risk indicator ROE include:
and acquiring an equipment fault fraction EF of the power transformation equipment.
And acquiring an equipment state score ES of the power transformation equipment.
And acquiring the batch defect fraction BD of the power transformation equipment.
And obtaining a risk index ROE according to the equipment failure score EF, the equipment state score ES and the batch defect score BD, wherein the ROE is EF + ES-BD.
Specifically, the specific methods for obtaining the equipment fault score EF of the power transformation equipment, obtaining the equipment state score ES of the power transformation equipment, and obtaining the batch defect score BD of the power transformation equipment respectively include:
(1) the specific steps of obtaining the equipment fault fraction EF of the power transformation equipment comprise:
acquiring fault full score F of power transformation equipmentf。
Obtaining fault reference score F of power transformation equipmentb。
It is to be noted that those skilled in the artThe personnel can set the fault full score F of the power transformation equipment according to the actual situationfAnd fault reference branch F of power transformation equipmentbThe specific values of (b) are not intended to limit the scope of the present invention.
And acquiring the total number N of the transformer equipment in the network.
And acquiring the total equipment fault times n of the power transformation equipment.
Acquiring the total network fault rate f of the power transformation equipment according to the total number N of the on-network equipment and the total number N of equipment faultsnWherein
acquiring the total number N of the transformer equipment in the network provided by the ith supplieri。
Respectively acquiring the number n of equipment faults in the 1 st operating year interval of the power transformation equipment provided by the ith supplier1And the 2 nd operation year interval equipment failure times n2And the number n of equipment faults in the 3 rd operation year interval3And the 4 th operation year interval equipment failure frequency n4And the number n of equipment faults in the 5 th operation year interval5Wherein, the 1 st operation year interval is 0 to 5 years of operation, the 2 nd operation year interval is 6 to 10 years of operation, the 3 rd operation year interval is 11 to 15 years of operation, the 4 th operation year interval is 16 to 20 years of operation, and the 5 th operation year interval is more than 20 years of operation.
According to the number n of equipment faults in the 1 st operation year interval1And the 2 nd operation year interval equipment failure times n2And the number n of equipment faults in the 3 rd operation year interval3And the 4 th operation year interval equipment failure frequency n4And the number n of equipment faults in the 5 th operation year interval5Obtaining the total number n of equipment faults of the transformation equipment provided by the ith supplierFWherein n isF=n1+n2+n3+n4+n5。
According to the total number N of the transformer equipment provided by the ith supplieriAnd the total number n of equipment failures of the transformation equipment provided by the ith supplierFObtaining the failure rate f of the transformation equipment provided by the ith suppliersWherein
acquiring the total number F of the faultless power transformation equipment provided by the ith supplieri。
According to the total number F of the fault-free power transformation equipment provided by the ith supplieriObtaining a maximum value F of the total number of the fault-free power transformation equipment provided by the suppliermaxWherein F ismax=max(Fi)。
According to fault full score FfAnd a fault reference point FbFailure rate f of the whole networkn1 st operation year interval equipment failure frequency n1And the 2 nd operation year interval equipment failure times n2And the number n of equipment faults in the 3 rd operation year interval3And the 4 th operation year interval equipment failure frequency n4And the number n of equipment faults in the 5 th operation year interval5And the total number n of equipment failures of the power transformation equipment provided by the ith supplierFFailure rate f of power transformation equipment provided by ith suppliersTotal number of failed power transformation equipment F provided by ith supplieriAnd a maximum value F of the total number of non-failed power transformation devices provided by the suppliermaxObtaining an equipment failure score, EF, wherein,
when n isFWhen the content is equal to 0, the content,
when n isFNot equal to 0, and fs≥fnWhen EF is equal to Fb-(4×n1+3×n2+2×n3+1×n4+1×n5);
When n isFNot equal to 0, and fs<fnWhen the temperature of the water is higher than the set temperature,
(2) the specific step of obtaining the equipment state score ES comprises the following steps:
respectively acquiring the total number ES of the transformation equipment in the normal state provided by the ith supplier1Total number of substation devices in attention status ES2And total number of abnormal-state power transformation devices ES3。
It should be added that, for the discrimination of the power transformation equipment in the normal state, the attention state and the abnormal state, there is a unified discrimination standard in the art, and a person skilled in the art can obtain the total ES of the power transformation equipment in the normal state provided by the ith supplier by discriminating the state of the power transformation equipment according to the discrimination standard1Total number of substation devices in attention status ES2And total number of abnormal-state power transformation devices ES3。
Total number of power transformation devices ES according to normal state1Total number of substation devices in attention status ES2And total number of abnormal-state power transformation devices ES3Obtaining a basic score ES of the equipment state of the power transformation equipmentbWherein
acquiring the total number N of the transformer equipment in the network provided by the ith supplieri;
Acquiring a first equipment year occupation ratio coefficient x of power transformation equipment provided by the ith supplier1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3。
Illustratively, a first equipment age ratio coefficient x of the power transformation equipment provided by the ith supplier is acquired1The second is provided withSpare year occupation ratio coefficient x2And a third device age ratio coefficient x3The method comprises the following specific steps:
respectively acquiring the number n of the transformation equipment in the 1 st operation year interval provided by the ith supplier1And the number n of the power transformation equipment in the 2 nd operation year interval2And the number n of the transformation equipment in the 3 rd operation year interval3,
Wherein, the 1 st operation year interval is 0 to 5 years of operation, the 2 nd operation year interval is 6 to 15 years of operation, and the 3 rd operation year interval is more than 15 years of operation.
According to the total number N of the transformer equipment provided by the ith supplieriAnd the number n of the transformation equipment in the 1 st operation year interval provided by the ith supplier1And the number n of the transformation equipment in the 2 nd operation year interval provided by the ith supplier2And the number n of the transformation equipment in the 3 rd operation year interval provided by the ith supplier3Obtaining a first equipment age ratio coefficient x of the transformation equipment provided by the ith supplier1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3Wherein
obtaining a first equipment operation age correction coefficient cs of the power transformation equipment provided by the ith supplier1The second equipment operation age correction coefficient cs2And a third equipment operation age correction coefficient cs3Wherein cs is1=1.2,cs2=1,cs3=0.8。
It is necessary to supplement the above-mentioned first equipment operation age correction coefficient cs1The operating age correction coefficient of the power transformation equipment with the operating time of 0 to 5 years and the second equipment operating age correction coefficient cs are provided for the ith supplier2The operating age correction coefficient of the power transformation equipment with the operating time of 6 to 15 years is provided for the ith supplier, and the operating age correction coefficient of the third equipmentPositive coefficient cs3And the operating age correction coefficient of the power transformation equipment with the operating time of more than 15 years is provided for the ith supplier. Since the shorter the operating life of the power transformation device, the more valuable the evaluation of the operating quality of the power transformation device by the power transformation device parameters, the correction factor cs for the operating life of the first device1Has the largest value, and the second equipment operation age correction coefficient cs2Is less than the first equipment operation age correction coefficient cs1Value of (c), third plant operational age correction factor cs3The value of (a) is minimal.
Basic score ES according to device statusbThe first equipment year occupation ratio coefficient x1The second equipment year occupation ratio coefficient x2The third equipment year occupation ratio coefficient x3The first equipment operation age correction coefficient cs1A second operating life correction coefficient cs2And a third operating age correction factor cs3Obtaining a device status score ES, wherein ES is ESb×(x1×cs3+x2×cs2+x3×cs1)。
(3) The specific steps of obtaining the batch defect fraction BD include:
acquiring the number n of batch defect cases found by the operation unit processed by the ith supplier1。
Acquiring the number n of batch defect cases found by a running unit which is not processed by the ith supplier2。
The number n of batch-wise defective cases found from the unit of operation processed by the ith supplier1And the number n of batch-type defective cases found by the operation unit which is not processed by the ith supplier2Obtaining a batch defect score BD, wherein BD 2 × n1+8×n2。
By determining the risk index ROE of the power transformation equipment in the three aspects, the comprehensiveness of the obtained risk index ROE can be improved, and therefore the comprehensiveness of the operation quality index EQE of the operation quality of the power transformation equipment is further improved.
Thirdly, the cost index COE may include a device reliability score ER of the power transformation device, a general defect score CD of the power transformation device, an emergency defect score UD of the power transformation device, and a major defect score MD of the power transformation device. Specific types of defects generated in the power transformation equipment include: general defects, emergency defects, and major defects; for the specific types of the defects generated by a certain power transformation equipment, the field has a unified judgment standard, and through the judgment standard, a person skilled in the art can judge the specific types of the defects generated by the power transformation equipment.
Illustratively, the specific step of obtaining the cost index COE in step S2 includes:
and acquiring an equipment reliability score ER of the power transformation equipment.
A general defect score CD of the power transformation device is obtained.
And acquiring an emergency defect score UD of the power transformation equipment.
And acquiring a major defect score MD of the power transformation equipment.
And obtaining a cost index COE according to the device reliability score ER, the general defect score CD, the emergency defect score UD and the major defect score MD, wherein the COE is ER + CD + UD + MD.
Specifically, the specific methods for acquiring the device reliability score ER of the power transformation device, acquiring the general defect score CD of the power transformation device, acquiring the emergency defect score UD of the power transformation device, and acquiring the major defect score MD of the power transformation device are respectively as follows:
(1) the specific step of obtaining the equipment reliability score ER comprises the following steps:
acquiring the total number N of the transformer equipment in the network provided by the ith supplieri。
Obtaining statistical year n of power transformation equipmentr。
Get the ith supply respectivelyNumber of hours t of overhaul outage of commercial power transformation equipment1Hours t of minor repair outage2Number of first class non-stop hours t3And the second class non-stop hours t4And the number of non-stop hours t of the third kind5。
According to the total number N of the transformer equipment provided by the ith supplieriAnd the statistical year n of the power transformation equipment provided by the ith supplierrHours t of major repair outage1Hours t of minor repair outage2Number of first class non-stop hours t3And the second class non-stop hours t4And the number of non-stop hours t of the third kind5Obtaining the overhaul shutdown coefficient r of the transformation equipment provided by the ith supplier1Minor repair shutdown coefficient r2First class of non-stop coefficients r3Class II non-stop coefficient r4And a third class of non-stop coefficients r5Wherein
according to the major repair outage coefficient r1Minor repair shutdown coefficient r2First class of non-stop coefficients r3Class II non-stop coefficient r4And a third class of non-stop coefficients r5Obtaining the equipment reliability basic score ER of the power transformation equipmentbWherein ERb=3×r1+1×r2+3×r3+2×r4+1×r5。
Acquiring a first equipment year occupation ratio coefficient x of power transformation equipment provided by the ith supplier1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3。
Illustratively, the above-mentioned obtaining the first device age ratio coefficient x1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3And the step of obtaining the device status score ESObtaining a first equipment age ratio coefficient x in the step1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3The specific methods are the same, and thus are not described herein again.
Obtaining a first equipment operation age correction coefficient cs of the power transformation equipment provided by the ith supplier1A second operating life correction coefficient cs2And a third operating age correction factor cs3Wherein cs is1=1.2,cs2=1,cs3=0.8。
Base score ER based on device reliabilitybThe first equipment year occupation ratio coefficient x1The second equipment year occupation ratio coefficient x2The third equipment year occupation ratio coefficient x3The first equipment operation age correction coefficient cs1A second operating life correction coefficient cs2And a third operating age correction factor cs3Obtaining a device reliability score ER, wherein ER ═ ERb×(x1×cs3+x2×cs2+x3×cs1)。
(2) The specific steps of acquiring the general defect score CD comprise:
acquiring general defect full score C of power transformation equipmentf。
Obtaining a general defect benchmark score C of a power transformation deviceb。
It should be noted that, a person skilled in the art can set the general defect full score C of the power transformation equipment according to actual conditionsfAnd general defect benchmark score CbThe specific values of (b) are not intended to limit the scope of the present invention.
Acquiring the total number N of the transformer equipment in the network provided by the ith supplieri。
Acquiring the general defect number n of the transformation equipment provided by the ith supplierc1。
According to the ith supplierTotal number of on-grid stations N of transformer equipmentiAnd the number n of general defects of the transforming equipments provided by the ith supplierc1Obtaining a general defect rate basic value c of the power transformation equipment1Wherein
acquiring a first equipment year occupation ratio coefficient x of power transformation equipment provided by the ith supplier1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3。
Illustratively, the above-mentioned obtaining the first device age ratio coefficient x1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3And obtaining a first device age ratio coefficient x in the step of obtaining the device status score ES1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3The specific methods are the same, and thus are not described herein again.
Obtaining a first equipment operation age correction coefficient cs of the power transformation equipment provided by the ith supplier1A second operating life correction coefficient cs2And a third operating age correction factor cs3Wherein cs is1=1.2,cs2=1,cs3=0.8。
According to the general defect rate basic value c1The first equipment year occupation ratio coefficient x1The second equipment year occupation ratio coefficient x2The third equipment year occupation ratio coefficient x3The first equipment operation age correction coefficient cs1A second operating life correction coefficient cs2And a third operating age correction factor cs3Obtaining a correction value c of the general defect rate of the power transformation equipment2Wherein c is2=c1×(x1×cs1+x2×cs2+x3×cs3)。
And acquiring the total number N of the transformer equipment in the network.
Acquiring general defect total number n of power transformation equipmentc。
According to the total number N of the on-grid stations and the total number N of the general defects of the transformation equipmentcObtaining the general defect rate basic value c of the whole network of the power transformation equipment3Wherein
obtaining a first whole-network equipment year occupation ratio coefficient y of the power transformation equipment1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3。
Illustratively, the first network-wide equipment age ratio coefficient y is obtained1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3The method comprises the following specific steps:
respectively acquiring the total number n of the power transformation equipment in the 1 st operation year interval1And the total number n of the power transformation equipment in the 2 nd operation year interval2And the total number n of the power transformation equipment in the 3 rd operation year interval3Wherein, the 1 st operation year interval is 0 to 5 years of operation, the 2 nd operation year interval is 6 to 15 years of operation, and the 3 rd operation year interval is more than 15 years of operation.
According to the total number N of the on-grid transformer equipment and the total number N of the transformer equipment in the 1 st operation year interval1And the total number n of the power transformation equipment in the 2 nd operation year interval2And the total number n of the power transformation equipment in the 3 rd operation year interval3Obtaining a first whole network equipment year occupation ratio coefficient y of the power transformation equipment1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3Wherein
obtainingFirst whole-network equipment operation age correction coefficient cy of power transformation equipment1And the second whole network equipment operation age correction coefficient cy2And the operation age correction coefficient cy of the third network-wide equipment3Wherein, cy1=1.2,cy2=1,cy3=0.8。
It is necessary to supplement that the above-mentioned first network-wide device operation age correction factor cy1The operation year correction coefficient of the power transformation equipment with the operation time of 0-5 years in the whole network and the operation year correction coefficient cy of the second whole network equipment2The operation year correction coefficient of the power transformation equipment with the operation time of 6 to 15 years in the whole network and the operation year correction coefficient cy of the third whole network equipment3And the operation year correction coefficient of the power transformation equipment with the operation time of more than 15 years in the whole network is obtained.
First equipment operating age correction factor cs similar to power transformation equipment provided by ith supplier1The second equipment operation age correction coefficient cs2And a third equipment operation age correction coefficient cs3Since the shorter the operation period of the power transformation equipment, the more reference value the evaluation of the operation quality of the power transformation equipment, the correction coefficient cy of the operation period of the first whole network equipment1The value of (a) is maximum, and the second whole network equipment operation age correction coefficient cy2Is less than the first equipment operation year correction coefficient cy1The value of (a), the third whole network equipment operation age correction coefficient cy3The value of (a) is minimal.
According to the general defect rate basic value c of the whole network3The first whole network equipment age ratio coefficient y1The second whole network equipment age ratio coefficient y2Third whole network equipment age ratio coefficient y3The operation age correction coefficient cy of the first whole network equipment1And the second whole network equipment operation age correction coefficient cy2And the operation age correction coefficient cy of the third network-wide equipment3Obtaining the general defect rate correction value c of the whole network of the power transformation equipment4Wherein c is4=c3×(y1×cy1+y2×cy2+y3×cy3)。
Correcting value c according to general defect rate of whole network4Obtaining a critical reserve N for the occurrence of a general defect of the transformation equipmentccWherein
according to the general defect full score CfGeneral Defect benchmark score CbGeneral defect rate correction value c2And the correction value c of the general defect rate of the whole network4A generic defect score CD is obtained, wherein,
when c is going to2When equal to 0, if Nsc≤NccIf CD is equal to CbIf N is presentsc>NccIf CD is equal to Cf;
When c is going to2≥c4When the temperature of the water is higher than the set temperature,
when c is going to2<c4When the temperature of the water is higher than the set temperature,
(3) the specific steps of obtaining the emergency defect score UD comprise:
acquiring emergency defect full-scale U of power transformation equipmentf。
Obtaining emergency defect benchmark sub-U of power transformation equipmentb。
It should be noted that, those skilled in the art can set the full fraction U of the emergency defect of the power transformation equipment according to the actual situationfAnd an emergency defect reference branch UbThe specific values of (b) are not intended to limit the scope of the present invention.
Acquiring the total number N of the transformer equipment in the network provided by the ith supplieri。
Acquiring the number n of emergency defects of the power transformation equipment provided by the ith supplieru1。
According to the total number N of the transformer equipment provided by the ith supplieriAnd the number n of emergency defects of the power transformation equipment provided by the ith supplieru1Obtaining the basic value u of the emergency defect rate of the power transformation equipment1Wherein
acquiring a first equipment year occupation ratio coefficient x of power transformation equipment provided by the ith supplier1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3。
Illustratively, the above-mentioned obtaining the first device age ratio coefficient x1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3And obtaining a first device age ratio coefficient x in the step of obtaining the device status score ES1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3The specific methods are the same, and thus are not described herein again.
Obtaining a first equipment operation age correction coefficient cs of the power transformation equipment provided by the ith supplier1A second operating life correction coefficient cs2And a third operating age correction factor cs3Wherein cs is1=1.2,cs2=1,cs3=0.8。
According to the emergency defect rate basic value u1The first equipment year occupation ratio coefficient x1The second equipment year occupation ratio coefficient x2The third equipment year occupation ratio coefficient x3The first equipment operation age correction coefficient cs1A second operating life correction coefficient cs2And a third operating age correction factor cs3Obtaining an emergency defect rate correction value u for the power transformation equipment2Wherein u is2=u1×(x1×cs1+x2×cs2+x3×cs3)。
And acquiring the total number N of the transformer equipment in the network.
Acquiring total number n of emergency defects of power transformation equipmentu。
According to the total number N of the on-grid stations and the total number N of the emergency defects of the power transformation equipmentuObtaining the basic value u of the emergency defect rate of the whole network of the power transformation equipment3Wherein
obtaining a first whole-network equipment year occupation ratio coefficient y of the power transformation equipment1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3。
Illustratively, the above-mentioned obtaining the first network-wide device age ratio coefficient y1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3And acquiring the first whole network equipment age ratio coefficient y in the step of acquiring the general defect fraction CD of the power transformation equipment1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3The specific methods are the same, and thus are not described herein again.
Obtaining a first whole-network equipment operation age correction coefficient cy of the power transformation equipment1And the second whole network equipment operation age correction coefficient cy2And the operation age correction coefficient cy of the third network-wide equipment3Wherein, cy1=1.2,cy2=1,cy3=0.8。
According to the basic value u of the emergency defect rate of the whole network3The first whole network equipment age ratio coefficient y1The second whole network equipment age ratio coefficient y2Third whole network equipment age ratio coefficient y3First whole network equipment operation year repairPositive coefficient cy1And the second whole network equipment operation age correction coefficient cy2And the operation age correction coefficient cy of the third network-wide equipment3Obtaining the whole network emergency defect rate correction value u of the power transformation equipment4Wherein u is4=u3×(y1×cy1+y2×cy2+y3×cy3)。
According to the corrected value c of the emergency defect rate of the whole network4Obtaining a critical reserve N for the occurrence of an emergency defect of the transformation equipmentcuWherein
according to the emergency defect full score UfThe emergency defect reference is divided into UbAnd an emergency defect rate correction value u2And the total network emergency defect rate correction value u4And obtaining an emergency defect score UD, wherein,
when u is2When equal to 0, if Nsu≤NcuIf UD is equal to UbIf N is presentsu>NcuIf UD is equal to Uf;
When u is2≥u4When the temperature of the water is higher than the set temperature,
when u is2<u4When the temperature of the water is higher than the set temperature,
(4) the method comprises the following specific steps of:
obtaining the major defect full score M of the power transformation equipmentf。
Obtaining major defect benchmark M of power transformation equipmentb。
It should be noted that those skilled in the art can set the actual conditions according to the actual conditionsFull-scale major defect M of power transformation equipmentfAnd major defect benchmark score MbThe specific values of (b) are not intended to limit the scope of the present invention.
Acquiring the total number N of the transformer equipment in the network provided by the ith supplieri。
Obtaining the number n of major defects of the power transformation equipment provided by the ith supplierm1。
According to the total number N of the transformer equipment provided by the ith supplieriAnd the number n of significant defects of the power transformation equipment provided by the ith supplierm1Obtaining the major defect rate basic value m of the power transformation equipment1Wherein
acquiring a first equipment year occupation ratio coefficient x of power transformation equipment provided by the ith supplier1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3。
Illustratively, the above-mentioned obtaining the first device age ratio coefficient x1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3And obtaining a first device age ratio coefficient x in the step of obtaining the device status score ES1The second equipment year occupation ratio coefficient x2And a third device age ratio coefficient x3The specific methods are the same, and thus are not described herein again.
Obtaining a first equipment operation age correction coefficient cs of the power transformation equipment provided by the ith supplier1A second operating life correction coefficient cs2And a third operating age correction factor cs3Wherein cs is1=1.2,cs2=1,cs3=0.8。
According to the major defect rate basic value m1The first equipment year occupation ratio coefficient x1The second equipment year occupation ratio coefficient x2The third equipment year occupation ratio coefficient x3The first equipment operation age correction coefficient cs1A second operating life correction coefficient cs2And a third operating age correction factor cs3Obtaining the major defect rate correction value m of the power transformation equipment2Wherein m is2=m1×(x1×cs1+x2×cs2+x3×cs3)。
And acquiring the total number N of the transformer equipment in the network.
Acquiring the total number n of major defects of the power transformation equipmentm。
According to the total number N of the on-grid stations and the total number N of the major defects of the power transformation equipmentmObtaining the basic value m of the major defect rate of the whole network of the power transformation equipment3Wherein
obtaining a first whole-network equipment year occupation ratio coefficient y of the power transformation equipment1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3。
Illustratively, the above-mentioned obtaining the first network-wide device age ratio coefficient y1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3And acquiring the first whole network equipment age ratio coefficient y in the step of acquiring the general defect fraction CD of the power transformation equipment1The second whole network equipment age ratio coefficient y2And the third whole network equipment age ratio coefficient y3The specific methods are the same, and thus are not described herein again.
Obtaining a first whole-network equipment operation age correction coefficient cy of the power transformation equipment1And the second whole network equipment operation age correction coefficient cy2And the operation age correction coefficient cy of the third network-wide equipment3Wherein, cy1=1.2,cy2=1,cy3=0.8。
According to the major defect rate basic value m of the whole network3The first whole network equipment age ratio coefficient y1The second whole network equipment age ratio coefficient y2Third whole network equipment age ratio coefficient y3The operation age correction coefficient cy of the first whole network equipment1And the second whole network equipment operation age correction coefficient cy2And the operation age correction coefficient cy of the third network-wide equipment3Obtaining the whole network major defect rate correction value m of the power transformation equipment4Wherein m is4=m3×(y1×cy1+y2×cy2+y3×cy3)。
Correcting value m according to gross defect rate of whole network4Obtaining critical reserve N of the power transformation equipment for generating major defectscmWherein
according to the major defect full score MfMajor defect benchmark MbAnd a correction value m of the major defect rate2And gross defect rate correction value m of whole network4And a significant defect score, MD, is obtained, wherein,
when m is2When equal to 0, if Nsm≤NcmThen MD ═ MbIf N is presentsm>NcmThen MD ═ Mf;
When m is2≥m4When the temperature of the water is higher than the set temperature,
when m is2<m4When the temperature of the water is higher than the set temperature,
by determining the cost index COE of the power transformation equipment in the four aspects, the comprehensiveness of the obtained cost index COE can be improved, and the comprehensiveness of the operation quality index EQE of the operation quality of the power transformation equipment is further improved.
It should be noted that, the specific values of the efficiency index EOE, the risk index ROE and the cost index COE are not innovations of the present invention, and the present invention combines the efficiency index EOE, the risk index ROE and the cost index COE to comprehensively evaluate the operation quality of the power transformation equipment, thereby facilitating the working personnel to make operation and maintenance plans for the power transformation equipment provided by different suppliers, and also providing guidance for the type selection of the power transformation equipment.
The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.