CN101170254A - Unbalanced protection method and device for high-voltage serial connection compensation capacitor group - Google Patents
Unbalanced protection method and device for high-voltage serial connection compensation capacitor group Download PDFInfo
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- CN101170254A CN101170254A CNA200710050077XA CN200710050077A CN101170254A CN 101170254 A CN101170254 A CN 101170254A CN A200710050077X A CNA200710050077X A CN A200710050077XA CN 200710050077 A CN200710050077 A CN 200710050077A CN 101170254 A CN101170254 A CN 101170254A
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Abstract
An unbalanced protection device for high-voltage compensation capacitor sets in serial connection, relates to relay protection of high-voltage power transmission wires, which solves the problems of the prior protection devices, including less functions and low sensitivity. The device includes a A/D conversion module, which converts the current from a capacitor set current transformer D and an unbalanced current transformer E into digital quantities; a data identification calculation module, which perform identification and calculation for capacitor set current Ic, unbalanced current delta I, threshold current Imk in a capacitor set A, capacitive reactance variance ratio Kx of original capacitive reactance on arm H, and quantity of error capacitor units s according to the coefficient of reliability Kk; a storage module, which stores the threshold current Imk, the capacitive reactance variance ratio Kx, the coefficient of reliability Kk, the error occurrence times and the calculation results; and a protection output module, which launches alarm or trip protection according to the identification results from the data identification calculation module.
Description
Technical field:
The present invention is relevant with the protective relaying device and the method for ultra-high-tension power transmission line, and is especially relevant with the protection and the guard method of the compensator with series capaci tance of transmission of electricity in the circuit.
Background technology:
At present, the 500kV AC transmission system is that China realizes one of main means that big capacity remote distance power transmits.Adopt the transmission line series capacitor compensation technology, can effectively shorten the electrical distance between power transmission line first and last end, therefore, the transmission line series capacitor compensation technology is to improve the effective means of 500kV AC power line ability to transmit electricity.
In high-voltage electric power circuit, adopt series compensation device that electric power networks is carried out series compensation.Compensation way is single-phase compensation, and every is a capacitor group mutually.This capacitor group is formed (Fig. 1) by a plurality of capacitors through connection in series-parallel.
Each capacitor is made up of a plurality of capacitor unit connection in series-parallel again.Fuse technique in the many employings of existing high-pressure series capacitor, inner a plurality of capacitors are through interior fuse connection in series-parallel (as Fig. 2).
Fuse technique has guaranteed that effectively after the capacitor fault, fault current makes interior fuse failure in adopting, and makes the fault capacitor cell out of service, and does not influence other capacitor unit; The condenser capacity that breaks down is only lost 1.5%-3%.Series compensation device is made up of up to a hundred capacitors, therefore need not be out of service after the single capacitor unit fault, but need change during Awaiting Overhaul.
For finding that the internal capacitor cell failure takes place in the series compensation device, all adopted the unsymmetrical current protection.Its principle wiring such as Fig. 3.
The capacitor group is the wiring of H type.The unsymmetrical current instrument transformer that is connected on " bridge is poor " loop is used for Measurement of capacitor group unsymmetrical current.For guaranteeing that unsymmetrical current protects not misoperation, generally the unsymmetrical current protection is designed to have and moves the ratio braking characteristic of threshold.Its ratio characteristic is the ratio of capacitor group unsymmetrical current and capacitor group load current.When the ratio of capacitor group unsymmetrical current and capacitor group load current is reported to the police or protection deferred action during greater than definite value.
There is following shortcoming in existing high-pressure series capacitor group imbalance protecting method:
1) protection sensitivity is low, and unsymmetrical current proportionality coefficient definite value is bigger in the unbalance protection definite value, and its guard method can't reflect single capacitor fault.Generally want a plurality of capacitor units (more than 3) fault, and all must under the situation that increase unsymmetrical current direction develops, just can report to the police after the capacitor unit fault of fault, otherwise unsymmetrical current can not accurately reflect the fault degree of capacitor.
2) existing guard method can't reflect capacitor symmetric form fault in succession.
As (as Fig. 3) after in certain capacitor on capacitor group H1 arm a capacitor unit fault being arranged, can produce certain unsymmetrical current Δ i
1, be not enough to also cause that protection is reported to the police or action because unsymmetrical current is very little; If through on the symmetrical capacitor group H3 arm capacitor unit fault being arranged also after a while.Because for the H arm is symmetric form fault (as Fig. 4), its unsymmetrical current can reduce on the contrary; Unbalance protection can not move.
Therefore for capacitor unit symmetric form fault takes place in succession, the unsymmetrical current protection can't reflect.
Owing to the high-voltage serial connection compensation capacitor was just checked once in general 1 year, if repeatedly symmetric form fault takes place in the capacitor group around here, a plurality of symmetric form capacitor unit faults, and unsymmetrical current is still very little, original protection can't be judged; The operations staff can't judge whether the capacitor unit fault.This safe operation for series capacitor bank is totally unfavorable.
Summary of the invention:
The object of the invention provides a kind of simple in structure, and fault resolution is strong, can both accurately judge various faults, can estimate the high-voltage serial connection compensation capacitor group imbalance protecting method and the device of the capacitor unit number of faults of capacitor group.
The present invention is achieved in that
High-voltage serial connection compensation capacitor group imbalance protecting method of the present invention, capacitor group A adopts the wiring of symmetrical H type, 4 arm H that are connected on the H arm of capacitor symmetry
1, H
2, H
3, H
4On, each H arm is made up of M*N single capacitor B connection in series-parallel, N capacitor also is unified into a group, be cascaded by M group and form a H arm, every single capacitor B inside is made up of K*L capacitor unit C connection in series-parallel again, L capacitor unit also is unified into a unit group, there be K unit group to be cascaded, flow through on the primary side lead of whole capacitor device group current transformer D is installed, unsymmetrical current instrument transformer E is housed in the bridging line of H type, judges that the method that capacitor unit fault and estimation capacitor unit number of defects X take place in the capacitor group comprises the steps:
(1) calculate capacitive reactance rate of change Kx after capacitor unit fault of generation and storage on the H arm,
X
cThe capacitive reactance of the previous H arm of fault electric capacity,
X '
cBe the capacitive reactance after taking place after the capacitor unit fault on this H arm,
(2) secondary current with current transformer D and unsymmetrical current instrument transformer E is converted to digital quantity through the A/D module samples respectively,
(3) data judge that computing module obtains digital quantity respectively through all-wave Fu Shi algorithm capacitor group electric current I c and the unsymmetrical current Δ I of power frequency 50Hz, the load current threshold Imk that compares Ic and capacitor group A, as Ic>Imk, then calculate unsymmetrical current coefficient delta i and storage
Otherwise, enter once more to remake after the step (2) next time and judge,
(4) data judge that computing module calculates the variation delta ibh of unsymmetrical current coefficient,
Δi
bh=Δi
n-Δi
n-k
Δ in is the unsymmetrical current coefficient that capacitor group A calculates for the n time,
Δ in-k is the unsymmetrical current coefficient that capacitor group A calculates for the n-k time,
K is the arbitrary integer among the 1-10, and n is the number of times that has calculated unsymmetrical current coefficient delta i, judges whether | Δ ibh| 〉=0.25KxKk, K
kBe safety factor, 1.2 〉=K
k〉=0.8,
Be, then judge and break down that failure logging m increase by 1 also enters down step, enter next computer judgement otherwise n is added 1,
(5) number X of the capacitor unit that breaks down of estimation H arm,
The number of times that i breaks down for the H arm that has write down, m is the failure logging sum.
High-voltage serial connection compensation capacitor group unbalance protection device comprises as lower unit:
The A/D modular converter, the electric current with capacitor group current transformer D and unsymmetrical current instrument transformer E generation is converted into digital quantity respectively,
Data are judged computing module, digital quantity is obtained capacitor group electric current I c and the unsymmetrical current Δ I that power current is 50Hz through all-wave Fu Shi algorithm, according to the capacitive reactance rate of change K of threshold electric current I mk, the capacitor group electric current I c of the capacitor group A of memory storage and unsymmetrical current Δ I, the capacitive reactance of original H arm
x, safety factor K
kCalculating also judges whether capacitor group A the quantity of the capacitor unit fault and the capacitor unit that breaks down takes place,
Storage module, storage threshold electric current I
Mk, capacitive reactance rate of change K
x, safety factor K
k, number of times that breaks down and result of calculation,
The protection output module judges that according to data the judged result of computing unit is reported to the police or trip protection.
This patent adopts the load current proportionality coefficient variable quantity of unsymmetrical current of the band memory characteristic of on-load electric current threshold to judge capacitor group fault first.Have following characteristics:
1. improve the resolution capability to the series compensation capacitor cell failure, can detect single and a plurality of capacitor unit faults, it is highly sensitive in traditional series compensation capacitor group unsymmetrical current protection.
2. no longer according to unsymmetrical current size judgment component fault, when taking place in succession, capacitor unit symmetric form fault also can accurately judge;
3. do not taking place to estimate the quantity of capacitor unit fault under the capacitor group symmetrical fault situation simultaneously.
4. need not change the wiring of traditional unbalance protection, criterion is simple.
Description of drawings:
Fig. 1 is a capacitor group structure chart.
Fig. 2 is a capacitor arrangement figure.
Fig. 3 is unsymmetrical current protection elementary diagram.
Fig. 4 is a capacitor symmetrical cell fault schematic diagram.
Fig. 5 is a capacitor unit fault schematic diagram.
Fig. 6 is the inventive method flow chart.
Fig. 7 is a structured flowchart of the present invention.
Embodiment:
The present invention is by the A/D modular converter, and data are judged computing module, storage module, and the protection output module constitutes.
Minimum fault for high-voltage serial connection compensation capacitor group is the capacitor unit fault.Because after a small amount of capacitor unit fault, device still can move, so the series compensation device unbalance protection at first shows as under low variable quantity to reporting to the police.Because resistance and inductance are very little for capacitive reactance capacitor, therefore mainly consider condensance in steady operation.With the specified capacitive reactance of each capacitor unit is that x calculates, and every single capacitor B forms (as Fig. 2) by K*L (K string, L are also) capacitor unit C connection in series-parallel; The capacitive reactance X of each capacitor B is
Capacitor group A adopts the wiring of symmetrical H type, and each capacitor group A forms (M string, N also, as Fig. 1) by M*N capacitor B connection in series-parallel).
Each H arm capacitive reactance X of capacitor group
cFor
It is out of service that a capacitor unit fault takes place, and then the fault capacitive reactance capacitor becomes
The H arm capacitive reactance that has the fault capacitor becomes
Capacitive reactance rate of change Kx after on the H arm capacitor unit fault taking place is
Calculate as can be known by connection in series-parallel, total K*L*M*N capacitor unit on the H arm, during n capacitor unit of the every loss of capacitor, at n than hour considering capacitor group operation characteristic, the rate of change K of the increase of impedance and the impedance of original H arm
xSubstantially linear.Therefore capacitor unit fault n is individual on each H arm, and the capacitive reactance increase is about K on the fault H arm
x* Xc*n.This result is an acceptable in actual engineering.
Consider that each capacitor can not be in full accord in the capacitor group on real system H arm, have very little deviation.The single capacitor error of general present manufacturer can accomplish ± 5% in, but actual product (comprising each capacitor unit) error can be littler, on capacitor bank, considered simultaneously the matching relationship of the positive negative error of capacitor, so capacitor group unsymmetrical current Δ I is very little.In real system, the record ripple map analysis when normally moving according to the series compensation capacitor that has been come into operation in Sichuan, unsymmetrical current coefficient when the capacitor group flows through the specific load electric current | Δ I| is 0~0.00015.
Consider that there is certain difference in the capacitive reactance on each H arm of true capacitor group, and the characteristic of actual high-voltage series compensation capacitance, its influence of resistance and inductance under stable state can be ignored too late, simultaneously because the capacitor group is the H type is symmetrically distributed.Set forth for simplifying, the situation that a capacitor unit fault takes place on the H1 arm can only be discussed earlier, analyze to after the capacitor unit fault to the influence of capacitor group unsymmetrical current.
As Fig. 5, after H1 arm fault, unsymmetrical current Δ i calculates when flowing through the specific load electric current:
X
1′=(1+Δx)X
1
X
1' be the capacitive reactance of H1 arm after the H1 arm generation capacitor unit fault;
Δ x is a capacitive reactance variable quantity after capacitor unit fault of generation.
Δ i
Bhmin: minimum change of unbalance current amount.
Consider that Δ x is for X
1, X
2Very little.X
1, X
2Substantially the same.Following formula can get
This shows, for n capacitor cell fault takes place on the H arm, then
Wherein
K
BphBe minimum change of unbalance current coefficient.
This shows that when on a H arm capacitor unit fault taking place, capacitor unsymmetrical current electric current and fault capacitor unit number are ratio and change.
In like manner according to being distributed symmetrically property of H
When n capacitor unit fault of H2 arm, Δ i=-K
Bph* n.
When on the H3 arm during n capacitor unit fault, Δ i=K
Bp* n.
When on the H4 arm during n capacitor unit fault, Δ i=-K
Bph* n.
To capacitor unit faults analysis and implementation take place:
Series capacitor compensation group electric current, the series capacitor compensation unsymmetrical current becomes secondary current through current transformer with primary side current, carries out A/D after the input A/D module and is converted into digital quantity.Digital quantity obtains series capacitor compensation group power current Ic and the uneven power current Δ of series capacitor compensation I to the program computing module through all-wave Fu Shi algorithm.This programme adopts 12 points of each cycle (20ms) average sample to calculate.
I (k), Δ i (k) are k sampled value in the cycle, then each Ic of cycle calculating and Δ I.
Under the very little situation of capacitor group load current, series capacitor compensation group current transformer and unsymmetrical current instrument transformer can not be reflected to secondary side well, therefore set string and mend a load current threshold I
MkCan better reflect series capacitor compensation group primary current at this electric current current transformer more than threshold.This also is a parameter of often using in traditional protection.Therefore can directly adopt this parameter of traditional protection.If Ic is greater than underload electric current threshold I
Mk, then declare Ic for effective; Otherwise continue to calculate I
cEach cycle (20ms) calculates a unsymmetrical current coefficient delta i=Δ I/I
c, and with the number of times of calculated data and Δ i as a result
nDeposit memory in.Δ i
nCalculate the n time unsymmetrical current coefficient delta I for protecting.Calculate Δ i
Bh=Δ i-Δ i
M-k, according to the sampling calculated rate, n-k is actual to be the interval of a time, and this time interval is escaping oscillating current time setting-up time at interval, and this is according to concrete system and difference.The delay time of the high unsymmetrical current protection of general traditional unbalance protection all will be considered to escape the oscillating current time, can directly adopt the delay time of traditional serial compensation capacitance group unbalance protection, therefore should not set forth at this paper the time.Judge whether greater than minimum unsymmetrical current ratio variable quantity 0.25K
xK
kAs greater than then being judged to the capacitor unit fault, send alarm signal by the protection output unit.The protection output unit can be the actual alarm tripping relay, mends in the unit protection at complete string to be a warning trip signal, and reporting to the police to trip through complete protection again exports.Write down the variable quantity absolute value of this time fault, it is all that accumulative total surpasses minimum unsymmetrical current ratio variable quantity | Δ i
Bh| and, the total quantity M of estimation capacitor unit infringement.If surpass the quantity M that the series capacitor compensation group allows damage
XzThe time, then send protection tripping operation information by the protection output unit.M
XzBe the capacitor unit number that the permission of capacitor group damages, this is according to different manufacturers product, and producer can propose this parameter.This protection trip time can with trip time one of traditional unbalance protection to, generally divide high uneven tripping operation time-delay, reflect more cell failure; Low uneven tripping operation time-delay reflects less cell failure.
In real protection is provided with, at first according to whole series compensation capacitor group capacitor calculation of parameter after a capacitor unit fault takes place in a H arm (capacitive reactance is Xc) (capacitive reactance becomes Xc '), for the rate of change K of original H arm impedance
x
Protective device by current transformer compensation condenser group electric current and the series capacitor compensation group unsymmetrical current sampling that whenever is in series is obtained capacitor group electric current and the capacitor unsymmetrical current obtains digital quantity after the A/D conversion, and process power frequency digital filtering device is after obtain power frequency capacitor group electric current electric current I
cWith power frequency capacitor unsymmetrical current Δ I.
Work as I
cGreater than capacitor group load current threshold I
MkThe time; Calculable capacitor unsymmetrical current coefficient, a power frequency period calculates once at least:
When Δ i changes, calculable capacitor unsymmetrical current index variation amount
Δi
bh=Δi
n-Δi
n-k
Δ i
n: the unsymmetrical current coefficient that capacitor unit calculates for the n time
Δ i
N-k: the unsymmetrical current coefficient that capacitor unit calculates for the n-k time.
When | Δ i
Bh| 〉=0.25K
xKK
kThe time capacitor unit fault judge to take place, protection is reported to the police.
K
k: safety factor.1.1≥K
k≥0.9。
When | Δ i
Bh| 〉=0.25K
xK
kIn time, thought the capacitor unit fault taken place, and record is once | Δ i
Bh|.Each cycle estimation capacitor unit fault number
M is historical m the fault of the capacitor of record,
X is the capacitor unit number of faults of estimation.
Allow the quantity M of fault greater than the capacitor group as x
xThe time, select the protection delay tripping time according to the size of X.
Claims (2)
1. high-voltage serial connection compensation capacitor group imbalance protecting method is characterized in that capacitor group A adopts the wiring of symmetrical H type, 4 arm H that are connected on the H arm of capacitor symmetry
1, H
2, H
3, H
4On, each H arm is made up of M*N single capacitor B connection in series-parallel, N capacitor also is unified into a group, be cascaded by M group and form a H arm, every single capacitor B inside is made up of K*L capacitor unit C connection in series-parallel again, L capacitor unit also is unified into a unit group, there be K unit group to be cascaded, flow through on the primary side lead of whole capacitor device group current transformer D is installed, unsymmetrical current instrument transformer E is housed in the bridging line of H type, judges that the method that capacitor unit fault and estimation capacitor unit number of defects X take place in the capacitor group comprises the steps:
(1) calculate capacitive reactance rate of change Kx after capacitor unit fault of generation and storage on the H arm,
X
cBe the capacitive reactance of the previous H arm of fault electric capacity,
X '
cBe the capacitive reactance after taking place after the capacitor unit fault on this H arm,
(2) secondary current with current transformer D and unsymmetrical current instrument transformer E is converted to digital quantity through the A/D module samples respectively,
(3) data judge that computing module obtains digital quantity respectively through all-wave Fu Shi algorithm capacitor group electric current I c and the unsymmetrical current Δ I of power frequency 50Hz, the load current threshold Imk that compares Ic and capacitor group A, as Ic>Imk, then calculate unsymmetrical current coefficient delta i and storage
Otherwise, enter once more to remake after the step (2) next time and judge,
(4) data judge that computing module calculates the variation delta ibh of unsymmetrical current coefficient,
Δi
bh=Δi
n-Δi
n-k
Δ in is the unsymmetrical current coefficient that capacitor group A calculates for the n time,
Δ in-k is the unsymmetrical current coefficient that capacitor group A calculates for the n-k time,
K is the arbitrary integer among the 1-10, and n is the number of times that has calculated unsymmetrical current coefficient delta i,
Judge whether | Δ ibh| 〉=0.25KxKk, K
kBe safety factor, 1.2 〉=K
k〉=0.8, be, judge then and break down that failure logging m increase by 1 also enters down step, otherwise being added 1, n enters next computer judgement,
(5) number X of the capacitor unit that breaks down of estimation H arm,
The number of times that i breaks down for the H arm that has write down, m is the failure logging sum.
2. high-voltage serial connection compensation capacitor group unbalance protection device comprises as lower module:
The A/D modular converter, the electric current with capacitor group current transformer D and unsymmetrical current instrument transformer E generation is converted into digital quantity respectively,
Data are judged computing module, digital quantity is obtained capacitor group electric current I c and the unsymmetrical current Δ I that power current is 50Hz through all-wave Fu Shi algorithm, according to the capacitive reactance rate of change K of threshold electric current I mk, the capacitor group electric current I c of the capacitor group A of memory storage and unsymmetrical current Δ I, the capacitive reactance of original H arm
x, safety factor K
kCalculating also judges whether capacitor group A the quantity of the capacitor unit fault and the capacitor unit that breaks down takes place,
Storage module, storage threshold electric current I
Mk, capacitive reactance rate of change K
x, safety factor K
k, number of times that breaks down and result of calculation,
The protection output module judges that according to data the judged result of computing module is reported to the police or trip protection.
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