LT5337B - Identification method of short-circuit to earth and place of the same in triphase electrical network - Google Patents

Abstract

The invention relates to electrical energetics and can be used in triphase electrical distributing network for identification permanent or momentary fault and distance to a fault place. The method is characterized in that recordings are made not longer as 100 Ás and less than 100 ns by time intervals. In that case impact of the noise less than 10kHz is reduced. Distance from first end of section of feeding line to short - circuit to earth place is identified by minimizing objective function f2, which is difference function between registered and emulative process.

Description

The invention relates to the field of electricity and can be applied to a method of identifying and locating a landing in a three-phase power distribution network.

The main failures of power distribution networks are wiring interruptions and / or earthings. There are known methods for diagnosing faults in power distribution networks as described in SU 1762279 and SU 1698849. In SU 1762279, fault location detection is based on the recognition of a useful reflection signal from the fault location and its use in fault location detection. SU 1698848 describes a phase-to-ground method for detecting a first half-wave at a short-circuit of a discharge current, measures the amplitudes of the two constituents of the discharge-current half-wave spectrum, and finds the distance to the landing according to an appropriate formula.

The disadvantage of both inventions is the comparatively complex and inaccurate [landing positioning. In addition, none of the inventions record transient transient descents.

The present invention provides a novel method for determining the location of a landing in a three-phase power grid. It differs from known ones in that it records not only permanent but also transient self-grounding and more accurately identifies the location of a past or present ground between a phase and a grounded object in one section of a three-phase power line connected to a bus section of a power substation. This allows power network maintenance services to effectively eliminate the [descent] that occurred and / or prevent a potential malfunction where, for some reason (lightning discharge, tree branches, etc.), transient [descents] occur.

The method is characterized in that it registers the initial downstream current sequence and voltage change processes of a voltage transformer connected to a busbar section and of a power line zero sequence current transformer. Better landing accuracy is achieved by registering logs at intervals of up to 100 ps and less than 100 ns, thereby reducing the impact of noises below 10 kHz, using special algebra to isolate processes in other power lines and load them into the model in which the simulated process is compared with the recorded one, [landing position and model element parameters are found, minimizing the objective function, which is a function of the difference between the registered and simulated processes.

The invention will now be further described with reference to the accompanying drawings, in which:

Fig. 1 is a block diagram of a device used to carry out this method;

Fig. 2 is a schematic diagram of a scaling filter for a high frequency current process.

The grounding device of the present invention uses a device schematically depicted in Fig. 1 consisting of a zero sequence current process identification and isolation analog circuit block 1, a zero sequence voltage process identification and isolation analog circuit unit 2, analog code converters and a memory unit 3 changing the measured during grounding, analogous zero-sequence current and voltage processes to digital and writes recorded processes to buffer memory, controller unit 4, coordinating the registered process recognition, performing analysis, modeling, parameter optimization, fault location identification and communication with external systems; indication unit 5, showing the calculated distance to the ground.

In accordance with the present invention, the location of a ground between a phase and a grounded object in a single-phase power line connected to a bus section of a power substation is determined by analogously recording the initial post-ground zero and current U0 variations in respective blocks the connected voltage transformer and from the power line zero-order high-frequency current scaling filter 6 (FIG. 2) installed in block 1. The parameters of the high-frequency current process scaling filter 6 depend on the power line segment and configuration. The use of a scaling filter 6 allows for a more accurate recording of the initial post-ground zero-sequence high-frequency current processes and more accurate detection of the fault location. Also, better grounding accuracy according to the present invention is achieved by recording faults at intervals of up to 100 ps and less than 100 ns, thereby reducing the influence of noises having frequencies of less than 10 kHz. Block 3 converts the recorded analog signal to digital. In Block 4, special algebra distinguishes processes occurring in other sections of the power lines and loads them into a model where the simulated process is compared with the recorded one. Grounding location and model element parameters, i.e. the transient characteristics of the simulated voltage and current transformer in the model, as well as the wave parameters and nodal capacities of the power lines, are found by minimizing the objective function, which is a function of the difference between the recorded and simulated processes.

The method of the present invention consists of an algorithm whereby a processor located in the controller unit 4 determines the grounding location in the power line sections in the following steps:

1) As a first step, check that the device's power supply line has been grounded. [The landing is considered to have occurred on the power supply of the device if the positive sign has a number (I):

i ρ = Σ'Α (D y = i where ij is the jth registration of the current; Uj is the jth registration of the voltage value; n- \ is the number of the current values of all N registrations: n ^ <N.

2) If the first stage confirms the occurrence of a grounding in the power line, i.e. if the number (I) is positive, performs the second step of defining the transition characteristics of the current and voltage measuring transformers, minimizing the objective function ή:

/, = ΣΙ rem {F _} , derem {l - derem (l _} , \ 3 + deremil ^ lJ = min (II)

7 = 1 here I, - vector: I, = [z, z ' ₂ , ..., z _n2 ], U, - vector: V, = [u ₁ , u ₂ , ..., u _{n 2} ], F, vector of n ₂ values (n ₂ <N) of impulse function of defined form, 1 = [l, l, ..., l] _n2 ; rem and derem - algebra operations for gauge vectors defined by the formulas:

{zj „= rew ((% J„, (yJ „) (III) n

² k = TJ ^x j (yM-j ~ ^d yk ^ -jPP ^d ykl, ^{z =} [ ⁽⁾ 'yvy2' - ^ yn- ^ (> v) = 1 ( ^x k) '= derem ((z _k ) ", (Y _k )") (V)

3) In the third step, determine the ground line segment where the ground occurred and the distance to the ground point in meters from the beginning of the segment, minimizing the target function /,:

/ ₂ = ^ lrem (F ₂ , S _A ) -re »i (F ₂ , sJ = min (VI) k = \ where F ₂ is a vector of M values of the defined impulse function (N = LM, L> 1), L - integer integer, S and N - vectors obtained from registrations and found in the model are calculated using the following formulas:

c _i. ί _Λ Ik In A 11 ......

^a k ^{- e} || ⁵ Λ / (λ-1) + || 'ΡΛ / (* - 1) +2 |'···> | ⁵ Λ / (λ-1) + Λ / |) \ ^VI1 / ^a k ^ M (k - \) + j ~ ^ M (k - \) + j ~ ^W ^ M (k - \) + j {VIII ) where m and / - voltage and current values obtained from the registrations or calculated in the model; w is a non-negative rational number. The derived results are displayed on the display unit 5, which, in addition to the distance from the start of the segment to the landing site, also indicates the number of the segment on which the landing occurred and the recognition reliability.

Claims (4)

DEFINITION OF INVENTION A method for determining a ground between a phase and a grounded object in an isolated ground circuit within a three-phase power line segment by means of a zero sequence current process identification and isolation analogue circuit unit (1), a zero sequence voltage process identification and isolation analogue unit (1). 2), the analog code converter unit (3), the controller unit (4) and the interface and indication unit (5), characterized in that: - records the initial after-ground zero-sequence current lo and voltage U _o processes in blocks (1) and (2) from the bus transformer-connected voltage transformer and the power line zero-order high-frequency current scaling filter (6) mounted in the block ( 1); - verifies that there has been a [grounding] on the power line, the presence of which is indicated by a positive number (I): where ij is the jth registration of the current, uj is the jth registration of the voltage value, n1 is the number of the current values of the total N registrations: η1 <Λ /; - if the number (I) is positive, - determine the transient characteristics of the transformers measuring current and voltage, minimizing the objective function fj: where I, - vector: I, = [zj, z ₂ , U, - vector: U, = [μ ,, μ ₂ , ..., μ _λ2 ], Ę-vector of values of impulse function of defined form n ₂ (n ₂ <N), 1 = [l, 1, ..., l] „ ₂ ; rem and derem - algebra operations for gauge vectors defined by the formulas: (zj ,, = γΜ <Λ) «, (λ) ,,) ( ¹¹¹ ) (x,)„ = derem ((z _k ) _n , (y _k ) _n ) \ (V) - determines the power line segment where the landing has occurred and calculates the distance in meters from the start of the power line segment to the [landing site], minimizing the function of the target f ₂ : / ₂ = ^ kw {F ₂ , sJ-rem (F ₂ , sJ = min (VI) * = 1 where F ₂ is a vector of the defined value of the impulse function M (N = LM, L> 1), L is a healthy natural number, S and Š - vectors obtained from registrations and found in the model are calculated using the following formulas: A IL IK | [...... ^a k> ^ū k ^e | j ^{4 5} A / (j (: - l) + l |> | ⁵ M (tl) + 2I> -) | ⁵ iW (il) + A / | j V ^VI1 / ^a k ^ M (k - \) + j ⁼ ^ M (k - \) + j - ^W iM (kV) + j (VIN) here ū and i- voltage and current values obtained from registrations or calculated in the model; w- is not a negative rational number. 2. The method of claim 1, further comprising detecting initial zero-sequence current and voltage change processes for periods of up to 100 ohms and less than 100 ns, thereby reducing the influence of noises below 10 kHz. 3. A method as claimed in any one of the preceding claims, characterized in that transient transient descents are recorded. 4. A method as claimed in any preceding claim, characterized by recording a decrease in the half-life and longer duration of one industrial frequency.