SU901921A1 - Device for measuring electric energy loss for corona in power line - Google Patents

Description

The invention relates to electrical engineering and can be used to measure crown loss in high voltage power lines.

Known devices for measuring the loss of electricity per crown in power lines.

However, of the known devices for measuring the loss of electric energy on the crown in the power line contains voltage dividers, probes, measuring elements of capacitors and multiplier-summing circuit [1].

The disadvantage of this device is the relatively low accuracy of the measurement, due to the large number of elements of multiplier-summing circuits, introducing phase and amplitude errors in the signals proportional to the total charges of the phase wires.

The closest technical solution to the proposed one is a device for measuring electric energy losses per crown in a power line, which contains voltage dividers, compensation units, antenna probes, capacitors, a factor of ⁵ but-summing integrating devices, wattmeters, inverters and an indicator [2].

The disadvantage of this device is the low accuracy of loss measurement, ¹⁰ due to the presence of inverters in its circuit, the use of which leads to the appearance of additional amplitude and phase errors in the formation of signals proportional to the charges of the phase wires of the power lines.

The purpose of the invention is to improve the accuracy of measuring losses.

_Λ For this purpose, a device for measuring electrical energy losses per crown in a power line, containing probes located under the phase wires of the power line 3 901921 and grounded through capacitors, three multiplier-integrating devices whose outputs are connected to the inputs of the wattmeters, to the other inputs of which connected cheny ₅ outputs respective phase voltage dividers, two subtraction unit incorporated, the inputs and outputs of which are electrically isolated with each other, wherein one of the inputs of the subtractor nodes ₁₀ interconnected and connected to the probe and the middle phase to the inputs of integrating summing-reprographic device, the other inputs of subtraction node connected to the corresponding _1S governmental probes extreme phases outputs the subtraction units coupled to respective inputs of integrating summing-reprographic devices.

The drawing shows a block diagram _{20 of a} device for measuring electrical energy loss per crown in a power line.

The apparatus comprises a phase conductor transmission line 1-3, probes ₂₅ 4-

6, capacitors 7 ^_ 9, subtraction nodes 10 and 11, the inputs and outputs of which are galvanically isolated from each other, multiplier-integrating devices 12-14, voltage meters 15 “17 and ₃₀ dividers 18-20 phase voltage.

The device operates as follows.

The charges of the phase wires 1-3 lines induce signals 4-6 located under them, proportional to ^{35 of} these charges. The voltage drop from these charges from the capacitors 7 “9 are supplied to the subtraction nodes 10 and 11. At the output of the subtraction unit 10 forms a signal proportional to the difference signal probes 4 and 5, and the output of subtraction unit 11 - a signal proportional to signal difference probes 6 and 5 · Solution known Maxwell's equation relating the total ^charge-45 rows phase conductors q, q, q ^ with the signal from the probe sensor 5 ^ and charges q ^ and q ^^ j, has the form = ⁺ тЫ-5% - ₅ ⁺ +

-q ₂ = + m ₂₎ d-5 ^ 4-5 ^{+ m} 2 5Ή5 · ⁺ + oο l / £. q, 5 = '* M- ^ 4 -!> ^{+ m} , 5 <4 ^{+ + m} 3.6-5 I 6-5

It can be seen from the equation that in the counting- ⁵⁵ decisive scheme of the device it is not necessary to apply inversion of the probe signals.

The input signals arriving at the multiplier-summing devices are multiplied by the coupling coefficients and added up. The signals received at the output of the multiplier-summing devices, proportional to the total charges of the wires of their phases, then go to the inputs of the wattmeters 15 ~ 17, and to the other inputs of the wattmeters are fed from the dividers 18-20 of the corresponding phase voltages. The output signals of the wattmeters, representing the product of quantities proportional to the total charges of the phase wires by the signals proportional to the corresponding phase voltages, characterize the corona losses in the phases of the power line.

The proposed device is structurally simpler compared to the known due to the implementation of the subtraction of the probe signals.

Claims (2)

3 9 reductions and grounded through capacitors, three multiply-summing integrating devices, the outputs of which are connected to the inputs of wattmeters, to the other inputs of which are connected to the outputs of the corresponding phase voltage dividers, two subtractors are introduced, the inputs and outputs of which are galvanically separated from each other one of the inputs of the subtraction nodes are interconnected and connected to the probe of the middle phase and to the inputs of multiplying-summing integrators, the other inputs of the subtraction nodes are connected respectively probes extreme phases nodes subtractor outputs connected to respective inputs of integrating summing-reprographic devices. The drawing shows block diagrams of a device for measuring the loss of electrical energy per corona in a power line. The device contains phase 1–3 power transmission lines, probes 6, capacitors 7–9, nodes 10 and 11 of reading, the inputs and outputs of which are gan vanally interconnected, 12-1U integrating devices, power meters 15 -17 and 18-20 phase voltage dividers. The device works as follows. The charges of the phase conductors 1-3 of the line impose on the probes located below them –6 signals proportional to these charges. The voltage drop from these charges from the capacitors 7-9 is applied to nodes 10 and 11 of the subtract. The output of the subtraction unit 10 produces a signal proportional to the difference between the signals of the probes and 5, and at the output of the node 11 it’s output proportional to the difference of the signals of the probes 6 and 5. The solution of the known Maxwell equation connecting the total charges of the phase wires q, q, qo The charge signal q is a scrap of the probe sensor and looks like 4l A-5. and-5 4t-5 -РЗ, + 2,5-45 + 2,6 S k-5 g, 4-9 4- + m 3,6-S q fe-5 From the equation it can be seen that in the metering device circuit you do not need to invert the signals of the probes. Input signals to multiplying devices are multiplied by the coupling coefficients j and added together. The signals obtained by the output of multiplying-summing devices, proportional to the total charge of the wires of their phases, are then fed to the inputs of wattmeters 15–17, and to the other inputs of wattmeters are supplied from dividers 18–20 of the corresponding phase voltages. The output signals of wattmeters, representing the product of values proportional to the total charge of the phase conductors to the signals proportional to the corresponding phase voltages, characterize the corona losses in the phases of the transmission line. The proposed device is structurally simpler compared to the known one by subtracting the signals of the probes therein. Apparatus of the Invention A device for measuring electric power loss to a corona in a transmission line, comprising probes, transmission lines located under the phase conductors and grounded through capacitors, three multiplying-summing integrators, whose outputs are connected to the inputs of wattmeters, and the corresponding dividers are connected to other inputs. phase voltage, characterized in that, in order to improve the accuracy of loss measurement, two subtractors, inputs and outputs, are introduced into it x are galvanically separated from each other, with one of the inputs of the subtraction nodes interconnected and connected to the middle phase probe and to the inputs of multiply-summing integrating devices, the other inputs of the subtraction nodes are connected respectively to the probes of the extreme phases, the outputs of the subtraction nodes are connected to the corresponding inputs multiplying -summing integrators. Sources of information taken into account during the examination 1. USSR author's certificate No. 111068, cl. G 01 R 21/01, 1957. 2. USSR author's certificate number 387296, cl. G 01 R 21/00, 1977 (prototype).