SE504416C2 - Control measurement system for control measurement of energy measurement systems - Google Patents

Abstract

The invention relates to a checking system for control measurement of an energy measuring system connected in a high-voltage network. Such an energy measuring system (2) is used to measure the energy consumed in a plant, for instance a distribution plant, connected to the high-voltage network. The energy measuring system comprises an energy meter (23), a normal current (21) connected to the energy meter and a normal voltage (22) connected to the energy meter. The checking system (1) is mobile and comprises a high-voltage transformer to be connected to the normal voltage of the energy measuring system, a heavy-current transformer to be connected to the normal current of the energy measuring system, a normal-current-generating means connected to the heavy-current transformer, a normal-voltage-generating means connected to the high-voltage transformer and adapted to generate a normal voltage, and a comparator unit (8), which is connected to the normal-current-generating means and the normal-voltage-generating means and which is adapted to be connected to the energy meter. The comparator unit is adapted to determine a normal value of the consumed energy and to compare the normal value with the measured value of the energy meter and determine the difference therebetween. The difference is a measure of the total error of measurement of the energy measuring system.

Description

504 416 2 10 15 20 25 30 35 absolute values and a correction number, or measurement error, is determined.

This method of control measurement is associated with many disadvantages. It only gives a picture of the faults of the individual measuring transformers and not of the total faults of the entire energy management system. It is a time-consuming procedure to remove the measuring transformers, transport them to and from the laboratory and reassemble them. During disassembly or assembly, the high-voltage mains must be switched off.

Another known measuring system is based on a very accurate normal measuring transformer, which is placed on a trailer and thereby mobile. The normal measuring transformer is connected to the high voltage network in parallel with the measuring transformer to be checked. This measuring system is also not capable of measuring control other than the individual measuring transformers. The standard measuring transformer must be able to handle the high voltages in the high-voltage network with very high accuracy, which means that it must be made very large and heavy. To illustrate its size, it can be mentioned that it is 5 meters long and weighs 1.5 tons. It is also a disadvantage that the control measuring system is dependent on the high-voltage network. Another disadvantage of this control measurement system is that it is only designed for control measurement of one voltage transformer at a time.

Thus, there is no known control measuring system with which the total fault of an energy measuring system can be determined.

A basic requirement for such a control measurement system is that it must be mobile. Not even this basic requirement can be met using the prior art.

OBJECTS OF THE INVENTION An object of the present invention is to provide a mobile control measuring system with which the total error of an energy measuring system can be determined.

Another object of the present invention is to provide a control measuring system which is not dependent on the high voltage network. Summary of the Invention The above and other objects of the invention are achieved with a control measuring system according to appended claim 1.

The high-voltage and high-current generating means contribute to the mobility of the control measuring system by making the system independent of the high-voltage network, which, among other things, enables current and voltage normal means which are considerably smaller than the above-mentioned, known per se mobile transformer. This is because the strict operational requirements imposed on equipment that is to work in the network do not need to be taken into account.

A preferred embodiment of the control measuring system which has the features stated in claim 2 has the advantage that currents and voltages in the system can be generated with selectable levels. Thereby, the energy measuring system can be tested under different operating conditions that may arise in the network, which is not possible with known technology.

Brief Description of the Drawings Fig. 1 shows in block diagram form a control measurement system in accordance with an embodiment of the present invention.

Fig. 2 shows in more detail the system in Fig. 1.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT Fig. 1 shows in block diagram form a control measuring system according to a preferred embodiment of the present invention. The control measuring system comprises the units framed with a dotted line which have reference numerals 1. The control measuring system 1 is shown connected to an energy measuring system 2. The energy measuring system comprises the units framed with a dotted line which have reference numerals 2.

The control measuring system comprises a power supply unit 3, a current combiner 6, a voltage combiner 7, a comparator unit, or normal comparator, 8 and a control and regulating unit 9. The energy measuring system 2 comprises a current detector unit 21, a voltage detector unit 22 and an energy measuring unit 23. the units 21 and 22, respectively, are connected to a high-voltage network from which they can be separated by means of a disconnector 24. To the end of the lines 25 of the high-voltage network, a system, such as a switchgear, is connected. at 26.

The control measuring system 1 is mobile in accordance with the invention and is preferably arranged in a vehicle, such as a bus, with a trailer. How this mobility is possible will be shown in more detail below. The control measuring system 1 is supplied via some other external supply than the high-voltage network, such as a portable power plant or an AC power station. This external supply is connected to 10. The power supply unit 3 is in turn connected to the socket 11, the current detector unit 21 of the energy measuring system 2 is connected to the current combiner 6, partly to the normal comparator 8 and partly to one socket 11. connected.

The power supply unit 3 is further connected to a voltage detector unit 22 of the energy measuring system 2 of the energy measuring system 2. the combiner 7, which in turn is connected to the normal comparator 8 and a socket 12.

The control measuring system 1 has a further interface with the energy measuring system, namely between the normal comparator 8 and the energy measuring unit 23. The energy measuring unit 23 has an optical output 27 and / or a contact output 28. This emits pulses with a frequency proportional to the energy consumption measured by the energy measuring unit 23. The output (s) 27 and / or 28 of the energy measuring unit 23 are thus connected (s) to the normal comparator 8. The control unit 9 is connected to the normal comparator 8 for obtaining measured values from this. and to the power supply unit 3 for determining the frequency of the current and the voltage leaving the power supply unit. The control and regulating unit thus regulates the current and voltage leaving the power supply unit 3, the feedback being the measured values from the normal comparator.

The control measuring system 1 operates in the embodiment shown in 3-phase (three currents and 3 voltages). This should only be seen as an example. Other system variants, for example 3 currents and 2 voltages are of course possible within the scope of the invention.

The control measuring system 1 works briefly in the following way. The power supply unit 3 generates current, in three phases, and supplies it to the current combiner 6. The current combiner 6 generates strong current (in three phases), of the same order of magnitude as the current in the high voltage network, at very low voltage and supplies this strong current to the current detector unit 21. The current combiner 6 also generates a reference or normal current and supplies it to the normal comparator 8. In the current detector unit 21 the current is transformed down and fed to the energy measuring unit 23.

The power supply unit 3 also generates voltage, in three phases, and supplies this voltage to the voltage combiner 7. The voltage combiner 7 generates high voltage (in three phases) of the same order of magnitude as the voltage in the high voltage network, at very low current, and supplies this high voltage to the voltage 22. The voltage combiner 7 also generates a reference or normal voltage and supplies it to the normal comparator 8. The voltage detector unit 22 transforms the voltage down and supplies the down-transformed voltage to the energy measuring unit 23.

The energy measuring unit 23 measures the energy flow.

The normal comparator 8 determines a reference or normal energy flow and compares this with the corresponding value obtained from the optical output 27 of the energy measuring unit 23.

The difference that the normal comparator detects is a measure of the total measurement error in the energy measurement system 2.

The control and regulating unit 9, which here constitutes a PC, is used to control and regulate the control measuring system, which comprises controlling the phase ratio, frequency and amplitude of the currents and voltages via the power supply unit 3.

In the following, the control measuring system 1 according to the invention will be described in more detail with reference to Fig. 2. The power supply unit 3 comprises a current generator 4, a voltage generator 5, a mains part 41, which is 504 10 15 20 25 30 30 416 6 connected to the external the power source and to the current and voltage generators and which supply direct voltages to each generator 4, 5, and a first 42 and a second 43 function generator, which generate and to the current generator 4 and the voltage generator 5 respectively supply signals for controlling the frequency and amplitude of the currents and voltages generated by the generators 4 and 5, respectively, and for controlling the mutual phases between the currents and between the voltages.

The current combiner 6 has three inputs, one for each phase. To each input are two conductors 44, 45; 46, 47; 48, 49 from the generator 4 connected. Leaders 44, 45; 46, 47; 48 are connected to the primary side of transformers 50-52 for up-transforming the currents supplied from the current generator 4. Each 50-52 secondary side of the transformer has 54; 55, 56; 57, 58, to the primary side of a measuring transformer 59, 60 and two connections 53, respectively, which are connected 61 in the current detector unit 21. Between one of the transformers 54, 56 and 58, respectively, and the measuring transformer 63, Consequently, the normal transformer 62-64 and the feeder flow through 59-61, a standard converter 62, 64 is connected. the measuring transformer 59-61 of the same current. Each measuring transformer 59-61 transforms the current and supplies it to 23, the secondary side of the formator 59, 60 and 61, respectively, is connected. the energy meter, or the Wh meter, to which the measuring transformers 62-64 transform down the currents with substantially the same conversion factor and then supply them to a normal meter 65 in the comparator unit 8.

The current transformers 50-52 for up-transformation are designed so that they generate large currents in their secondary windings, for example 600 A or 1200 A, at the same time as the voltage drop across the secondary windings is extremely low, a few volts. This means that the power development in the transformers 50-52 becomes very low and that the transformers 50-52 can thereby be made relatively small. This is necessary for mobility and for the connection cables for the large currents to be short (a few meters). 50 15 4 25 The voltage combiner 7 comprises three transformers 66-68 for transforming the voltages supplied from the voltage generator to high voltage levels, such as for example 20 kV or 130 kV, and three normal transformers 69-71 . Each of the transformers 66-68 is connected to a measuring transformer 72-74 for voltage detection. Each measuring transformer 72-74 transforms down the voltage and supplies it to the energy meter 23. Each normal transformer 69, 70 or 71 is connected to one of the secondary side of the transformers 66, 67 or 68 and transforms down the voltage with essentially the same conversion factor as the measuring transformers to then supply the voltage to the normal meter 65. The transformers 66-68 are designed so that they generate the high voltage at low current, for example a few tens of milliamps. They have a relatively small format, which is possible partly due to the low power they need to cope with, and partly because they do not have to be designed in the same way as the operating transformers.

In the normal meter, a value, hereinafter referred to as normal value, is determined for the incoming energy. The normal value is fed to a comparator circuit 75 in the comparator unit 8. The energy meter 23 determines a corresponding value, referred to in the following measured value, which applies to the energy measuring system 2. The measured value is fed to the comparator circuit 75 via the optical output 27 and compared there with normal value. - that. measuring system 2.

The difference is the total measurement error in the whole energy- This total error can not be determined with conventional measurement methods.

As shown in broken lines, the system 1 can also be used for control measurement of each of the measuring transformers 59-61, 72-74, the comparator unit 8 having inputs provided for the purpose.

The control measuring system according to the invention is mobile.

More specifically, it is arranged in a vehicle, preferably a bus with a trailer. The high voltage transformers are arranged on the trailer and the rest of the system 1 is arranged in the bus, whereby only short cables are required between the trailer and the bus for transmitting the low voltages and the currents. Furthermore, the distances between the transformers 50-52 and 66-68, respectively, and the normal transformers 62-64 and 69-71, respectively, are short. The new ideas contained in the invention and the unique design of the system, according to the description above, have given such small components that the entire system can fit in a bus with a trailer. This leads to large cost savings as there is no disassembly and the system is highly mobile. assembly of components in the energy measurement system.

An advantage of the control measurement according to the invention is that it is an immediate comparison and is not based on an absolute value having to be determined. It is therefore not critical if the currents and voltages applied to the measuring transformers 59-61 and 72-74 vary slightly with time, for the variations are reflected both in the energy measuring system 2 and in the control measuring system 1. Another important advantage is that those in the control measuring system The input feed-up transformers do not have to be as large in terms of power as the feed-up transformers used in the prior art when controlling individual measurement transformers in the laboratory, and they can thereby be made considerably smaller.

Finally, it is an advantage that the control measuring system 1 does not presuppose access to the high-voltage network but receives its supply from another source, preferably a fuel-powered, portable power plant. This does not disturb the load ratio on the network by the control measurement and vice versa.

Furthermore, a cumbersome connection to the high-voltage network (short-circuit effects, etc.) is avoided. In addition, the normal transformers operate under controlled conditions at each measurement, which means that you are well aware of the normal transformers' possible conversion errors and other values that vary with the applied current / voltage and the environment. The connection to a power source other than the high-voltage grid also has the advantage that the dimensions of the normal transformers can be considerably reduced in relation to the above-mentioned known mobile normal transformer. The reason for this is that the requirements for insulation properties and other properties required for the transformer to withstand the operating conditions and the safety of the high-voltage network do not exist.

The PC is an important tool for making the measurement rational and quickly performing any correction calculations and reporting the measurement results.

Claims (6)

504 416 10 10 15 20 25 30 35 PATENT CLAIMS Control measuring system for control measurement of an energy measuring system connected to a high voltage network, which energy measuring system (2) is used for measuring the energy consumed in a plant connected to the high voltage network, for example a switchgear, and comprises an energy measuring unit (23), a current detector unit (21) connected to the energy measuring unit for detecting the current taken out and a voltage detector unit (22) connected to the energy measuring unit - is mobile and that detecting the corresponding voltage, provided that the control measuring system (1) comprises a high voltage generating system (66-68) for connection to the voltage detector unit of the energy measuring system, a strong current generating means (50-52) for connection to the current detector unit of the energy measuring system, a current normal means connected to the strong current generating means (62-64) for generating a normal current, one to the the high voltage generating means connected to the normal voltage means (69-71) for generating a normal voltage and a comparator unit (8), which is connected to the current normal means for receiving the normal current and to the voltage normal means for receiving the normal voltage and which is arranged for connection to the energy measuring unit for receiving a measured value determined by the energy measuring unit. the comparator unit is arranged to determine a normal value of the consumed energy and to compare the normal value with the measured value and determine the difference between these, which difference is a measure of the total measurement error of the energy measuring system. Control measuring system according to claim 1, characterized in that the control measuring system comprises (3), power source and which is arranged to generate and to it a power supply unit which is connected to an external high-current generating means and to the high voltage device, respectively. The generating means supplies currents and voltages of a certain frequency, amplitude and phase, respectively. Control measuring system according to claim 2, characterized in that the control measuring system comprises (9), the supply unit for regulating said frequency, amplitude a control and regulation unit which is connected to power and phase. Control measuring system according to claim 2 or 3, characterized in that the power supply unit comprises a current generator (4), which is connected to the high-current generating means, a voltage generator (5), which is connected to the high-voltage generating means, a first function generator ( 42), which is connected to the current generator and a second function generator (43), which is connected to the voltage generator. A control measuring system according to any one of the preceding claims, wherein the current detector unit of the energy measuring system comprises at least one current measuring transformer and that its voltage detector unit comprises at least one voltage measuring transformer, characterized in that the high voltage generating means comprises at least one high voltage transformer. low current, the amplitude of which is less than 0.1 A, that the high current generating means comprises at least one current transformer which generates the strong current at extremely low voltage, the amplitude of which is less than 10 V, that the voltage normal means comprises at least one voltage normal transformer and that the current normal means comprises at least one , wherein the voltage transformer is connected to the voltage normal transformer and is arranged for connection to the voltage measuring transformer so that it is connected in parallel with the voltage normal transformer and wherein the current transformer is connected to the current normal transformer and is arranged for connection to the current measuring transformer so that it is connected in series with the current normal transformer. 504 416 12 Control measuring system according to one of the preceding claims, characterized in that the comparator unit is arranged for connection to at least one current and / or voltage measuring transformer.