RU2775865C1 - Method for monitoring the performance of an active electric energy meter - Google Patents

Abstract

FIELD: electrical measurements.

SUBSTANCE: invention relates to electrical measurements and can be used in an active electrical energy meter. To control the meter performance, the active power of the electrical circuit is measured, a test signal is applied, the total active power is measured, the measured fictitious active power, the fictitious active power measurement error are determined, the fictitious active power measurement error is compared with the marginal error, and information is generated on the meter performance monitoring result.

EFFECT: increasing metrological reliability, simplifying the design and the possibility of performing automatic control of the meter's performance without interrupting the controlled electrical circuit.

7 cl

Description

Technical field

The invention relates to electrical measurements and can be used in an active electrical energy meter.

Explanations of terms used in the claims and description

inventions

The following terms are used according to GOST 31818.11-2012 “Apparatus for measuring AC electrical energy. General requirements. Tests and test conditions. Part 11" and GOST 20911-89 "Technical diagnostics. Terms and definitions”, as well as the following terms with their respective explanations:

- fictitious power - power, which, when monitoring the performance of the meter, simulates a change in the power of the electrical circuit controlled by the meter;

- test signal - test action in the form of current or voltage applied to one and/or several measuring inputs of the measuring element of the meter to create fictitious power;

- total power - the power measured by the meter, with the simultaneous influence of the power of the electrical circuit and fictitious power.

State of the art

Currently, various methods are known for monitoring the performance of active electric energy meters at the place of use (without dismantling the meters and without interrupting the power supply), the purpose of which is to identify the state of the meter in which the measurement error of the meter goes beyond the limit set by the manufacturer for performance monitoring. The inoperable state of the meter may be due to natural or forced damage to the metrologically significant elements and components of the meter, as well as external influences, including unauthorized interference in its operation.

A well-known health monitoring system for electric energy metering systems according to the RF patent for utility model No. 115950, in which a data collection module is used to check the operability of electric energy meters and other components of the system, which performs the formation of an assessment of the state of operability and localization of failures of the commercial metering system based on periodic checking the information availability of meters. The disadvantage of such monitoring of the meter's performance is limited functionality, since only the communication performance is checked - the functioning of the communication channel, although an indirect (according to the increment of the metered energy readings) assessment of the metrological performance of the meter can be performed, however, this assessment is not reliable, since it does not allow timely identify underestimation of consumed energy due to damage to the measuring part of the meter or when exposed to its measuring part.

A known method for monitoring the performance of an electronic meter according to the RF patent for invention No. 2088943, according to which the shift angle between the voltages and currents of each phase is measured, and the performance criterion is determined by the ratio of the tangent of the measured angle and the ratio of reactive power to active power of each phase. The disadvantages of this method is a significant impact on the results of monitoring the performance of the counter of non-sinusoidal currents and voltages, as well as the inability to detect interference in the operation of the counter, for example, by changing the parameters of the current and / or voltage sensors.

There is a known method for monitoring the metrological serviceability of an intelligent measuring instrument according to the RF patent for invention No. the value of the measured value and the current value of the controlled parameter corresponding to it, the differences between the last obtained value of the measured value and its values obtained earlier are calculated, and for the values of the measured value, the difference of which exceeds the triple permissible measurement error, the current values of the controlled parameter corresponding to them are compared with each other and based on the results of such a comparison, the metrological serviceability of an intelligent measuring instrument is judged. With this method, the controlled parameter is recommended to be chosen in such a way that its values depend to a minimum on the values of the measured quantity. Although electric energy meters are measuring instruments, this method of control cannot be used, since they do not have a controlled parameter that characterizes the critical component of the meter error.

Known electricity meter with a built-in virtual load according to the PRC patent for utility model No. 205844511U, in which the meter performance is monitored using an additional measuring element built into the meter, while using a current source that creates fictitious power, also built into the meter.

There is a method for checking the operability of the counter according to the PRC application for invention No. 107121659 A, in which the following steps are performed:

1) an external control device (additional measuring element) is connected to the meter, the meter is switched to the testing mode;

2) using a control device, they measure the current and voltage in the current and voltage circuits of the meter, determine the amount of measured energy, transmit the data obtained to the main measuring unit of the meter;

3) calculate the real-time power corresponding to the measured values of voltage and current, determine the power measured by the meter in a given time interval by the number of pulses at the pulse output of the meter, compare the powers measured by the meter and the control device, calculate the meter error;

4) The measured error value of the counter is displayed in real time on the display of the counter, it can be downloaded to a computer through a dedicated data interface, automatically generating a test report archive, and realizing the function of viewing, querying, reporting and printing the control result;

5) the meter generates a current that creates fictitious power for the meter, which allows the meter to be tested with little or no load.

Both of the latter solutions suggest a way to control the meter's performance by measuring fictitious (or total) power using an additional measuring element (built-in or external). In this case, the readings of the additional measuring element are compared with the readings of the main measuring element of the meter, a significant difference in readings indicates a violation of the meter's performance. The disadvantage of these solutions is that they use an additional measuring element that performs the function of a reference meter, which complicates the design of the meter, reduces its metrological reliability, while performance monitoring does not allow detecting unauthorized interference in the operation of the meter, for example, by changing the parameters of the current sensors and/or voltage. At the same time, as follows from the descriptions of the patents, the necessary actions in the control of performance are performed manually, that is, the control is carried out by the operator occasionally, which increases the possible underestimation of energy due to significant time intervals between control cycles.

As the closest analogue, the method according to the PRC patent for invention No. 107121659 A was adopted.

Disclosure of the essence of the invention

The technical problem to be solved by the claimed invention is to control the operability of the active electrical energy meter without interrupting the electrical circuit it controls.

The aim of the invention is to create an active electric energy meter capable of controlling its performance without significantly complicating the design of the meter and reducing its metrological reliability.

The technical result obtained in the implementation of the claimed invention consists in the possibility of performing automatic monitoring of the meter's performance during its use (without interrupting the electrical circuit in which the meter is included), in simplifying the design of the meter (no additional measuring element is required) and in increasing the metrological reliability of the meter (the source of the test action of the required accuracy, which creates fictitious power, has a sufficiently high reliability).

The technical result is achieved by the fact that the operability control of the active electrical energy meter is performed without interrupting the controlled electrical circuit by applying a test signal to the meter that specifies fictitious active power, while performing the following actions:

a) measure the active power of the electrical circuit;

b) a test signal is applied to the measuring input of the measuring element of the counter;

c) measure the total active power acting on the meter;

d) determine the measured fictitious active power as the difference between the total active power and the active power of the circuit;

e) determine the measurement error of fictitious active power;

f) compare the fictitious active power measurement error with the marginal error specified for performance monitoring;

g) form information about the result of monitoring the meter performance.

The features of the invention, coinciding with the features of the prototype, - monitoring the performance of the electric energy meter is performed without interrupting the controlled electrical circuit by applying to the meter a test signal that specifies a fictitious active power.

The features of the invention, which are different from the prototype, perform the following actions:

a) measure the active power of the electrical circuit;

b) a test signal is applied to the measuring input of the measuring element of the counter;

c) measure the total active power acting on the meter;

d) determine the measured fictitious active power as the difference between the total active power and the active power of the circuit;

e) determine the measurement error of fictitious active power;

f) compare the fictitious active power measurement error with the marginal error specified for performance monitoring;

g) form information about the result of monitoring the meter performance.

Special cases of the invention:

- the test signal is the current passed through the current circuit of the meter;

- the test signal is the voltage introduced into the measuring current circuit of the measuring element of the meter;

- the value of the test signal and the shift of its phase relative to the voltage of the electrical circuit is selected depending on the value of the power of the electrical circuit;

- performance monitoring is carried out for each measuring element of the counter in turn;

- the value of electric energy measured by the meter is corrected taking into account the value of the fictitious active power and the duration of its supply to the meter;

- these actions are performed automatically using the built-in software.

Implementation of the invention

Structurally, the meter, which is made with the possibility of using the proposed method for monitoring performance, practically does not differ from a conventional meter containing current and voltage circuits connected to a controlled electrical circuit, the signals from which are fed to the measuring inputs of the measuring element that creates output signals proportional to the active energy, measured by integrating active power over time, and having other functional elements (memory device, display, test output, data transmission device and other devices). To implement the proposed method, the meter must have an additional test signal source that generates a given value of fictitious power, and software with a health monitoring function.

The control cycle includes the measurement of the active power of the electrical circuit in which the meter is connected, in its current mode of operation. The value of the measured active power of the circuit can be determined by determining the increment of readings of the reading device for a set time or by processing the signals generated by the pulse test output of the meter, the pulse frequency of which is proportional to the measured power. This can be measured, for example, the number of pulses coming from the test output for a set time, or the duration of the period or the frequency of the pulses of the test output.

Then, a test signal is applied to the measuring input of the measuring element of the meter, which specifies the fictitious active power, and the resulting total active power acting on the meter is measured. The value of the total active power is determined similarly to the value of the measured active power of the circuit.

Then the measured fictitious active power is determined as the difference between the total active power and the active power of the circuit, the measurement error of the fictitious active power is determined and it is compared with the maximum error specified for the performance monitoring, information on the result of the meter performance monitoring is generated.

The test signal can be either a current passed through the current circuit of the meter or a voltage introduced into the measuring current circuit of the measuring element of the meter. In the first version, the test current, flowing through the current sensor included in the current circuit of the meter, is added to the current in the controlled circuit, and a signal depending on the total current is sent to the measuring current input of the measuring element. In the second version, the test voltage is added to the voltage of the current sensor, and the total voltage is supplied to the measuring current input of the measuring element.

The value of the test signal and the shift of its phase relative to the voltage of the electrical circuit is selected depending on the value of the power of the electrical circuit. Since the mode of operation of the electrical circuit is unpredictable, it is advisable to form the value of the test signal and its phase shift relative to the voltage of the electrical circuit depending on the value of the circuit power: with a small active power of the circuit, the test signal should increase the total active power, and with high power, reduce the total power . This can ensure that the performance of the meter is monitored at the set value of the control power. For example, if a test point with a current of 5 A at 220 V is selected, then with a circuit power of 0.5 kW, dummy power should increase the total power by 0.6 kW, and with a circuit power of 2.5 kW, dummy power should reduce the total power by 1.4 kW. Functionality control, if necessary, can be performed at several control points of the measurement range set for the meter.

In multi-element meters, performance monitoring is carried out for each measuring element of the meter in turn, while in three-phase meters, the active power of the circuit is understood as the sum of the active powers of all phases of the electrical circuit.

Since the process of monitoring the performance of the meter occurs without interrupting the power supply, in some cases, accounting for fictitious power can distort the data on the actual consumption of electrical energy. In this regard, the value of electrical energy measured by the meter can be corrected taking into account the value of the fictitious active power and the duration of its supply to the meter.

Health monitoring is performed by means of the built-in software of the counter, the frequency of its execution is set programmatically, it can also be performed by an external command.

The invention has been described without reference to specific embodiments thereof, as those skilled in the art will be able to design many different embodiments within the scope of the proposed claims.

The proposed method does not exclude the presence of other hardware and software necessary for the operation of the counter, a different sequence of actions or other actions, in addition to those specified in the claims. Specifying an action in the singular does not exclude the possibility of performing several such actions. For example, it is possible to monitor the meter's performance in turn by several cycles, in each of which the type of test signal, its value and phase are set. This will allow not only to check the performance of the meter in various modes of operation, but also to detect unauthorized interference in the operation of the meter.

Since the actions for measuring the active power of the electric circuit and the total active power do not coincide in time, a possible change in the operating mode of this circuit during the test signal can affect the measurement result of the total active power and distort the value of the measured fictitious active power. In this regard, immediately after measuring the total active power, it may be necessary to re-measure the active power of the electrical circuit, and the subsequent actions should be carried out only if the circuit operation mode remains unchanged. If an unacceptable change in the circuit mode is detected, the meter should be re-checked, while information about the meter's performance can be generated after the first positive result of the control, and information about the violation of the meter's performance - after the completion of the set number of control cycles with negative results.

Under actual operating conditions of the meter, the voltage in the electrical circuit is unstable, therefore, additional steps may be required to measure the voltage and correct the value of the measured fictitious active power in order to bring its value to the voltage for which the fictitious power is set.

Claims (14)

1. A method for monitoring the operability of an active electrical energy meter without interrupting the controlled electrical circuit, which consists in applying a test signal to the meter that specifies fictitious active power, characterized in that the following actions are performed: a) measure the active power of the electrical circuit; b) a test signal is applied to the measuring input of the measuring element of the counter; c) measure the total active power acting on the meter; d) determine the measured fictitious active power as the difference between the total active power and the active power of the circuit; e) determine the measurement error of fictitious active power; f) compare the fictitious active power measurement error with the marginal error specified for performance monitoring; g) form information about the result of monitoring the meter performance. 2. The method according to claim 1, characterized in that the test signal is a current passed through the current circuit of the meter. 3. The method according to claim 1, characterized in that the test signal is a voltage introduced into the measuring current circuit of the measuring element of the meter. 4. The method according to claim 1, characterized in that the value of the test signal and its phase shift relative to the voltage of the electrical circuit are selected depending on the power value of the electrical circuit. 5. The method according to p. 1, characterized in that the performance monitoring is carried out for each measuring element of the counter in turn. 6. The method according to claim 1, characterized in that the value of electrical energy measured by the meter is corrected taking into account the value of the fictitious active power and the duration of its supply to the meter. 7. The method according to p. 1, characterized in that these actions are performed automatically using software.