RU60734U1 - MOBILE COMPLEX FOR TESTING MEASURING TRANSFORMERS - Google Patents

Abstract

The utility model relates to electrical measurements. The mobile complex for verification of measuring current and voltage transformers is a mobile self-propelled means, in the back of which is placed equipment for verifying the test object and a lift for moving model transformers and the type of equipment to be verified at the place of verification. Equipment for checking current and voltage transformers at the workplace of their installation according to the error criterion on the secondary winding. It includes a step-down power transformer with a regulating device providing a control range from 1% to 120% of the rated current of the current transformer being verified, a current comparison device and a load device for the current transformer being verified, and the equipment for conducting voltage transformer verification includes load devices in the form conductivity or resistance stores for calibrated and reference voltage transformers, a high voltage source with a nominal frequency value 50 or 60 Hz. 2 ill.

Description

The utility model relates to a method for periodically checking means for measuring the amount of active and reactive electric energy, in particular measuring current and voltage transformers, at the place of their installation, which is used to control and confirm the metrological characteristics of these means within the permissible error limits for measuring current and voltage measurements of measuring transformers at the place of installation. The utility model can be used in power engineering both for metrological testing of measuring transformers and for their comprehensive examination.

In the framework of this utility model, the question of metrological control over the parameters of current and voltage is considered not in a stationary laboratory, but directly in the switchgear of electrical installations, where calibrated measuring instruments are located.

Currently, verification of measuring equipment (measuring current and voltage transformers) is carried out in specially equipped rooms. To verify one or more of these transformers, they are dismantled from the place of their installation and delivered to the laboratory. And for the period of their verification, similar ones from the exchange fund are installed, and in the absence of such, electrical installations for this period remain without means of accounting for the amount of electricity. After checking and identifying the suitability of the dismantled transformers in terms of error (accuracy class), these transformers are installed in their original place.

With such organization of verification work, a significant exchange fund is required, or the energy facility operates without metering devices throughout the entire process of dismantling, delivery, verification and installation. For power facilities, such operations are time consuming and expensive.

Currently, in many areas of technology, specialized mobile information-measuring complexes are being created, which quickly service geographically dispersed and inaccessible objects with a large number of them.

For example, a mobile measuring laboratory is known (RU No. 2054247, A 01 J 7/00, 1996). It consists of a van with a calculator located in it, a set of built-in sensors associated with the calculator, designed to measure and control the parameters of the object under study in a stationary van, and a power supply unit for measuring equipment.

The disadvantage of this invention is the ability to measure and control the test object only within the limits of a stationary measuring laboratory located in a car van.

A mobile measuring laboratory for the diagnosis and testing of objects (RU No. 2086946, G 01 M 17/00, 1997) was selected as a prototype. It contains a van with a device for automatically collecting and processing the measured information in the form of an on-board computer, a set of built-in sensors for measuring vehicle-laboratory parameters associated with the on-board computer, a set of portable sensors installed on the test vehicle and connected by cable communication lines to portable microcomputer. The testimony of portable sensors in accordance with the test program and the order of their survey recorded portable microcomputer. To fully process the test results obtained from portable sensors, information is entered after testing in the on-board computer.

The disadvantage of the prototype is the inability to use the specified equipment for the purposes of metrological verification of measuring instruments.

This utility model is aimed at solving the technical problem of delivering exemplary calibration equipment to the location of verified measuring instruments, equipped with special equipment that allows verification of current and voltage transformers

directly at the place of their installation without dismantling, the measuring transformer, using one of the working measuring instruments as a load device.

The technical result achieved in this case is to reduce the time for periodic verification of mass-sized objects such as current and voltage transformers, various voltage and current levels, and reduce the time without accounting for the functioning of the power facility.

The specified technical result is achieved in that the mobile complex for moving and delivering exemplary calibration equipment contains all the necessary equipment for conducting verification of the test object. Exemplary and auxiliary calibration equipment delivered to the place of verification is placed with the help of a lift in the immediate vicinity of the test object, a scheme for comparing the metrological characteristics of the measuring instrument with the standard using special calibrated conductors and cables is assembled. The electric power of the assembled circuit from the 220 V (380 V) electric network is produced by a portable cable directly at the power facility.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

This useful model is illustrated by specific examples of execution, which, however, are not the only possible, but clearly demonstrate the possibility of achieving the desired technical result.

Figure 1 - diagram of the calibration of the current transformer;

figure 2 is a calibration diagram of a voltage transformer.

This utility model considers the presence of a mobile complex designed for verification of measuring current transformers 1 and voltage transformers 2, regulated by GOST 8.216-88 for voltage transformers and in accordance with GOST 8.217-2003 for

current transformers. Verification data is necessary to accurately account for the amount of active and reactive electrical energy.

Using a mobile calibration complex, it will take 4-6 days to verify 50-60 measuring instruments (transformers) at the installation site, this is due to the absence of the need for mounting and dismounting of measuring instruments and time for their transportation. The measuring instrument is prepared for verification in 1-2 hours, the preparation of exemplary measuring instruments of a mobile laboratory and the calibration itself takes no more than 1 hour.

Verification is carried out by a differential method for determining the errors of current transformers of frequency 50 Hz with an accuracy class of 0.01 and less accurate with secondary rated currents of 1 and 5 A.

According to this scheme, current transformers from 5 A to 15000 A and voltage transformers from 3 kV to 500 kV are verified.

The equipment necessary for checking the current transformer is taken out of the car and installed in the immediate vicinity of the verified current transformers. The time required for this is 15 minutes. For unloading there are necessary hoisting mechanisms. The time required to prepare the equipment is 1-2 hours.

The mobile complex for measuring instrument transformers verification is a mobile self-propelled means, for example, a van type truck, in the back of which model equipment for carrying out verification of the object under study is placed and unfastened. A mobile elevator is mounted on a mobile self-propelled vehicle for unloading a model current transformer or voltage transformer and corresponding to the type of equipment verification at the place of verification and for subsequent loading of this equipment and model current and voltage transformers.

Exemplary equipment for checking current transformers at the place of their placement according to the criterion of the error of the current parameter on the secondary winding includes an exemplary current transformer 3,

step-down power transformer 4 with a regulating device providing a control range from 1% to 120% of the rated current of the current transformer being verified and setting this current with an error not exceeding ± 10%, a device for comparing 5 currents with an allowable current error in the range of ± 0.03% to ± 0.001% and a phase angle of ± 3.0 'to ± 0.1' and the load device 6 of the current transformer being verified as a secondary load with an error in the load resistance not exceeding ± 4%, and same connecting cables 7 for assembly this equipment to each other and connecting to the verified current transformer in accordance with the verification scheme, which is presented in figure 1.

Exemplary equipment for conducting verification of voltage transformers at their location according to the error criterion for the voltage parameter on the secondary winding includes a part of the equipment for verification of current and additionally includes the following components: an exemplary voltage transformer 8, a high voltage source 9 with a nominal frequency value of 50 or 60 Hz with a permissible frequency deviation of not more than ± 0.5 Hz and voltage regulation in the range from 20 to 120% of the rated primary voltage of the transformer being verified voltage, load devices 10 in the form of conductivity or resistance stores, providing the load of the voltage transformer being verified and a model voltage transformer in the range from 25 to 100% of its rated power with a margin of error of the active and reactive power components of not more than ± 4%, as well as connecting cables 7 for connecting the equipment to each other and connecting to the transformer under verification in accordance with the verification scheme, which is presented in figure 2.

For both types of verifications, the same comparison device 5 of the KNT-03 brand (TU 4225-003-12298401-02) is used, which is designed to determine in a differential way the errors of current transformers of frequency 50 Hz with an accuracy class of 0.01 and less accurate with secondary

rated currents of 1 and 5 A, as well as for determining in accordance with GOST 8.216-88 in a differential way the errors of transformers of voltage of frequency 50 Hz, accuracy class 0.01 and less accurate with secondary rated voltages from 30 to 160 V, for checking current transformers and voltage of industrial frequency 50 Hz. This device is supplied in Russia by Energosila MK LLC and Metra Telecom LLC.

Verification is carried out as follows, for example, verification of errors on the secondary winding of the current transformer.

Directly in the vicinity of the current transformer being verified, the corresponding equipment is unloaded, which are connected using connecting cables to the circuit shown in Fig. 1. Then, the terminals of the primary and secondary windings of the transformer to be verified are connected to the output of the step-down transformer and the input of the current comparison device. The error is defined as the deviation of the secondary winding parameters of the transformer being verified with respect to similar parameters on the model transformer.

Delivered laboratory calibration equipment to the installation site of working measuring instruments for carrying out a metrological test without dismantling heavy, dimensional and located at a height working measuring instruments allows you to minimize the presence of an expensive exchange fund of measuring instruments and to reduce the time required for performing metrological verification by hundreds or more in the traditional way in laboratories specially equipped for this purpose, located dozens and hundreds of kilometers from the operating site x measurement means.

Claims (1)

A mobile complex for calibration of measuring transformers, containing a mobile self-propelled means, in the back of which is placed and fixed equipment for conducting verification of the test object, characterized in that the standard equipment for testing current transformers at the place of installation includes an exemplary current transformer lowering the power transformer with a regulating device providing a control range from 1 to 120% of the rated current of the current transformer being verified and setting this current with an error not exceeding ± 10%, a device for comparing currents with an allowable error in current ranging from ± 0.03 to ± 0.001% and in phase angle from ± 3.0 to ± 0.1 'and the load device of the transformer being verified current in the form of a secondary load with an error in the load resistance not exceeding ± 4%, exemplary equipment for testing voltage transformers at the place of installation includes an exemplary voltage transformer, load devices in the form of conductivity or resistance stores, providing load a narrow verified voltage transformer and an exemplary voltage transformer in the range from 25 to 100% of its rated power with a limit of permissible error of the active and reactive components of the power of not more than ± 4%, a high voltage source with a nominal frequency value of 50 or 60 Hz with an allowable frequency deviation of not more than ± 0.5 Hz and voltage regulation in the range from 20 to 120% of the rated primary voltage of the voltage transformer being verified, as well as connecting cables for connecting equipment connecting with each other and connecting to the transformer under verification in accordance with the verification scheme, while a mobile elevator is mounted on a mobile self-propelled vehicle for unloading an exemplary voltage transformer and corresponding to the type of equipment verification at the place of verification and subsequent loading.