RU2257635C1 - Method for testing circuit-breaker current protective gear (alternatives) - Google Patents

Abstract

FIELD: electrical engineering; testing circuit-breakers.

SUBSTANCE: novelty in proposed method for testing circuit-breakers involving desired current supply to them is that current value is reduced or converter is cut off at instant when power contacts start separating. In this way protective gear responds to voltage rise across contacts or to opening of circuit-breaker auxiliary contact.

EFFECT: enhanced reliability and extended service life.

4 cl, 4 dwg

Description

The invention relates to electrical engineering and can be used for testing circuit breakers.

The widely known method of testing circuit breakers (hereinafter - circuit breakers) / 1 / for the operation current of the overcurrent protection, consisting in measuring the current and smoothly increasing the current supplied between the input and output terminals from the current source, has the disadvantage of high labor costs and high energy consumption .

The closest in technical essence and the achieved results is / 2 / a method for testing the current protection of a circuit breaker, which consists in setting the current setting, supplying a given current from a controlled source between the input and output terminals of the circuit breaker. The disadvantage of this method is to reduce the resource of the switch and increased power consumption. The disadvantage is that when the switch is tripped, an arc is formed in it, leading to increased wear.

The aim of the invention is to increase reliability and resource.

This goal is achieved due to the fact that they measure the voltage between the input and output terminals, compare it with the second setting and, when this setting is exceeded, reduce the current setting.

The goal is achieved in the second embodiment of the invention due to the fact that they measure the voltage between the input and output terminals, compare it with the second setting and, when this setting is exceeded, the current supply from the source is stopped.

The goal is also achieved in the third embodiment of the invention by controlling the state of the block contact of the circuit breaker and, when the state of this block contact changes with respect to the initial state, lowering the current setting.

In the fourth embodiment of the device, the goal is achieved due to the fact that they control the state of the block contact of the switch and, when the state of this block contact changes with respect to the initial one, the current supply from the source is stopped.

In addition to all options, the current setting smoothly rises from the initial to the final value and when the circuit breaker is tripped, the value of the tripping current is stored.

Figure 1, 2, 3, 4 shows a diagram for the implementation of variants of the methods in accordance with the numbers. Here it is indicated: 1 - test switch, 2 - adjustable current transducer, 3 - start button, 4 - first setpoint block, 5 - inverse control key, 6 - second setpoint block, 7 - direct control key, 8 - voltage source, 9 - threshold element.

The method is implemented as follows when testing thermal current protection or maximum current protection-cutoff.

The first option is figure 1. The maximum value is set by block 4 of the setting. This is the current value at which the switch 1 must trip. The setpoint 6 sets the minimum current value. This is the current value at which the final phase of the opening of the switch contacts will occur. Most often, this value is zero. Switch 1 is turned on and button 3 is used to turn on the current transducer 2. The latter delivers current to the switch 1 set by the block 4 settings. If necessary, simultaneously with the start of the converter 2, a stopwatch can be started, which is not shown in the drawing. If the current is sufficient for the circuit breaker to operate (with maximum or thermal protection), circuit breaker 1 is turned off. At the moment the contacts begin to move, the voltage on them rises. The threshold element 9 is triggered, since the voltage at its input rises from a unit value of Volts in the closed state to a value of more than a dozen volts. At the signal of this element 9, the key 5 is closed and the key 7 is opened. This converter 2 sets the reduced current setting. Therefore, the end of the opening of the contacts of the switch occurs with the accompanying current of a small (most often zero) value.

The arc at the contacts of the switch has limited power, in some cases it does not occur at all, which is explained by the high speed of converter 2.

The second option is figure 2. Block 4 of the setting sets the current value at which the circuit breaker 1 should trip. The circuit breaker 1 is turned on and the current transformer 2 is turned on with the button 3. The latter delivers current to the switch 1 set by the block 4 settings. If necessary, simultaneously with the start of the converter 2, a stopwatch can be started, which is not shown in the drawing. If the current is sufficient for the circuit breaker to operate (with maximum or thermal protection), circuit breaker 1 is turned off. At the moment the contacts begin to move, the voltage on them rises. The threshold element 9 is triggered. Upon its signal, the converter 2 is locked and the current at its output is interrupted. Therefore, the end of the opening of the switch contacts occurs without an accompanying current. An arc does not occur at the switch contacts. This is due to the high speed of the converter 2.

The third option is figure 3. The maximum value is set by block 4 of the setting. This is the current value at which the switch 1 must trip. The setpoint 6 sets the minimum current value. This is the current value at which the final phase of the opening of the switch contacts will occur. Most often, this value is zero. Switch 1 is turned on and button 3 is used to turn on the current transducer 2. The latter delivers current to the switch 1 set by the block 4 settings. If necessary, simultaneously with the start of the converter 2, a stopwatch can be started, which is not shown in the drawing. If the current is sufficient for the circuit breaker to operate (with maximum or thermal protection), circuit breaker 1 is turned off. At the moment the main contact begins to move, the contact block of the circuit breaker opens. The source 8 is switched off. By this fact, the key 5 is closed and the key 7 is opened. This converter 2 sets the reduced current setting. Therefore, the end of the opening of the contacts of the switch occurs with the accompanying current of a small (most often zero) value. The arc at the contacts of the switch does not occur at all, which is explained by the high speed of the converter 2.

The fourth option is figure 4. Block 4 of the setting sets the current value at which the circuit breaker 1 should trip. Turn on the circuit breaker 1 and use button 3 to turn on the current transducer 2. The latter delivers current to the switch 1 set by the block 4 settings. If necessary, simultaneously with the start of the converter 2, a stopwatch can be started, which is not shown in the drawing. If the current is sufficient for the circuit breaker to operate (with maximum or thermal protection), circuit breaker 1 is turned off. At the moment the power contacts begin to move, the block contact opens. At its signal, the converter 2 is locked and the current at its output is interrupted. Therefore, the end of the opening of the switch contacts occurs without an accompanying current. The arc at the contacts of the switch does not occur at all, which is explained by the high speed of the converter 2.

A positive effect from the use of all variants of the method is that the interruption of the current occurs not due to the opening of the contacts of the switch, but due to the termination of the current source. Therefore, the breaking of the contacts of the switch occurs without the formation of a long arc. This does not reduce the life of the switch. Switches allow a limited number of trips in maximum current mode. This increases the reliability of the equipment.

Sources of information

1. Reference for the adjustment of electrical equipment of power plants and substations. Ed. Musaelian E.S. M .: Energoatomizdat, 1984, p. 119, Fig. 3-25.

2. Ibid., P. 121, Fig. 3-27.

Claims (4)

1. A method of testing current protection of a circuit breaker, consisting in setting the current setting, in the supply of a given current from a controlled source between the input and output terminals of the switch, characterized in that they measure the voltage between the input and output terminals, compare it with the second setting and if this is exceeded settings reduce the current setting. 2. A method for testing the current protection of a circuit breaker, which consists in setting the current setpoint, in supplying a given current from a controlled source between the input and output terminals of the circuit breaker, characterized in that the voltage between the input and output terminals is measured, it is compared with the second setting and if this is exceeded the settings stop supplying current from the source. 3. A method for testing the current protection of a circuit breaker, which consists in setting the current setting, in supplying a given current from a controlled source between the input and output terminals of the circuit breaker, characterized in that they control the state of the circuit breaker contact and when the state of this block contact changes with respect to initial lower the current setting. 4. A method for testing the current protection of a circuit breaker, which consists in setting the current setting, in supplying a given current from a controlled source between the input and output terminals of the circuit breaker, characterized in that they control the state of the circuit breaker contact and when the state of this block contact changes with respect to the initial stop supplying current from the source.

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