RU16229U1 - DEVICE FOR PROTECTING ELECTRICAL INSTALLATIONS AGAINST VOLTAGE - Google Patents

Abstract

1. Device for protecting electrical installations from overvoltage, comprising a non-linear surge suppressor, characterized in that it additionally includes an automatic impulse control unit and an alarm unit, the input of which is connected to the first output of an automatic impulse control unit, and an automatic impulse control unit equipped with a second output and connected by an input to the output of a nonlinear surge suppressor. 2. The device according to claim 1, characterized in that it further comprises an information processing unit, the input of which is connected to the output of the alarm unit.

Description

The proposed utility model relates to electrical engineering and is intended to protect electrical installations, mainly electric vehicles, including trolleybuses with contactor, thyristor and transistor control. It can be used in networks, both with an isolated and grounded negative pole. During operation, the insulation of electrical installations is under the influence of surge pulses.

Overvoltage pulses occur both in the electrical installation itself and in the supply network.

Studies have shown that on moving trolley buses, overvoltage impulses occur, on average, at a frequency of 60 impulses per hour, and peak overvoltage values can reach more than 3000 V and last up to 2 ms.The occurrence of overvoltages leads to aging of the insulation caused by ionization processes in the insulation.

At the same time, insulation is the main protective measure for a person from electric shock when in contact with the power system; in addition, the level of electrical safety and fire safety of the electrical installation depends to the greatest extent on the state of insulation.

Known devices for protection of electrical installations from overvoltages. These include protective gaps and valve arresters 1, s. 134-138.

The principle of operation of these devices is that there is an air spark gap between two live parts, one of which is connected to the phase of the network, and the other to the ground. As a result of exceeding the nominal value by a specified value by the network direction, a breakdown of the air gap occurs, after which the voltage on the insulation of the electrical installation is determined by the voltage drop

air gap of the protective device. Thus, the protective device “cuts off the upper part of the overvoltage.

The main disadvantage of the known protective devices is the high level of surge protection, which leads to an accompanying current.

A device for protecting electrical installations from overvoltage, containing a nonlinear surge suppressor 1, p. 142. This device is the closest to the claimed combination of essential features and is selected as a prototype.

Nonlinear surge arresters are made on the basis of resistors with a high degree of non-linearity, having different conductivity at rated and high voltage. As a result, an insignificant current passes through the resistors at the operating voltage, which eliminates the spark gap and connects the nonlinear surge suppressor directly to the network.

When the voltage is lower than the response voltage, the conductivity of the nonlinear surge suppressor is low, and the current passing through it does not exceed 0.5-1 mA. With an increase in voltage above the threshold of operation, the conductivity of the device increases sharply and the current passing through it can reach hundreds or even thousands of amperes. In this case, the voltage across the insulation exceeds the residual voltage at the surge suppressor, which is significantly lower than the surge wave.

A significant drawback of the prototype is the lack of continuous automatic monitoring of the technical condition of the device during its operation, as a rule, the control is carried out by an external preventive inspection once every three months and preventive tests once every three years, which does not ensure the timely detection of failed surge arresters.

The utility model is based on the task of improving the device for protecting electrical installations against overvoltages by introducing a node into it, which provides continuous automatic monitoring of the technical condition of the overvoltage limiter during its operation, which makes it possible to increase the reliability of protection of insulation of electrical installations.

The problem is solved in that in the device for overvoltage protection, containing a non-linear surge suppressor, according to the utility model, an automatic pulse limiter and an alarm block are additionally introduced, the input of which is connected to the first output of the automatic pulse limiter, while the automatic control unit the pulse limiter is equipped with a second output and is connected by an input to the output of a nonlinear surge suppressor.

In addition, the device may further comprise an information processing unit connected by an input to the output of the alarm unit.

The use in the inventive device of the automatic control unit of the pulse limit allows automatic control of the operation of the nonlinear surge suppressor and feed the information to the input of the alarm unit.

In the normal technical condition of the surge suppressor, the automatic control unit detects its operation at the moment of impulse restriction. In this case, the alarm unit issues a control. signal. A prolonged absence of a signal indicates a possible failure of the surge suppressor.

The information processing unit additionally makes it possible to keep track of the number of limited impulses; ps, which makes it possible to analyze the operation mode of the surge suppressor and predict the possibility of a failure during its operation.

Pa drawing shows the connection diagram of the device in the preferred embodiment.

A device for protecting electrical installations against overvoltages contains a nonlinear overvoltage limiter 1, the input of which is connected to the network, and the output is to the input of the automatic pulse limit control unit 2, made in the form of a current transformer. The output of the primary winding of the current transformer is connected to the network, and the output of the secondary winding is connected to the input of the alarm unit 3. The alarm unit 3 contains an LED connected to the transistor switch and is provided with autonomous power supply from the battery or on-board electrical system network. To the output of block 3 is connected the input of the information block 4. A personal computer can be used as the information block.

The device operates as follows.

When an overvoltage pulse occurs, the conductivity of the nonlinear surge suppressor increases sharply. This ensures that a large amount of pulsed current passes through the limiter 1, which creates a voltage drop in the circuit. In the case of normal operation of the limiter, the voltage drop is not more than 80% of the breakdown voltage of the insulation. The pulse current passing through the primary winding of the current transformer of the automatic pulse limiting control unit 2 is amplified by the secondary winding. From the secondary winding, the signal is fed to the input of the alarm unit 3, providing the opening of the transistor switch.

When the transistor switch is opened, the LED receives power from an autonomous source. The LED lights up, which only lights up when the overvoltage pulse is limited.

1 The information processing unit 4 records the number of operations of the alarm unit 3 and reflects information on the number of limited pulses, which allows one to judge the operation mode of the electrical installation.

The information processing unit can also measure leakage currents, monitor the operation of electrical equipment and, if necessary, perform other functions. In case of failure of the nonlinear surge suppressor 1, the pulse current through it and, accordingly, through block 2 does not pass and the LED does not light up.

An embodiment of the device is possible in which the transistor switch of unit 3 is open during the absence of overvoltage pulses, which ensures the burning of the LED. At the moment the pulse passes, the key closes and the LED goes out.

Thus, a non-illuminating or constant burning LED of the alarm unit indicates a malfunction of the nonlinear surge suppressor.

The device was tested on a T-45 brand trolleybus.

As a non-linear surge suppressor, a surge suppressor with a non-linear resistor was used, the limiter case had double insulation. A device mounted on 600V inputs provided, on average, 60 restrictions on surge pulses per hour.

An additional connection of the device in parallel with the contacts of the contactors of the trolleybus start-brake system reduced the overvoltage pulses that occur when the contactor arc is broken.

When an overvoltage pulse occurs, the LED of the alarm unit lights up, which testified to the operability of the device. 1 V.P. Larionov and published, 1982; 296s

Fri Source of information: dr. "High-voltage technique M .: EnergoFormula

Claims (2)

1. Device for protecting electrical installations from overvoltage, comprising a non-linear surge suppressor, characterized in that it additionally includes an automatic impulse control unit and an alarm unit, the input of which is connected to the first output of an automatic impulse control unit, and an automatic impulse control unit equipped with a second output and connected to the output of the nonlinear surge suppressor. 2. The device according to claim 1, characterized in that it further includes an information processing unit, the input of which is connected to the output of the alarm unit.