SU970532A1 - Device for overcurrent protecting of electric installation - Google Patents

Description

The invention relates to electrical engineering, is intended to disconnect consumers and sources of electric energy in three-phase and single-phase versions with increasing current in any of the phases and can be used to protect vehicle generators.

A device for current. . _l protection with a dependent characteristic ^{υ of} the response time, containing an intermediate transformer, a rectifier bridge, charging RC circuits connected through a resistor and capacitor to a part of the turns of the secondary winding of the intermediate transformer, the threshold unit is connected to the remaining part of the turns of the secondary winding [1].

The disadvantage of this device 20 will introduce the complexity of the settings and ryo, regulation ~ current.

Closest to the proposed technical essence is a device for electronic relay protection. installation from overload currents and co. A short circuit, containing in each phase a sensor connected via a conversion unit with intermediate transformers, a rectifier mos, a volume and a smoothing capacitor to the ³⁰ input relay block, made in the form of parallel circuits consisting of a reference element connected in series, an adjustable resistor, and output relay windings , through the make contacts of the output relays to the smoothing capacitor are connected a short circuit unit and an overload unit, and an executive unit [2].

The disadvantage of this device is its low sensitivity to overload currents, since the return coefficient of the output relay block made of an intermediate relay and a zener diode is not high enough.

The purpose of the invention is to increase the sensitivity of protection to overload currents when using conventional intermediate relays.

This goal is achieved by the fact that the device for protecting the electrical installation against overload currents contains current transformers installed in each phase, to the secondary windings of which there is a converting unit made in the form of a rectifier bridge and a smoothing capacitor connected to its output to one of the plates of which is connected through variable resistor ^ first terminal of the output relay winding parallel to the smoothing capacitor of the converter unit are connected a contact contact of the output relay and the first timing RC circuit, in parallel with the capacitor of which the executive relay is connected, a half-wave bridge rectifier connected to 10 two phases of the supply network, a second timing RC circuit, an intermediate relay with the closing and opening contacts, and the second closing contact are additionally introduced 15 cycles of the output relay, and to the output of a half-wave bridge rectifier connected in series are the second make contact of the output relay and the second time .. giving the RC circuit, a pair llelno ^m Satoru capacitor which are incorporated an intermediate relay normally open contact which is connected in parallel to the first normally open contact of the output relay and the break contact - between the second output terminals of the relay coil and said second electrode of the smoothing capacitor converting unit.

The drawing shows a schematic diagram of the proposed device, 30

The device contains current transformers 1, converting unit 2, made in the form of a rectifier bridge 3 and a smoothing capacitor 4, variable resistor 5, the winding of the output 35 relay 6 with the first and second make contacts 7 and. 8, a first timing RC circuit with a resistor 9 and a capacitor 10, a half-wave bridge rectifier 11, a second time -'4O giving an RC circuit with a resistor 12 and a capacitor 13, an intermediate relay 14 having a delay to trip and return, with a closing 15 and opening 16 contacts, executive relay 17 and power contacts 18.

The device operates as follows.

When the load current flows through the power network with closed contacts 18, the current flowing through the winding of the output relay 6 is insufficient for its operation, therefore, power is not supplied to the capacitor 10 and the executive relay 17 does not work.

¹ When an overload occurs at 55, when the voltage on the winding of the output relay 6 reaches the operating voltage ^ the specified relay is activated and closes its make contacts 7 and 8, through which the charge of capacitors 10 and 13 starts. When the intermediate relay reaches the winding 14 tripping voltage, the specified relay is triggered and switches, its contacts. The NO contact 15 of this relay closes and the capacitor 10 continues to charge through it. The NO contact 16 of the intermediate relay 14 opens, while losing the power to the coil of the output relay 6, which opens its NO contacts 7 and 8. This starts the discharge of the capacitor 13 to the intermediate coil relay 14 and at some point in time the voltage on the winding of the intermediate relay 14 decreases to the value of the return voltage, and its contacts return to their original state, i.e. make contact 15 opens, and make contact 16 closes and the winding of the output relay 6 again receives power.

In the presence of a short-term overload, a decrease in the voltage at the output of the converting unit 2 on the capacitor 4 will cause a decrease in the voltage at the winding of the output relay 6, it is enough to decrease the voltage at the winding of the specified relay by a small amount, for example, 0.99 of the response voltage of the output relay 6, and this relay will not work therefore, the capacitor 10 will not charge. press and the executive relay 17 will not work.

In the case of a prolonged overload through alternately closing contacts 7 and 15 and the resistor 9, the capacitor 10 is charged to the operating voltage of the actuating relay 17.

Thus, the proposed device allows to increase the sensitivity of the protection to overload currents when using simple intermediate relays in the circuit.

Claims (1)

1. USSR author's certificate number 367502, cl. H a2 H 3/08, 1971. 2, USSR Author's Certificate No. 538443, cl. H 02 H 3/08, 1970,