SU1490674A2 - Spark-safe power supply source - Google Patents

Abstract

The invention relates to the field of electrical engineering and can be used in mine electrical prospecting equipment, as well as for powering other devices operated in explosive environments. The goal is to increase the output intrinsically safe power. The device contains a battery 1, two limiting resistors 2 and 5, a zener diode 3, a recovery thyristor 4, a charging capacitor 6, a protection thyristor 7, a measuring resistor 8, a cut-off diode 9, a shunt capacitor 10, a capacitor 11, a resistor 12, a thyristor 13 and diode 14. In normal mode, the thyristors 7 and 13 are turned off, and thyristor 4 is turned on through resistor 2 and zener diode 3. Capacitors 6 and 11 are charged. When disconnecting a non-inductive load, an electrical discharge occurs. Capacitor 11 turns on thyristor 13. The source output circuits are shunted and the discharge stops prematurely. The current through the resistor 8 is increased, the thyristor 7 is turned on, and 13 is turned off. Capacitor 6 is discharged through open thyristor 7 to thyristor 4 and turns off the latter. After the discharge, the capacitor 6 is recharged through the resistor 2 and the thyristor 7. The voltage on the capacitor 6 is increased, the zener diode 3 is punctured, the thyristor 4 is turned on, and the capacitor 6 turns off the thyristor 7. The output voltage is restored at the source output. Artificially reducing the duration of the electric discharging discharges allows increasing the intrinsically safe output power of the source. 1 il.

Description

14)

The invention relates to electrical engineering and can be used in electrical equipment for mine, as well as for power supply.

other devices operated in explosive environments.

The aim of the invention is to increase the intrinsically safe output power.

The drawing shows a diagram of the proposed power source.

The intrinsically safe power source contains a battery 1, the first limiting resistor 2, Zener diode 3, recovery thyristor 4, second limiting resistor 5, charging, capacitor 6, protection thyristor 7, measuring resistor 8, cut-off diode 9, shunt capacitor 10, capacitor 11 , resistor 12, thyristor 13 and diode 14.

The battery of battery 1 is connected to the positive terminal through the first limiting resistor 2 to the recovery thyristor 4 anode 4 and one of the plates of the charging capacitor 6, and through the second limiting resistor 5 to the protection thyristor 7, and to the other capacitor plate 6 and through the section diode 9 with positive output terminal.

The negative terminal of the battery 1 is connected to the cathodes of recovery thyristors 4 and protected 7, and through the measuring resistor 8 to the output negative terminal. In addition, the control electrode of the recovery thyristor 4 is connected via Zener diode 3 to the connection point of the first limiting resistor 2 and charging capacitor 6. The control electrode of the protection thyristor 7 is connected to the connection point of the shunt capacitor 10 and the first lead of resistor 12 which is connected via capacitor 11 to to the control electrode of the thyristor 13. The thyristor 13 is connected by an anode to the positive one, and by the cathode to the positive output terminals and to the second terminal of the resistor 12. In addition, the control electrode of the thyristor 13 through the diode 14 is connected to the connection point of the resistor 12 and the cathode of the thyristor 13.

Intrinsically safe power source operates as follows.

In the normal state, when the load is connected, the thyristors 7 and 13 are turned off, and thyristor 4 is turned on through resistor 2 and zener diode 3. Capacitor 6 is charged, the left facing has a negative potential, 0 and the right is positive.

The capacitor 11 through the diode 14 charges up to a voltage equal to t

The voltage drop across the resistor 12: 5

"

where and is the voltage drop across the resistor 12i

and is the voltage value of the capacitor 10;

R is the resistance value of the resistor 1 2}

5 n value of load resistance.

When disconnecting a non-inductive load, an electrical discharge arises. At the initial moment, the magnitude of the voltage on the capacitor 10 does not change, and the current in the load decreases abruptly, causing a "corresponding decrease in the voltage on the resistor 12, which becomes equal to

“. (and - Up) R

R R + RH

Q where and is the voltage drop across resistor 12 when an electrical discharge is triggered;

and o is a decrease in voltage at 5 electrical discharges.

The decrease in voltage across resistor 12 is accompanied by the discharge of capacitor 11 through the control electrode of the thyristor 13 and causes it to turn on. The output circuits of the power source are shunted by the thyristor 13, the electrical discharge of the trip is stopped prematurely and intrinsic safety is ensured.

Turning on the thyristor 13 leads to an increase in the current through the resistor 8. When this current increases to a predetermined value, the voltage on the resistor 8 causes the switching on

five

Ristor 7 and, therefore, the disconnection of the thyristor 13.

Capacitor 6 is discharged through open thyristor 7 to thyristor 4

and disables the latter. After the discharge, the capacitor 6 is recharged through the resistor 2 and the thyristor 7. When the voltage across the capacitor 6 is equal to the voltage of the zener diode 3, a current in the control electrode of the thyristor 4 appears, the latter is turned on, the capacitor 6 is discharged through thyristor 7 and turns it off. Thereafter, the operating voltage is restored at the output of the power supply.

Claims (1)

Thus, due to the presence in the power source of an additional resistor, capacitor, diode and thyristor connected in a certain way, artificial reduction of the duration of the electrical discharges of the opening and, consequently, the intrinsic safety of the output circuit is provided. This makes it possible to increase the output power by increasing the output current of the power supply with the help of the measuring resistor 8 to a value that exceeds the current of the intrinsically safe circuit with discharges of natural duration. Invention Formula Intrinsically safe power source for auth.St. No. 412601, characterized in that, with an enhanced intrinsically safe output circuit, it is equipped with an additional resistor, capacitor, diode and thyristor, the anode of the additional thyristor connected to the positive terminal of the load, the second plate of the shunt capacitor is connected to the cathode of the additional thyristor, anode additional diode and negative terminal of the load, the cathode of the additional diode is connected to the control electrode of the additional thyristor and one of the plates of the additional diode capacitor, the other lining of which is connected to the second plate of the shunt capacitor.