SU723186A1 - Spark-proof power source - Google Patents

Description

I

The invention relates to intrinsically safe power supply systems for automation devices, telemechanics, communications, operating in explosive atmospheres in coal mines and can also be used in non (}) tegaz and chemical industry.

An intrinsically safe power source is known, which contains an emf source, a shunt thyristor. The EMF source and the measuring resistor are connected in series with the load, the bypass thyristor is connected parallel to the load, and the control electrode is connected to the measuring resistor J ..

The disadvantages of the known device is the reduction of the equivalent inductance only for concentrated inductive elements and the limitation of the discharge only in the short load mode, which leads to a substantial reduction in the top-gun intrinsically safe mountain (t.

Another device is known comprising an EMF source, a primary thyristor, a shunt thyristor, an auxiliary thyristor, a measuring resistor, a discharge start sensor with a control signal driver, the EMF source, the primary thyristor, the measuring resistor and the discharge start sensor being connected in series with the load, The shunt thyristor is connected in parallel to the load, the output of the control signal generator is connected to the control electrode of the shunt thyristor, and the control electrode of the auxiliary shooting gallery Stora popklyuchen to NZ epitelnomu resistor 2.

However, this device does not allow to increase the intrinsically safe my;

The purpose of the invention is a popcienier ncKpci safe and powerful.

Delivered by the fact that the source of the power source, gpabzhch m nst ({nick current, condensate and no | 4ii-on IM element, with -icxi КЧГ -И-лгор post372

Switched parallel to the output of the source of the eye, the current source is switched on after a time and according to the source of emf, the auxiliary thyristor is connected to the output, and the main thyristor control electrode is connected to the output of the current source through the threshold element.

The drawing shows an intrinsically safe power supply circuit.

The power source contains a source of DC 1, the main thyristor 2, the shunt thyristor 3, the auxiliary thyristor 4, the measuring resistor 5, the sensor 6 of the beginning of the discharge with the driver

7 control signal. A current source 8, a capacitor 9, a threshold device 10 are introduced into the device. EMF source

I, the main thyristor 2, the measuring resistor 5, the sensor 6 of the beginning of the discharge is connected in series with the load

I1, the shunt thyristor 3 is connected parallel to the load, the output of the driver 7 of the control signal of the connections to the control electrode of the shunt thyristor 3, the control electrode of the auxiliary thyristor 4 is connected to the measuring resistor 5, the source

8current is connected in series and according to the source of EMF 1, parallel to their output is auxiliary thyristor 3, capacitor 9 is connected in parallel with the output of the current source, and the control electrode of the main thyristor 2 is connected to current source 8 through the threshold device 10. In addition,

A limiting resistor 12 and a diode 13 can be introduced into the device.

The device works in the following way.

At a nominal load, the control electrode of the main thyristor 2 receives a triggering voltage through the threshold device 1O: from the source 8 of the current. The thyristor 2 is open, the auxiliary thyristor 4 is closed, since the voltage drop across the measuring resistor 5 is not enough to open it, the shunt thyristor 3 is also closed, because there is no signal from the output of the control signaling device. The load is supplied with energy from the source of EMF 1. In the event of a circuit of an inductive load and the occurrence of a discharge, the sensor 6 of the beginning of the discharge absorbs the control signal and through the driver 7 turns on the shunt thyristor 3, kotpr1,1y short circuits the load.

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The voltage drop across the measuring resistor 5 will suddenly increase, the auxiliary thyristor 4 opens for the time of the discharge of the capacitor 9, At the moment

its switching on, the voltage of the capacitor 9, equal to the sum of the emf of the two sources, is applied to the anode of the main thyristor 2 in the locking direction, it is rapidly locked, de-energizing the shunt thyristor 3. When the auxiliary thyristor is switched on, the load circuit is disconnected from the power source and, consequently, from bottom gap. Voltage

self-induction load applied to the thyristor 3 in the blocking direction; it is also locked. Next, the circuit is restored, after the charging time of the capacitor 9 from the current source

the main thyristor 2 is turned on via the threshold device 10.

When the load current increases above the permissible voltage drop across measuring resistance 5, it becomes sufficient to open the auxiliary thyristor 4, it opens and connects current source 8 in series with source EMF 1 to the discharge start sensor 6. Under the influence

the pulse current of the capacitor 9, the sensor 6 generates a control signal, which through the driver 7 is supplied to the control electrode of the shunt thyristor 3. The shunt thyristor 3 turns on, shorting the load circuit. At the time of the operation of the auxiliary thyristor 4, the voltage of the capacitor 9 turns out to be applied opposite to the voltage of self-induction

ruzki, and to the anode of the main thyristor

2 - in the locking direction. Under the action of this voltage, the energy inductance of the load is reduced into the discharge gap and the acceleration of the thyristor 2 locks is accelerated. Then the thyristor 3 is provided, the self-induction voltage of the load is applied to it in the blocking direction, and the thyristor 3 is also locked.

Heartily, power limit,

allocated in the discharge gap, occurs due to the acceleration of the switching off time of the main thyristor 2 and a decrease in the voltage across the discharge gap in

the initial period of formation of the discharge.

To set the required output impedance to the source of the EMF 1 consistently with him

Claims (1)

'Claim An intrinsically safe power supply containing an EMF source, a main thyristor, a shunt thyristor, an auxiliary thyristor, a measuring thyristor, a discharge start sensor with a control signal shaper, and an EMF source, main thyristor, a measuring resistor, a discharge start sensor are connected in series with the load, the shunt thyristor is connected in parallel load, the output of the driver of the control signal is connected to the control electrode of the shunt thyristor, and the control electrode of the auxiliary shooting gallery Stora connected to the measuring resistor, characterized in that, in order to improve the intrinsically safe powerful. In fact, it is equipped with a current source, a capacitor and a threshold element, while the capacitor is connected in parallel with the output of the current source, the current source is connected in series and in accordance with the EMF source, an auxiliary thyristor is connected in parallel with their output 10, and a control electrode is connected to the output of the current source through the threshold element main thyristor.