SU1403336A1 - D.c. power source - Google Patents

Description

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ABOUT

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The invention relates to electrical engineering, in particular, to controlled generator sources of direct current electricity.

The aim of the invention is to increase the reliability of operation by eliminating the possibility of a prolonged increase in the voltage at the output of a source of electric power of direct current resulting from breakdowns of switching of the main and quenching thyristors. The drawing shows the electrical circuit of the proposed source I of direct current electricity. j The source of DC electricity contains a generator I of: standing, minus power: pin 2 of which is connected to the cathodes I of the main 3 and extinguishing 4 thyristors j and with one pin 5 of the input I of the element 6, and positive power pin I 7 - with another pin 8 of the input of the threshold element, through the excitation winding 9 of the dc generator and the extinguishing diode 10 connected in parallel with the anode of the main thyristor 3, and through the resistor 11 with the extinguishing thyristor anode 4, connected: through the switching capacitor 12 ic anode base thyristor 3 The thyristor control device 13, connected by the input to the output of the threshold element 6, and the first 14 and the second 15 outputs respectively to the control transitions of the main 3 and extinguishing 4 thyristors, the first relay element 16 with actuation, less than or equal to the trigger voltage of the threshold element 6, winding 17, the findings of which are connected to the strength of the DC generator through the tuning resistor 18 of the first relay element, and disconnecting contacts 19 and 20 connected in series with the boundary resistor 21, the anode and the cathode of the main thyristor Zo are interconnected. The source of DC power also contains a second relay element 22 with a tripping voltage greater than the tripping voltage of the threshold element 6, the first 23 and 24 and the second 25 and 26 loosening contacts and make contacts 25 and 27, first 28 and second 29 capacitors. The first relay element 16 also has additional opening 30 and 31 and closing 30 and

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32 pins Moreover, the winding pins 33 of the second relay element through the resistor 34 The settings of the second relay element and the resistor 18 settings of the first relay element are connected to the terminals of the winding 17 of the first relay element and through the first unwinding contacts 23 and 24 of the second relay element winding the first and second relay elements connected to the power terminals 2 and 7 of the DC generator, the first capacitor .28 is connected to the terminals of the windings 33 of the second relay element and through the second disconnecting contacts 25 and 26 of the second relay socket The element is parallel to the second capacitor 29 connected in parallel to the closing contacts 25 and 27 of the second relay element Ko Kotipytsego capacitor 2 is connected to the anode of the main thyristor by the other terminal B1 via the disconnecting terminals 30 and 31 of the first relay element 7 of the direct current generator and through the closing contacts 30 and 32 of the first relay element to the anode of the extinguishing thyristor,

. The source of DC power works as follows.

At the initial excitation of the direct current generator 1, the first and second relay elements are in the initial state and the excitation current of the direct current generator flows through the circuit: the positive power output 7 of the direct current generator its excitation winding 9, the limiting resistor 21 ,, disconnecting end ° cycles 19, and 20 of the relay element minus power output 2 of the DC generator. This is the time of the excitation current and output voltage of the DC generator through the disconnecting contacts 30 and 31 of the first relay element roiskhodit charge the switching capacitor 12,

When the output voltage of the generator reaches a certain value, the main thyristor 3 opens and the main part of the exciter current of the dc generator begins to flow through it, making it easier in the future to break the initial excitation circuit with the break contacts 19 and 20 "

At the point in time when the output voltage of the generator becomes

3 14 equal to the response voltage of the first relay element, the latter operates, breaking the initial excitation circuit of the dc generator and its closing contacts 30 and 32 connects the output of the charged switching capacitor 2 to the anode.

ra 4, which at this moment is closed

When the output voltage of the generator reaches the voltage of the trigger element 6, it triggers and the thyristor control device 13 removes the control signal from the main thyristor and sends a signal to open the auxiliary thyristor 4, which opens, applying to the main thyristor 3 for example: polarity of the switched capacitor 12o of the main thyristor is locked at the same time, and the output current and output voltage of the direct current generator is 1in. down; switching conductive capacitor 12 thus recharged reverse voltage.

The tripping voltage of the first relay element and the threshold element should be chosen as large as possible to each other, since this switch will charge the maximum thyristor to maximum voltage and lock the main thyristor more reliably.

The output voltage of the DC generator will be reduced to a value equal to the release voltage of the threshold element 6, at which the thyristor control device 13 removes the control signal from the auxiliary thyristor and supplies it to the main thyristor. The thyristors reversely switch and the output voltage of the generator is reversed. The current increases again. Switching of the thyristors 3 and 4 occurs periodically. At this, the average value of the output voltage of the DC generator remains constant.

However, when the DC power source is in operation, the switching processes of thyristors 3 and 4 may be interrupted, at which the main and auxiliary thyristors are in the open state at the same time, and the switching capacitor remains discharged.

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In the DC power source, the elimination of thyristor switching fails is performed automatically without disconnecting the DC generator from the mains. When the thyristor switching processes fail, the excitation current and output voltage of the DC generator begin to increase.

When the output voltage of the DC generator becomes equal to the response voltage of the second relay element, the second relay element is activated and disconnects the positive power output of the generator from the winding circuits of the first and second relay elements through disconnecting contacts 23 and 24, and also shunt the second capacitor 29 with closing contacts 25 and 27 "In this case, the second capacitor is quickly discharged, the first relay element is turned off, the closure contacts 30 and 31, the charge of the switching Capacitor 12 begins, The capacitor 28 is discharged to the winding of the control circuit relay of the second relay element, failing to turn off, the generator output voltage continues to increase, and the thyristor control unit continuously sends a signal to turn on the extinguishing thyristor. At the moment when the voltage on the first capacitor 28 becomes below the release voltage of the relay of the second relay element 22, the second relay element closes the opening contacts 23 and 24, supplying power from the DC generator to the first relay element, which is triggered INDICATES closure contacts 30 and 32 and the locking feeding voltage of the switching capacitor 12 to the main thyristor 3 "main thyristor is latched, which causes a decrease excitation current and the output voltage of the generator constant current to a predetermined level

When the second relay element is disconnected, contacts 25 and 26 are closed, which at the first moment of time leads to the redistribution of charges between the first and second capacitors with a decrease in the voltage of the first capacitor 28. The first and second capacitors are further charged. Moreover, the capacitance of the second capacitor must be chosen so that the charge of the capacitors occurs quite slowly and by the end of their charge the generator output voltage will decrease to a value less than the response voltage of the second relay element. This will prevent the false relay from triggering the second relay element.

Thus, in the proposed constant-current electric power source, the automatic switch-off process is switched on.

terminals of the direct current generator and opening contacts ,. through which the anode and the cathode of the main thyristor are interconnected, characterized in that, in order to increase the reliability of operation by eliminating the possibility of a prolonged increase in the voltage at the output 0 of the constant-current power source, resulting from disruptions of the switching of the main and quenching thyristors, a second relay element was additionally introduced with a thyristor working voltage, which increases the reliability of the power supply, and the higher voltage triggers its operation.

;. second break contacts and make contacts, first and second capacitors, first relay

20 the element is made with additional opening and closing contacts, the terminals of the windings of the second relay element are connected to the terminals of the windings of the first relay element and through the first spreading contacts of the second relay element windings of the first and second relay elements are connected to power terminals generator of direct current, the first capacitor is connected to the winding pins of the second relay element and through the second disconnecting contacts of the second relay element parallel to the second capacitor yuchennom paral-

3g directly to the opening contacts of the second relay element, the switching capacitor is connected by one output to the anode of the main thyristor, and the other output through the opening contacts of the first relay element to the positive power output of the DC generator and through the closing contacts of the first relay element to the anode of the extinguishing thyristor, F: Formula of invention

 A DC power source, containing a DC generator, the negative power input of which is connected to the cathodes of the main and quenching thyristors and to the input terminal of the threshold element, and the positive power output to another input of the threshold element through the parallel-connected winding excitation of the DC generator. and the extinguishing diode - with the anode of the main thyristor, and through a resistor - with the anode of the extinguishing thyristor connected through the commutator to the anode of the main (thyristor), control device tfristors, connected by an input to the threshold element cell, and the first and second outputs, respectively, to control junctions of the primary and secondary thyristors, the first relay element with a tripping voltage less than or equal to the triggered voltage of the threshold element, winding, the outputs of which are connected forcefully

Claims (3)

Claim A direct current electric power source containing a direct current generator, the negative power input of which is connected to the cathodes of the main and quenching thyristors and with one output of the input of the threshold element, and the positive power output is connected to the other output of the input of the threshold element through a parallel connected excitation winding DC generator and a quenching diode with the anode of the main thyristor, and through the resistor - with the anode of the quenching thyristor, connected through a switching capacitor to the anode of the main thyristor, device thyristor control, connected to the output of the threshold element by the input, and the first and second outputs respectively to the control transitions of the main and quenching thyristors, the first relay element with a trip voltage less than or equal to the threshold voltage of the threshold element, a winding whose terminals are connected to the power terminals of the DC generator current and disconnecting contacts, through which the anode is connected 5 and the cathode of the main thyristor, characterized in that, in order to increase the reliability of operation by eliminating the possibility of a long-term increase in the output voltage 10 of the DC power source due to switching failures of the main and quenching thyristors, a second relay element with an operating voltage15 higher than the threshold voltage of the threshold element, the first and second opening contacts and closing contacts, the first and second capacitors, the first relay 20, the element is made with additional opening and closing contacts, 'the terminals of the windings of the second relay element being connected to the terminals of the windings of the first relay element 25 and through the first opening contacts of the second relay element, the windings of the first and second relay elements are connected to the power terminals of the DC generator, the first the capacitor is connected to the terminals of the winding of the second relay element and through the second disconnecting contacts of the second relay element parallel to the second capacitor, connected y paral35 allel NC contacts of the second relay element, the switching capacitor is connected to one terminal of the main thyristor anode and the other terminal through the bars of the first NC kon40 relay element to the positive power terminal DC generator and via make contacts of the first relay element to the anode of quench thyristor.