SU1376168A1 - Device for checking load state and connecting same to d.c. power source - Google Patents

Description

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the analyzer is connected to the output of the device, the output of the analyzer is connected to the power input of the threshold element of the protection unit and through the relay coil to the second output of the control input connected also via serially connected emitter-base transistor of the second transistor switch, collector-emitter junction of the transistor of the first transistor switch and five resistors - to the first output of the control input, the number of transistor's lecturers of the newly introduced third transistor switch is connected to the first input switch device emitter - to the common point of the first output of the seventh resistor and the first input output of the threshold element of the protection unit, and the base through the sixth resistor is connected to the first output of the control input, the second output of the seventh resistor is connected to the collector of the transistor of the second transistor, with a common point of the first and second closing contacts, respectively, of the first and second contactors and with the second input terminal of the threshold element of the protection unit, the first and second relay elements are also reintroduced, the first one is made and base

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transistor optocoupler, the input of the first relay element is connected to the output of the threshold element of the protection unit, the first input terminal of the second relay element is connected to the common point of the second and third resistors, the second input terminal of the second relay element is connected to the common point of the throttle and the first contact of the first contactor, and the output pins of the first and second relay elements, which are respectively the pins of the collector and emitter of the phototransistor of the optocoupler and the closing contacts of the second relay, are connected between and connected in parallel between the output of the analyzer lowering the output voltage of the first transistor and the base of the transistor switch.

2. The POP.1 device, distinguished by the fact that in the second relay element the winding of the second relay, the second capacitor and the eighth resistor are connected in a series circuit whose opposite terminals are input terminals of the second relay element, while between connected in series by the winding of the second relay and the second capacitor. included diode.

The invention relates to electrical engineering and can be used for switching high-power loads, including the capacitive component in direct-current networks.

The aim of the invention is to increase reliability by ensuring control of the state of the load before and after it is connected, and also by eliminating the limitation of the load regardless of its nature.

Fig. 1 is a diagram of a device for checking the load condition and connecting it to a DC power source; FIGS. 2 and 3 are diagrams of voltages and currents at characteristic points of the circuit, respectively, when the device is turned on and off.

The device consists (see Fig. 1) of contactors 1 and 2 with closing contacts 1.1, 1.2, 2.1, 2.2 and M1 1 with 1.3, 1.4, 2.3, 2.4 contacts, from peJte 3 with closing 3,

- and opening contacts 3.2, from the drossel 4, the transistor 5, the first 6, the second 7 and the third 8 transistor switches, from the diode 9, from the protection block 40 O with the threshold element 11, with the first (high-speed) relay element 12 on the base of the transistor optocoupler 13 and the second relay element 14 on the basis of a relay having closing contacts 14.1, from a capacitor .15, from

the capacitor 16, the analyzer lowers the input voltage 17 and the first 18, the second 19, the third 20, the fourth 21, the second 22, the sixth 23, the seventh

cf, 24 and eighth 25 resistors. Through series-connected disconnecting contacts 2.3, 1.3 and choke 4, the capacitor 16 is connected to the input of the device. The common point of these contacts, coils and chokes 4 is connected via pin 1.1 to the output, to the capacitor 16 there are connected in series through resistor 18 and parallel connected leads 2.1 and 3.1

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windings of capacitors 1 and 2, in parallel with which contacts 3.2 and the collector-emitter junction of transistor 5 are connected respectively. Parallel to j junction base-emitter of this transistor, pins 1.2 and resistors 19 and 20 connected in series are connected; their common point through the contacts 2.4 is connected to the common point drossel 4 and the capacitor 16, connected, moreover, through the contact, s 2.2 with the output of the device. In parallel with the output pins, a resistor 21 is connected through pins 1.4. 15

The control input of the device is connected via an output voltage decrease analyzer to the winding of the relay 3; through the first transistor switch 6 and the resistor 22 - to the base-emitter junction of the transistor of the second switch 7; through the second transistor switch 7 and the resistors 23, 24 to the base-emitter junction of the third switch transistor 8; through the analyzer of the output voltage-25 nor 17 and the second transistor switch 7 to the power input of the protection unit 10.

The input of the transistor switch 6 is connected to the output of the protection unit 10, which is simultaneously the output of both 30 relay elements 12 and 14 (collector-emitter junction of the transistor optocoupler 13 and the closing contacts 14.1 of the relay 14). The input of the first of these elements

associated with the output of the threshold element

11, and the second input (relay coil 14). Through capacitor 15 is connected to diode 9. This diode, together with relay coil of series 14 connected to relay 14 and resistor 25, forms the second relay element. Diode 9 bypasses the coil of the relay 14 and the capacitor 15 in series. The common point of the relay coil 14 with the diode 9 and the free terminal of the resistor 25 are the input terminals of the second relay element, connected respectively to the common point of resistors 19, 20 and to the common point of droplets 4 and contacts 1.1 and 1.3. The transition of the collector - emitter of the transistor of the third key 8 in series with the resistor 24 is connected between the input and the output of the device, and the resistor 24 is simultaneously connected to the input of the protection unit.

The output voltage reduction analyzer 17 is a threshold device sensitive to

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: lower output voltage of the device. The operating state of the analyzer corresponds to the state of conduction through the output terminals, for example, through a clamped transistor. The analyzer enters this state at the output voltage, which exceeds the threshold level after the delay time after the activation signal to the control input, which is sufficient to increase the output voltage. before the set value.

The plots in figure 2 and fig.Z shows:

26 - signal at the control input; 27 - voltage across the winding of the first contactor (1); 28 is a view of the load current in its normal state (with a capacitive component); 29.1 - the voltage on the capacitor 1 6 under normal load conditions; 29.2 - the voltage on the capacitor 16 with a load greater than permissible; 30 - voltage across the winding of the second contactor (2); 31 - voltage at a common point of resistors 19 and 20; 32 - im-, pulse of the second relay element 14; 33 - switching on (in FIG. 2) and switching off (in FIG. 3) the first relay element 12 and transistor switches 6, 7 and 8; 34.1 is the output voltage under normal load conditions; 34.2 - output voltage at a load greater than permissible.

The device works as follows.

Prior to supplying the control signal, capacitor 16 through the opening contacts 2.3 and 1.3 and choke 4 is charged to the input voltage. With the input of the switch-on command to the control input (plot 26 in FIG. 2), a relay 3 is triggered, closing the current circuit through the resistor 18 to the windings of the contactors 1.2. But only contactor 1 (plot 27) works at this stage, since the second winding turns out to be shunted by transistor 5, receiving base current through contacts 2.4 and resistor 19. As a result of switching contacts 1.3 and 1.1, capacitor 16 through choke 4 will be connected to the output of the device. The charges of this capacitor and the load capacitance (if any), initially discharged, are redistributed, and the charge current of the load capacitance is limited by the choke 4, the first surge in plot 28 (Fig. 2).

However, under the conditions of operation, the capacitance of the capacitor 16 must be chosen at least an order of magnitude greater than the capacity of the load. Therefore, in the absence of load, the steady-state voltage at the output of the unit will be close to the input. If the payload is present, an additional discharge will take place (plot 29.1). The closed contacts J.2 of the contactor 1 are interrupted by the base current of the transistor 5 and then the contactor 2 is activated (plot 30).

If by the time of opening 2.4 of the contacts (see plot 31), the output voltage of the device is no less than the value guaranteeing the absence of overload, the capacitor 15, charging through the winding turnip 14 and the resistor 25, will cause a short-term release of the relay 14 (her, plot 32), the transistor switch 6 will begin to function, and then (due to the current through the resistor 22) the transistor switch 7 (diagram 33). The latter will provide the threshold device 11 with power, and since its initial state (in the absence of an overload) corresponds to the presence of output voltage, it triggers the relay element 12 (plot 33) and the phototransistor triggered after opening the contacts 14.1 will support transistor switch 6, hence, 7 in the open state (self-locking will occur). Through the transistor switch 7 and the resistor 23, a base current of the transistor switch 8 arises and, having opened (plot 33), forms a connection between the device input and the output (plot 28, the second current surge), due to which the output voltage will be brought to the input level ( minus the saturation voltage of the transistor key 8 and the voltage drop across the resistor 24, plot 34.1).

Contactor 2 with its contacts 2.2 through previously activated contacts 1, will short the choke 4, which

It is used only at the stage of switching on contacts 1.1, in order to reduce their current (the initial charging capacitive load) and the current of the first electronic key 6 at the moment of its switching on (see plots 28, 29. 1, 34.1), accompanied by a surge in the charge metering current load, to which undesirable (or unacceptable) additive dozary dny current-to capacitor 16,

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much greater capacity than the load capacity. If during the load test the capacitor 16 is discharged through it faster than the estimated time (plot 29.2) and by the time the contacts 2.4 are open, the voltage at the input of the chain: diode 9 - resistor 25, will be less than needed for operation of the relay element ( relay 14), the load will be rejected, the transistor switches are not turned on, which will prevent their crash, the output voltage (see plot 34.2 When it reaches its nominal value, it drops to zero due to the final discharge of the capacitor 116 through an excessive load.

When scheduled to shut down nor. the sequence of turning off contactors is the same as when turned on: first the first, then the second. It is prepared in advance, even when turned on. The opening contacts 2.4 prevent the early switching off of the contactor 2 at the beginning of turning off the contactor 1, when only contacts 1.2 are opened. The second preparatory operation is to block the contactor 2 with contacts 2.1 (at the moment of their closing the circuit to the contactor winding It is already formed by contacts 3.1), and the third is the opening of the circuit from the input to the capacitor 16 (already opened by contacts 1.3), additionally by contacts 2.3, in order to avoid the appearance of a through circuit from the input to the output (besides the third transistor to South of the circuit, which is switched off initially) along the circuit: contacts 1.3 is turned off: contactor I, choke 4, contacts 2.2 have not yet turned off contactor 2. Contacts 2.2, would be the last to turn off when such a circuit was in progress, imminent due to the presence in the chain; drossel 4,

The sequence of scheduled shutdown processes is as follows.

Disconnection of the signal from the control input (plot 26) and at the same time all three electronic switches, the first 6, second 7 and third 8, power (see its current transistor base voltage diagram 33) and de-energization of the relay 3 winding. 1.2 are energized by the energy of the capacitor 16,

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The contact closure 3.2 relays 3, shorting the winding of the contactor 1 (plot 27). Contactor 1: turns off, and contacts of contactor 2 continue to be maintained in the same state by the current of the winding through contacts 2.1, and the resistance in the circuit of this winding has decreased (due to shorting of the winding of contactor 1), which is necessary to prolong its operation until it is completely turned off KOHTiaKTOpa 1 from a discharging (since the transistor switch 8 is turned off) capacitor 16 - plot 29.1 Contacts 1.1 are disconnected, but without breaking current, as the connection of the capacitor 16 to the output through contacts 2.2 is retained. Contacts 1.3 are turned on, but the connection of the capacitor 16 with the input is not established yet, because the jj2.3 contacts continue to be open. From the moment of contact closure 1.4, forced discharge of co-sensor 16 (plot 29.1) starts through resistor.or 21. The output voltage repeats the falling voltage of capacitor 16 (plot), but only until the end of the stage.

Preparation for a new cycle of operation: | charge of the capacitor 16 through the contacts, 2,3,1.3 and 4 choke (plug 29.1) and closing of the contacts 2.4, which will lead to the formation of the base current of the transistor 5 and subsequently, when

the voltage in the collector circuit of the transistor, - to shorting the winding of the capacitor 2.,

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35

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Self-switching due to overloading goes through the following stages.

Immediate disconnection of the electronic connection between the input and output (triggering of the threshold device 11, turning off the first relay element 12 and transistor switches 6, 7 and 8, all coming together from self-blocking) and the discharge of the capacitor 16 to the load.

The operation of the analyzer 17 due to a decrease in the output voltage and the switching off of the relay 3, the disconnection of the contactors 1 and 2 in the specified sequence, or in another, if the overload is so strong that the con-. The capacitor 16 is discharged before the release voltage of the contactors is earlier than: the relay 3 is turned off.

The next cycle of operation can be started after removing the voltage from the control input, and then its subsequent supply.

Thus, the load is automatically controlled each time, both by the turn-on time and throughout the entire work cycle. Due to this, it excludes the output from the device in the emergency state of the consumer, regardless of whether this state was t & a prior to switching on, or occurred during operation.

The device can operate on a load from zero to maximum and of any kind - capacitive, inductive, active, or complex.

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Claims (2)

1. DEVICE FOR CHECKING THE LOAD CONDITION AND CONNECTION. j. A DC power source containing a diode, a protection unit comprising a threshold element whose input is the input of a protection unit, the first capacitor, the first lining of which is connected to the first output of the first resistor, the first and second switching elements, which differs from me in that , in order to increase reliability by ensuring control of the load state before and after it is connected ·, as well as by removing the load limitation irrespective of its nature, the first switching element is designed as a contactor with two closing and two disconnecting groups of contacts, the second switching element is designed as a first transistor switch, and a second contactor is additionally introduced with two closing and two disconnecting groups of contacts, a relay, a choke, a transistor, a second, third, fourth, fifth, sixth and seventh resistors , the second transistor switch, the analyzer of the lowering of the output · 'of the voltage, while the first input terminal of the device through the series-connected third disconnecting contacts, respectively, the first 2 second and second contactors and the first closing contact of the first contactor is connected to the first output terminal of the device, the common point of the third opening and first closing contacts of the first contactor is connected via a choke to the first plate of the first capacitor, the second plate of which is connected to the second input and second output terminals of the device, the second the output of the first resistor through the parallel-connected first make contacts of the second contactor and the relay, respectively, and through the series-connected with these the windings of the first and second \ contactors are connected to the second plate of the first capacitor, the second contactor winding is connected in parallel, the second disconnecting relay contact, the common point of the windings of the first and second contactors is connected to the collector of the transistor, the emitter of which is connected to the second plate of the first capacitor, which through the second and the third resistor is connected to the base of the transistor, the second closing contact of the first contactor is connected in parallel with the emitter-base transition of the transistor, between the common point of the second and three rd resistor and said first electrode of the first capacitor included fourth normally closed contact of the second contactor parallel with the output device via a fourth 'break contact of the first contactor connected to the fourth; resistor, the first and second input! pins of the output voltage analyzer are connected to the first and the second pins of the control input, ‘Third and fourth input pins 1376168 A1 3 four 13761 of the analyzer are connected to the output of the device, the output of the analyzer is connected to the power input of the threshold element of the protection unit and through the winding of the relay - $ with the second output of the control input connected also through a series-connected emitter- ¹ junction base of the transistor of the second transistor switch, collector-emitter re-10 stroke of the transistor of the first transistor switch and the fifth resistor to the first output of the control input, count- (transistor of the newly entered The third transistor switch is connected to the first input terminal of the device, the emitter to the common point of the first terminal of the seventh resistor and the first input terminal of the threshold element of the protection unit, and the base is through sixth 20 the resistor is connected to the first output of the control input, the second output of the seventh resistor is connected to the collector of the transistor of the second transistor switch, with a common point of the first 25 and second make contacts, respectively, of the first and second contactors and the second input terminal of the threshold element of the protection unit, again _; The first and second relays are also introduced .30 elements, the first one is made on the basis of 68 the transistor ί optron, the input of the first relay element is connected to the output of the threshold element of the protection unit, the first input terminal of the second relay element is connected to the common point of the second and third resistors, the second input terminal of the second relay element is connected to the common point of the throttle and the first closing contact of the first contactor, and the output terminals the first and second relay elements, which are respectively the findings of the collector and emitter of the phototransistor of the optocoupler and the closing contacts of the second relay, are connected between the fight is parallel and connected between the output of the output voltage analyzer and the base of the transistor of the first transistor switch. 2. The device according to claim 1, characterized in that in the second relay element the winding of the second relay, the second capacitor and the eighth resistor are included in a series circuit, the opposite terminals of which are the input terminals of the second relay element, between the serially connected windings of the second relay and the second a capacitor. included diode.