RU2179775C2 - Overcurrent protective gear - Google Patents

Abstract

FIELD: electrical engineering; relay protection for users with dependent protection characteristic. SUBSTANCE: newly introduced in overcurrent protective gear are reference-voltage source and 2AND gate whose output is connected to input of final element; its first input is connected to output of OR gate and second input, to one of outputs of signal shaper that functions to record critical overcurrent; other outputs of signal shaper are connected to respective inputs of time-setting circuit and current sensor is inserted in series with circuit under protection. First inputs of signal shaper are connected to its output through voltage divider and its second ones, to respective levels of reference voltages. In this way device provides for protecting dc and ac power circuits and realizes single- valued current and time settings due to discrete principle of control. EFFECT: enhanced reliability. 6 cl, 1 dwg

Description

 The invention relates to electrical engineering, in particular to relay protection of consumers with a dependent protective characteristic.

выход триггера соединен с входом исполнительного элемента, при этом датчики тока выполнены на резисторах.A device is known for protecting a low-power three-phase circuit from overcurrent [1], comprising an actuator, a rectifier, two threshold elements, two current-limiting resistors, a timing circuit, an isolation diode, an optoelectronic switch, an IK trigger, two current sensors included in the gap between two phases of the protected circuit, while the threshold elements are made in the form of transistor switches self-locking at an overload current, the first two inputs of each threshold element are connected to the corresponding current sensor, and the output one of them is connected to the anodes of the first two corresponding rectifier diodes, the anode of the third diode of which is connected to a terminal for connecting to the mains phase without a current sensor, the cathodes of the rectifier diodes are combined and connected to the first output of the optoelectronic switch, the second output of which is connected through the first current-limiting resistor to the anode of the separation diode, the cathode of which is connected to the terminal for connection to the phase of the supply network without a current sensor, the third inputs of the threshold elements are combined and connected to the anode a separate diode, the third output of the optoelectronic switch is connected to the C-input of the IK-trigger and, through the second current-limiting one, to the terminal for connecting to the positive power bus and the I-input of the trigger, the R-input of the trigger is connected to the timing circuit, K- and S-inputs and the fourth output of the optoelectronic switch combined and connected to a common power bus,

the trigger output is connected to the input of the actuator, while the current sensors are made on resistors.

 In the known device, in order to pass a short-time overcurrent, the timing circuit blocks the shutdown of the actuator for the duration of the overload, but the timing circuit itself requires external control signals to generate such locks.

 The closest in functionality and in terms of features for the proposed technical solution is a device for overcurrent protection [2], containing a series-connected current transformer, a signal conditioner and a voltage divider, an actuator, an OR logic element and timing RC circuits, inputs which are connected to a voltage divider, and the outputs through an OR gate are connected to the actuator, and the number of additional RC circuits is due to the required accuracy aschitnoy device characteristics.

 The disadvantages of the known device for overcurrent protection are its limited functionality and reliability, the device implements a dependent protective characteristic by rectangular approximation of the starting process, followed by the imposition of one rectangle on the other, in which two variable values OVERLOAD CURRENT X OVERLOAD TIME can take different values, but at the same time, the constant current load should always be below the main rectangle, which reduces the functionality and the reliability of the device when managing multiple consumers in a complex sequence diagram.

 In addition, in this protection device, the source of the control signal is a current transformer, which eliminates the use of the device in DC circuits, and use current shunts and low-resistance resistors as current sensors, which also limits the functionality of the device.

 The known protection device also has an ambiguity in the formation of the passage time of the overload current, because the response threshold for a specific input of the OR logic element is strictly fixed, and the control signal from the voltage divider for charging the corresponding time-generating RC circuit can take a discrete value from the sufficiency for triggering at a specific input of the OR logic element when charging the corresponding RC circuit and to failure for operation by another input of the OR gate when charging another RC circuit, which leads to ambiguity and reduces the reliability of the device as a whole.

 The objective of the invention is to expand the functionality and increase the reliability of the device for protection against overload to current.

The present invention solves the problem, in which the device for overcurrent protection, containing a current sensor, an actuator, a signal conditioner, a voltage divider, an OR logic element and timing circuits, the number of which provides the required time delay for the passage of the overload current and the outputs of which connected to the corresponding inputs of the OR element,
the new one is that a reference voltage source and a 2I logic element are introduced into it, the output of which is connected to the input of the executive body, its first input is connected to the output of the OR logical element, and the second input is connected to one of the outputs of the signal shaper registering the critical value of the overload current , while the other outputs of the signal shaper are connected by the magnitude of the transmission of the overload current with the corresponding inputs of the timing circuits, and the current sensor is connected to the gap of the protected circuit, to its output via the first inputs of the signal conditioner are connected through a voltage divider, and its second inputs are connected by the magnitude of the overload current transmission with the corresponding levels of the reference voltage;
the signal driver is made on comparators, while the non-inverting inputs of the comparators controlling the timing circuits, and the inverting input of the comparator controlling the logic element 2I are connected to the corresponding levels of the reference voltages, and their inverting inputs and the non-inverting input are respectively connected to the midpoint of the divider connected between the output a current sensor and a common bus of a voltage reference source;
timing circuits are made according to the scheme of a single vibrator;
OR logic element is made on parallel-connected pnp transistors, while their bases are connected through the corresponding current-limiting resistors to the corresponding outputs of the timing oscillator single-vibrator circuits, their emitters are combined and connected to the biased power bus, and the collectors are also combined and connected to the first the input of the logic element 2I, while the collector-emitter junctions of the transistors are shunted by the diode in the opposite direction;
logic element 2I is made on a pnp type transistor, while its base is connected via a current-limiting resistor to the output of a comparator registering the critical value of the overload current, its emitter is connected to the combined collectors of transistors of the OR logic element, and its collector is connected via a current-limiting resistor to the input of the executive body, while the base-emitter junction of the transistor is shunted by the diode in the opposite direction;
the actuator is made according to the scheme of a pnp type transistor switch that controls the relay coil with a switching contact pair, the switching contact being connected to the power bus, the making contact connected via a current-limiting resistor to the base of the transistor key, and the opening contact connected to the first input of the winding a contactor switching a protected circuit, the second terminal of the winding of which is connected to a common power bus.

 The drawing shows a circuit diagram of a device for protection against overcurrent.

 The device comprises a current sensor 4, connected to the gap of the protected circuit, a signal conditioner 9, made on comparators 10-12, while the non-inverting inputs of the comparators 10.11 and the inverting input of the comparator 12 are connected to the corresponding levels of the reference voltage specified by the multi-link voltage divider 6-8 from a parametric voltage regulator on the resistor 14 and the zener diode 13 connected to the power bus 42 by the cathode, and the inverting inputs of the comparators 10, 11 and the non-inverting input of the comparator 12 are connected to the average a voltage divider 2.3, connected between the output of the current sensor 4 and the common bus 1 of the reference voltage source - the anode of the zener diode 13, the voltage divider 3 resistor 3 that can be connected to the current sensor 4 can be shunted by the diode 5, and the outputs of the comparators 10.11 are connected to corresponding to the inputs of the timing circuits 15,27, each of which is made according to the single-oscillator circuit on the comparator 23, the non-inverting input of which is connected on one side to the midpoint of the voltage divider 18,22, connected in turn between the output the house of the comparator 23 and the biased power bus 39, on the other hand, it is connected to the output of the corresponding comparator through the differential RC circuit 16.17 and the diode 19 connected in series, while the resistor 17 of the differential RC circuit is connected between the anode of the zener diode 13 and the common point of switching on the capacitor 16 of the differential RC circuit and the anode of the diode 19, the cathode of which is connected to the non-inverting input of the comparator 23. The inverting input of the comparator 23 is connected to the signal output of the integrating RC circuit 21.24 connected between the output of the computer a rotor 23 and a biased power bus 39, while the capacitor 21 of the integrating RC circuit is shunted by a diode 20, and its resistor 24 is shunted by a resistor 25 and a diode 26 serially connected, and the outputs of the timing chains-one-shots 15.27 are connected to the corresponding inputs of the OR logic element ( 33), made on transistors of 36.37 pp-p type, with their bases connected through the corresponding current-limiting resistors 34.35 with the corresponding outputs of the timing circuits, single-vibrators, their emitters are combined and connected to the offset on the power supply bus 39, and the collectors are also combined, shunted relative to the emitters by a diode 38 and connected to the first input of a logic element 2I (28), made on a transistor 31 of the rp-p type, the emitter of which is its first input, and the base is the second input, and through a current-limiting resistor 29 connected to the output of a single-shot 12, and through a diode 30 - to its emitter, while its collector through a current-limiting resistor 32 is connected to the input of the actuator 43, made according to the transistor switch circuit on the transistor 46 pa with a base-emitter resistor 45 and a relay coil 47 connected as a load to its collector circuit and shunted by a diode 48, while the switching contact of the relay 47 is connected to the power bus 42, the make contact is connected through the current-limiting resistor 44 to the base of the transistor 46, and the disconnect contact connected to the first input of the winding of a contactor 40 commuting a protected power circuit, the second output of which is connected to a common power bus 41.

 The device operates as follows.

 When power is supplied through normally closed contacts to the roll 47, the coil of the contactor 40, which includes a protected power circuit.

 The voltage divider 2,3 is selected so that in the absence of current overload at the inverting inputs of the comparators 10,11 and at the non-inverting input of the comparator 12 of the signal conditioner 9 there is a higher voltage level than at their non-inverting inputs and the inverting input, respectively, set to the transmittance overload current corresponding to the reference voltage from the multi-link voltage divider 6-8 and parametric voltage regulator 13,14. At the same time, a logical “0” is formed at the outputs of the comparators 10, 11, and the corresponding single-vibrators 15.27 controlled by them are in a normally stable state, i.e. at their outputs there is also a logical "0", opening transistors 36.37 of the OR logic element (33), but at the same time, at the output of the comparator 12, which registers critical current overload, there is a logical "1", which is connected through a series-connected resistor 29 and diodes 30.38 reliably closes the transistor 31 of the logic element 2I (28), while the transistor 46 of the executive body 43 is also closed.

 When an overload occurs to the current, the stages of passing the overload current begin to be sequentially switched on by the appearance of a logical "1" at the corresponding outputs of the comparators 10 (11) and triggering of the corresponding single-vibrators 15 (27) on the positive edge for the corresponding time of passing the overload current, with transistors 36 (37 ) of the logical element OR (33) also close for the corresponding time, but at the same time if the overload current after the expiration of the corresponding time becomes less, or does not exceed the critical value overload current, the transistor 31 of the logic element 2I (28) will also be closed and the actuation of the Executive body 43 does not occur.

 If a critical overload or short circuit occurs in the protected circuit after a minimum time delay, the corresponding OR transistor (33) opens, and through the transistor 31 of the logic element 2I (28) that opens when a critical overload occurs, the transistor 46 of the actuator 43 opens, its relay 47 is activated, which breaks the power supply circuit of the winding of the contactor 40, through the resistor 44 it becomes self-locking, the contactor 40 turns off the protected power th chain, the diode 5 prevents inputs of comparators 10-12 from possible impact of maximum allowable input voltage.

 Thus, the proposed technical solution implements a dependent protective characteristic in which the OVERLOAD CURRENT X OVERLOAD TIME can take different values, but at the same time, consumers are disconnected from the protected circuit only when the CRITICAL VALUE of the OVERLOAD current is exceeded, which can vary within any limits.

 The proposed technical solution allows you to effectively protect power circuits of direct and alternating current using various current sensors.

 The proposed technical solution implements unambiguous current and time settings due to the discrete control principle using comparators and single-vibrators.

 Thus, the proposed device for protection against overcurrent has advanced functionality and increased reliability.

Sources of information
1. Copyright certificate of the USSR 1598023, cl. H 02 H 7/06, 1990.

 2. Copyright certificate of the USSR 750633, cl. H 02 H, 3/093, 1980.

Claims (6)

 1. Device for protection against overcurrent, comprising a current sensor, an actuator, a discrete shaper of signals of overcurrent, a voltage divider, an OR logic element and timing circuits that provide the required time delay for passing the overload current and the outputs of which are connected to the corresponding inputs logical OR element, characterized in that a reference voltage source and a logical element 2I are introduced into it, the output of which is connected to the input of the executive body, its first input is connected with the output of the OR logic element, and the second input is connected to one of the outputs of the discrete signal conditioner, through which the critical value of the overload current is recorded, while the other outputs of the discrete signal conditioner are connected to the corresponding inputs of the timing circuits, and the current sensor is connected to open the protected circuit, to the first inputs of the discrete signal conditioner are connected to its output via a voltage divider, and its second inputs are connected to the corresponding levels of the reference voltage.  2. The device according to p. 1, characterized in that the discrete current overload driver is made on comparators, while the non-inverting inputs of the comparators controlling the timing circuits, the inverting input of the comparator controlling the logic element 2I are connected to the corresponding levels of the reference voltage, and their inverting inputs and non-inverting inputs are respectively connected to the midpoint of the voltage divider connected between the outputs of the current sensor and the common bus of the reference voltage source.  3. The device according to p. 1, characterized in that the timing chains are made according to the scheme of a single vibrator.  4. The device according to claim 1, characterized in that the OR gate is made on parallel connected pnp transistors, while their bases as inputs of the OR gate are connected through the corresponding current-limiting resistors with the corresponding outputs of the timing circuits, their emitters combined and connected to a biased power bus, and the collectors are also combined and connected as an output of an OR logic element to the first input of a 2I logic element, while the collector-emitter junctions of transistors shunted by the diode in the opposite direction.  5. The device according to p. 1, characterized in that the logic element 2I is made on a transistor pnp type, while its base as a second input of a logical element 2I is connected through a current-limiting resistor to one of the outputs of a discrete signal conditioner, according to which the critical value of the overload current is recorded, its emitter as the first input of the logic element 2I is connected to the output of the logical element OR, and its collector as the output of the logic element 2I is connected through a current-limiting resistor Odom actuator body, with the base-emitter junction of transistor shunted diode in reverse direction.  6. The device according to p. 1, characterized in that the actuator is made according to the circuit of an n-pn type transistor switch, which controls the relay winding with a switching contact pair, while the switching contact is connected to the power bus, the make contact is connected through a current-limiting resistor with the base of the transistor switch, and the NC contact is connected to the first input of the coil of a contactor switching a protected circuit, the second output of which is connected to a common power bus.