RU2124257C1 - Overcurrent protective device for dc circuits - Google Patents

Abstract

FIELD: overcurrent protective gear; overcurrent releases for automatic circuit breakers. SUBSTANCE: device has rectifier, measuring unit, final element, and power unit whose input is connected to circuit being protected. Power unit has, apart from rectifier, two transistors, two resistors, and voltage regulator diode. Circuit arrangement provides for operation at different voltages across circuit under protection even in case of 10 times difference. EFFECT: improved reliability; facilitated manufacture and in- service maintenance. 1 dwg

Description

 The invention relates to the electric power industry, in particular, to current protection devices.

 Known current protection devices for DC circuits (1 - 8), including those powered by the voltage of the protected DC circuit (9).

 Closest to the proposed device is (10).

 It contains a control protection unit consisting of an input relay, a time delay circuit, a DC to AC converter, an output stage and a controlled key, to the input of which the output of the measuring element is connected, an electromagnetic release is connected to the output, and the outputs of the power supply including a diode bridge, one diagonal of which is the input of the power supply and connected to the buses of the protected circuit, the other diagonal - to the first terminals of the ballast resistor and zener diode, the first and second conclusions to torogo are the outputs of the power supply and the second terminal of the resistor connected to the second terminal of the zener diode.

The resistance value of the ballast resistor is determined by the supply voltage U _p of the control unit of protection, the current consumption I _p and the rated voltage of the protected circuit U. The current consumption I _{p is the} sum of the current consumption of the nodes of the control unit of protection and current through the zener diode. The sum of the currents of consumption of nodes during the operation of the device varies little; the range of permissible minimum and maximum values of permissible currents through the zener diode is small; therefore, with a constant value of the resistance of the ballast resistor, the voltage U of the protected circuit can vary in a very small range.

 This is a disadvantage of the device, because the need to change the resistance of the ballast resistor depending on the voltage U leads to certain operational inconveniences or to versions of the protection device, which is inconvenient in the manufacture of the manufacturer.

 In the real circuit of the device (10) described in (11), in accordance with the range of possible values of U, the ballast resistance consists of several resistors switched by a switch, which reduces the reliability of the device.

 The objective of the proposed device is to increase reliability and convenience in the manufacture and operation.

 The solution to this problem is provided by the fact that the current protection device for DC circuits contains a control protection unit, the input of which is connected to the output of the measuring element, the output is an electromagnetic release, and to the power circuits are the outputs of the power supply unit, which includes a diode bridge, one diagonal of which is the input of the power supply and is connected to the buses of the circuit to be protected, the other diagonal is to the first terminals of the resistor and zener diode, and the first and second conclusions of the zener diode are outputs of the power supply, additionally introduced two transistors and a second resistor, the collector of the first transistor is connected to the first output of the first resistor, the base is connected to the second output of the first resistor and to the collector of the second transistor, the emitter of the first transistor is connected to the base of the second transistor and to the first output of the second resistor, and the emitter of the second transistor - with the second terminals of the second resistor and zener diode.

 The drawing shows a structural diagram of the device. It contains a control unit of protection 1, to the input of which the output of the measuring element 2 is connected, to the output is an electromagnetic release 3, to the power circuits are the outputs of the power supply 4, which includes a diode bridge 5, one diagonal of which is the input of the power supply 4 and is connected to tires 6 of the protected circuit, another diagonal - to the first conclusions of the resistor 7 and the zener diode 8; the first and second conclusions of the zener diode 8 are the outputs of the power supply 4, into which the first transistor 9, the second transistor 10 and the second resistor 11 are also introduced. The collector of the first transistor 9 is connected to the first output of the first resistor 7, the base to the second output of the first resistor 7 and to the collector of the second transistor 10, the emitter of the first transistor 9 is connected to the base of the second transistor 10 and to the first terminal of the second resistor 11, and the emitter of the second transistor 10 is connected to the second terminals of the second resistor 11 and zener diode 8.

 With increasing current in the protected circuit 6 increases the voltage at the output of the measuring element 2; when it exceeds the setpoint, the control unit 1 protects the electromagnetic release 3, which opens the switch 12.

To determine the permissible voltage values U of the protected circuit, at which the power supply unit 4 can function normally, we consider two limiting modes of its operation:
U = U _min , (1)
U = U _max . (2)
For the given power supply circuit, the equality
U = U _ke1 + U _be2 + U _p , (3)
Where
U _ke1 - voltage between the collector and the emitter of the first transistor 9;
U _BE2 - voltage between the base and emitter of the second transistor 10.

,(6)
где
R₇, R₁₁ - соответственно величина сопротивления резисторов 7, 11;
β - коэффициент усиления транзистора 9.In mode (1), transistor 9 is saturated, transistor 10 is closed. Moreover, it is permissible to assume that U _ke1 = 0; U _be2 <1B; then from (3) it follows
U _min ≈ U _p . (4)
To ensure the closed state of the transistor 10, the resistance of the resistor 11 must satisfy the inequality
R ₁₁ ≤ U _be2 / I _p ≤ 1 / I _p . (5)
To ensure the saturated state of the transistor 10, the condition must be satisfied

, (6)
Where
R ₇ , R ₁₁ - respectively, the resistance value of the resistors 7, 11;
β is the gain of the transistor 9.

.(7)
В режиме (2) транзистор 9 закрыт по цепи коллектора, транзистор 10 - насыщен; при этом справедливо
U ≈ I_п • R₇ + U_п. (8)
Из (8) и (7) наибольшее значение U:
U_max≈ (β+1)U_min .(9)
Как следует из (9), минимальное и максимальное значения напряжения U защищаемой цепи могут отличаться по крайней мере в 10 раз. Реально эти значения ограничиваются допустимыми токами и напряжениями транзисторов, но этого достаточно для обеспечения практических потребностей, т.к. для промышленных сетей постоянного тока применяются напряжения 110, 220 и 440В, а с учетом допустимых предельных значений от 0,8 до 1,1 номинального, т.е. от 88 до 484 В, или в 5,5 раза.After simple transformations from (6) with some assumptions

. (7)
In mode (2), transistor 9 is closed along the collector circuit, transistor 10 is saturated; this is true
U ≈ I _p • R ₇ + U _p . (eight)
From (8) and (7) the largest value of U:
U _max ≈ (β + 1) U _min . (9)
As follows from (9), the minimum and maximum voltage U of the protected circuit can differ by at least 10 times. In reality, these values are limited by the permissible currents and voltages of the transistors, but this is enough to ensure practical needs, because For industrial DC networks, voltages of 110, 220 and 440V are used, and taking into account the permissible limit values from 0.8 to 1.1 of the nominal, i.e. 88 to 484 V, or 5.5 times.

 Thus, the proposed device eliminates the need for switching ballast resistors depending on the voltage U of the protected circuit, which increases the reliability and convenience in its production and operation.

Sources of information
1. A.S. USSR N 1064363, H 02 H 3/08, 1983.

 2. A.S. USSR N 1008839, H 02 H 3/08, 1985.

 3. A.S. USSR N 1228178, H 02 H 3/08, 1986.

 4. A.S. USSR N 1390685, H 02 H 3/08, 1988.

 5. A.S. USSR N 1422284, H 02 H 3/08, 1988.

 6. A.S. USSR N 1658269, H 02 H 3/08, 1991.

 7. A.S. USSR N 1661895, H 02 H 3/08, 1991.

 8. A.S. USSR N 1704212, H 02 H 3/08, 1992.

 9. A.S. USSR N 1261039, H 02 H 3/08, 1986.

 10. A.S. USSR N 160741, class 21c, 6850, IPC H 02, 1961.

 11. Blocks semiconductor series BPR11 and BPR22 of the maximum release. Technical description IGPN.656111004TO.

Claims (1)

 An overcurrent protection device for DC circuits, containing a control protection unit, to the input of which the output of the measuring element is connected, to the output is an electromagnetic release, and to the power circuits are the outputs of the power supply unit, which includes a diode bridge, one diagonal of which is the input of the power supply unit and connected to the tires of the circuit to be protected, another diagonal to the first terminals of the first resistor and zener diode, and the first and second terminals of the zener diode are outputs of the power supply, characterized in that it additionally two transistors and a resistor are given, the collector of the first transistor is connected to the first output of the first resistor, the base to the second output of the first resistor and to the collector of the second transistor, the emitter of the first transistor is connected to the base of the second transistor and to the first output of the second resistor, and the emitter of the second transistor is connected to the second conclusions of the second resistor and zener diode.