RU2056691C1 - Electrical installation protective device (options) - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: device has controlled valve and current sensor connected in series with circuit whose first lead is connected to that used for connecting input d.c. voltage supply; control input of controllable switch is connected to current supply output; control lead of controllable valve is connected to first lead used for connecting control supply, and through controllable switch it is connected to vacant lead of current sensor; second lead of series circuit is connected to output lead used for connecting electrical installation; point of connection of controllable valve and current sensor is connected to second lead used for connecting control supply through adjustable resistor whose control lead is connected to vacant lead of current sensor. EFFECT: improved design. 2 cl, 2 dwg

Description

 The invention relates to electrical engineering and can be used to protect power supplies, electrical installations, electronic equipment, etc.

 A device is known for overcurrent protection of a DC electrical installation against overload [1] comprising a thyristor connected in series with a current sensor and an electrical installation, a thyristor disconnected connected in parallel with the thyristor anodes connected through a capacitor, a first transistor, the base-emitter junction of which is shared with the first the resistor and the first zener diode are connected in parallel with the current sensor, and the collector through the second resistor to the control electrode of the disconnecting thyristor, the second trans side, the base-emitter junction of which is connected through the second zener diode and the third resistor in parallel with the electrical installation, the power button connected in series with the four resistor in parallel with the thyristor, and the power button connected in parallel with the serial circuit of the first zener diode and the emitter-collector junction of the transistor, and the thyristor the anode is connected to the current sensor through a series-connected additional diode and an alarm element, and the collector of the second transistor h Res additional resistor is connected to the control electrode comprising a thyristor.

 The disadvantages of the device are its complexity due to the use of a large number of semiconductor devices, low reliability when turned on.

 A device for controlling a controlled valve [2] containing a controlled valve and a current sensor connected in series, and the control terminals of the controlled valve are connected to the terminals for connecting a control source through a controlled resistance, the control input of which is connected to the output of the current sensor.

 The disadvantages of this device are low reliability and narrow functionality.

 It is also known a device for current protection [3] containing the main and auxiliary thyristors, the anodes of which are connected directly, and the cathodes are connected via a capacitor, a load current sensor connected through a reacting organ to the control electrode of the auxiliary thyristor, the cathode of which is connected to the negative terminal through the charge circuit of the storage capacitor to load.

 The disadvantage of this device is its low reliability due to the fact that monitoring the state of the load circuit at the time of switching on the main thyristor is provided by an additional threshold stage.

 Known closest to the proposed device for current protection [4] containing the main and auxiliary thyristors (controlled valves), the anodes of which are connected directly, and the cathodes are connected via a capacitor, a load current sensor connected through a reacting organ to the control electrode of the auxiliary thyristor, whose cathode is connected through a circuit the charge of the capacitor is connected to a negative load terminal, a diode whose anode is connected to the cathode of the main thyristor, and the cathode is connected to the control electrode of the main thyristor flax clamp load.

 The disadvantage of the prototype device is the relatively large power consumption caused by the serial connection of the overload (current) sensor, controlled by the thyristor valve and an additional diode, which increases the power consumption on both the additional diode and the controlled thyristor valve, as the blocking increases (increase in the electrical current) ) current of the control input (control electrode cathode) of the controlled valve, which leads to an increase in the voltage drop at the power terminals of the control the flowing gate of the thyristor (and its transition, the anode is the cathode), which increases the heating of the main controlled valve (thyristor), which increases the response time, since with an increase in the temperature of the controlled valve (thyristor) the carrier recombination time increases when the controlled (main) valve is locked ( thyristor). For reliable locking, an increase in the capacitance of the switching capacitor is necessary. In addition, the disadvantage of the device is its low reliability due to the possibility of a false activation of the protection caused by a false inclusion of an auxiliary controlled valve, with a short-term abrupt change (decrease in current) of the current of the electrical installation, power source, electronic equipment, etc. especially in the presence of its inductive nature, since the discharge of the switching capacitor along the resistor circuit and the control input of the auxiliary thyristor in its forward direction increases for its control input that causes it to enable or disable wrong (locking) the main thyristor. In this case, the simultaneous discharge of the switching capacitor both through the reverse power leads of the main thyristor and along the control input circuit in the forward direction (circuit parallel to the additional diode) leads to an increase in the response time of the protection and, when overloaded, the relatively large on-off current of the on and off button leads to increase in overall dimensions of them and the whole device, and a relatively large voltage of the power source increases the turn-on time of the transistor, since with an increase in edelno allowable stress is reduced in transistor gain decreases its speed and switching loss increases.

 The purpose of the invention is the reduction of power consumption (increase in efficiency) and increase the reliability of the device.

 This object is achieved in that in a device for protecting an electrical installation containing a controlled valve and a current sensor included in a series circuit, the first output of which is connected to a terminal for connecting an input DC voltage source, a controlled key, a control input of which is connected to the output of a current sensor, control the output of the controlled valve is connected to the first output for connecting the control source and through the managed key to the free output of the current sensor, the second output of the serial circuit pi is connected to the output terminal for connecting the electrical installation, the connection point of the controlled valve and the current sensor is connected to the second terminal for connecting the control source through a controlled resistance, the control terminal of which is connected to the free terminal of the current sensor.

 This object is achieved in that in a device for protecting electrical installations containing a controlled valve and a current sensor included in a serial circuit, the first terminal of which is connected to the first terminal for connecting an input DC voltage source, a second serial circuit consisting of a controlled key and an additional power source , for example, a pre-charged capacitor, and connected in parallel to the controlled valve of the first serial circuit, the control input of the managed key p connected to the output of the current sensor, the control terminal of the controlled valve is connected to the first terminal for connecting the control source, the second terminal of the first serial circuit is connected to the output terminal for connecting the electrical installation, the connection point of the controlled valve and current sensor of the first serial circuit is connected to the second terminal for connecting the control source through a controlled resistance, the control terminal of which is connected to the free terminal of the current sensor.

 The essence of the invention is to change the totality of the features of the known device, and the exception of the series-connected valve allows to reduce the power loss and thereby increase the efficiency of the device, and the possibility of self-formation of the control switching signal of the controlled valve, taking into account almost all the parameters of the device (temperature of the controlled valve, its CVC, and the nature of the load, the magnitude of the input voltage, etc.), allows for the inclusion of the load with a minimum time by switching on the electrical installation, as well as ensuring the self-switching off of the control source when the current of the controlled valve increases, including its current, and thereby reduce the total current near the places of connection of the controlled valve, the minimum value and rate of rise, thereby increasing the likelihood of turning on without burning the electrodes when turned on a relatively large load, thereby increasing the reliability of the entire device, the use of a relatively low-voltage control source can reduce the cut-off power of the control circuit, and the execution of the option where a two-operation controlled valve can be used as a controlled valve, the speed of which is greater than a single-operation valve, increases the reliability of the electrical installation protection by its shorter shutdown time during overload or short circuits, and in case of short circuits the current sensor can perform current limiter functions, i.e. load.

 A patent search showed the absence of protection devices with the proposed combination of essential features.

 In FIG. 1 shows a functional (principle) electrical circuit of the device, in which a two-operation controlled valve (lockable, combination-lockable, etc.) is used as a controlled valve; in FIG. 2 is a functional (principle) electrical diagram of a device in which a single-operation controlled valve is used as a controlled valve.

 The device of FIG. 1 contains a controllable valve 1 and a current sensor 2, connected in series between the first terminal 3 for connecting an input source of constant voltage (current) and the first terminal 4 for connecting an electrical installation 5, the second terminal 6 of which is intended for connection to a common bus (second terminal). The second terminal 7 is for connecting a second terminal of an input source of constant voltage (current). The connection point of the first terminals (cathode) of the controlled valve 1 and the current sensor 2 is additionally connected to the second terminal 8 for connecting the control source of the controlled valve 1 through the controlled resistance 9 made in this example on the amplifying element 10 (field-effect transistor), the control terminal 11 of which is connected to the second output of the current sensor 2. The control terminal (control electrode) of the controlled valve 1 is connected to the first terminal 12 for connecting a control source, and to the second terminal of the current sensor 2 through a controlled key 13, made electrically (or electrically and optically for an optically controlled thyristor), the control input of which, for example, is electric connected to the first output of the current sensor through a threshold element, or optically to the optical output of the current sensor. The controlled resistance can be performed on other amplifying elements, for example, a bipolar transistor or in the form of an amplifying circuit.

 The device of FIG. 2 is characterized in that a parallel-connected valve 1 includes a series-connected circuit from a controlled key 14, the control input of which is connected to the output of the current sensor 2, and a power source 15, for example, a capacitor previously charged by the circuit 16, as well as using a single-operation valve as a controlled valve 1 ( or two-operation) controlled valve 1.

 It is possible in one device to combine both variants of the device, where the speed of the managed key 14 exceeds the speed of turning on the managed key 13.

 The device operates (Fig. 1) as follows.

 When using as a controlled valve 1 a dual-operation controlled valve controlled by the cathode to turn on the device and electrical installation 5, a control voltage is supplied to the control terminals 12 and 8 (including) provided that there is a voltage at the terminals 3 and 7 of the input DC voltage, and in connection with the absence of a voltage drop on the current sensor 2 supplied to the input of the controlled resistance 9, the resistance value 9, determined by the conductivity of the element 10, is small and the control switching signal m is maximal and determined by a control source connected to pins 8 and 12. Therefore, under the influence of a control switching signal, controlled valve 1 starts to open by connecting electrical installation 5 to the input source of terminals 3 and 7, and depending on the size and nature of the electrical installation, the activation of controlled valve 1 throughout its switching area is different, therefore, the time of its switching on depends on a large number of factors: from the I – V characteristic of the controlled valve, temperature, size and nature of the used electrical installation 5.

 With a large load or its reactive nature, especially capacitive or active-capacitive, with an increase in the current of the controlled valve 1, the output signal of the current sensor 2 also increases, therefore, the resistance 9 also increases. When the current of the controlled valve is sufficient to turn it on and hold it on in the on state (switching current), the resistance value 9 is large and the control switching signal of the control input of the controlled valve 1 is turned off, thereby reducing the total current initially on the area of the structure of the controlled valve, which reduces the likelihood of burning the controlled valve when the electrical installation is turned on, since burning occurs near the connection points of the control output (input) of the controlled valve 1 due to the relatively large total current of both the switching circuit and the initially switched on area of the structure of the controlled valve .

 This ensures the self-formation of the control signal of optimal minimum duration and thereby increases the reliability of the entire protection device when it is turned on to the electrical installation or with a variable conductivity value, or of an active-resistive nature, etc., ensuring self-cutting of the control switching signal, reducing the total value and slew rate in the initially included area of the structure of the controlled valve 1. When a locking signal is supplied to the terminals 12 and 8 are controlled off valve, cutting off the electrical installation.

 When the electrical installation 5 is overloaded or short-circuited, the current sensor 2 plays the role of a load as a short-circuit current limiter, at a current through which exceeds the permissible output from the current sensor, a signal to turn on key 13 is supplied, while the blocking current of the controlled valve 1 increases and it turns off, turning off the electrical installation. When using an element as a controlled key 13, the turn-off time of which is relatively long, the electrical installation is switched off before the next switching signal is applied.

 The operation of the device of FIG. 2 when turned on is similar to the operation of the device of FIG. 1.

 When an overload or short circuit occurs in the electrical installation 5, the current sensor 2 starts to perform the load functions as a current limiter, and when the overload current is more than the maximum permissible by the output signal, a controlled key (valve) 14 is connected from the current sensor, connected in series with the source 15, for example, previously charged capacitor, circuit 16, while the reverse voltage of the source 15 is applied to the controlled valve, which closes the controlled valve 1 by the reverse voltage.

 Turning off the controlled valve 1 ensures that the electrical installation 5 is disconnected from the source of terminals 3 and 7.

 Thus, the electrical installation is protected from overload or short circuit, and the use of controlled resistance 9 allows to increase the reliability of the device when turned on by ensuring self-formation of the control switching signal of optimal minimum duration, reducing the likelihood of burning through the structure of the controlled valve 1 when turning on the electrical installation with large inrush currents or reactive nature. When using a two-operation controlled valve 1, the control source can also provide shutdown of the electrical installation along the controlled resistance circuit 9.

 When using an additional control input in a controlled resistance connected to an additional output of sensor 2, the control source (pins 8 and 12) can be turned off for a while, providing a delay in the repeated switching on of the electrical installation after overload when using pins 8 and 12 as a control source continuous switching source (e.g. current).

 Thus, the proposed options provide an increase in the reliability of the entire device compared to the prototype when turned on at relatively high currents of electrical installations, for example starting ones, by reducing the likelihood of burning through the structure of controlled valves 1, by ensuring the self-formation of a control switching signal of optimal minimum duration, taking into account the I-V characteristic of the controlled valve, temperature, magnitude and nature of the electrical installation 5.

 The proposed options can provide the ability to use the device on various types of controlled valves 1, single or dual operation.

Claims (2)

 1. Device for protecting electrical installations, containing a controlled valve and a current sensor included in a serial circuit, the first output of which is connected to a terminal for connecting an input DC voltage source, a controlled key, the control input of which is connected to the output of a current sensor, characterized in that it is provided controlled resistance and terminals for connecting a control source, and the control terminal of a controlled valve is connected to the first terminal for connecting a control source and through indications will switch to a free terminal of the current sensor, the second terminal of the series circuit connected to the output terminal for electrical connection, a connection point regulation valve and a current sensor connected to the second terminal for connecting a control source through a controlled resistance, a control terminal of which is connected to the free terminal of the current sensor.  2. Device for protecting electrical installations, containing a controlled valve and a current sensor included in the first serial circuit, the first output of which is connected to the first output for connecting an input DC voltage source, a second serial circuit consisting of a controlled key and an additional power source, such as a pre-charged capacitor, and connected in parallel to the controlled valve of the first serial circuit, while the control input of the first controlled key is connected to the output a current sensor, characterized in that it is equipped with controlled resistance and terminals for connecting a control source, wherein the control terminal of a controlled valve is connected to the first terminal for connecting a control source, the second terminal of the first serial circuit is connected to an output terminal for connecting an electrical installation, the connection point of the controlled valve and the current sensor of the first serial circuit is connected to the second terminal for connecting a control source through a controlled resistance, yuschy end connected to the free terminal of the current sensor.

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