SU1721595A1 - Overall protection power supply unit - Google Patents

Abstract

The invention can be used to power electronic equipment devices with wide functionality and high reliability. The source contains a transformer, a power and auxiliary rectifiers with capacitive filters, a voltage regulator, a complex protection unit, an output voltage lower control unit, an emergency state indication unit, and two decoupling diodes. Such a construction of the source circuit allows one to avoid the deterioration of its parameters when the output voltage is lowered, and also to improve the conditions of its operation. 1 h. apt. 1 il.

Description

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The invention relates to electrical engineering and can be used to power electronic equipment devices with stabilized DC voltage.

A known DC voltage regulator, comprising a serial regulating element, the control circuit of which is connected to the output of the feedback amplifier, an output smoothing filter and a protection assembly consisting of an actuator on the thyristor, a power transition connected between the input terminal and the regulating element, sensors emergency modes and thyristor control unit, the output of which is connected to the control electrode of the thyristor.

What disadvantages include the inability to turn off the executive

element and inoperability of the undervoltage sensor at the stabilizer output. Closest to the invention is a power supply with integrated protection, comprising a fuse, a transformer, stabilizer rectifiers and an auxiliary source, an auxiliary source filter, the stabilizer itself, consisting of a regulating element, an input and output filters and a feedback amplifier, as well as a complex protection consisting of a thyristor and protection nodes against low and high input voltage of the power source, against current overload, against high output voltage congestion and from elevated temperature in controlled areas of the power source, and the dynistor of the node of protection against high input voltage and thermal contacts are connected

parallel to the emitter-collector circuit of the transistor overcurrent protection node, the collector of the matching transistor of the regulating element and the feedback amplifier are connected to the emitter of this transistor through a current sensor and a powerful transistor of the undervoltage protection node, the last protection node is connected to the power collector by the first input the transistor of the regulating element, and the second input to the collector of the transistor of the high-voltage input protection node, the output of the high-output protection node The stabilizer is connected to the transistor base of the overcurrent protection node, and the voltage collector of the overvoltage protection node and the limiting resistor connected in series with the protection thyristor control junction are connected in parallel to the collector of the transistor; the regulator transistor matching base is connected to the output feedback amplifier, and the latter's input, reference voltage source and adjustable voltage divider of the overvoltage protection node tabilizatora filter connected to the output of the stabilizer.

However, due to the absence of a low output voltage protection node in the power supply, the output voltage of the stabilizer can significantly decrease during operation due to various reasons. The consequence of this decrease in voltage can be as a degradation of the modes and operating conditions of the active elements of the stabilizer load, as well as malfunctions or failures in the operation of analog and digital devices supplied with stabilized voltage, the value of which differs from the nominal (calculated) value. The undervoltage protection node cannot disconnect the matching and power transistors due to a decrease in the input voltage of the stabilizer after the stabilizer reaches the rated operating mode.

Each time the protection is activated, the fuse connected in series with the primary winding of the transformer will blow, which requires frequent replacement of it in the process of operation.

Due to the absence of the emergency shutdown indicator of the power supply, maintenance of the power supply system, which includes the power supply, is difficult, since it requires additional time to determine the stabilizer, which has shut off and caused the entire power supply to turn off.

The aim of the invention is to enhance the functionality and increase the reliability of the device.

The goal is achieved by those. that the power supply with integrated protection containing a transformer, power and

0 auxiliary rectifiers with capacitive filters, voltage regulator, consisting of a regulating unit on the power and matching transistors with separated collector circuits,

5 of an amplifier-measuring unit and an output capacitor, an integrated protection unit consisting of an overcurrent control unit, a dynistor sensor controlling the output voltage overestimation, a rectifier, an output voltage monitoring unit of the voltage regulator, a voltage regulator switching-on unit, turning off the stabilizer, thyristor node of the stabilizer output short circuit

5 voltages, N nodes for controlling temperature regimes, a fuse and an actuating node, the fuse being connected to the primary circuit of the transformer, the secondary winding of which is

0 middle output and two symmetrical taps are connected via rectifying diodes to capacitive filters of rectifiers, the input of the measuring and amplifying unit is connected to the output of the stabilizer

5 voltage, and the output and input power - respectively with the base and collector of the matching transistor, the emitter of the power transistor is connected to the output bus, the collector of the matching transistor through

0 serially connected output circuit of the switch-on node and current sensor of the current control node, overload connected to the first terminals of the dynistor sensor of overvoltage control and temperature control nodes, the second terminals of which and the output of the overload current control node are connected to the control input of the voltage regulator shutdown node the output of which is connected to the disconnecting input of the stabilizer activation node, the activation input of which is connected to the collector of the power transistor, the input of the overestimate control node a single voltage is connected to the output of the voltage stabilizer, and the output is connected to the control input of the overload current control node, the control input of the thyristor node of the short circuit of the voltage regulator output is connected to the output of the overcurrent control node, the node

output voltage control, consisting of an output voltage divider, a reference voltage source with a smooth voltage rise and a DC amplifier, an alarm condition indication node, two isolating diodes, and an actuator node is made on a relay with two break contacts , with the output circuit of the thyristor node connected to the output of the voltage regulator through the first isolating diode, and to the output of the auxiliary rectifier through the parallel connected winding of the executive relay and node display, the first break contact of the actuating relay is connected between the output of the power rectifier and the collector of the power transistor, and the second break contact is connected between the output of the auxiliary rectifier and the first output of the dynistor sensor of the overvoltage control of the rectifier, the output of the DC amplifier of the undervoltage output connected to the control input of the overcurrent control node, the control inputs to the outputs of the output voltage divider and the reference voltage source, the input to This is connected to the auxiliary rectifier filter through the second decoupling diode.

In addition, additional output pins were added to the power supply with complex protection, and the actuator relay was equipped with additional break contacts according to the number of these pins.

The power supply with complex protection contains transformer 1, power 2 and auxiliary 3 rectifiers with capacitive filters 4 and 5, respectively, voltage regulator b, complex protection nodes, overload current control node 7, input voltage ohmic sensor 8, nodes 9 and 10 controls, respectively, for lowering and overestimating the output voltage of the voltage regulator, nodes 11 and 12 for turning on and off, respectively, the voltage regulator, and nodes 13 for controlling temperature conditions, thyristor node 14 - output voltage regulator output, actuating protection unit 15, emergency condition indication unit 16, decoupling diodes 17 and 18 and fuse 19. Stabilizer 6 consists of a regulating node on the power 20 and a matching 21 transistors with divided collector circuits measuring unit 22 and the output capacitor 23. Node 9

The control consists of a divider 24 of the output voltage of the stabilizer, a source 25 of the reference voltage with a smooth increase in the voltage, and an amplifier 26 of direct current 5. Rectifier 2 contains diodes 27 and 28, rectifier 3 contains diodes 29 and 30. Fuse 19 is connected to the primary circuit of the transformer 1, the secondary winding of which with an average output and with

0 by two symmetrical taps connected via rectifying diodes 27, 28 and 29.30, 17 with capacitive filters 4 and 5 of rectifiers 2 and 3, respectively. The input of the node 22 is connected to the output of the stabilizer 6, and you go to the power input, respectively, with the base and collector of the transistor 21. The emitter of the transistor 20 is connected to the output bus. The collector of the transistor 21 through serially connected output circuit

0 of node 11 and current sensor of node 7 is connected to the first terminals of sensor 8 and nodes 13, the second terminals of which and the output of node 7 are connected to the control input of node 12, the output of which is connected to the disconnecting input

5 of the node 11, the turn on input of which is connected to the collector of the transistor 20. The input of the node 10 is connected to the output of the stabilizer 6, and the output is connected to the control input of the node 7, the control input of the node 14 is connected to

0 output node 7. The output of amplifier 26 of node 9 is connected to the control input of node 7, and the control inputs to outputs of divider 24 and source 25, whose input is connected to output of rectifier 3 via diode 17. Node

5 15 is made on the relay with two break contacts. The output circuit of the node 14 is connected to the output of the stabilizer 6 through the diode 18, and to the output of the rectifier 3 through the parallel winding of the executive relay 15 and the display unit 16. The first break contact of the relay 15 is connected between the output of the rectifier 2 and the collector of the transistor 20, and the second break contact between the output of the rectifier 5 and the target 3 and the first output of the dynistor sensor 8.

The power source works as follows.

After connecting to AC

0, the source voltage is not turned on if the output voltage of the rectifier 3 is below the threshold voltage of the node 11, while the output voltage of the device is zero. If the input voltage of the device

5 corresponds to the nominal value (with specified tolerances), then the node 11 turns on and switches the voltage of the filter 5 to the collector of the transistor 21 and to the node 22. The voltage stabilizer 6 goes to the nominal mode. In this case, node 9 is not

works because the voltage rise of source 22 is lower than the rate of rise of output voltage of stabilizer 6. When sensor 8 or nodes 13 are triggered, node 12 is turned on, which causes node 11 to turn off and voltage from node 22 is turned off, and node 14 also turns on, as a result, the display unit 16 is turned on, the diode 18 is opened and the capacitor 23 is discharged through the thyristor of the node 14, turns on the relay 15 and disconnects the transistor 20 and the distor 8, respectively, from the rectifiers 2 and 3 regular enrollment from the network.

In the case of a current overload of the stabilizer 6, the node 7 is turned on, causing its output signal to turn on the nodes 12 and 14. Next, the device disconnecting process proceeds as described. As the output voltage of the stabilizer 6 is lowered or raised, nodes 9 or 10 are activated, respectively, causing the output signal to turn on node 7. Next, the device turns off the process as described.

A third pair of disconnecting contacts of the relay 15 can be used to automatically turn off other power sources that form the power supply system with the device.

Claims (2)

Claim 1. Power supply with complex protection, comprising a transformer, a power and auxiliary rectifiers with capacitive filters, a voltage stabilizer consisting of a regulating node on a power and matching transistors with divided collector circuits, from an amplifier-measuring node and an output capacitor , block of complex protection consisting of an overload current control node, a dynistor sensor of an over-voltage control, a rectifier, an over-voltage control node voltage regulator, voltage regulator switch-on node, stabilizer shutdown node, voltage regulator thyristor node, voltage regulator output, N temperature control nodes, fuse and actuator node, the fuse is connected to the primary winding of the transformer, the secondary winding of which has an average output and two symmetric taps through the rectifying diodes connected to the capacitive filters of the rectifiers, the input of the measuring and separating node is connected to the output of the stabilizer n april, and the power supply output and input, respectively, with the base and collector of the matching transistor, the emitter of the power transistor is connected to the output bus, the collector of the matching transistor through a series-connected output circuit of the switch-on node and the current sensor of the overload current control node is connected to the first terminals of the dynistor monitoring sensor 0 overvoltage and temperature control nodes, the second terminals of which and the output of the overload current control node are connected to the control input of the voltage regulator shutdown node, the output of which is connected to the shut-off input of the stabilizer switch-on node, the enable input of which is connected to the collector of the power transistor, the input of the control unit for the over-voltage of the output voltage 0 is connected to the output of the voltage regulator, and the output is connected to the control input of the overcurrent control node that controls the input thyristor - short-circuiting the first output node na5 direct voltage stabilizer connected to the output of the current control node overload otlichayuschiy-. so that, in order to expand functionality and increase reliability, a node has been introduced into it, 0 underestimate the output voltage, consisting of an output voltage divider, a reference voltage source with a smooth voltage rise and a DC amplifier, an alarm indication node 5 states, two isolating diodes, and the actuating node is made on a relay with two break contacts, the output circuit of the thyristor node is connected to the output of the voltage regulator 0 through the first isolating diode, and to the output of the auxiliary rectifier through the parallel connected winding of the executive relay and the display unit, the first disconnecting contact of the executive relay is connected between the output of the power rectifier and the collector of the power transistor, and the second disconnecting contact is connected between the output of the auxiliary rectifier mitel and first 0 by the output of the dynistor sensor controlling the overvoltage of the rectifier, the output of the dc amplifier of the undervoltage node of the output voltage is connected to the control input of the current control node 5 overloads, control inputs — with the outputs of the output voltage divider and the source of the reference voltage, the input of which is connected to the filter of the auxiliary rectifier via the second decoupling diode. 2. The power source of claim 1, wherein that additional output pins are entered, and the relay of the actuating unit is provided with additional break contacts according to the number of indicated pins.