SU736075A1 - Protected dc voltage supply source - Google Patents

Description

The invention relates to electrical engineering, namely to power sources, and can be used in power systems of automation devices and computer technology.

Known power supplies with protection ⁵ and control of the output parameters, containing voltage stabilizers, amplifier, controlled and executive bodies £ 1].

The closest technical Niemi ¹⁰ The solution to this invention is a DC power source with protection comprising at least two bipolar permanent stabilizer zheniya ₅ The stresses, to the output terminals of which are connected sensors output voltages of negative and positive polarities, whose outputs are connected to inputs of blocks allocation of maximum and minimum voltage of negative and positive polarity, differential amplifier, reference voltage source, the first switching unit, blocks azdelitelnyh diodes positive and negative polarity outputs connected to the input terminals of the DC voltage stabilizers [2}.

However, the known device does not provide a current limit at the time of switching on, there is no circuit solution that excludes the possibility of false triggering of the device, which is protected from short-term interference, and, moreover, it has a low accuracy of operation due to the variation in the parameters of the input zener diodes.

The aim of the invention is to increase reliability and eliminate false positives.

This is achieved by the fact that in the DC power supply with protection, containing at least two different-polar DC voltage stabilizers, the output terminals of which are connected to the output voltage sensors of negative and positive polarity, the outputs of which are connected to the inputs of the maximum and minus diode negative isolation blocks negative and positive polarities, differential amplifier, reference voltage source, first switching unit, section blocks input diodes of negative and positive polarity, the outputs connected to the input terminals of the DC voltage stabilizers, introduced input current sensors connected to the output terminals of the DC voltage stabilizers, which are connected to the input resistor divider through the input input current isolation blocks, the output of which is through the first 15 a dividing diode is connected to the combined output of the unit for allocating the maximum voltage of positive polarity and through the second diode - to the connection point of the output of the first 20 introduced potentially setting variable resistor and the first input of the differential amplifier. The combined output of the positive voltage undervoltage isolation unit through 25 normally open first contacts of the input connected to the input of one of the DC voltage stabilizers of the relay and the third isolation diode are connected to the connection point 30 of the output of the second potential setting variable resistor and the second input of the differential amplifier . Moreover, the cathode of the third isolation diode is connected to the combined output of the negative voltage maximum voltage isolation block, the anode of the second isolation diode through the second contacts of the input relay to the combined output of the negative voltage minimum voltage isolation unit 40, and the inputs of the potentially setting variable resistors are combined and connected to reference voltage source. The output of the differential amplifier through the introduced first noise suppressing unit and the zener diode is connected to the input of the first switching unit, the output of which is connected to the combined input of the positive dividing diode block, to the output of the second switching unit and through the second damping unit and the fourth dividing diode - to the output selection unit ⁵⁵ undervoltage zhitelnoy positive polarity, the output of the second switching unit is connected to an integrated unit yhodu separability.

The drawing shows a circuit diagram of a power supply of a constant direction, with wired.

The power supply contains bipolar stabilizers 1, a negative sensor 2 and a positive polarity sensor 3, a positive voltage maximum voltage isolation unit 4 and a positive voltage minimum voltage isolation unit 5, a negative voltage maximum voltage isolation unit 6, a negative voltage minimum voltage isolation unit 7, a differential amplifier 8, a reference voltage source 9, a first switching unit 10, a dividing diode block of negative polarity.

In addition, the device includes a block of isolation diodes of positive polarity, an input current sensor 13, an input current isolation unit 14, a resistor divider 15, a first isolation diode 16, a first potential setting variable resistor 17, nee contacts 18 and second contacts 19 of the relay 20, the second 21 and third 22 are diode isolators, the second potentially sets a variable resistor 23, the first and second 25 noise suppressing blocks, the fourth 26 is a separate diode, zener diode 27, the second switching unit 28.

The power source operates as follows. The voltage is applied to the terminals 29, 30 and the reference voltage source 9, while the differential amplifier 8 is set to the initial state in which the signal at its output is low and the first switching unit 10 has a high potential at the output, as a result of which the block 12 of the diode isolators is positive polarity is under reverse voltage.

The output of the second switching unit 28 at this time is low potential, and the block 11 of the dividing diodes of negative polarity is also under reverse voltage. (Potentials are applied to terminals 29 and 30, exceeding in absolute value all the output ratings of the monitored sources).

In controlled bipolar stabilizers 1 at the moment of switching on through power elements (transistors, diodes) (in the absence of limitation 736075), an inrush current appears that does not pass through the stabilizers due to the mismatch signal coming from the input current sensors. 13 to the input of the differential amplifier 5 for 8, puts the differential amplifier 8 and the switching units 10 and 28 into a state in which the signal at the output of these blocks decreases and with a strong mismatch becomes equal to 10 the potential of the common point of the circuit.

Locking of the transistors of protected sources takes place and, therefore, current is limited at the moment of switching on. Contacts 18 and 19 at the moment ^{5 of the} inclusion are open, so there is a current limitation without false operation of the protection device. Relay 20 is connected to the input of a stabilized power supply, switched on by the last ²⁰ in the protected group, or, taking into account the inertial relay, to the input of that source, the switching delay time of which, together with the switching time of the relay, ensures guaranteed establishment of output ratings, i.e. the feedback loop of the memory cell is not closed until * p, until all transient processes on inclusion are completed.

At the end of the moment of switching on, the relay 20 is activated, and its contacts 18 and 19 are closed, transferring the protection device from the limiting mode to the discrete operating mode.

In the discrete operating mode, when the presence ^{of 35} PIR any error signal (output care controlled parameters TU standards) supplied with current or voltage sensors through blocks vyde- Lenia maximum and minimum signals occurs memorizing and off nominal output protected sources. Thus, the protection device at the time of switching on works as a limiting device (currents and voltages that develop above the established norm at the time of switching on in the power elements of controlled sources are limited), and at the end of the switching on time as a discrete (disconnecting) protection device.

The specified mode of operation of the proposed protection device increases the reliability of the most controlled device and ₅₅ reduces the possibility of false positives protection at the time of inclusion.

In the process, the protection device is affected by various short-term interference, which can cause false alarms of the protection device. To eliminate this phenomenon, the signal at the input of the first switching unit 10 and the input of the differential amplifier 8 is fed through the suppressed blocks 24, 25, which allows you to configure the protection device to operate from a mismatch signal of a certain duration, which also eliminates the possibility of false positives and increases the reliability of protected sources and devices protection.

The use of a highly sensitive differential amplifier 8 in conjunction with potentially driving resistors 17 and 23, isolation diodes 21 and 22 to the inputs of the differential amplifier 8 allows to increase the temperature stability of the device. For any number of diodes in the circuits for extracting the maximum and minimum signals, the temperature drift of the voltage at the inputs of the differential amplifier 8 depends only on the temperature change in the leakage current of the isolation diodes 21 and 22. Due to the fact that the resistors 17 and 23 are the same and approximately the same at their midpoints potential (for presetting the differential amplifier 8 to the initial state, the potential at the first input of the differential amplifier 8 is several millivolts higher than at the second and during the determined differential amplifier sensitivity), temperature drift voltage at their middle points with respect to each other and at the nominal value is practically absent. The specified circuit solution can significantly increase the accuracy and temperature stability of the protection device and thereby increase its reliability and reduce the possibility of false alarms.

The use of two switching units allows the protection of stabilized sources of positive and negative polarity. The protected sources can be either linear or key (in the latter case, usually one switch 10 is enough).

The proposed device is protected allows to increase the reliability of the protected power sources, and therefore, the computer as a whole.

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When the proposed device is protected by reducing the number of failures and malfunctions, expensive machine time is saved.

The use of one device is wired to several sources, which reduces the cost of the protection device.

In addition, the reliability in operation and the reduction of false positives during the tuning process (manufacturing of the machine) can reduce the debug time of the computer.

Claims (2)

units for isolating maximum and minimum voltages of negative and positive polarity, differential amplifier, source of reference voltage, first switching unit, blocks of separation diodes of negative and positive polarity, outputs connected to the input terminals of constant voltage regulators, entered Input current sensors connected to the output terminals of the DC voltage regulators, which are connected to the input resistor through the input current separation units Tieliu vkod which via a first diode connected to the separating obe dinennrmu output unit vschepeni makeimalnrgo positive voltage p NOSTA floor and through a second diode raadelitelny - to the exit point of the first compound administered daeteyd alnozadayuteth); peremennog6 resistor to the first input differential amplifier. The combined output of the block is indicated by the minimum positive voltage across the normally open circuit; the first contacts are injected, connected to the input of one of the constant voltage regulators of the relay, and the third isolation diode are connected to the connection point of the output of the second variable setpoint resistor and the second input differential amplitude l. Moreover, the third divider diode is connected to the combined output of the maximum voltage generator of the opposite polarity, the anode of the second separated diode through the second contacts of the introduced turnip is connected to the combined output of the negative polarity selection voltage generator, and the inputs of the potential variables of the resistors are combined and connected to a reference voltage source. The output of the differential amplifier is through the inputted first interference suppressor unit, and the zener diode is connected to the input of the first switching unit, the output of which is connected to the combined input of the separation diode unit of positive polarity, to the output of the inputted second switching unit and through the second interference suppression unit and the fourth isolation diode - to the output of the block of the minimum voltage and the positive position, and the output of the second switching unit is connected to the unit bypass of the “negative” diodes; extraordinary brightness. The drawing shows a principal electrical power supply circuit of a constant direction, wired. The power source contains different-field stabilizers 1, a negative sensor 2 and a positive polarity sensor 3, an absolute polarization maximum voltage block 4 and a positive polarity minimum polarization voltage block 5, a negative polarity maximum voltage isolation unit 6, negative voltage minimum voltage isolation unit 7, differential voltage 8, reference voltage source 9, first switching unit, Yu, and separation diode units of negative polarity. In addition, the device includes a block of 12 positive polarity isolation diodes, an input current sensor 13, an input current separation unit 14, a resistor divider 15, a first separating diode 16, the first potentially setting variable resistor 17, the first contacts 18 and the second contacts 19 of relay 20, the second 21 and third 22 separation diodes, the second potentially setting variable resistor 23, the first 24 and second 25 interfering blocks, the fourth 26 split diode, the zener diode 27, the second switching unit 28. The power supply operates as follows brazom The voltage is applied to the terminals 29, ZO and the source 9 of the reference voltage, while the differential amplifier 8 is reset, at which the output signal has a low level and the first switching unit Yu has a high potential output, resulting in a block 12 positive polarity diodes are under reverse voltage. The output of the second switching unit 28 is low at this time, and the block 11 of the negative polarity separation diodes is also under reverse voltage (Potentials greater than all output ratings of the monitored sources are supplied to terminals 29 and 30). In counterhraidable opposite-sex pn1x stabilizers 1, at the moment of switching on through feedthrough power elements (transistors, diodes) (with no; 1 and 5736 ni), a current rush appears that does not pass through stiffers due to the fact that the error signal coming from the sensors input current. 13 to the input of the differential amplifier 8, converts the differential amplifier 8 and the switching units 1O and 28 to a state in which the signal to the output of these blocks decreases and, with a strong mismatch, becomes equal to the potential of the common point of the circuit. The passage of the protected sources through the protected sources occurs and, consequently, the current is limited at the moment of switching on Contacts 18 and 19 at the time of switching on, therefore, the current is limited without false triggering of the device. Relay 2O. Connects to the CSR input of a stabilized power source that is switched on after it in the protected group, or taking into account the inertial relay to the input of that source, the turn-on time of which, together with the turn-on time of the relay, ensures guaranteed output ratings, i.e. The uienb feedback of the memory cell does not close until all transitions have been completed for switching on. After the moment of switching on, the relay 20 is activated, and its contacts 18 and 19 are closed, transferring the protection device from the limiting mode to the discrete operating mode. In the discrete mode of operation, the presence of any error signal (output monitored output parameters per TU norms) input from current sensors or voltage through the maximum and minimum signal extraction units takes place and deactivates the output ratings of the protected sources. Thus, the protection device at the time of switching on as a limiting device (limits the currents and voltages developed above the established norm at the time of switching on monitored sources in power elements), and at the end of the switching on moment as a discrete (disconnecting) protection device. The specified mode of operation of the proposed protection device increases reliability. the monitored device itself reduces the possibility of false alarms are energized at the moment of switching on. In the course of operation, various short-duration interferences that can cause false positives of the device are affected by the protection device. To eliminate this phenomenon, the input signal of the first switching unit U and the input of the differential amplifier 8 is fed through the attenuated blocks 24, 25, which allow you to configure the device to be protected from a certain duration error signal, which also eliminates the possibility of false positives and increases the reliability of the protected sources. and protection devices. The use of a highly sensitive differential amplifier 8 in conjunction with potentially driving resistors 17 and 23, separation diodes 21 and 22 to the inputs of the differential amplifier 8 allows to increase the temperature stability of the device. With any number of diodes in the circuit for selecting the maximum and minimum signals, the temperature drift of the voltage at the inputs of the differential amplifier 8 depends only on the temperature change of the leakage current of the separation diodes 21 and 22. Due to the fact that the resistors 17 and 23 are the same at their midpoints approximately the same potential is set (for presetting the differential amplifier 8 b the initial state the potential at the first input of the differential amplifier 8 is a few millivolts higher than on the second m input and determined by a sensitivity of the differential amplifier), voltage temperature drift at their middle points with respect to each other and at the nominal value is practically absent. The specified circuit solution allows to significantly increase the accuracy and temperature stability of the protection device and thereby increase its reliability and reduce the possibility of false alarms. The use of two switching units protects the stabilized sources of positive and negative polarity. Protected sources can be both linear and key (in the latter case, one switch 10 is usually enough). The proposed protection device makes it possible to increase the reliability of the protected power sources, and, consequently, the computer as a whole. 7 By operating the proposed protection device, by reducing the number of failures and failures, expensive machine time is saved. The use of one protection device for several sources allows; - to reduce the cost of the device. In addition, reliability in operation and reduction of false positives in the process of tuning (manufacturing the machine) makes it possible to reduce the debugging time of the calculating machine. Claims of the Invention A DC power supply with protection that contains at least two different types of constant voltage regulators, the output terminals of which are connected to an output polarity sensor of negative and positive polarity, the outputs of which are connected to the inputs of the maximum and negative and positive polarity minimizers, differential amplifier, reference voltage source, first switching unit, negative separation diode blocks and field polarity, the outputs connected to the input of the DC voltage stabilizer, characterized in that, in order to ensure reliability and prevent false alarms, input current sensors connected to the output of the DC voltage regulator are inserted into it The input current splices are connected to an input resistor divider, the output of which through the first isolating diode is connected to the combined output of the maximum voltage suppressor unit polarity and through the second isolation diode - to the connection point of the output of the first potential-entered 1k; rumonium resistor to the first input aH4x}) f-pr-HUHajibHoro amplifier, the output of the positive polarity release voltage generator through the normally open contacts the input, connected to the input of one of the stabilizers of the constant voltage relay and the third isolation diode are connected to the connection point of the output of the second input of the potential setting pulse) O1X1 resi Operations and second input di (| a third amplifier diode is connected to the combined output of the negative voltage polarity isolation unit, the second separation diode anode through the second contacts, the input relay to the combined output of the negative polarity voltage, and potentially setting variables resistors are combined and connected to the source of the reference voltage, the output of the differential amplifier through the input of the first interference suppression unit and stabilized it is connected to the input of the first switching unit, the output of which is connected to the combined input of a dividing diode unit of positive polarity, to the INPUT of the inserted second switching unit and through the second noise suppressor unit and the fourth dividing diode to the output of the minimum polarity isolation unit the output of the second switching unit is connected to the combined input of the separation diode unit of negative polarity. Sources of information taken into account in the examination 1. USSR author's certificate number 457986, cl. G 05 F 1/58, 1979. 2. USSR author's certificate No. 546872, class, G 05 F 1/58, 23