SU957120A1 - Indicator of voltage at power supply buses - Google Patents

Description

one

The invention relates to electrical measuring equipment and is intended for use in constant voltage sources.

A voltage detector between electric circuits is known, containing polarized relays with two windings, a diode connected to the capacitor charge circuit through the first relay coil, a thyristor switching element installed in the capacitor discharge circuit to the second relay coil and connected to the control electrode to the bus power supply with locking polarity directly, and to one of the capacitor plates through a resistor l.

The disadvantage of this device is due to the fact that it cannot operate at 20 smoothly increasing controlled voltages. The inability to turn on a polarized relay in this case is due to the low level of charge

capacitor current, i.e. the current through the first winding of the relay.

The closest technical solution to the proposed one is a voltage detector on the power supply buses. containing a polarized relay with two windings, included in the capacitor charge circuit through the first winding of the relay diode and thyristor, shunted by the contact pair of the relay, threshold element with which the control electrode of the thyristor is connected to the power supply bus with unlocking polarity, the thyristor switching element , installed in the capacitor discharge circuit to the second relay winding and connected by a control electrode to the power supply bus with locking polarity directly, and to one of the capacitor plates through a resis torus 2.

Claims (2)

A disadvantage of the known device is that the contacting of the contact group is shorting. The thyristor is not stable because its current has a very small value, equal to the leakage current of the capacitor. Possible contact disturbances cause interruptions in the normal functioning of the device as a whole. In addition, the two-contact relay used in the device has the worst performance — lower reliability and less winding resistance, which requires more energy to switch such a relay. This, in turn, entails the need to increase the capacitor capacitance and its size, which degrades the weight and dimensional characteristics of the known detector. The aim of the invention is to improve the reliability of such. devices by eliminating the need to use a separate contact group for a relay in the alarm circuit. The goal is achieved by the fact that the voltage signaling device on the power supply buses contains a polarized relay with two windings, a diode and a thyristor connected to the charge circuit of the capacitor through the first winding switch, a switching element installed in the capacitor discharge circuit to the second winding of the relay and supplied with a resistor in the control circuit, the threshold element, both windings of the polarized relay are connected to each other by the same terminals and shunted by additionally introduced diodes connected in the reverse directions of the switches The main element of which is connected to the point of connection of the capacitor to the charge diode, and the base through the additionally introduced displacement resistor to the collector and one of the power lines connected to the free output of the second winding of the relay, the thyristor is implemented in an optocoupler with an LED and placed between the other the power bus and the connection point of the charge diode, the bias resistor and the resistor in the basic control circuit of the transistor, and the threshold element is included in the current circuit of the LED, laid between the power buses. The drawing shows a circuit diagram of the proposed voltage detector on the power buses. 04 The device contains a polarized relay 1 with windings 2, 3 and contacts k, charging diode 5, auxiliary diodes 6, 7, capacitor 8, diode-thyristor optocoupler 9, in the current circuit of the LED of which a threshold element 10 with a zener diode 11 and a resistor is connected 12, a switching element 13 made on a transistor 1 with a resistor 15 in the base circuit and a bias resistor 1b. The diagram also indicates the power buses 17 and 18 on which the voltage is monitored. The device works as follows. At the time of triggering of the threshold element 10, during which the breakdown of its Zener diode 11 occurs, the thyristor 9 of the optocoupler is illuminated by f the counting of the current, the LED of this optocoupler and the diode 5 along the circuit of the capacitor B - winding 2 - diode 7 a charge current of the capacitor 8 appears which causes switching of the polarized relay 1 (the current through the winding 3 does not pass because it is shunted by diode 7) Contacts C of relay 1 result in a position opposite to that indicated on the diagram. After charging the capacitor 8, the current through the thyristor does not stop but is maintained at a level greater than the switching current due to the current through the bias resistor 16 (with an appropriate choice of its nominal value). The capacitor 8 is under voltage all the time when the voltage on the power supply buses 17 and 18 is present, without breaking due to its leakage current. The switching element 13 at this stage of operation of the detector does not work, because when the capacitor 8 is charged, a voltage drop across the diode 5 is applied to the base-emitter transition of the transistor 14 through the resistor 15. At the end of the charge of the capacitor 8, the diode 5 plays the role of a negative feedback element for the transistor 14 (the internal resistance of the diode operating in the low-current mode increases significantly), with the result that there is no current in the transistor in this case either. If the controlled voltage on the power supply buses 17 and 18 is turned off, then the thyristor 9 of the optocoupler is turned off, and the capacitor 8, charged to a voltage level that previously had 5 at the output of the signalizer, opens the transistor 1, introducing it into saturation due to the current through the base-emitter a junction passing through resistors 15 and 16, winding 3 and diode 6. Transistor 14, being saturated, forms a discharge circuit of capacitor 8 to winding 3 through its collector junction (diode 6 is still in the ET9Y circuit, and diode 7 Do not interfere with the current through the winding 3, since the polarity it is turned on opposite to the direction of the current). As a result, a surge in voltage is generated on the winding 3, which leads to the reverse switching of relay 1 (its contacts take the initial position shown in the diagram). The described cycle of operation is repeated when the voltage is subsequently applied to the power lines 17 and 18. The state of the contacts thus indicates to the consumer the presence or vice versa, the absence of a controlled voltage. The resistor 15 in the control circuit of transistor 1 + may be absent) if, when calculating the circuit, it turns out that the holding current of the thyristor 9 of the optocoupler in the on state and the base current of the transistor, which brings it to saturation, have similar values. If, under the conditions of operation of a monitored power source, its voltage does not increase smoothly, but appears abruptly, then the optocoupler 9 and the threshold element 10 can also be removed from the device. In this case, power bus 17 should be connected directly to diode 5 and resistor 16. The proposed voltage detector favorably differs from the known ones in that it does not need a polarized relay in the special contact group to ensure its operation. only in the output circuit connected directly to the consumer. Maintaining the capacitor 8 of the detector in a charged state (and storing, thus, the energy sufficient to switch the polarized relay 1 when the input voltage disappears) is guaranteed to be switched on by the optocoupler 9 for the entire time the input voltage is applied through the resistor 1b. The possibility of using a conventional polarized relay with one 0 (contact group increases the reliability of the detector, does not require an increase in the capacitance (and, hence, dimensions) of the capacitor. Use as a thyristor in the charging circuit of the capacitor 8 of the thyristor optocoupler 9 whose LED is connected to the threshold element 10, makes it possible to use any threshold element without having any difficulty in associating it with the thyristor control input (with an LED). Possibility of simplifying the circuit of the detector with p The bot from the sharply applied voltage on the power supply tires 17 and 18 by eliminating only two of its elements without changing the rest of the circuit creates additional advantages, since the immutable part of the circuit can be implemented as a separate structurally complete module suitable for independent use, and in combination with a thyristor optocoupler and a threshold element. Invention formula A voltage detector on power buses, containing a polarized two-winding relay, a diode and a thyristor, are included e into the capacitor charge circuit through the first relay coil, a switching element installed in the capacitor discharge circuit to the second relay coil and equipped with a resistor in the control circuit, a threshold element, characterized in that, in order to increase the reliability of operation, both windings are polarized relays connected to each other by the same leads and shunted by additionally inserted diodes connected in reverse directions, the switching element is made on a transistor, the emitter of which is connected to the connection point of the condensate A thyristor is implemented in an optocoupler with an LED and is located between the other power supply bus and the connection point of the charging diode , a bias resistor and a resistor in the basic control circuit of the transistor, and the threshold element is included in the LED current circuit ,. Laid between the power tires. Sources of information taken into account in the examination5. USSR Author's Certificate No., G, G 01 R 19/16, 1970. 2. USSR author's certificate number 382013, cl. G 01 R 19/16, 1971. ffu / JfO