RU2009612C1 - Logic element - Google Patents

Abstract

FIELD: pulse engineering. SUBSTANCE: device has two diode bridges 1, 28, three units of galvanic de-coupling 5, 18 and 31, three transistors 14, 16 and 25, two capacitors 4, 21, diode 6, polarity transformer 7, de-coupling circuit 13, seven resistors 17, 22, 24, 26, 27, 29 and 32, threshold member 30, master oscillator 11, starting circuit 19. EFFECT: improved reliability o operation. 1 dwg

Description

 The invention relates to a pulse technique and can be used in various automation systems, for example, in railway transport.

 A logical element is known that contains an output rectifier, a diode bridge, the first diagonal of which is connected to the first and second information input of the logic element, and is included in the second diagonal in series with the input element of the galvanic isolation node, the collector-emitter junction of the transistor, the output element of the galvanic isolation node is connected to the input of the amplifier [1].

 The disadvantage of this known device is its lack of reliability with defects in the electrical circuit.

 The closest technical solution to the proposed invention is a logic element containing a diode bridge connected by an diagonal of alternating current with the first and second information inputs, a first capacitor, a first galvanic isolation unit on an optocoupler, a diode, a polarity converter, based on series-connected first and second diodes the connection point of which is connected to the first terminal of the capacitor, the first capacitor being connected at one end to the anode of the diode, the master oscillator is connected connected through the first decoupling resistor to the base of the first transistor, which is connected through the second decoupling resistor to the second input of the decoupling circuit, the second transistor whose base through the base resistor is connected to its emitter and the negative input of the diode bridge, and through the output circuit of the second galvanic isolation node the positive output of the diode bridge, the trigger circuit, the input of which is the trigger input of the device, and the output is connected to one terminal of the second capacitor and one terminal of the first resistor, The second output of the second capacitor is connected to the common bus of the first and second information inputs [2].

 The disadvantages of this device are the appearance of a false output signal when the amplifier is excited; when leaks occur in the galvanic isolation node at the optocoupler, at the input of the amplifier and a change in the threshold properties of the latter; lack of protection against a false signal at the first and second information inputs; insufficiency of the threshold stable signal at the first and second information inputs due to the voltage drop across the collector-emitter transistor circuit and the input of the galvanic isolation node in the capacitor in the feedback circuit of the logic element, which leads to the accumulation of defects.

 The aim of the invention is to increase reliability.

 This goal is achieved by the fact that in order to increase reliability, a collector resistor of the first transistor, an additional transistor with a base and collector resistors are inserted into it, the connection point of which is connected to the plus output of the additional diode bridge, the collector resistor of the second transistor, the second output of which is connected to the positive output a diode bridge, as well as a second capacitor, a threshold element, the first terminal of which is connected to a common bus and emitter of the first transistor, and the second terminal after the input element of the additional galvanic isolation node on the optocoupler and the input elements of the first and second galvanic isolation nodes on the optocouplers are connected to the second output of the collector resistor of the first transistor and the second output of the first resistor, the second input of the isolation circuit is connected to the common point of the additional galvanic isolation on the optocoupler threshold element, the output element of the additional galvanic isolation node on the optocoupler is the output of the device, and the output element is first about the galvanic isolation node on the optocoupler is connected to the base-emitter circuit of the additional transistor, the emitter of which is connected to the negative output of the additional diode bridge and the cathode of the diode, the anode of which is connected to the cathode of the second polarity converter diode, the second terminal of the polarity converter capacitor is connected to the collector of the additional transistor, the first the output of the first capacitor is connected to the anode of the diode, the second output of the first capacitor is connected to the collector of the second transistor, the negative outputs of the diode x bridges and their diagonals AC united, and an output circuit run connected to the first terminal and the second capacitor via the second resistor - to the anode of the first diode polarity inverter, a second terminal of the second capacitor is connected to the common bus.

 The drawing shows a schematic diagram of a logical element.

 The logic element contains a diode bridge 1 connected by an diagonal of alternating current with the first 2 and second 3 information inputs, the first capacitor 4, the first node 5 of the galvanic isolation on the optocoupler, the diode 6, the polarity converter 7, made on the basis of series-connected first 8 and second 9 diodes, the connection point of which is connected to the first output of the capacitor 10, and the first output of the capacitor 4 is connected at one end to the anode of the diode 6, the master oscillator 11 connected through the first resistor 12 of the decoupling circuit 13 from the bases the first transistor 14, which through the second resistor 15 of the isolation circuit 13 is connected to the second input of the isolation circuit 13, the second transistor 16, the base of which through the base resistor 17, is connected to its emitter and the negative input of the diode bridge 1, and through the output element of the second galvanic unit decoupling 18 with the positive output of the diode bridge, the start circuit 19, the input of which is the input 20 of the start device, and the output is connected to the first output of the second capacitor 21 and the first output of the first resistor 22 and the second output is condensate and 21 is connected to a common bus 23 of the first 2 and second 3 information inputs, a collector resistor 24 of the first transistor 14, an additional transistor 25 with a base 26 and collector 27 resistors, the connection point of which is connected to the plus output of the additional diode bridge 28, the collector resistor 29 of the second transistor 16, the second terminal of which is connected to the positive output of the first diode bridge 1, as well as a threshold element 30 connected at one end to a common bus 23 and the emitter of the first transistor 14, and the second terminal through a follower about the connected input element of the additional node 31 of the galvanic isolation on the optocoupler and the input elements of the first 5 and second 18 nodes of the galvanic isolation on the optocouplers with the second output of the collector resistor 24 of the first transistor 14 and the second output of the first resistor 22, and the second input of the isolation circuit 13 is connected to a common point additional node isolated on the optocoupler 31 and the threshold element 30, and the output element of the additional node 31 galvanic isolation is the output of the device, and the output element 5 The galvanic isolation on the optocoupler is connected to the base-emitter circuit of the additional transistor 25, the emitter of which is connected to the negative output of the additional diode bridge 28 and the cathode of the diode 6, the anode of which is connected to the cathode of the second diode 9 of the polarity converter 7, the second terminal of the capacitor 10 of the polarity converter 7 connected to the collector of the additional transistor 25, and the second output of the first capacitor 4 is connected to the collector of the second transistor 16, while the negative outputs and their diagonals of alternating current 1 and 28 about connected, in addition, the output of the trigger circuit 19 is connected through a second resistor 32 to the anode of the first diode 8 of the polarity converter 7.

 The device operates as follows.

 Input information signals arrive synchronously and out of phase to the information inputs 2 and 3 relative to the common bus 23 of the source (power is not shown in the diagram). During their antiphase operation, there are signals on the diagonals of the alternating current of the diode bridges 1 and 28 that provide constant voltage on the diagonals of the direct current of the same bridges to provide power to the corresponding amplification stages performed on the second 16 and additional 25 transistors with the corresponding collector resistors 29 and 27. The cascades are controlled through the first and second nodes of the galvanic isolation on the optocouplers 5 and 18. The second galvanic isolation node on the optocoupler 18 provides the opening of the second 16 transistor (closure is provided by resistor 17), and the first galvanic isolation node on optocoupler 5 provides the opening and shutting down of additional transistor 25 (opening is provided by base resistor 26).

 Consider the operation of the circuit from the moment the signal is fed through the start input of the device 20 to the start circuit 19, and a negative potential appears on its output and, accordingly, on the capacitance of the second capacitor 21, which, through the first resistor 22, enters the power circuit of the first transistor stage 14 with collector resistor 24 and the second resistor 15 of the decoupling circuit 13, which is made according to the scheme with a common emitter, as a saturated key, the locking of which is ensured by a dynamic positive signal of the master oscillator 11 through the first the decoupling resistor 12 of the decoupling circuit 13. The common point of the second resistor 22 and collector resistor 24 of the first transistor 14 is at the same time the power supply circuit of the input circuits of the first 5, second 18 and an additional 31 nodes of the galvanic isolation on the optocouplers and threshold element 30, while if at this point negative voltage is greater than the threshold threshold element 30 and the direct voltage summarized with it at the inputs of the second 18, first 1 and additional 31 nodes of the galvanic isolation on the optocouplers, then the current flows through this circuit respectively, the opening of the second transistor 16, closing the additional transistor 25 and the signal at the output of the galvanic isolation node on the optocoupler, the condition for this is to close the first transistor 14, if the latter opens, then the divider on the first resistor 22 and collector resistor 24 of the first transistor 14 provides at the connection point of these resistors, the level of negative voltage is less than the required threshold threshold element 30 and, accordingly, the closure of the output circuits of the second 18, the first 5 and an additional 31 nodes gal vanicheskoy interchange at optocouplers. Thus, the variable position of the signal from the master oscillator 11 in the presence of a negative charge on the capacitance of the second capacitor 21 provides a periodic shutdown of the second 16 and an additional 25 transistors, as well as a dynamic output signal at the output of the additional galvanic isolation unit 31 at the optocoupler. This mode of operation of the first 16 and an additional 25 transistors ensures their antiphase operation and the charge of the first capacitor 4 through the diode 6 and the collector resistor 29 of the second transistor 16 to the voltage at the output of the diagonal of the direct current of the diode bridge 1, the capacitor 10 of the polarity converter 7 is charged through the collector resistor 27 additional transistor 25 with one pole of the DC potential at the output of the additional diode bridge 28, and through the second diode 9 of the polarity converter 7 to a negative potential and accumulated on the first capacitor 4. Thus, the capacitor 10 of the polarity converter 7 during the antiphase operation of the second 16 and an additional 25 transistors provides a voltage multiplication (approximately 1.6 times), which is supplied through the first diode 8 of the polarity converter 7 and the second resistor 32 to the second capacitor 21, in this case, the initial supply through the start circuit 19 of a negative potential ensures the passage of the dynamic signal from the master oscillator 11 through the transistor stages of the second 16 and additional ADDITIONAL transistors 25 and polarity inverter circuit 7 for feeding the second capacitor 21 after removal of the negative trigger signal it provides normal operation of the circuit.

 If there is a discrepancy in the antiphase signal at the first 2 and second 3 information inputs, at the outputs of the diode bridges 1 and 28, the voltage of the cascades of the second 16 and an additional 25 transistors disappears by the magnitude of this mismatch, which accordingly does not provide a charge for the capacitor 10 of the polarity converter 7 and the first capacitor 4 recharging of the second capacitor 21, which is discharged through the first resistor 22 and the collector resistor 24 of the first transistor 14, thereby blocking the entire device in the off state and before the arrival of a new start signal.

 False generation of the first 16 and additional 25 transistors or generation in the first 2 and second 3 information inputs does not provide optimal charge modes for the capacitor 10 of the polarity converter 7 of the first capacitor 4 and, accordingly, the level at the second capacitor 21 is insufficient for normal operation of the device, i.e., less than threshold properties set by the serial circuit of the first 5, second 18 and additional nodes of the galvanic isolation on the optocoupler, thereby eliminating the false output signal with these defects.

 Failures of the threshold element 30 lead either to the permanent opening of the first 5 and second 18 nodes of the galvanic isolation on the optocouplers, or to their constant closure, which excludes the dynamic operation of the second 16 and additional 25 transistors, recharging of the second capacitor 21 and is recorded as a device failure. Defects of similar circuit elements lead to a similar result, because either the dynamic mode of operation of the element circuit is not provided, or the optimal charge mode of the first capacitor 4 and the capacitor 10 of the polarity converter 7 is not ensured, and the corresponding level to the second capacitor 21, all of these defects lead to the absence of dynamic the output signal at the output of the additional node 31 galvanic isolation on the optocoupler (device output). Thus, a dynamic output signal at this output is possible only with synchronous antiphase signals at the first 2 and second 3 information inputs and the serviceability of all circuit elements, which ensures the high reliability of the device and the possibility of its use in domestic systems for ensuring the safety of train traffic in railway transport . (56) 1. Japan Application N 57-224, cl. H 03 K 9/14, 1976.

 2. USSR author's certificate N 1236605, cl. H 03 K 19/14, 1984.

Claims (1)

 LOGIC ELEMENT, containing a diode bridge, which is connected by a diagonal of an alternating current to the first and second information inputs, a first capacitor, a first galvanic isolation unit on an optocoupler, a diode, a polarity converter made on the first and second diodes connected in series, the connection point of which is connected to the first output a capacitor defining a generator whose output is connected to the first input of the decoupling circuit, the output of which is connected to the base of the first transistor, the output of the decoupling circuit is connected to their first and second inputs, respectively, through the first and second decoupling resistors, the second transistor, the base of which is connected through its base resistor to its emitter and the minus output of the diode bridge, and through the output element of the second galvanic isolation node, to the plus output of the diode bridge, the start circuit, the input of which is the launch input of the device, and the output is connected to the first output of the first resistor, characterized in that, in order to increase the reliability of operation, a second capacitor is introduced into it, a collector cut the source of the first transistor, an additional transistor with base and collector resistors, the connection point of which is connected to the positive output of the additional diode bridge, the collector resistor of the second transistor, the second terminal of which is connected to the positive output of the diode bridge, and a threshold element, the first output of which is connected to the common bus and the emitter of the first transistor, and the second output through a series-connected input element of an additional galvanic isolation node on the optocoupler and the input elements of the trans of the second and second nodes of the optocoupler isolation - with the second output of the collector resistor of the first transistor and the second output of the first resistor, the second input of the isolation circuit is connected to the common point of the additional galvanic isolation node on the optocoupler and the threshold element, the output element of the additional galvanic isolation node on the optocoupler is an output devices, and the output element of the first galvanic isolation node at the optocoupler is connected to the base-emitter circuit of an additional transistor, the emitter of which connected to the negative output of the additional diode bridge and the cathode of the diode, the anode of which is connected to the cathode of the second diode of the polarity converter, the second terminal of the capacitor of the polarity converter is connected to the collector of the additional transistor, the first terminal of the first capacitor is connected to the anode of the diode, the second terminal of the first capacitor is connected to the collector of the second transistor , the negative outputs of the diode bridges and their diagonal AC are combined, and the output of the trigger circuit is connected to the first output of the second capacitor and through the second resistor - to the anode of the first diode polarity inverter, a second terminal of the second capacitor is connected to the common bus.