SU976496A2 - Threshold regenerative device - Google Patents

Description

one

The invention relates to a pulse technique and can be used in sensitive threshold regenerative devices designed for long-term operation, for example, in automated control and management systems (ACMS).

According to the main author. St. No. 869О1О a threshold regenerative device is known, containing an amplifying element, a positive feedback circuit consisting of a switching element and serially connected communication element, an offset source and a control voltage source, which is connected between the output of the coupling element and the input of the switching element of the positive feedback circuit, and one of the outputs of the integrating element is connected to the input of the amplifying element, the input of which is connected to the input of the Communication element 1.

A disadvantage of the known device is low reliability.

The purpose of the invention is to increase the reliability of the device.

The goal is achieved by the fact that a second channel is introduced into the threshold device, and the second commuting signal is additionally introduced into each channel.

10 an element connected between the input of the perhvc switching element of its channel and the output of the first switching element of another channel and the input terminal, and the output of the first communication element 15 of each channel is connected to the second input of the integrated element of another channel, the second communication element connected between the output of the amplifying element and the input of the inputted registration element 20, one of the input p: is costly connected to the second communication element of the other channel, and the output is connected to the output terminal. The drawing shows a block diagram of a threshold regenerative device. The threshold regenerative device 1 contains two channels of diode regenerator 2 with amplifying elements 3 with an open input, feedback circuits 4, control voltage sources 5, displacement sources 6, communication elements 7, integration elements 8, combining nonlinear elements 9, the second communication elements 10, the registering elements 11, the input terminals of the 1st input 12 and 13, the input terminals of the 2nd input 14 and 15, the output terminals 16 and 17. The device works as follows. The trigger signal in the case of serviceable communication lines goes to the inputs of the amplifying elements 3 of both diode regenerators, either through the terminals of the 1st input 12 and 13, or through the terminals of the 2nd input 14 and 15. The signal is amplified by the amplifying elements 3 with the open input and from their first, the outputs are fed to the inputs of both elements. 7 communications (e.g., pulse transformers). From the first code (for example, through the winding of the pulse transformer of each element 7 of the communication, it sends a signal to the first input of the element 8 of the controlled integration (implemented, for example, on the R C elements) in the feedback circuit 4 of its diode regenerator 2. Simultaneously with the second The output of each element 7 of the link gives the signal from the second input of the element 8 summation and controlled integration in the feedback circuit 4 of another diode regenerator 2. Here the smoothing of pulsations of random parasitic fluctuations occurs, for example This is caused by the possibility of short-term noise from the signal circuits and power supply voltage additives by selecting the optimal value of the positive feedback circuit 4 frequency band. The resultant signal from the output of each of the adjustable integration elements 8 knocking on the inputs of two commuting nonlinear elements 9 (for example, diodes), using one of them, the output of which is connected to the input of the amplifying element 3 of its diode regenerator 2, 4 is an open circuit a positive feedback in dshshom regenerator 2; using the second transmission of the resulting signal to the input of the amplifying element 3 of another diode regenerator 2. If the resultant signal at the output of any element 8 is the controlled integration of the total voltage of the source 5 of the control voltage and the bias source 6, the switching nonlinear elements 9 of this regenerator 2 transition to the conducting state, its positive feedback circuit 4 closes, the regenerative process takes place and at the second output of the corresponding amplifying electric At the time of the terminal 3, the necessary (in magnitude and duration) for the recording element 11 is produced a pulse, which also returns to the initial state (by reset) the element 8 of the controlled {Integration. From the second output of each amplifying element 3, the shchshulsny signal is fed to the input of its communication element 10 (realized, for example, with the help of two storage capacitors). From the first code of each communication element Yu, the signal is fed to the burglar input of its recording element 11 (for example, a relay winding), and from the second output of each communication element 1O to the second input of the recording element 11 of another regenerator 2. The recording elements 11 of both regenerators 2 can They are implemented in a redundancy scheme, the output signals from which are fed to the output terminals 16 and 17. Thus, the proposed threshold regenerative device, which compares favorably with the known, is characterized by stability ( and bezoschibochnostyu) operation, i.e. possesses high reliability. An introduction to the schematic solution of the found combination of various types of redundancy (structural, informational, automatic restoration of working capacity) makes it possible to virtually eliminate the most dangerous errors of the first type (log non-sabotage) for many possible cases of element violations: disruptions and links between them ( lines and elements of communication, failure of the element of summation and controlled integration, switching of the linear element, loss of the amplifying properties of the amplifying element, etc.). Experimentally (by imitation of a violation), it was shown that the proposed technical solution possesses greater stability not only in comparison with the known, but also in comparison with the threshold regenerative device with simple structural redundancy (for example, with two permanent backup channels).

Increased noise immunity of the device's circuit solution both in supply circuits (the possibility of increasing the degree of filtering due to small, up to the tenth fractions of a milliampere, power consumption of diode regenerators with autonomous, powered by a storage battery; using elements of controlled integration in feedback circuits) and ON signal circuits (localization of the conversion process in diode regenerators, use of elements of controlled integration in feedback circuits, reduction of the initial minds voltage on the commutating nonlinear elements) allows virtually eliminate oshib1sh vtorogche form (false srabatshani) and coxpiaHHib INSTALLS, tainable operation of the device under conditions of action drawdowns supply voltage, and electrical noise.

The use of the proposed threshold regenerative device with high stability of work for long-term (or responsible) monitoring and measurement, for example, in the ASCS equipment, respectively, reduces both the customer's risk and the manufacturer's risk.

The proposed threshold regenerative device harstersnosis also

high sensitivity to pulse triggers and signals, a stable threshold level, the ability to flexibly adjust the device sensitivity over a wide range not only to the intensity of a pulse signal, but also to its duration on two channels of the device.

Purchasing formula

Threshold regenerative device auth. St. No. 86901O, characterized in that, in order to increase the reliability of the device, a second channel is introduced into it, and a second switching element is additionally inserted into each channel, connected between the input of the first switching element of its own channel and the output of the other switching element of the other channel, and the input terminal, and the output of the first communication element of each channel is connected to the second input of the integration element of the DRU1X1GO channel, the second communication element connected between the output of the amplifying element and the input of the entered A generating element, one of the inputs of which is connected to the second communication element of another channel, and the output is connected to the output terminal.

Sources of information taken into account during the examination 1. Copyright TSH P i№ 869010, clGn 03 K 5/24, 08.28.79.

Claims (1)

Claim Threshold regenerative device according to ed. St. No. S69010, characterized in that, in order to increase ^: reliability of the device, a second channel is introduced into it, and a second ”switching element included between the input of the first switching element of its channel and the output of the first switching element of the other _ channel is added to each channel , and an input terminal, and the output of the first communication element of each channel is connected to the second input of the integration element of another channel, the second communication element connected between the output of the amplifier element and the input of the input register element, one of the inputs of which is connected to the second communication element of another channel, and the output is connected to the output terminal.