SU1274051A1 - Device for switching telegraph signals with current overload protection - Google Patents

Abstract

The invention relates to electrical engineering and is intended for use in electronic telegraph devices. The purpose of the invention is the expansion of functionality. When the load current 7 exceeds the set value from the threshold block 11, the R input of the flip-flop 19 receives a signal 1. The flip-flop changes its state and from output 24 outputs a signal O to the elements 17 and 18. At both inputs 5 and 6 of the key block 4, signal 1, and the outputs 8 and 9 of this block have the same voltages close to zero. The current through the load 7 is interrupted, the output O of the block 11 again sets the signal O. However, the flip-flop 19 retains the zero state until the output 3 of the repeater 1 changes from 0 to 1. If the cause of the overload is eliminated by this moment Auto (Automatically recovers the normal switching mode of telegraph signals. 1 Il.

Description

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01 The invention relates to electrical engineering and is intended for use in electronic telegraph devices and radio stations having telegraph outputs. The purpose of the invention is to expand the functionality by automatically restoring the normal switching mode while eliminating the overload, enabling the device to be implemented in microminiature mode by reducing the values of consumption currents and power dissipation during a short circuit load, increasing reliability by eliminating the self oscillatory generation mode with a short circuit in load. The drawing shows a diagram of a device for switching telegraph signals with protection against current overloads. The device contains a control unit 1, made in the form of a logical repeater with direct 2 and inverse 3 outputs, a block of 4 keys with static first 5 and second 6 inputs serving for switching the polarity of the current in the load 7 connected between its first 8 and the second 9 outputs, and the protection unit 10, including the threshold unit 11, the power current-measuring terminals 12 and 13 included in the circuit between the positive power supply output 14 of the key 4 and the positive output of the source 15, the negative output of which is directly connected to the negative output 16 power block 4 keys. In block 10 of protection there are first 17 and second 18 elements of NAND and RS-flip-flop 19 with a direct static zero R input and a direct dynamic single S input connected with an inverted output 3 of a logical repeater (control unit) 1 and the first input 20 of the first element 17 NAND, direct output 2 of the logic follower 1 is connected to the first input. house 21 of the second element 18 AND-NOT. The second inputs 22 and 23, respectively, of the first 17 and second 18 elements are connected to the single output 24 of the RS flip-flop 19, the K-input of which is connected to the output 25 of the threshold unit 11, while the outputs 26 and 27 of the first 17 and second 18 elements AND-NOT are connected respectively, with the first 5 and the second 6 inputs of the 4 key block, made inverting. The device works in the following way. The impulses of the input information are fed to the input of the logical follower 1, converted by the elements 17 and 18 AND-NOT and are fed to the inputs 5 and 6 of the block 4 keys. The direction of the current in the load 7 depends on the logic state at the input of the logic follower 1. When operating in normal mode, the output of the trigger 19 contains a voltage of logic 1 (2.4-5 V), set on the leading edge of the signal from the inverter output 3 of the logic repeater 1, arriving at the dynamic S-input of the trigger 19. At the static K-input of the trigger 19 there is a voltage of logic O (0-0.4 B). When the load current 7 exceeds the set value from the threshold block 11, the R input of trigger 19 receives a signal 1. The trigger changes its state and output 24 sends an O signal to elements 17 and 18. Both inputs 5 and 6 of block 4 are set to signals 1, and at outputs 8 and 9 of this block - the same voltage close to zero. The current through the load 7 is interrupted. As a result, at the output 25 of the block 11, the signal O is set again, however, the trigger 19 retains the zero state until the inverter output 3 of the repeater 1 changes status from O to 1. The front of this signal affects the S input of the trigger 19, transfers it to state 1 at output 24. If the cause of the overload has been eliminated by this time, the normal switching mode of the telegraph signals is automatically restored. Otherwise, an increase in the current again leads to the interruption of the load current, as described above. A positive effect, created by the invention, is to expand the functionality of the device, since it automatically restores the normal switching mode of the telegraph signals after the overload has been removed. In addition, the self-oscillation mode of generation at a fixed state of the signal at the input

device arising in the device prototype with a short circuit load. The exclusion of such a mode leads to a decrease in the magnitudes of the current consumption and power dissipation, which makes it possible to implement the device in microminiatx performance and increases its reliability.

Claims (1)

Invention Formula A device for switching telegraph signals with current overload protection, comprising a control unit made in the form of a logic repeater with direct and inverse outputs, a block of keys with static first and second inputs serving for switching the polarity of the current in the load connected between its first and the second outputs, and the protection unit, including the threshold unit, with the power current-measuring outputs connected in the circuit between the positive power supply terminal of the key unit and the positive output source, negative output which is directly connected to the negative power supply of the key block, characterized in that, in order to expand the functionality by automatically restoring the normal switching mode while eliminating the overload, enable the device to be implemented in a miniature design by reducing the values of current consumption and power dissipation during a short circuit load and increase reliability by eliminating the self-oscillatory generation mode with short-circuit, in block 3 The boards additionally introduced the first and second elements NAND and RS trigger with a direct static zero R input and a direct dynamic single S input connected to the inverse output of the lot repeater and to the first input of the first NAND element, direct output the logical follower is connected to the first input of the second NAND element, and the second inputs of the first and second NAND elements are connected to the single output of the RS flip-flop, the R input of which is connected to the output of the threshold unit, while the outputs of the first and second I elements - NOT connected respectively to the first and second inputs of the key block, made inverting.