RU186642U1 - Discrete signal input device with open circuit diagnostics - Google Patents

Abstract

A discrete signal input device comprising a microprocessor element, a source of stabilized supply voltage of a microprocessor element, a data receiving / transmitting unit with galvanic isolation and discrete signal input channels, the input circuits of which contain an input resistor, a zener diode and an input of an optocoupler isolation element in series, while for galvanic connected controlled signals, the input circuits are combined into groups with a common wire, to which, through a zener diode, connected counterclockwise from communicating with the zener diodes of the input circuits, the output of the microprocessor-controlled element of the pole switching node of the power source of the controlled signals is connected, and the outputs of the optocoupler isolation elements are connected to the microprocessor element, preferably by the principle of multiplex group polling, characterized in that the device for each group of input signals additionally contains second microprocessor-controlled element switching nodes of the poles of the power source of the controlled signals to the outputs of which Connect additional resistors, second terminals connected to the input channels of the group. The technical result is the ability to diagnose the health of the input elements of the device channels without a load in a controlled circuit, as well as a break in installation to the point of connection to a controlled circuit in the presence of load and breaks in the load itself.

Description

The device relates to measuring equipment and is intended for use in control devices for AC and DC signals in automated control systems, diagnostics and process control.

The well-known complex IVK-ADK - “A complex of hardware and software for automating the diagnosis and control of devices and process control” (utility model patent RU No. 61438, G05B 15/00, G05B 19/4063, B61L 27/04, published 02.27.2007 ), while the complex includes a functional module for inputting discrete signals, the MDV contains a microprocessor element designed for preliminary processing of information about the input discrete signals and synchronous exchange of information with a remote communication hub through circuits with g elements isolation, the voltage stabilization element of the microprocessor element and the input channels of discrete DC voltage signals, the input circuits of which contain a resistor, a diode and a zener diode in series, designed to cut off interference, as well as an optocoupler isolation element, while the input circuits are combined into groups to reduce the number of common wires, and the outputs of the optocoupler isolation elements are interrogated by the microprocessor element in a matrix way to reduce the necessary about the number of its input / output lines.

The complex also contains a functional module for inputting discrete signals of alternating current MDV1, which differs from the module MDV in that in the input circuits of the channels for inputting discrete signals, the diode is replaced by a second zener diode connected in opposition to the first.

The well-known complex IVK-TDM - "The complex of software and hardware for automating the diagnosis and monitoring of devices and process control" (utility model patent RU No. 68723, G05B 15/00, G05B 19/4063, B61L 27/04, published 11.27.2007 ), which includes functional micromodules for inputting discrete signals of MMD containing a microprocessor element designed for preliminary processing of information about input discrete signals (including determining the duration and codes of pulse and encoded signals) and synchronously the first exchange of information with the control module of the information concentrator through elements of communication circuits, and input channels of discrete signals, the input circuits of which contain a series-connected resistor, diode, zener diode, designed to cut off interference, and an element of galvanic optocoupler isolation.

The disadvantages of these analogs is that the indicated functional modules for inputting discrete signals cannot diagnose malfunctions that occur in the channel, such as a broken circuit or load of the monitored circuit, as well as a malfunction of the elements of the channel itself.

It is also known “Input device for discrete DC and AC signals with diagnostics of open circuit or load of a controlled circuit” (utility model patent RU No. 159354, G05B 15/00, G05B 19/00, published 02/10/2016), containing a microprocessor element, a source stabilized supply voltage of a microprocessor element, a data receiving / transmitting unit with galvanic isolation and discrete signal input channels, in which, in order to diagnose malfunctions arising in the channel elements, as well as an open circuit or narrow controlled chains introduced second additional channels that control inputs relative to the second pole of the power source signal.

The disadvantage of this device is the doubled number of input circuit elements and the need to use zener diodes with a stabilization voltage of more than half the voltage of the input signal power source.

The closest analogue (prototype) is a "Discrete signal input device with diagnostics of operability of input circuits" (application for utility model RU No. 2016143320, G05B 15/00, G05B 19/00, announced 02.11.2016), containing a microprocessor element, a stabilized voltage source power supply of the microprocessor element, a data receiving / transmitting unit with galvanic isolation and input channels of discrete signals, the input circuits of which contain an input resistor, a zener diode and an input of an optocoupler isolation element in series, while I galvanically coupled monitored signals, the input circuits are combined into groups with a common wire, and the outputs of the optocoupler isolation elements are connected to the microprocessor element, preferably according to the principle of multiplex group interrogation, in this case, in order to diagnose malfunctions arising in the channel elements, as well as interruption of the installation or load of the monitored circuits, for each group of input signals, the device further comprises a microprocessor-controlled element for switching the poles of the pit source niya of controlled signals, the output of which is connected to the common wire of the group through a zener diode, which is turned on counter to the zener diodes of the input circuits.

The disadvantage of this device is the ability to diagnose malfunctions that occur in the channel elements, as well as a break in the installation or load of the controlled circuits only when connected to circuits having a load (two-pole signal), but does not have this ability when connected to a make (disconnect) contact through which only one of the poles of the power source. Such signals are often found in the control of railway automation devices in which relays are used (so far irreplaceable relays of the first (highest) reliability class). This problem could be solved by installing resistors imitating the load in the device and diagnosing the health of only the input circuit elements of the device itself, but at the same time it will lose the ability to control the open circuit to the connection point (including loss of contact in the device connector and open circuit in the controlled circuit ) The problem is solved by creating two types of modules on the basis of this device: with additional resistors - for monitoring single-pole signals and without additional resistors - for controlling two-pole signals (signals with a load in the circuit), but this complicates the design and requires binding of the signal type to the type of module.

The aim of the proposed technical solution is to create a universal device.

The essence of the proposed technical solution lies in the fact that in the known device for inputting discrete signals containing a microprocessor element, a source of stabilized voltage for the microprocessor element, a data receiving / transmitting unit with galvanic isolation, and input channels for discrete signals, the input circuits of which contain an input resistor in series, the zener diode and the input of the optocoupler isolation element, while for galvanically coupled controlled signals, the input circuits are combined into groups with a common wire, to which, through a zener diode, connected counter to the zener diodes of the input circuits, the output of the microprocessor-controlled element of the first pole switching node of the power source of the signals being connected is connected, and the outputs of the optocoupler isolation elements are connected to the microprocessor element, preferably by the principle of multiplex group polling, In addition, for each group of input signals, the device contains second switching nodes controlled by a microprocessor element. Nia poles power controlled signals are connected to the outputs of additional resistors, second terminals connected to the inputs of channels of its group.

Figure 1 shows a structural diagram of a device for inputting discrete signals, where: 1 - controlled signals; 2 - groups of input channels; 3 - the first nodes of the pole switching power supplies of the groups of controlled signals; 4 - second switching nodes of the poles of the power sources of the groups of controlled signals; 5 multiplexed input data read bus; 6 - outputs of the strobe signals of the microprocessor element; 7 - output microprocessor element for controlling the first nodes switching poles; 8 - output microprocessor element for controlling the second nodes switching poles; 9 - microprocessor element; 10 - node receiving / transmitting data with galvanic isolation; 11 - battery power device (the voltage value is shown conditionally); U1-U3 - inputs of the poles of the power sources of the controlled signals.

Figure 2 shows the diagram of the input part of one of the channels of the device connected to the controlled circuit of the DC signal, where: 12 - control element of the controlled circuit; 13 - load; U1 +, U1- - power poles of controlled signals; 3 - the first node switching poles of the power sources of the controlled signals; 4 - the second node switching poles of the power sources of the controlled signals; Bxl - channel input; R1 is the input resistor; R1a is an additional resistor simulating a load; VZ1 is the zener diode of the input circuit; VE1 is the input optocoupler; VEy - optocoupler of control of the first switching node; VEy2 - a control optocoupler of the second switching unit; Op1 - common wire control group of signals; VZ2 is a common zener diode of a group of signals.

The operation of the device can be conditionally divided into two modes: main and purely diagnostic.

The main mode. The microprocessor element (9) outputs (8) sets the second node switching poles of the power source of the monitored signals (4) in the state of connection to the common pole (U1-) of the loads (13) of the input signals, and output (7) - the first node switching poles of the power source monitored signals (3) to the state of connection to one of the poles (standardly also to the common pole of the input signal loads), provides strobe signals (6) to the groups of output transistors of the input channel optocouplers (2), reads information about the state of the monitored circuits from the multiplex bus (5) and transfers the results through the elements (10) of the galvanic isolation of information exchange circuits to a higher level of control or monitoring system. Then, after a certain period of time, the state of the first pole switching unit is changed (connected to another pole) and the next reading of information on the state of the monitored circuits, which should be inverse to the previous one. Those. each channel is described by the state “01” or “10” (as in the prototype). Any discrepancy indicates a malfunction in the channel: the absence of an inversion of the read information indicates a malfunction in the control circuit of the pole switching unit (for example, a malfunction of the VEy optocoupler), if the input elements are broken (to the device’s connector), the state “00” will be read, and the state “11 »It is possible if there is a malfunction in the pole switching node of the power source of the monitored signals, if one of the poles is not connected (for example, loss of contact in the connector, which leads to a current between channels with different oyaniem) or a fault in the output channel circuits (e.g., circuit optocoupler output transistor).

Purely diagnostic mode. The microprocessor element (9) with the output (8) sets the second (4) node for switching the poles of the power source of the controlled signals into the state of connection to the common pole (U1 +) of the control elements (12) of the controlled circuit. In this mode, for single-pole signals, only diagnostic information about the state of the channel elements remains: if the first switching node is in the U1 + state, then only “1” (current in the input circuit) should be read when the input elements are in good condition, and when the first node is found (3 ) in the state W- should be read only "O". For bipolar signals, the operation of the device is similar to the main mode, but interruptions in the input circuits are diagnosed up to the point of connection to the load (loss of contact in the connector, interruptions in the installation and the load itself).

Claims (1)

A discrete signal input device comprising a microprocessor element, a source of stabilized supply voltage of a microprocessor element, a data receiving / transmitting unit with galvanic isolation and discrete signal input channels, the input circuits of which contain an input resistor, a zener diode and an input of an optocoupler isolation element in series, while for galvanic connected controlled signals, the input circuits are combined into groups with a common wire, to which, through a zener diode, connected counterclockwise from communicating with the zener diodes of the input circuits, the output of the microprocessor-controlled element of the pole switching node of the power source of the controlled signals is connected, and the outputs of the optocoupler isolation elements are connected to the microprocessor element, preferably by the principle of multiplex group polling, characterized in that the device for each group of input signals additionally contains second microprocessor-controlled element switching nodes of the poles of the power source of the controlled signals to the outputs of which Connect additional resistors, second terminals connected to the input channels of the group.

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