RU2055401C1 - Device for monitoring state of object - Google Patents

Abstract

FIELD: monitoring devices. SUBSTANCE: device monitors states of detectors, which are designed as switching contacts and connected matrix circuit. Diodes are used as elements for decoupling of horizontal and vertical lines of matrix of detectors. Horizontal lines of matrix of detectors receives request pulses from pulse distributor. Signals from vertical lines are received by indication units. Indication units as well as detectors are connected in matrix circuit. Each detector corresponds to unique indication unit, shape of two matrices, number of indication units and detectors are same. Indication units receives information by strobe pulse, which is generated by pulse distributor. Device provides possibility to detect address of fired detector and detects errors in wiring. In addition device has diodes, line commutation unit and unit for power supply control. Introduced units decrease power consumption of device, because power supply is turned on only when at least one detector in network fires. Otherwise, power used by device is minimal. EFFECT: increased functional capabilities. 3 cl, 7 dwg

Description

 The invention relates to techniques for automatic control.

 A device for monitoring the state of objects [1] containing on-off sensors, diode isolation, a distributor, recording elements and indicators. Sensors and diodes are combined in a matrix circuit.

 The disadvantages of this device are the possibility of fixing only two states of the sensors "on" and "off", as well as significant power consumption of the device.

 Closest to the invention in technical essence is a device for monitoring the state of objects [2] containing diodes, n groups of m sensors in each group, the first output of each sensor is connected to the anode of the diode, the second conclusions of the sensors are connected in each of n groups, n analysis units signals, the first outputs of which are connected to the first group of inputs of the information processing unit, the second group of inputs of which is connected to the first group of outputs of the distributor, and each sensor is made in the form of a switching contact, a generator and an amplification unit Iteli, the average output of the switching contact of the sensor is its first output, and the second and third conclusions are connected to the first input of each of n signal analysis units, and the second output of one of the sensors in each of n groups with the second input of each of n signal analysis units, second the outputs of which are connected to the third group of inputs of the information processing unit, the cathodes of the same diodes of all groups are combined and connected to the corresponding outputs of the amplifier block, the inputs of which are connected to the second group of outputs of the pulse distributor s, the input of which is connected to the output of the generator.

 The disadvantage of this device is its high power consumption.

 In most cases, the operation of matrix networks implemented on sensors with switching contacts, the normal state of the network corresponds to broken sensors, and their operation is quite rare. Therefore, it seems impractical to constantly keep the device on with such wide functionality to determine the addresses of triggered sensors and installation malfunctions. If it was possible to generate an integral signal about the operation of sensors (at least one) in the network, then most of the equipment in the device could be turned off for a time when there were no triggered sensors in the network.

 In addition, it is often necessary to ensure continuity of control of the signal reset network (even when the equipment containing sensors is intermittent) in order to exclude checks on the operability of sensors before each equipment is switched on with sensors, as well as monitoring devices. In these cases, it is tempting to reduce energy consumption during non-working periods of the device. It is also advisable to transfer the network and device under centralized control. To do this, it is necessary to develop an integral (preferably non-current) signal on the operation of the sensors.

 The technical result of the invention is to reduce the power consumption of the device, as well as the ability to remotely control the signal collection network, i.e. generating an integrated sensor response signal.

 To do this, in a device for monitoring the state of objects containing a matrix of sensors made on switching contacts combined in n columns of m in each column, the same conclusions of the stationary contacts of the columns of sensors are connected by the corresponding vertical buses, the cathodes of the same diodes, anodes are connected to the terminals of the primary contacts of the sensors which are combined line by line, the anode of one of the diodes of each row is connected to the corresponding output of the amplifier block, the conclusions of the fixed contacts of one of the sensors are one of the n columns is connected to the inputs of the same name column of the signal analysis unit, the first and second outputs of which are connected to the first and second inputs of the corresponding column display unit of the matrix forming the information processing unit, the third inputs of the display units are connected line by line to the corresponding outputs of the first group of outputs of the pulse distributor, the outputs of the second group of which are connected to the inputs of the amplifier unit, and the input is connected to the output of the pulse generator, n additional diodes, a bus switching unit and a bus to power control, with n additional cathode diodes connected to the vertical buses of the sensor matrix, and the anodes combined and being the first output of the device, which is connected to the input of the power control unit, the first output of which is the second output of the device, and the second output is connected to the input of the bus switching unit the outputs of which are connected respectively with the outputs of the amplifier block.

 The bus switching unit may contain a relay, the winding of which is connected to the input of the unit with one terminal and the other terminal of the winding is grounded, the first conclusions of the relay contact group are connected to the outputs of the unit, and the second conclusions are grounded.

 The power control unit may include an operating mode switch, a pulse shaper, a trigger, a power supply, a timer and a relay, the output of the moving contact of the switch is grounded, the output of one fixed contact of the switch is connected to the first inputs of the installation and reset of the trigger, the output of another fixed contact of the switch is connected to the second input the installation of the trigger and the first input of the pulse shaper, the third input of the installation of the trigger is connected to the input of the block and the second input of the pulse shaper, the second input of the reset the gagera is connected to the output of the timer, the input of which is connected to the output of the pulse former, the relay coil is connected to the output of the trigger, the terminals of the first NO contact of the relay are connected respectively to the voltage source of the mains and to the input of the power supply, the terminals of the second NO contact of the relay are connected respectively to the second output of the block and a random voltage source, the output of the power supply is connected to the first output of the power control unit.

 Figure 1 shows the structural diagram of the proposed device; figure 2 is a functional block diagram of the signal analysis; figure 3 is a functional diagram of a signal indicating unit; figure 4 is a functional diagram of a pulse distributor; 5 is an electrical diagram of a bus switching unit; 6 is a functional diagram of a power control unit; Fig.7 is a functional diagram of the trigger.

 The device for monitoring the state of objects contains sensors 1 and diodes 2 included in the sensor matrix 3, additional diodes 4, signal analysis blocks 5, signal indication blocks 6 included in the information processing unit 7, amplifier unit 8, bus switching unit 9, generator 10, a pulse distributor 11, a power control unit 12, an integrated signal output 13 and a power control output 14.

 Block 5 signal analysis contains a decoder 15, the element is NOT 16 and the element is OR 17.

 The display unit 6 contains display elements 18, triggers 19 and 20, a reset and lock key 21.

 The pulse distributor 11 comprises counters 22 and 23 and elements 4I 24.

 The bus switching unit 9 comprises a relay 25 (winding) with a group of contacts 26.

 The power control unit 12 includes an operation mode switch 27, a pulse shaper 28, a trigger 29, a power supply unit 30, a timer 31, a relay 32 with contacts 33.

 The trigger 29 contains the logic circuit 2I-NOT 34, 2I-2OR-NOT 35 and the element is NOT 36.

The inputs of the trigger 29 implemented the following logical functions:
at the input S1, for the signals of one unit and another of the zero levels, the logical function AND is implemented, S1 together with input S2 are combined according to the OR scheme;
input R implements the logic circuit AND for signals of a single level.

 The sign Usl indicates the service voltage of the power supply, U network voltage of the primary supply network. From output 14, the secondary power supply voltage is supplied to units 5, 6, 7, 8, 10, and 11 of the device. For nodes 1-4, a separate power supply is not required, blocks 9 and 12 are powered by service voltage.

 In accordance with figure 1, the sensors 1 are combined in a matrix scheme (matrix of 3 sensors), conditionally consisting of m rows and n columns. The purpose of the diodes 2 (according to the number of sensors 1) is to decouple the horizontal and vertical buses of the matrix 3 with the simultaneous operation of several sensors 1.

 Similarly, matrix 3 of sensors 1, blocks 6 are assembled in the same matrix 7 (the number of blocks 6 and sensors 1, the number of rows m and columns n in both matrices should be equal). In other words, in block 7, each block 6 is assigned to a specific sensor 1. Each block 6 contains two triggers (trigger 19 detects the operation of the sensor 1 associated with it, trigger 20 additionally indicates an installation failure detected by interrogating the same sensor 1). The corresponding trigger 19 or 20 is displayed by the indicator elements 18. Using the key 21, when it is pressed briefly, the triggers 19 and 20 are reset, and when the button is pressed for a long time, information is entered into these triggers. The latter is necessary to block the indication during routine or repair work on the device containing the sensor.

 One input of block 6 is connected line by line with the corresponding horizontal bus, to which the gating signal from the distributor 11 arrives. Two other outputs of block 6 are connected to the vertical buses in columns and through the signal analysis blocks 5 to the vertical buses of the matrix 3 of sensor 1.

 A device for monitoring the state of objects operates in one of two modes: local (detailed) control or remote (integral) control.

 We will conditionally assume that in the initial state the sensors 1 are in the state shown in FIG. 1, service voltage is applied to the nodes of block 12. The relay 25 of the bus switching unit 9 is de-energized and contacts 26 block the outputs of the amplifier unit 8.

 Local control regime.

 To transfer the device to the local (detailed) control mode, the switch 27 of the power control unit 12 must be set to LOCAL. In this case, a single signal level will be applied to input S2, and a zero level will be applied to one of the inputs S1 and R of trigger 29, respectively. Trigger 29, relay 32, and relay block 25 in block 9 are triggered. Relay 32 supplies 3 voltages to contacts of the power supply unit through contacts 33 network and in block 9 service voltage to turn on the relay 25. The voltage of the secondary power appears on the bus 14 and on all blocks of the device. Relay 25, when turned on by contacts 26, unlocks the outputs of block 8. From the outputs of block 8 of the amplifiers, serial polling pulses generated by the distributor 11 are fed to the horizontal buses of the sensor array 3. The number of polling pulse outputs is equal to the number of horizontal buses, and the pulses themselves are shifted in time. The polling pulses are generated at the output of the second counter 23, recounting the pulses from the generator 10 after recounting the first counter 22.

 The outputs of the vertical buses of the matrix of 3 sensors are pairwise removed signals that are fed to the inputs of the respective signal analysis units.

The signals from the vertical buses of matrix 3 are identified as follows:
code 01 no sensors are triggered;
code 10 sensor 1 has triggered;
code 11 mounting bus break or mating connector in the interrogated sensor is removed;
code 00 one of the buses or both are “grounded”, or there is a mutual short circuit of the buses.

 These codes are decrypted by the decoder 15 included in the signal analysis unit 5. Violation signals (not code 01) are generated at the output of element NOT 16 of block 5 and trigger the corresponding trigger 19. Codes 00 and 11 are additionally recorded as a malfunction of the connections of sensors 1, a signal is generated at the output of element 17 OR, causing the corresponding trigger 20 to fire. Trigger 19 is triggered in the first (conditionally) cycle of polling sensors according to the gating signal generated at the output of element 4I 24 of the distributor 11. Trigger 20 is triggered in the second (next) polling cycle, provided that in the first polling cycle CA trigger 19. This eliminates the possibility of false triggering of the trigger 20 due to the bounce of the contacts of the sensor 1 when they switch at the time of the corresponding gating pulse.

 Let us assume conditionally that in the matrix of 3 sensors 1, one of them from address 1-1 (the first digit is the row number, the second column number) is the counterpart of the signal output connector, the other (2-2) the sensor has triggered, the response is removed in 3-3 part of the connector, 4-3 and 4-4 sensors worked. Then, when interrogating the horizontal buses of the matrix of 3 sensors in the matrix 7 in blocks 6 of the device in the first cycle of the survey, triggers 19 of blocks 1-1, 2-2, 3-3, 4-3 and 4-4 will be cocked, indicating violations in the corresponding sensors 1, and in the second polling cycle, triggers 20 of blocks 1-1 and 3-3, indicating malfunctions in the installation of sensors.

 With a short circuit in the bus of the sensor matrix 3, triggers 19 and 20 of all blocks 6 will be activated, which correspond to all sensors 1 connected to the faulty bus.

 Remote control mode and transition from local to remote mode.

 The device is put into remote control mode by setting the switch 27 (block 12) to the REMOTE position. The signal from the lower (according to the scheme) contact of the switch 27 (zero level) is fed to input S2 and the second input of the driver, and the signal of a single level from the upper contact to inputs S1 and R2 of trigger 29. In this case, the signal from the driver 2 through timer 31 is reset if there is no signal from diodes 4. Two further cases are possible: a triggered sensor in the network is available or a triggered sensor in the network is not.

 If matrix 3 has a triggered sensor, a zero level signal appears at output 13 (for signaling to another remote control) and at installation input S1 of trigger 29 (block 12). In this case, either the single state of the trigger 29 is confirmed, or the trigger 29 is cocked if it was in the reset state. The time set on the timer 31 is selected so that the trigger 29 is not reset in one polling cycle at the input R. Through the contacts 33 of the switched on relay 30, the service voltage is supplied to the relay 25 and the voltage of the main power supply to all other units of the device. Relay 25 with its contacts does not block the outputs of block 8 amplifiers. The algorithm of polling and determining the address of the triggered or triggered sensors is performed (as described above in the local control mode).

 If there are no triggered sensors in the network (the sensor has returned to its initial state) and there is a unit level signal on bus 13, then upon transition of the signal from the unit to zero with switches 27, the driver 28 generates a pulse that starts the timer 31 and after a specified time interval the output signal timer 31 trigger 29 is reset at the input.

 In this case, the relay 32 releases, the power supply unit 30 and the relay 25 are de-energized, through the contacts 26 of the relay 25 a zero potential is issued to the horizontal buses of the sensor matrix 3. The device operates with minimal power consumption, monitoring the state of the sensor network using an integrated signal.

 When the sensors in the network are triggered, a zero signal level from the output of the contacts 26 of the relay 25 through this sensor (diode 2) appears at the output of the diodes 4, the trigger 29 is turned on, the general power supply is turned on and the algorithm for determining the address of the triggered sensor is started (as described above).

 Transition from remote to local control mode.

 Switch 27 is set to LOCAL. A trigger 29 is triggered by a unit level signal at input S2. The algorithm for turning on the power and operation of the device is described above.

Claims (3)

 1. DEVICE FOR MONITORING THE STATE OF OBJECTS, containing a matrix of sensors made on switching contacts, combined in n columns of m in each column, the outputs of the same name fixed contacts of the columns are connected by the corresponding vertical buses, the cathodes of the same name diodes are connected to the outputs of the moving contacts of the sensors, the anodes of which are combined line by line, the anode of one of the diodes of each row is connected to the corresponding output of the amplifier block, the conclusions of the fixed contacts of one of the sensors of each of the n columns with are connected to the inputs of the same column of the signal analysis unit, the first and second outputs of which are connected to the first and second inputs of the corresponding column display unit of the matrix forming the information processing unit, the third inputs of the display units are connected line by line to the corresponding outputs of the first group of outputs of the pulse distributor, the outputs of the second group of which connected to the inputs of the amplifier unit, and the input is connected to the output of the pulse generator, characterized in that n additional diodes are introduced into it, the switching unit bus and power control unit, n additional cathode diodes connected to n vertical sensor matrix buses, and the anodes combined and are the first output of the device, which is connected to the input of the power control unit, the first output of which is the second output of the device, and the second output is connected to the input bus switching unit, the outputs of which are connected respectively with the outputs of the amplifier unit.  2. The device according to claim 1, characterized in that the bus switching unit comprises a relay, the winding of which is connected to the input of the unit with one output, the other terminal of the winding is earthed, the first outputs of the group of relay disconnect contacts are connected to the outputs of the unit, and the second outputs are earthed.  3. The device according to claim 1, characterized in that the power control unit comprises an operating mode switch, a pulse shaper, a trigger, a power supply, a timer and a relay, the output of the moving contact of the switch is grounded, the output of one fixed contact of the switch is connected to the first inputs of the installation and reset trigger, the output of another fixed contact of the switch is connected to the second input of the trigger setup and the first input of the pulse shaper, the third input of the trigger setup is connected to the input of the block and the second input of the form For a pulse, the second trigger reset input is connected to the output of the timer, the input of which is connected to the output of the pulse shaper, the relay winding is connected to the trigger output, the terminals of the first NO contact of the relay are connected respectively to the information source of the power supply network and to the input of the power supply, the terminals of the second NO contact of the relay - respectively, with the second output of the unit and the source of service voltage, the output of the power supply is connected to the first output of the power control unit.

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