RU142664U1 - PORTABLE DIAGNOSTIC COMPLEX OF AMBIENT AUTOMATIC EQUIPMENT - Google Patents

Abstract

1. Diagnostic complex of automatic equipment for hiding, containing a processor installed in the case, connected to the input of the monitor, the screen of which is located on the outside of the case, a real-time clock, non-volatile memory, a block for selecting measurement programs, the control elements of which are displayed on the outside of the case, block power supply, serially connected input protection circuits, controlled analogue switch, amplifier with controlled gain, analog-to-digital converter and buffer, output ohm connected to the input of the processor, the outputs of which through the control unit are connected to the corresponding outputs with the control inputs of the switch and amplifier, as well as to the synchronization input of an analog-to-digital converter, a connector for connecting the measuring circuits of the controlled equipment of the automatic equipment, mounted on the outside of the case and connected to input protection circuits, while the corresponding inputs of the processor are connected to the outputs of the block selection of measurement programs and real-time clock, and the input / output is connected to go / nonvolatile memory entry, the processor software includes software for each type of automation equipment hump corresponding program parametrov.2 diagnostic measurements. The complex according to claim 1, characterized in that for connecting external devices, a USB interface installed in the housing is introduced, with an input / output connected to the corresponding output / input of the processor, while the USB interface connector is output to the outside of the case. The complex according to claim 2, characterized in that the power supply is made in the form of a rechargeable battery�

Description

The utility model relates to monitoring and diagnostic devices, and can be used in railway transport for monitoring and diagnosing technical equipment at sorting slides and stations.

A known portable diagnostic and diagnostic complex comprising a monitor connected to each other through a control computer, a multi-channel analog-to-digital converter, a multi-channel analog signal generator, a multi-channel pulse-code signal generator, a multi-channel logic analyzer and a multi-channel diagnostic module made with digital control (RU 2363975 C1 G05B 23/02, 08/10/2009).

This design allows you to expand the functionality of the complex, to observe visual information on one screen simultaneously from a variety of measuring and diagnostic devices, which facilitates the analysis of the parameters of the diagnostic object and the search for its malfunctions.

A disadvantage of the known complex is the hardware duplication of cases, power supplies, interface devices and adapters and, as a result, the relatively large dimensions of the complex as a whole.

A well-known control and diagnostic complex of station devices for automatic automatic centralization contains modules for inputting analog and discrete signals from monitored devices, an insulation resistance control module associated with monitored devices, remote workstations and an Ethernet gateway, a database server and a collection controller connected by a local area network information on the basis of an industrial computer, which is connected to the insulation resistance control module, ana input modules og and discrete signals and with a database server associated with an automated sorting process control system, with a local area network gateway and an on-site mechanic on duty, a module for monitoring the status and detection of equipment malfunctions, associated with an information collection controller, on an automated on-site mechanics on-duty and with an automated control system for the sorting process, a collective display panel associated with a module for monitoring the status and detection of equipment malfunctions, made with the possibility of visual, voice and sound notification of a malfunction of controlled devices, while the local area network gateway and remote automated locations are connected to the corporate data network, providing diagnostic and statistical information on the operation of the equipment in systems of technical monitoring and diagnostics of the upper level (RU 98724, B61L 17/00, 10.27.2010).

In the well-known complex, the parameters of the serviced equipment are measured in the field, and their monitoring and diagnostics of the state of the equipment are carried out at a remote automated workstation of an on-duty electrician. In the field, the known complex does not carry out the measurement and control of the parameters of the serviced equipment of the hills automatic centralization, as well as the diagnosis of its condition.

The problem the utility model aims to solve is to create a universal portable diagnostic complex that measures, monitors parameters and diagnoses the state of automatic automatic centralization equipment in real time in the field without reducing its functionality.

The technical result of the proposed complex is to reduce the dimensions of the device by increasing the versatility of the constituent elements of the complex without compromising functionality.

The technical result is achieved by the fact that the portable diagnostic complex of the automation equipment includes a processor installed in the housing, with an output connected to a monitor input, the screen of which is located on the external side of the housing, a real-time clock, non-volatile memory, a unit for selecting measurement programs, the control elements of which are output to an external housing side, power supply, input protection circuits connected in series, controlled analogue switch, amplifier with controlled coefficient amplified an analog-to-digital converter and a buffer connected to the input of the processor, the outputs of which are connected via the control unit to the corresponding outputs with the control inputs of the switch and amplifier, as well as to the synchronization input of the analog-to-digital converter, a connector for connecting measurement circuits of controlled equipment mounted on the outside of the case and connected to the input protection circuits, while the corresponding inputs of the processor are connected to the outputs of the program selection block fereniya and real-time clock, and input / output - to the output / input of non-volatile memory, the processor software includes for each type of equipment automatic slide control the corresponding program for measuring diagnostic parameters.

To connect external devices, the complex additionally includes a USB interface installed in the housing, connected with an input / output to the corresponding output / input of the processor, while the USB input connector is displayed on the outside of the case.

The power supply switching element is located on the outside of the housing and can be made in the form of a touch or button switching element. The power supply can be made in the form of a battery connected to the USB interface connector.

The battery may be equipped with a charge indicator located on the outside of the housing.

The controls of the unit for selecting measurement programs are made in the form of a touch or button keyboard.

The essence of the proposed technical solution is illustrated by the drawing, which shows a structural diagram of a portable diagnostic complex equipment hump automation.

The portable diagnostic complex of the automation equipment includes the processor 2 installed in the housing 1, the output connected to the input of the monitor 3, the screen of which is located on the outside of the housing 1, a real-time clock 4, non-volatile memory 5, a measurement program selection unit 6, a complex unit power supply unit 7 , serially connected input protection circuits 8, controlled analog switch 9, amplifier 10 with controlled gain, analog-to-digital converter 11 (ADC 11) and buffer 12, with output connected to the input of the processor 2.

The outputs of the processor 2 through the control unit 13 is connected to the control inputs of the switch 9 and the amplifier 10, as well as to the synchronization input of the ADC 11.

On the outside of the housing 1, a connector 14 is installed for connecting the measuring circuits of the controlled equipment, connected to the input protection circuits 8.

In this case, the corresponding inputs of the processor 2 are connected to the outputs of the block 6 of the choice of measurement programs and 4 real-time clocks, and the other input / output is connected to the output / input of the non-volatile memory 5. The software of the processor 2 includes for each type of serviced equipment of the slide automation a corresponding diagnostic measurement program parameters.

The controls of the block 6 of the selection of measurement programs displayed on the outside of the housing 1 (not shown) and made in the form of touch devices or a keypad.

To connect external devices, the complex additionally includes a USB interface 15 installed in the case 1, input / output connected to the corresponding output / input of the processor 2. The USB input connector 15 is displayed on the outside of the case 1 (not shown in the drawing).

The switching element of the power supply unit 7 is located on the outside of the housing and can be made in the form of a touch or button switching element (not shown).

The power supply unit 7 can be made in the form of a rechargeable battery connected to a USB interface connector 15 and equipped with a charge indicator located on the outside of the case (not shown in the drawing).

The portable diagnostic complex of automatic automatic centralization (MPC GAC) measures and monitors the parameters and diagnostics of the technical condition of automatic automation equipment performed by the personnel of the sorting stations directly at their location.

The connection of the connector 14 MPC GAC to the electrical circuits of the serviced equipment of the automatic equipment is carried out using a measuring cable.

Before performing operations of measurement and control of parameters and diagnostics of the state of the serviced equipment, they include the power supply unit 7 of the MPC GAC. Using the keyboard of block 6, a measurement program for a given type of serviced equipment is selected. Block 6 generates an appropriate command for processor 2, which requests from memory 5 a program for measuring and controlling parameters for this type of equipment.

The measuring signal through a series-connected input circuit 8 of the protection, the managed switch 9 and the amplifier 10 is fed to the input of the ADC 11.

Input circuits 8 protect the GAC MPC elements from overvoltage in case of its unauthorized use. As such circuits, voltage dividers and varistors are used.

In accordance with the selected measurement program, the processor 2 through the control unit 13 controls the operation of the analog switch 9, amplifier 10, ADC 11 and buffer 12.

In accordance with the control signal, the switch 9 and amplifier 10 carry out the normalization of the signal to bring its level to acceptable, providing accurate analog-to-digital conversion. The frequency of the analog-to-digital conversion is set by the processor 2 - at least 1500 conversions per second and through the control unit 13 is sent to the synchronization input of the ADC 11.

The analog-to-digital conversion takes place in real time and is synchronized by clock pulses set by 4 real-time clocks.

The ADC 11 converts the analog signal into a digital one and transfers it to the buffer 12 for subsequent transmission to the processor 2. To prevent loss of the results of previous measurements, the buffer 12 accumulates the results of the analog-to-digital conversion and stores them until the processor 2 requests. The processor 2 sends the request through block 13 buffer 12 only after processing the previous measurement results. As buffer 12, a FIFO buffer is used.

The processor 2, in accordance with the selected measurement program, processes the results of the analog-to-digital conversion of the measured signals, sends them to memory 5 for storage at the same time as a request for the results of processing previous measurements of this type of equipment and information about the permissible parameters of the measured signals of the equipment and carries out the corresponding conversion of the received data for their subsequent visual display on the monitor screen 3.

The results of measurements of voltages, currents, time and frequency are displayed in a convenient form for perception. At the same time, on the screen of the monitor 3, the processor 2 displays reference information about the permissible parameters of the measured signals of the serviced device.

The processor 2 monitors the parameters of the measured signals by comparing their values with the acceptable ones, according to the results of the comparison, it diagnoses the state of the serviced object and displays a corresponding message, for example, “the section is free”, which allows the user of the complex in the field to monitor the state of the object and, if necessary, accept appropriate measures to restore its functioning in working mode.

MPC GAC measures, monitors the parameters and diagnoses the status of radar devices for measuring the speed of a car from a hill (RIS-VZM), track filling control devices based on the pulse sounding method (KZP-IZ), axle passage fixation devices (UFPO), radio monitoring sensors the freedom of switch sections (RTD-S), DD pressure sensors, inductively wire sensors (IPD); measurement of voltages and currents of output measuring and control power circuits and communication lines.

The MPC GAC provides for the possibility of increasing the volume of controlled equipment for automatic equipment for the hills. Using the USB interface 15 from an external computer, you can load 5 additional subprograms into the non-volatile memory for measuring, monitoring parameters and diagnosing the state of new types of HAC equipment.

Thus, the inventive portable diagnostic complex allows one user (an electrician) to quickly measure and control parameters, as well as diagnose the condition of the HAC in emergency situations when there are malfunctions in the HAC, in accordance with maintenance plans.

Claims (6)

1. Diagnostic complex of automatic equipment for hiding, containing a processor installed in the case, connected to the input of the monitor, the screen of which is located on the outside of the case, a real-time clock, non-volatile memory, a block for selecting measurement programs, the control elements of which are displayed on the outside of the case, block power supply, serially connected input protection circuits, controlled analogue switch, amplifier with controlled gain, analog-to-digital converter and buffer, output ohm connected to the input of the processor, the outputs of which through the control unit are connected to the corresponding outputs with the control inputs of the switch and amplifier, as well as to the synchronization input of an analog-to-digital converter, a connector for connecting the measuring circuits of the controlled equipment of the automatic equipment, mounted on the outside of the case and connected to input protection circuits, while the corresponding inputs of the processor are connected to the outputs of the block selection of measurement programs and real-time clock, and the input / output is connected to go / entry nonvolatile memory, CPU software includes software for each type of automation equipment hump corresponding program measuring the diagnostic parameters. 2. The complex according to claim 1, characterized in that a USB interface installed in the housing is inserted for connecting external devices, connected via an input / output to the corresponding output / input of the processor, and the USB interface connector is output to the external side of the housing. 3. The complex according to claim 2, characterized in that the power supply is made in the form of a rechargeable battery connected to a USB interface connector. 4. The complex according to claim 3, characterized in that the battery is equipped with a charge indicator located on the outside of the housing. 5. The complex according to any one of claims 1 or 2, characterized in that the power supply switching element is located on the outside of the housing and can be made in the form of a touch or button switching element. 6. The complex according to any one of claims 1 to 4, characterized in that the controls of the unit for selecting measurement programs are made in the form of a touch or button keyboard.

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