RU219480U1 - Device for operational monitoring of the technical condition and accounting for the operating time of communication equipment - Google Patents

Abstract

The utility model relates to means for automated control of the parameters of electrical circuits of communication equipment (TC) and can be used to automate the process of tracking the location of the TC, collecting, processing and transmitting information in systems for automated control of the technical condition and accounting for the operating time of the TC as part of automated communication systems and automated systems for monitoring the technical condition of the TC. A device for operational monitoring of the technical condition and recording the operating time of communication equipment, containing a signal receiving unit, a conversion unit, a microcontroller, a power supply unit, a galvanic isolation unit, a real-time clock unit, a reset unit, an information input and output unit; wherein the signal receiving unit is connected to the conversion unit, the output of which is connected to the galvanic isolation unit, the output of which is connected to the microcontroller; the reset unit is connected to the second input of the microcontroller, the real-time clock unit is connected by feedback to the microcontroller in order to bind all collected data to astronomical time for displaying them on the computer monitor, the power supply unit, the first output of which is connected to the input of the galvanic isolation unit, the second output is connected to the microcontroller, the third output is connected to the real-time clock unit, and the information input and output unit, connected by feedback to the microcontroller in order to transmit and display the received control data to the computer and reprogram the microcontroller with E VM. The fundamental difference from the prototype is that the device additionally contains a radio module, the output of which is connected to the input of the microcontroller by feedback, and the input is connected to the fourth output of the power supply, and an uninterruptible power supply, the output of which is connected to the input of the microcontroller, and the input is connected to the fifth output of the power supply. The technical result of the utility model is to increase the efficiency of monitoring the technical condition of communication equipment. 1 ill.

Description

The utility model relates to means for automated control of the parameters of electrical circuits of communication equipment (TC) and can be used to automate the process of tracking the location of the TC, collecting, processing and transmitting information in systems for automated control of the technical condition and accounting for the operating time of the TC as part of automated communication systems and automated systems for monitoring the technical condition of the TC.

The current level of development, the complexity of building technology, systems and communication networks determines the increasing requirements for their reliable operation and the quality of planning measures for technical support of communications. In order to fulfill these requirements, communication technology monitoring systems with a subsystem for monitoring the technical condition of communication technology are being introduced into communication systems and networks. The improvement of the monitoring system should be aimed at increasing the efficiency of the control process, that is, the ability to track the status of communication equipment and take measures to restore communication in a timely manner, and is based on automation of control processes on a close-to-real time scale. One of the directions for increasing the level of efficiency of monitoring the operation of the vehicle is the high-quality planning and implementation of technical support and timely maintenance activities, which are impossible without determining their timing and taking into account the operating time of the vehicle.

A device for automated control of the parameters of communication equipment is known (Patent No. 2729749 Russian Federation, IPC G05B 23/02 (2006.01), SPK G05B 23/02 (2020.02), Appl. ami, a block of stimulating signals, a control unit that includes the functions of a control computer, an analyzer unit, a comparison unit and a synchronization unit, a reference voltage source, a memory unit, a conversion unit, an interface unit, moreover, the outputs of the stimulating signal unit are connected to the corresponding inputs of the switch, the outputs of the mode control unit are connected to the inputs of the control unit, the outputs of which are connected to the inputs of the block of stimulating signals, the outputs of the switch are connected to the tested circuits and to the inputs of the measuring unit, the outputs of which are connected to the inputs of the control unit, the outputs of which are connected s to the control inputs of the switch and the information output unit, and the output of the reference voltage source is connected to the input of the control unit, the outputs of which are connected to the memory unit, the outputs of which are connected to the inputs of the interface unit, the outputs of which are connected to the inputs of the memory unit, the outputs of the stimulating signal unit are connected to the conversion unit, the output of which is connected to the input of the control unit.

The disadvantage is the lack of operational control for notification in case of emergencies on the vehicle for making decisions on its restoration.

Closest to the utility model from the prior art and adopted as a prototype is a device for monitoring the technical condition and recording the operating time of communication equipment (Patent No. 213344U1 Russian Federation, IPC G05B 23/00 (2006.01), G06F 11/34 (2006.01), SEC G05B 23/00 (2022.05), G06F 11/34 (2022.05), application 04.02.2022, published 07.09.2022 Bull. No. 25).

The prototype contains an information output unit, a signal receiving unit, a microcontroller, a conversion unit, an interface unit, a power supply unit, while the signal receiving unit is connected to the input of the conversion unit, the output of which is connected to the microcontroller, the input of which is connected to the output of the power supply unit, a galvanic isolation unit, the input of which is connected to the output of the conversion unit, and the output is connected to the input of the microcontroller, a reset unit, the output of which is connected to the input of the microcontroller, a real-time clock unit connected by feedback to the microcontroller in order to link all the collected data to astronomical time to display them on the computer monitor, and the second input of the real-time clock unit is connected to the output of the power supply unit, the output of which is connected to the input of the galvanic isolation unit, and the information input and output unit, connected by feedback to the microcontroller for the purpose of transmitting and displaying the received control data to the computer and reprogramming the microcontroller with the computer.

However, the main disadvantage of the prototype is the lack of the possibility of operational control by notification in case of emergencies on the vehicle to make decisions on its restoration and determine the location of communication equipment.

To eliminate this shortcoming, a new technical solution “Device for operational monitoring of the technical condition and accounting for the operating time of communication equipment” is directed, the technical task of which is to create a device to increase the efficiency of monitoring the technical condition of communication equipment.

The implementation of the task allows to achieve the following technical result:

increasing the efficiency of monitoring the technical condition of communication equipment.

The specified technical result is achieved by the fact that the claimed device for operational monitoring of the technical condition and recording the operating time of communication technology contains a signal receiving unit, a conversion unit, a microcontroller, a power supply unit, a galvanic isolation unit, a real-time clock unit, a reset unit, an information input and output unit; wherein the signal receiving unit is connected to the conversion unit, the output of which is connected to the galvanic isolation unit, the output of which is connected to the microcontroller; a reset unit is connected to the second input of the microcontroller, a real-time clock unit connected by feedback to the microcontroller in order to bind all collected data to astronomical time for displaying them on a computer monitor, a power supply unit, the first output of which is connected to the input of the galvanic isolation unit, the second output is connected to the microcontroller, the third output is connected to the real-time clock unit, and the information input and output unit, connected by feedback to the microcontroller in order to transmit and display the received control data on the computer and reprogram the microcontroller with computer.

The fundamental difference from the prototype is that the device additionally contains a radio module, the output of which is connected to the input of the microcontroller by feedback, and the input is connected to the fourth output of the power supply, and an uninterruptible power supply, the output of which is connected to the input of the microcontroller, and the input is connected to the fifth output of the power supply.

A distinctive feature contained in the device, the radio module is a GSM / GPRS module that allows you to receive and transmit digital data in mobile networks, connect and manage access using the mobile Internet, track the location of the vehicle, that is, the coordinates and movement parameters of any device to which it is connected.

The presence of an uninterruptible power supply in the device allows you to provide power when the main or backup power sources are turned off.

The essence of the utility model is illustrated by the drawing:

Fig. 1 Device for operational monitoring of the technical condition and accounting for the operating time of communication equipment. Functional diagram.

The diagram shows:

1. Microcontroller.

2. Signal receiving block.

3. Block conversion.

4. Block of galvanic isolation.

5. Power supply.

6. Real time clock block.

7. Block reset.

8. Block of input and output of information.

9. Radio module.

10. Uninterruptible power supply unit.

The microcontroller 1, made on the AVR chip, is designed to process digital information, control the processes of this processing, due to the possibility of remote programming of the microcontroller using the developed computer program "Program for monitoring the technical condition of communication equipment" (Certificate of state registration of the computer program No. 2021614774, date of state registration in the Register of computer programs 30.03.2021). The choice of a specific microcontroller is due to the required amount of information processing, depending on the amount of controlled communication technology.

The signal receiving unit 2 is designed to receive signals from the built-in control system of communication technology about its technical condition.

Conversion unit 3 is designed to convert the operating voltage of the controlled signal into the voltage required for its registration on the device.

The galvanic isolation unit 4 is designed to protect the device from electric shock, register the electrical signals coming from the conversion unit 3 and transmit information signals about the technical condition of the communication technology to the microcontroller 1 for their processing.

The power supply unit 5 is designed to provide a constant highly stable voltage by converting the mains voltage up to 5 V, it supplies voltage to the galvanic isolation unit 4, the real-time clock unit 6 and the microcontroller 1.

The real-time clock block 6 is designed to record chronometric data (current time, date, day of the week, etc.), as well as transfer information through the microcontroller 1 and the information input and output block 8 to the computer.

Reset block 7 RESET is designed to manually reset the firmware of the microcontroller 1.

The block of input and output of information 8 is intended for the interaction of the device with the computer, the firmware of the microcontroller 1, the programming of the real-time clock block, and the transfer of information via the USB-B(A) port to the computer.

The radio module 9 is a GSM/GPRS module, which is designed to automate the process of controlling and tracking the location of the vehicle at a distance without using a wired connection.

The uninterruptible power supply unit 10 is designed to ensure that in the event of problems with the power supply, there is no instant shutdown of the communication equipment.

All structural elements of the device for operational monitoring of the technical condition and recording the operating time of communication equipment are connected by electrical connections. The signal from the built-in control system of the tested communication technology is fed to the input of the signal receiving unit 2, the output of the signal receiving unit 2 is connected to the input of the conversion unit 3, the output of which is connected to the input of the galvanic isolation unit 4, the output of which is connected to the input of the microcontroller 1; the first output of the power supply 5 is connected to the input of the galvanic isolation unit 4, the second output of the power supply 5 is connected to the input of the microcontroller 1, the third output of the power supply 5 is connected to the input of the real time clock unit 6, the output of which is connected in feedback to the microcontroller 1, the fourth output of the power supply 5 is connected to the input of the radio module 9, the fifth output of the power supply 5 is connected to the input of the uninterruptible power supply 10, the output of the uninterruptible power supply 10 is connected to the input of the microcontroller 1, radio module 9 is connected to the input of the microcontroller 1 by feedback, the output of the reset unit 7 is connected to the input of the microcontroller 1, the input and output unit of information 8, which is connected by feedback to the microcontroller 1 for the purpose of transmitting and displaying the received control data to the computer and reprogramming the microcontroller 1 with the computer.

The device works as follows.

The input voltage 220 V/50 Hz is supplied to the power supply unit 5. The power supply unit 5 supplies power to the microcontroller 1, to the real time clock unit 6, to the uninterruptible power supply unit 10, to the radio module 9 and to the galvanic isolation unit 4. When voltage is applied from the power supply unit 5, the microcontroller 1 starts working.
From the built-in control system of communication technology, signals are received at the input of the signal receiving unit 2, which are then transmitted to the conversion unit 3, in which the voltages of the controlled signals are converted into the voltages necessary for their registration on the galvanic isolation unit 4, where the electrical signal is registered in the form of unlocking the photodiode element, through which a voltage of 5 V is supplied from the power supply unit 5, which is an information signal about the good state of the communication equipment, and then from the galvanic isolation unit 4 coming to the microcontroller 1 for its processing. Upon receipt of information signals about the health of the state of the communication technology to the microcontroller 1, the real-time clock unit 6 is turned on, which begins to keep records of chronometric data, namely the date and time of switching on, the total operating time of the communication technology, which are displayed visually on the computer monitor by transmitting the appropriate signals through the microcontroller 1 and then to the input and output information block 8 and to the radio module 9. Operational control over the stable operation of the vehicle at the operator’s workplace is carried out on a computer, in real time, where using a radio module For 9, the location of the vehicle is tracked. When using the radio module 9, it is also possible to control other parameters of the vehicle, such as the indicator of temperature sensors, the status of ports, interfaces, etc. The information received by the radio module 9 goes into the radio channel through an external antenna and is transmitted to the microcontroller 1, which constantly monitors and analyzes the level of the received signal. When the signal level is above the detection threshold, the microcontroller 1 understands that the radio signal has appeared, turning on the radio module 9 to search for synchronization and adjustment. In case of disconnection of the main power source on the vehicle, the device automatically switches to offline operation using the uninterruptible power supply unit 10. With the help of the input and output information block 8, the processed information is transferred, namely the results of control to the computer, and the microcontroller 1 and the real time clock block 6 are programmed or reprogrammed. In the absence of signals from the built-in monitoring system of communication technology about the technical condition of communication technology to the signal receiving unit 2 and, accordingly, the absence of the control voltage coming from the conversion unit 3 to the galvanic isolation unit 4, the power supply unit 5 will not send an information signal to the microcontroller 1, in which the non-working state of the communication technology is recorded, which is visually displayed on the computer monitor through the input and output unit of information 8 in the form of a message about the unavailability of the communication technology for operation. At the request of the operator, using the reset unit 7, it is possible to manually reset the firmware of the microcontroller 1 through the RESET input of the microcontroller 1, after which it is possible to reprogram it from the computer through the information input and output unit 8.

The technical result of the utility model is to create a new device for operational monitoring of the technical condition and accounting for the operating time of communication equipment, which ensures an increase in the efficiency of monitoring the technical condition of communication equipment.

The claimed device for operational monitoring of the technical condition and recording the operating time of communication technology is industrially applicable, since for its implementation widely used components and products of the radio engineering industry and computer technology are used.

Claims (1)

A device for operational monitoring of the technical condition and recording the operating time of communication equipment, containing a signal receiving unit, a conversion unit, a microcontroller, a power supply unit, a galvanic isolation unit, a real-time clock unit, a reset unit, an information input and output unit; wherein the signal receiving unit is connected to the conversion unit, the output of which is connected to the galvanic isolation unit, the output of which is connected to the microcontroller; the reset unit is connected to the second input of the microcontroller, the real-time clock unit is connected by feedback to the microcontroller in order to bind all collected data to astronomical time for displaying them on the computer monitor, the power supply unit, the first output of which is connected to the input of the galvanic isolation unit, the second output is connected to the microcontroller, the third output is connected to the real-time clock unit, and the information input and output unit, connected by feedback to the microcontroller in order to transmit and display the received control data to the computer and reprogram the microcontroller with E CM, characterized in that the device additionally contains a radio module, the output of which is connected to the input of the microcontroller by feedback, and the input is connected to the fourth output of the power supply, and an uninterruptible power supply, the output of which is connected to the input of the microcontroller, and the input is connected to the fifth output of the power supply.

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