RU158265U1 - INTEGRATED DEVICE FOR MEASURING ENVIRONMENTAL PARAMETERS IN THE INTERESTS OF RADAR - Google Patents

Abstract

An integrated device for measuring environmental parameters in the interests of radar, consisting of a body, direction and wind speed sensors, atmospheric pressure sensor, temperature and air humidity sensor, water temperature sensor, water salinity sensor; inside the case there is a transceiver unit, a power supply unit, a control unit, a positioning unit, characterized in that in the upper part of the device inside an airtight transparent sphere-shaped fairing there is an additionally built-in video recording unit; the antenna of the transceiver unit and ultrasonic sensors for determining the direction and speed of the wind are located at the corners of the upper part of the complex device outside the transparent fairing; in the upper part of the device’s case, on the sides there are sensors of atmospheric pressure, temperature and humidity; digital temperature and salinity sensors and a valve of the device’s self-liquidation unit are located in the lower part of the device’s body; on the side in the middle part of the device’s body there is a device for fastening to the carrier or mast of the coastal post and a sealed connector for receiving - issuing information, supplying power, charging the battery and checking the health of the device during routine maintenance; on the opposite side of the attachment device is a toggle switch for supplying power to the device.

Description

The utility model relates to the field of hydrometeorology, and in particular to devices for the automated measurement of hydrometeorological environmental parameters at a fixed point in the World Ocean using modern means of measuring and processing signals placed on buoys and transmitting the results through communication channels.

This information can be used for the operational forecast of weather conditions.

A device for determining the hydrometeorological parameters of the environment, the closest in technical essence of the claimed utility model and selected as a prototype.

The prototype contains a transmitting device, a wind parameter meter, an atmospheric pressure meter with a barport, air and water temperature sensors, a control module with an optional GPS unit, an information memory unit, a central module with a controller, a buoy orientation device, a salinity detection sensor, a power source, (patent No. 23228757 Russian Federation, IPC G01W 1/04, G01C 13/00, B63B 22/00. Device for determining the characteristics of sea wind waves / Authors and patent holders Balakin RA, Rozanov MI, Dobrotvorsky AN and others claimed 04.0 9.2006; publ. 10.07.2008).

The main disadvantage of this device is the lack of means for determining the range of visibility and atmospheric phenomena.

A new technical solution is aimed at eliminating this drawback: an integrated device for measuring environmental parameters in the interests of radar, the technical task of which is to expand the capabilities of technical means for monitoring the surrounding hydrometeorological situation.

The implementation of the indicated technical task of the proposed utility model allows to achieve the following technical result: the use of a video recording unit expands the capabilities of the device for monitoring the following hydrometeorological parameters, such as sea waves, cloud cover, visibility, and atmospheric phenomena.

In the claimed device, the transmitting device is replaced by a transceiver unit; a control module with an optional GPS unit, an information memory unit, a central module with a controller, a buoy orientation device are replaced by a control unit. The air temperature sensor has been replaced by a temperature and humidity sensor.

The specified technical result is achieved by the fact that a new device has been developed comprising a housing, wind direction and speed sensors, atmospheric pressure sensor, temperature and humidity sensor, water temperature sensor, water salinity sensor; Inside the housing are the transceiver unit, power supply, control unit, positioning unit.

In the upper part of the device inside a sealed transparent sphere-shaped fairing, there is an additionally built-in video recording unit.

The antenna of the transceiver unit and ultrasonic sensors for determining the direction and speed of the wind are located at the corners of the upper part of the complex device outside the transparent fairing of a spherical type. At the top of the device on the sides are sensors of atmospheric pressure, temperature and humidity. At the bottom of the device are digital temperature and salinity sensors and a valve of the device’s self-liquidation unit. On the side in the middle part of the device’s body there is a device for attaching to the carrier or mast of the coastal post and a sealed connector for receiving - issuing information, supplying power, recharging the battery and checking the health of the device during routine maintenance. On the opposite side of the attachment device is a toggle switch for supplying power to the device.

The fundamental difference between the claimed device from the prototype is that it has a video recording unit.

This is what allows you to get additional information about the hydrometeorological situation: the presence of clouds, hydrometeors, sea wave parameters - wave height, period and direction of their propagation, visibility.

The essence of the utility model is illustrated by drawings:

Figure 1. An integrated device for measuring environmental parameters in the interests of radar. Functional diagram.

Figure 2. An integrated device for measuring environmental parameters in the interests of radar. Weather sensor block (enlarged). Functional diagram.

Figure 3. An integrated device for measuring environmental parameters in the interests of radar. The unit of hydroacoustic sensors (enlarged). Functional diagram.

Figure 4. An integrated device for measuring environmental parameters in the interests of radar. Control unit (enlarged).

Figure 5. Integrated device for measuring environmental parameters in the interests of radar. Video registration unit, (enlarged).

The figure 1 presents a functional diagram of an integrated device for measuring environmental parameters in the interests of radar, including:

1. The block of weather sensors.

2. The block of video registration.

3. The unit of hydroacoustic sensors.

4. The control unit.

5. The positioning unit.

6. Transceiver unit.

7. Power supply.

8. The self-liquidation unit of the device.

In a functional diagram, the device blocks in FIG. 1 are interconnected by electric communication lines.

The first output of the control unit 4 is connected to the input of the unit of weather sensors 1, and the output of the unit of weather sensors 1 is connected to the first input of the control unit 4.

The second output of the control unit 4 is connected to the input of the video recording unit 2, and the output of the video registration unit 2 is connected to the second input of the control unit 4.

The third output of the control unit 4 is connected to the input of the unit of hydroacoustic sensors 3, and the output of the unit of hydroacoustic sensors 3 is connected to the third input of the control unit 4.

The fourth output of the control unit 4 is connected to the input of the self-liquidation unit of the device 8.

The fifth output of the control unit 4 is connected to the input of the power supply 7, and the output of the power supply 7 is connected to the fourth input of the control unit 4.

The sixth output of the control unit 4 is connected to the input of the transceiver unit 6, and the output of the transceiver unit 6 is connected to the fifth input of the control unit 4.

The seventh output of the control unit 4 is connected to the input of the positioning unit 5, and the output of the positioning unit 5 is connected to the sixth input of the control unit 4.

The figure 2 presents a functional diagram of the depicted in the figure 1 block of weather sensors 1 (enlarged), including:

1.1 Atmospheric pressure sensor.

1.2 Temperature and humidity sensor.

1.3 Wind direction and speed sensors.

1.4 Ultrasonic generator.

1.5 microcontroller.

The atmospheric pressure sensor 1.1, the temperature and humidity sensor 1.2 are located in the upper part on the sides of the complex device and are electrically connected to the microcontroller board 1.5.

The direction and wind speed sensors in the amount of 3 (three) pieces are located at the corners on the upper platform of the integrated device for measuring environmental parameters in the interests of radar and are electrically connected to an ultrasonic generator, which in turn is connected to the 1.5 microcontroller.

The microcontroller 1.5 and the ultrasonic generator 1.4 are structurally located on one board.

The first output of the microcontroller 1.5 is connected to the input of the atmospheric pressure sensor 1.1, and its output is connected to the second input of the microcontroller 1.5 by electric wire communication.

The second output of the microcontroller is connected to the input of the temperature and humidity sensor 1.2, and its output is connected to the third input of the microcontroller by electric wire communication

The third output of the microcontroller 1.5 is connected to the first input of the ultrasonic generator 1.4, and its second output is connected to the fourth input of the microcontroller 1.5 by electrical communication via current-carrying tracks on the board.

The first output of the ultrasonic generator 1.4 is connected to the first inputs of the sensors of direction and wind speed 1.3, and their first outputs are connected to the second input of the ultrasonic generator 1.4 using a multicore cable.

The fourth output of the microcontroller 1.5 is connected to the first input of the central microcontroller 4.1 (Fig. 4), and the first output of the latter with the first input of the microcontroller 1.5 by electrical communication using a cable.

The figure 3 presents a functional diagram of the block of hydroacoustic sensors 3 shown in figure 1 (enlarged), including:

3.1 Water temperature sensor.

3.2 Water salinity sensor.

3.3 microcontroller.

In the block of hydroacoustic sensors, figure 3 sensors of temperature, water salinity are located in the lower part of the complex device and are connected by an electrical connection through a sealed inlet to the device with a microcontroller 3.3, the board of which is located inside the lower part of the complex device.

The first output of the microcontroller 3.3 is connected to the input of the water salinity sensor 3.2, and the output of the water salinity sensor 3.2 is connected to the first input of the microcontroller 3.3 through a sealed input by electrical communication using a cable.

The second output of the microcontroller 3.3 is connected to the input of the water temperature sensor 3.1, and the output of the water temperature sensor 3.1 is connected to the second input of the microcontroller 3.3 through a sealed input by electrical communication using a cable.

The third output of the microcontroller 3.3 is connected to the second input of the central microcontroller 4.1, and the second output of the latter with the third input of the microcontroller 3.3 is electrically connected using a cable.

Figure 4. presents a functional diagram of the control unit 4 shown in figure 1 (enlarged), including:

4.1 Central microcontroller.

4.2 Management Board

4.3 Direction orienting device.

4.4 Microcontroller.

Structurally, the control unit 4 of figure 1 is assembled on a single board and located inside the integrated device.

The first output of the central microcontroller 4.1 is connected to the first input of the microcontroller 1.5, and its fourth output is connected to the first input of the central microcontroller 4.1.

The second output of the central microcontroller 4.1 is connected to the third input of the microcontroller 3.3, and its third output is connected to the second input of the central microcontroller 4.1.

The third output of the central microcontroller 4.1 is connected to the first input of the control board 4.2, and its first output is connected to the third input of the central microcontroller 4.1.

The fourth output of the central microcontroller 4.1 is connected to the first input of the microcontroller 4.4, and its first output is connected to the fourth input of the central microcontroller 4.1.

The fifth input of the central microcontroller 4.1 is connected to the first output of the direction orienting device 4.3.

The first output of the microcontroller 4.4 is connected to the fourth input of the central microcontroller 4.1, and its fourth output is connected to the first input of the microcontroller 4.4.

The second output of the microcontroller 4.4 is connected to the first input of the video recording unit 2, and the first output of the video registration unit 2 is connected to the second input of the microcontroller 4.4.

The third output of the microcontroller 4.4 is connected to the first input of the positioning unit 5, and the first output of the positioning unit 5 is connected to the third input of the microcontroller 4.4.

The fourth output of the microcontroller 4.4 is connected to the first input of the transceiver unit 6, and the first output of the transceiver unit 6 is connected to the fourth input of the microcontroller 4.4.

The fifth output of the microcontroller 4.4 is connected to the second input of the control board 4.2, and the second output of the control board 4.2 is connected to the fifth input of the microcontroller 4.4.

The first output of the control board 4.2 is connected to the third input of the central microcontroller 4.1, and the third output of the central microcontroller 4.1 is connected to the first input of the control board 4.2.

The second output of the control board 4.2 is connected to the fifth input of the microcontroller 4.4, and the fifth output of the microcontroller 4.4 is connected to the second input of the control board 4.2.

The third output of the control board 4.2 is connected to the first input of the power supply 7, and the first output of the power supply 7 is connected to the third input of the control board 4.2

The fourth output of the control board 4.2 is connected to the first input of the device self-destruction unit.

The figure 5 presents a functional diagram of the video recording unit of figure 1 (enlarged), including:

2.1 DVR No. 1.

2.2 DVR No. 2.

2.3 DVR No. 3.

Structurally, the video recording unit 2 of figure 1 is located inside a transparent spherical fairing and is a horizontal board with three video recorders and connectors installed on it for decoupling control signals and removing signals with video information.

The first DVR is located in the center of the board and is designed to monitor the sky and clouds in a vertical plane. The other two DVRs are observing in a horizontal plane. The first output of the DVR 2 is connected to the second input of the microcontroller 4.4 of the control unit 4, and its output 2 is connected to the first input of the DVR 2.

The device operates as follows

The device program provides a 10-minute interrogation cycle of the central controller of the measuring sensors.

For an integrated device, there are two ways to use it:

1. Autonomous;

2. Using a carrier.

The stand-alone use is as follows:

The prepared integrated device is mounted on a carrier (for example, on a helicopter). The helicopter, being at a small height from the water surface at the point of setting the device, performs a reset upon command.

When separating from the resetting device, the toggle switch located on the device is turned on, and power is supplied from the power supply unit 7 to the control board 4.2 of the control unit 4. From the control board 4.2, power of the corresponding ratings is supplied to the blocks of the complex device.

After 20 seconds, which are necessary for splashing the device and stabilizing it on the sea surface, the complex device is brought into working condition. In the absence of commands from the media, the device operates offline. On command from the control unit 4 in accordance with the installed program, a survey of all sensors is performed. First of all, the video recording block is polled. From the central microcontroller 4.1, a signal is sent to the microcontroller 4.4, from which the control command is sent to the video recording unit. In the shutter line of the DVR shutter, delay lines with a selected delay time are used. Depending on the duration of the applied signal, those DVRs are selected for which the delay time is less than the duration of the control signal. Alternately with a time delay, environmental parameters are recorded. Therefore, the video information block is sequentially, but not immediately transmitted and processed. Secondly, a block of digital weather sensors is polled. From the central microcontroller 4.1, a control command is sent to microcontroller 1.5, which in turn performs polling and data collection from weather sensors in turn. The collected environmental parameters are supplied in a compact form by the unit to the input 1 of the central microcontroller 4.1. In the third turn, a block of hydroacoustic sensors is polled. From the central microcontroller 4.1, a control command is sent to the microcontroller 3.3, which in turn performs an interrogation of the water temperature sensor and the water salinity sensor. The data collected in a compact form by a data block are fed to input 2 of the central microcontroller 4.1.

The collected video and hydrometeorological data and the received signals from the positioning unit, direction orienting devices are sent to a miniature information carrier such as (flash memory) of control unit 4, and also through a microcontroller 4.4 to the transceiver unit for transmitting information over the communication channel. With the end of the operating time, reducing the voltage on the battery, the voltage is removed from the valve of the self-liquidation unit of the device and water through the open valve enters the device and floods it.

The method of use on the media is as follows:

The prepared integrated device is mounted on a carrier (for example, ship, ship, helicopter, coastal post).

In this case, the power and control of the integrated device is carried out by cable from the carrier. On command from the carrier, power is supplied to the control board 4.2 of the control unit 4, from the control board 4.2 power is supplied to the blocks of the complex device.

At a command from the carrier, a command is sent to the control unit to interrogate the sensors. By this command, from the control unit in accordance with the given command, a survey of all selected sensors is performed. The data collected through the cable connector is received for further processing and development of proposals for the effective use of radar.

Thus, the technical result of this utility model is to create a new modern device with advanced capabilities for monitoring the hydrometeorological situation and the possibilities of using it from a surface ship, ship, helicopter, unmanned vehicles (air, surface).

The claimed device is industrially applicable, since in its manufacture widespread devices and components, such as small-sized digital sensors, microcontrollers, microprocessors and flash memory cards, can be used.

In addition, it can be used outdoors and in any premises that require observation and collection of hydrometeorological information.

Claims (1)

An integrated device for measuring environmental parameters in the interests of radar, consisting of a body, direction and wind speed sensors, atmospheric pressure sensor, temperature and air humidity sensor, water temperature sensor, water salinity sensor; inside the case there is a transceiver unit, a power supply unit, a control unit, a positioning unit, characterized in that in the upper part of the device inside an airtight transparent sphere-shaped fairing there is an additionally built-in video recording unit; the antenna of the transceiver unit and ultrasonic sensors for determining the direction and speed of the wind are located at the corners of the upper part of the complex device outside the transparent fairing; in the upper part of the device’s case, on the sides there are sensors of atmospheric pressure, temperature and humidity; digital temperature and salinity sensors and a valve of the device’s self-liquidation unit are located in the lower part of the device’s body; on the side in the middle part of the device’s body there is a device for fastening to the carrier or mast of the coastal post and a sealed connector for receiving - issuing information, supplying power, charging the battery and checking the health of the device during routine maintenance; on the opposite side of the attachment device is a toggle switch for supplying power to the device.

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