CN217477512U - AIS navigation mark information broadcasting device - Google Patents

Abstract

The utility model discloses an AIS (automatic identification system) beacon information broadcasting device, which relates to the technical field of beacon information broadcasting and aims to realize AIS beacon navigation information broadcasting with low power consumption and lasting power supply, and comprises a plurality of solar panels, a shell, a charging module, a ternary lithium battery power supply module, an AIS radio frequency board, a communication antenna, a battery/communication antenna control panel, a GPS (global positioning system) antenna and a VHF (very high frequency) antenna, wherein the charging module, the ternary lithium battery power supply module, the AIS radio frequency board, the communication antenna, the battery/communication antenna control panel, the GPS antenna and the VHF antenna are arranged in the shell; the solar panel is fixed outside the shell; the three-element lithium battery power supply module, the AIS radio frequency board and the battery/communication antenna control board are fixed together, and the three-element lithium battery power supply module is clamped between the AIS radio frequency board and the battery/communication antenna control board; the communication antenna is connected to the battery/communication antenna control board; the GPS antenna and the VHF antenna are respectively connected to the AIS radio frequency board; the GPS antenna and the VHF antenna are arranged on the top of the shell; the utility model has the advantages of practice thrift the energy consumption, prolong battery continuation of the journey, can broadcast fairway buoy running state and hydrometeorology information.

Description

AIS navigation mark information broadcasting device

Technical Field

The utility model relates to a technical field is broadcast to the fairway buoy information, and more specifically relates to a technical field is broadcast to AIS fairway buoy information.

Background

The navigation mark is mainly used for helping to guide a ship to sail, locate and mark an obstacle and a manual mark for warning, and provides facilities or systems with safety information for various water activities. Is arranged in or near a navigation water area to mark the positions of a navigation channel, an anchorage ground, a beach risk and other navigation obstacles.

The navigation mark usually completes its own work by receiving and sending different radio signals, and needs to be placed in a work place for a long time, and if the power consumption of the navigation mark is too high or the battery needs to be replaced or charged frequently, the operation of the navigation mark is troublesome and troublesome.

Therefore, on the basis of ensuring that navigation aid information such as navigation mark running state, hydrological meteorological information and the like is normally broadcast, the navigation mark has lasting and stable endurance and low power consumption, and becomes an important device design link.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: the AIS navigation aid information broadcasting with low power consumption and lasting power supply is realized. In order to solve the technical problem, the utility model provides a device is broadcast to AIS fairway buoy information.

The utility model discloses a realize above-mentioned purpose and specifically adopt following technical scheme:

an AIS (automatic identification system) navigation mark information broadcasting device comprises a plurality of solar panels, a shell, a charging module, a ternary lithium battery power supply module, an AIS radio frequency board, a communication antenna, a battery/communication antenna control board, a GPS (global positioning system) antenna and a VHF (very high frequency) antenna, wherein the charging module, the ternary lithium battery power supply module, the AIS radio frequency board, the communication antenna, the battery/communication antenna control board, the GPS antenna and the VHF antenna are arranged in the shell;

the charging port of the charging module is connected to the input end of the ternary lithium battery power supply module, the power supply ends of the solar panel and the ternary lithium battery power supply module are connected to the power supply ports of the AIS radio frequency board and the battery/communication antenna control board, and the switch ports of the AIS radio frequency board, the solar panel and the ternary lithium battery power supply module are respectively connected to the control port of the battery/communication antenna control board;

the solar panel is fixed outside the shell; the ternary lithium battery power supply module, the AIS radio frequency board and the battery/communication antenna control board are fixed together and vertically arranged in the shell, and the ternary lithium battery power supply module is clamped between the AIS radio frequency board and the battery/communication antenna control board;

the communications antenna is connected to the battery/communications antenna control board; the GPS antenna and the VHF antenna are respectively connected to the AIS radio frequency board; the GPS antenna is mounted on the top inside the housing, and the VHF antenna is mounted on the top outside the housing.

Preferably, the communications antenna is connected to the battery/communications antenna control board through an SMA socket.

Preferably, said GPS antenna and said VHF antenna are connected to said AIS radio frequency board through SMA sockets, respectively.

Preferably, shielding cases are respectively arranged on the AIS radio frequency board and the battery/communication antenna control board.

Preferably, the ternary lithium battery power supply module is arranged between the AIS radio frequency board and the battery/communication antenna control board, one long stud bolt penetrates through the upper ends of the AIS radio frequency board and the battery/communication antenna control board, the other long stud bolt penetrates through the lower ends of the AIS radio frequency board and the battery/communication antenna control board, and the two long stud bolts are both fixed with the AIS radio frequency board and the battery/communication antenna control board through nuts.

Preferably, jelly glue is filled and sealed in the shell.

Preferably, the charging module comprises a wireless charging module and a wired charging module.

Preferably, the number of solar panels is 4.

Preferably, the communication antenna is 433.

Preferably, the system further comprises at least one acquisition interface connected to the battery/communication antenna control board.

The utility model has the advantages as follows:

the utility model provides a combined power supply of a solar panel and a ternary lithium battery power supply module, mainly using the solar panel, reducing the power consumption of the ternary lithium battery power supply module in daily life, and reducing the charging frequency of the ternary lithium battery power supply module; the utility model fixes the ternary lithium battery power supply module, the AIS radio frequency board and the battery/communication antenna control board together, thereby saving the installation space; the utility model also reduces the signal noise through the shielding case; the utility model has simple internal arrangement, only the AIS radio frequency board and the battery/communication antenna control board need to supply power, the power consumption is lower, and the cruising ability of the battery of the device is further improved; the utility model has firm structure and high reliability by sealing the tank with jelly glue; the utility model discloses can realize the external broadcasting of information such as fairway buoy positional information, fairway buoy running state information, hydrology meteorological information, extensive applicability.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic view of the present invention;

reference numerals: 101-shell, 102-shield, 103-AIS radio frequency board, 104-GPS antenna, 105-VHF antenna, 106-communication antenna, 107-battery/communication antenna control board, 108-ternary lithium battery power supply module, 109-wireless charging module, 109 a-wireless charging board, 109 b-charging coil.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Example 1

As shown in fig. 1 to 2, the present embodiment provides an AIS beacon information broadcasting device, which includes a plurality of solar panels, a housing 101, and a charging module, a ternary lithium battery power supply module 108, an AIS radio frequency board 103, a communication antenna 106, a battery/communication antenna control board 107, a GPS antenna 104, and a VHF antenna 105 disposed inside the housing 101;

the charging port of the charging module is connected to the input end of the ternary lithium battery power supply module 108, the power supply ends of the solar panel and the ternary lithium battery power supply module 108 are both connected to the power supply ports of the AIS radio frequency board 103 and the battery/communication antenna control board 107, and the switch ports of the AIS radio frequency board 103, the solar panel and the ternary lithium battery power supply module 108 are respectively connected to the control port of the battery/communication antenna control board 107;

the solar panel is fixed outside the shell 101; the three-element lithium battery power supply module 108, the AIS radio frequency board 103 and the battery/communication antenna control board 107 are fixed together and vertically installed in the shell 101, and the three-element lithium battery power supply module 108 is clamped between the AIS radio frequency board 103 and the battery/communication antenna control board 107;

the communication antenna 106 is connected to the battery/communication antenna control board 107; the GPS antenna 104 and the VHF antenna 105 are respectively connected to the AIS radio frequency board 103; the GPS antenna 104 is mounted on top inside the housing 101, and the VHF antenna 105 is mounted on top outside the housing 101.

In this embodiment, the communication antenna 106 is connected to the battery/communication antenna control board 107 through an SMA socket; likewise, the GPS antenna 104 and the VHF antenna 105 may also be connected to the AIS radio frequency board through SMA sockets, respectively.

In order to prevent signal interference, shielding cases 102 are respectively disposed on the AIS radio frequency board 103 and the battery/communication antenna control board 107.

In order to fix the three-element lithium battery power supply module 108, the AIS radio frequency board 103 and the battery/communication antenna control board 107 which are arranged together, the three-element lithium battery power supply module 108 is arranged between the AIS radio frequency board 103 and the battery/communication antenna control board 107, one stud bolt penetrates through the upper ends of the AIS radio frequency board 103 and the battery/communication antenna control board 107, the other stud bolt penetrates through the lower ends of the AIS radio frequency board 103 and the battery/communication antenna control board 107, and the two stud bolts are both fixed with the AIS radio frequency board 103 and the battery/communication antenna control board 107 through nuts.

To indicate the stability and robustness of the entire device, jelly glue may be potted within the housing 101.

In addition, the communication antenna 106 may be a 433 communication antenna.

On the other hand, the charging module may include a wireless charging module 109 and a wired charging module, so that a user may charge the ternary lithium battery power supply module 108 in two ways, and during wired charging, the charging module is externally connected with a charging power supply through a set interface, and the charging power supply charges the ternary lithium battery power supply module 108; the wireless charging module 109 generally includes a charging coil 109b and a wireless charging pad 109a to enable wireless charging. In particular, the schematic diagram of fig. 2 mainly shows a related schematic diagram for implementing the control function.

Finally, as the preferred scheme of this embodiment, the quantity of solar panel is 4, realizes solar energy power supply by 4 solar panels.

The device is broadcast to AIS fairway buoy information of this embodiment when using, be the power supply of AIS radio frequency board 103 and battery/communication antenna control panel 107 by polylith solar panel or ternary lithium cell power supply module 108, normally supply by solar panel, just switch when not enough solar panel electric energy and supply power by ternary lithium cell power supply module 108, specific switching control is realized by battery/communication antenna control panel 107, thereby realize energy-conservingly, reduce ternary lithium cell power supply module 108's power consumption, so that can also reduce the frequency of charging, the duration of the device has been promoted, can charge for it through the module of charging when ternary lithium cell power supply module 108 electric energy is not enough.

The function of the device is realized mainly by the power supply of a communication antenna 106, a GPS antenna 104, a VHF antenna 105, an AIS radio frequency board 103 and a battery/communication antenna control board 107, wherein the GPS antenna is used for acquiring positioning information, the battery/communication antenna control board 107 and the communication antenna 106 plugged on the battery/communication antenna control board are responsible for short-distance remote control signals, the battery/communication antenna control board 107 is used for processing and generating short-distance remote control signals, and the communication antenna 106 is responsible for sending out the signals; the AIS radio frequency board 103 is used to transmit an AIS signal, which is an alarm indication signal, and then broadcasts the signal through the VHF antenna 105.

On the other hand, whole device simple structure, the space occupy-place is little, still seals the jar through jelly glue, sound construction, and the reliability is high.

Example 2

This example is based on the solution of example 1.

In this embodiment, at least one acquisition interface is further included, connected to the AIS radio frequency board 103.

The acquisition interface is used for acquiring the navigation mark running state and/or the hydrological data, the navigation mark running state can comprise solar panel voltage, solar charging current, lithium battery residual capacity, lamp working current and the like, and the hydrological data can comprise water flow velocity, flow direction, wave period and the like.

Meteorological data such as wind speed and direction, air temperature, air pressure, visibility and the like can be acquired through the acquisition interface; and water quality data such as water temperature, salinity, turbidity, dissolved oxygen, PH, oil spill, etc.

Then, the battery/communication antenna control board 107 monitors and judges related data to realize real-time monitoring, and the AIS radio frequency board 103 and the VHF antenna 105 realize marine autonomous broadcasting of collected information such as the operation state of the navigation mark, the hydrometeorology and the like, and can also set an information broadcasting scheme according to data conditions. The number of the specific acquisition interfaces can be set according to the specific acquisition monitoring scheme.

Claims (10)

1. The AIS beacon information broadcasting device is characterized by comprising a plurality of solar panels, a shell (101), a charging module, a ternary lithium battery power supply module (108), an AIS radio frequency board (103), a communication antenna (106), a battery/communication antenna control board (107), a GPS antenna (104) and a VHF antenna (105), wherein the charging module, the ternary lithium battery power supply module, the GPS antenna and the VHF antenna are arranged in the shell (101);

the charging port of the charging module is connected to the input end of the ternary lithium battery power supply module (108), the power supply ends of the solar panel and the ternary lithium battery power supply module (108) are connected to the power supply ports of the AIS radio frequency board (103) and the battery/communication antenna control board (107), and the switch ports of the AIS radio frequency board (103), the solar panel and the ternary lithium battery power supply module (108) are respectively connected to the control port of the battery/communication antenna control board (107);

the solar panel is fixed outside the shell (101); the ternary lithium battery power supply module (108), the AIS radio frequency board (103) and the battery/communication antenna control board (107) are fixed together and vertically installed in the shell (101), and the ternary lithium battery power supply module (108) is clamped between the AIS radio frequency board (103) and the battery/communication antenna control board (107);

the communications antenna (106) is connected to the battery/communications antenna control board (107); -said GPS antenna (104) and said VHF antenna (105) are respectively connected to said AIS radio frequency board (103); the GPS antenna (104) is mounted on the top inside the casing (101), and the VHF antenna (105) is mounted on the top outside the casing (101).

2. The AIS beacon information dissemination device according to claim 1, wherein said communication antenna (106) is connected to a battery/communication antenna control board (107) through an SMA socket.

3. The AIS beacon information dissemination device according to claim 1, characterized in that said GPS antenna (104) and said VHF antenna (105) are connected to said AIS radio frequency board (103) through SMA sockets, respectively.

4. The AIS beacon information dissemination device according to claim 1, wherein said AIS radio frequency board (103) and said battery/communication antenna control board (107) are provided with shielding cages (102), respectively.

5. The AIS beacon information broadcasting device according to claim 1, wherein the ternary lithium battery power supply module (108) is arranged between the AIS radio frequency board (103) and the battery/communication antenna control board (107), one long stud bolt penetrates through the upper ends of the AIS radio frequency board (103) and the battery/communication antenna control board (107), the other long stud bolt penetrates through the lower ends of the AIS radio frequency board (103) and the battery/communication antenna control board (107), and both long stud bolts are fixed with the AIS radio frequency board (103) and the battery/communication antenna control board (107) through nuts.

6. The AIS beacon information dissemination device according to claim 1 wherein said housing (101) is potted with jelly glue.

7. The AIS beacon information dissemination device according to claim 1, wherein said charging module comprises a wireless charging module (109) and a wired charging module.

8. The AIS beacon information broadcasting device of claim 1, wherein the number of solar panels is 4.

9. The AIS beacon information dissemination device according to claim 1, wherein said communication antenna (106) is a 433 communication antenna.

10. The AIS beacon information dissemination device according to claim 1, further comprising at least one data acquisition interface connected to said AIS radio frequency board (103).

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