KR102377558B1 - Cores for GPS-based ocean position tracking device - Google Patents

Abstract

The present invention relates to a core for a GPS-based marine positioning device. According to the present invention, the core for a GPS-based marine positioning device comprises: a lower casing having a lower casing body, holding pipes provided on both outer peripheral surfaces of the lower casing body, a plurality of lower battery pocket members, a weight receiving pocket, and a plurality of seawater resistance blades; a battery embedded in the lower battery pocket member; a weight built into the weight receiving pocket; a lower plug coupled to a plug coupling hole; an inner plate having an inner plate body, a protrusion part, and a mounting part; a GPS transceiver module provided on an upper surface of the protrusion part; a cover provided on an upper portion of the mounting part; a transparent upper casing coupled to an upper end of the lower casing body; a sealing member interposed between the upper outer peripheral surface of the lower casing body and a lower inner peripheral surface of the transparent upper casing; and a controller provided on a lower surface of the protrusion part to control the battery and the GPS transceiver module, respectively. Accordingly, since the core is equipped with an ocean current resistance blade so that it can track the marine oil pollution accident area in real time while moving along with the oil pollutants moved by the ocean current, as well as being able to use it in combination with various types of buoyancy devices.

Description

Cores for GPS-based ocean position tracking device}

The present invention relates to a core for a GPS-based marine positioning device. More particularly, the present invention relates to a core installed in a GPS-based marine location tracking device that can track a marine oil pollution accident area in real time while moving along with oil pollutants moved by ocean currents.

Republic of Korea Patent No. 2051547 (registration date: 2019.11.27., title of invention: IOT-based smart buoy) is a buoy that floats on the surface of the ocean and can communicate with the outside using a communication network. A pair of first upper and lower housings 100 and 200 that form an accommodating space and are provided with a sensor unit 210 and a transmitting/receiving antenna 110 to transmit detection information of the sensor unit to an external server and receive a control signal from an external server ); a pair of second upper and lower housings 300 and 400 disposed in a double structure inside the pair of first upper and lower housings 100 and 200; and a photovoltaic panel 330 provided in the second upper and lower housings 300 and 400, an energy storage unit 430 for storing power generated by the solar panel, and the sensor unit 210 for the power of the energy storage unit. ) and a control unit 440 for controlling the operation and controlling the transmission/reception information of the transmission/reception antenna 110 , and the first upper housing 100 includes the first upper and lower housings 100 and 200 . A moisture removal unit 600 for removing the generated moisture is provided, and the second lower housing 400 is provided at the edges of the second lower housing body 410 and the second lower housing body 410 and the second It includes a second lower flange 420 that faces the edge of the upper housing 300 , and the second lower flange 420 can be seated on the inner surface of the first lower housing 200 , and in the seated state A seating plate 270 protrudes to form a separation space between the lower surface of the second lower housing 400 and the inner surface of the first lower housing 200 , and the first lower housing 200 and the second upper housing 300 . ) and the second lower housing 400 are IoT-based, characterized in that a moisture discharge unit 700 for inducing moisture from the upper side of the second upper housing 300 to the inner region of the first lower housing 200 is provided. A smart buoy is disclosed.

In this prior art, by providing a moisture removal unit in the first upper housing, when moisture occurs in the first upper and lower housings, it is possible to efficiently remove moisture by supplying external air, and to prevent abnormal operation and damage to internal electrical components. However, it is not possible to move according to the current and the housing and the control unit are integrally formed, so maintenance is difficult.

An object of the present invention, created to solve the above problems, is to provide a core for a GPS-based marine location tracking device that can track a marine oil pollution accident area in real time while moving along with oil pollutants moved by ocean currents is to do In addition, an object of the present invention is to provide a core that can be used in combination with various types of buoyancy devices.

An object of the present invention is a hollow structure with an open upper surface, a lower casing body having a plug coupling hole formed in the center of the lower surface, holding pipes provided on both outer peripheral surfaces of the lower casing body, and an upper surface inside the lower casing body A plurality of lower battery pocket members formed to be opened, a lower surface communicating with the plug coupling hole, a weight receiving pocket provided inside the lower side of the lower casing body, and a plurality of seawater resistance provided on the lower surface of the lower casing body a lower casing having a blade; a battery embedded in the lower battery pocket member; a weight built into the weight receiving pocket; a lower plug coupled to the plug coupling hole; An inner plate body located on the upper portion of the lower battery pocket member, a protrusion formed in the center of the upper surface of the inner plate body, and a mounting portion mounted on the upper end of the lower casing body with the edge of the inner plate body expanding upwards an inner plate; a GPS transceiver module provided on the upper surface of the protrusion; a cover provided on an upper portion of the holder; a transparent upper casing coupled to the upper end of the lower casing body; a sealing member interposed between the upper outer circumferential surface of the lower casing body and the lower inner circumferential surface of the transparent upper casing; It can be achieved by a core for a GPS-based marine positioning device comprising a controller provided on the lower surface of the protrusion to control each of the battery and the GPS transceiver module.

Preferably, the cover of the present invention further comprises a plurality of lamp brackets on the upper surface, further comprising an illuminance sensor provided in the center of the upper surface of the cover, further comprising an LED lamp mounted on the lamp bracket,

The illuminance sensor and the LED lamp are each controlled by the controller.

Preferably, the lower casing of the present invention further includes a plurality of dimples formed around the plug coupling hole, and the seawater resistance blade is provided in the dimples.

Preferably, the weight of the present invention is made of a metal material, a through hole is formed in the center portion, and the lower plug further comprises a support column formed on the upper surface to be inserted into the through hole of the weight. do.

As described above, the present invention has an effect of tracking the marine oil pollution accident area in real time while moving along with the oil pollutants moved by the current by providing the current resistance blade. In addition, the present invention has a feature that can be used in combination with various types of buoyancy devices.

1 is a perspective view showing a core for a GPS-based marine location tracking device according to an embodiment of the present invention.
Figure 2 is a bottom view showing a state in which the lower plug of the core for the GPS-based marine positioning device of Figure 1 is removed.
3 is an exploded perspective view of FIG. 1 ;
4 is a perspective view illustrating a cover, an LED lamp, and an illuminance sensor of FIG. 3 .
5 is a perspective view showing a state in which the GPS-based marine positioning device core according to the present invention is mounted on the buoyancy device.
6 is an exploded perspective view of FIG. 5 ;

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 to 4, the core 100 for a GPS-based marine positioning device according to the present invention is a lower casing 10, an inner plate 20, a cover 30, a transparent upper casing 40, a battery (BTY), lower plug 50, sealing member 60, LED lamp (led), illuminance sensor (lux), GPS transceiver module (gps), weight (W), and consists of a controller (CTB).

The lower casing 10 is a hollow structure with an open upper surface, and a lower casing body 11 having a plug coupling hole 11a formed in the center of the lower surface and a plurality of dimples 11b formed around the plug coupling hole 11a. And, a holder tube 12 provided on both outer peripheral surfaces of the lower casing body 11, a plurality of lower battery pocket members 13 formed so that the upper surface is opened inside the lower casing body 11, and the lower surface is a plug It communicates with the coupling hole 15a and consists of a weight receiving pocket 15 provided inside the lower side of the lower casing body 11, and a seawater resistance blade 17 provided inside the dimple 11b, respectively.

The lower casing body 11 is made of a plastic material, and has a cylindrical shape as a whole, and a lower part is formed in a semi-sphere shape. In addition, the lower casing body 11 is formed with a fastening thread (no number) on the outer periphery of the upper end. In addition, four dimples 11b are formed in the lower part of the lower casing body 11 .

In the lower battery pocket member 13 , three pockets form a pair and four are formed inside the lower casing body 11 .

The plug coupling hole 15a is formed with a thread (no number) on the inner periphery.

The dimple 11b is formed in a rectangular shape.

The seawater resistance blades 17 are formed one by one in the longitudinal direction of the dimples 11b, and each seawater resistance blade 17 is formed at an angle of 0°, 90°, 180° and 270°. Here, the seawater resistance blade 17 is provided to move along with the oil contaminants that collide with the seawater and are moved by the sea current.

The battery BTY is embedded in the lower battery pocket member 13 . Here, 12 batteries 40 are embedded in the lower battery pocket member 13 .

The weight (W) is built in the weight receiving pocket (15).

Here, the weight W is made of a metal material in which a through hole Wh is formed in the center portion.

The lower plug 50 is coupled to the plug coupling hole 15a.

Here, the lower plug 50 is provided to prevent the weight W from being separated from the weight receiving pocket 15 .

In addition, the lower plug 50 has a support column 50a formed on its upper surface, and the support column 50a is inserted into the through hole Wh of the weight W to prevent the weight W from swinging. prevent.

The inner plate 20 includes an inner plate body 21 located on the upper portion of the lower battery pocket member 13 , a protrusion 23 formed in the center of the upper surface of the inner plate body 21 , and the inner plate body 21 . The edge of the tube is expanded to the upper part and consists of a holder 25 mounted on the upper end of the lower casing body 11 .

A GPS transceiver module (gps) is provided on the upper surface of the protrusion 23 .

Here, since the GPS transmission/reception module (gps) is a well-known component, a detailed description or illustration thereof will be omitted. In addition, the GPS transceiver module (gps) is embedded in the lower casing body 11, which is a higher position than the holder tube 12 provided on the outer circumferential surface of the lower casing body 11 .

The cover 30 is provided with a plurality of lamp brackets 31 on the upper surface and is seated on the upper portion of the mounting unit 25 .

The illuminance sensor (lux) is provided at the center of the upper surface of the cover 30 .

An LED lamp (led) is provided on the lamp bracket (31). Here, a total of three LED lamps (led) are provided, one for every 120° based on the illuminance sensor (lux).

The transparent upper casing 40 has a protruding handle 41 formed on the central upper surface and is fastened to the upper end of the lower casing body 11 .

The sealing member 60 is interposed between the upper outer peripheral surface of the coupled lower casing body 11 and the lower inner peripheral surface of the transparent upper casing 40 .

A controller (CTB) is provided on the lower surface of the protrusion (21) to control the battery (BTY), the GPS transceiver module (gps), the illuminance sensor (lux) and the LED lamp (led), respectively.

The controller (CTB) detects the illuminance through the illuminance sensor (lux) to control the on or off of the LED lamp, receives the real-time location from the GPS satellite, and transmits the location of the oil accident area in real-time.

5 and 6, the GPS-based marine positioning device core 100 according to the present invention shows a state mounted on the annular buoyancy device 200.

Here, the buoyancy device 200 may be made of a material having a specific gravity smaller than that of water, such as synthetic resin material, wood, etc., and may have a hollow structure inside depending on the purpose of use.

Since the support protrusion 230 provided on the inner circumferential surface of the buoyancy device 200 has a structure that is inserted into the holder tube 12, the core 100 for a GPS-based marine location tracking device according to the present invention can move smoothly depending on the seawater. There is, but is mounted so as not to be separated from the buoyancy device (200).

In addition, in order to transmit and receive the desired GPS signal of the GPS transceiver module (gps), the GPS transceiver module (gps) must be located above the sea level regardless of weather conditions or the flow of seawater. To this end, a buoyancy device 200 having a suitable buoyancy is required, and even if the core 100 for a GPS-based marine location tracking device fluctuates by the weight W, it always returns to an upright original position like Ottogi. should be able to be

Although the present invention as described above is limited to one embodiment, it is clear that all embodiments modified based on the technical idea of the present invention are not limited thereto and fall within the scope of the present invention.

10: lower casing 20: inner plate
30: cover 40: transparent upper casing
50: lower plug 60: sealing member
led : LED lamp lux : Illuminance sensor
gps: GPS transceiver module W: weight
CTB : Controller
100: Core for GPS-based marine positioning device
200: buoyancy device

Claims (4)

A hollow structure with an open upper surface, a lower casing body having a plug coupling hole formed in the center of the lower surface, holding pipes provided on both outer peripheral surfaces of the lower casing body, and a plurality of lower portions formed so that the upper surface is opened inside the lower casing body a lower casing having a battery pocket member, a lower surface communicating with the plug coupling hole, a weight receiving pocket provided inside a lower side of the lower casing body, and a plurality of seawater resistance blades provided on a lower surface of the lower casing body;
a battery embedded in the lower battery pocket member;
a weight built into the weight accommodating pocket;
a lower plug coupled to the plug coupling hole;
An inner plate body located on the upper portion of the lower battery pocket member, a protrusion formed in the center of the upper surface of the inner plate body, and a mounting portion mounted on the upper end of the lower casing body with the edge of the inner plate body expanding upwards an inner plate;
a GPS transceiver module provided on the upper surface of the protrusion;
a cover provided on an upper portion of the holder;
a transparent upper casing coupled to the upper end of the lower casing body;
a sealing member interposed between the upper outer circumferential surface of the lower casing body and the lower inner circumferential surface of the transparent upper casing;
It consists of a controller provided on the lower surface of the protrusion to control each of the battery and the GPS transceiver module,
The lower plug core for GPS-based marine positioning device, characterized in that it further comprises a support column formed on the upper surface to be inserted into the through hole of the weight.
The method of claim 1,
The cover further comprises a plurality of lamp brackets on the upper surface,
Further comprising an illuminance sensor provided in the center of the upper surface of the cover,
Further comprising an LED lamp mounted on the lamp bracket,
The illuminance sensor and the LED lamp are each controlled by the controller.
The method of claim 1,
The lower casing further includes a plurality of dimples formed around the plug coupling hole,
The seawater resistance blade is a GPS-based marine positioning device core, characterized in that provided in the dimple.
The method of claim 1,
The weight is made of a metal material and a core for a GPS-based marine positioning device, characterized in that a through hole is formed in the center portion.

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