KR100804549B1 - Buoylight using solar energy - Google Patents

Abstract

A buoylight using solar energy is provided to control a position of a buoyancy body and light emission of a light emitting unit in real time by including a GPS module and a remote controller, and to sense damage of the buoylight caused by partial or complete water immersion of the buoyancy body by including water pressure sensors. A buoylight(100) using solar energy comprises a first body(10), a second body(20) and a third body(30). The first body, the second body and the third body are respectively filled with buoyancy material(50) of polyurethane foam in the inside, and have a respective independent buoyancy module. The first body is loaded with a GPS module(13) and a remote controller(15) in the inside, and thus a position of a buoyancy body and light emission of a light emitting unit are remotely controlled in real time. The third body is equipped with a plurality of water pressure sensors(31), and is formed so as to sense damage of the buoylight caused by partial or complete water immersion of the buoyancy body.

Description

Buoylight using solar energy}

1 is a block diagram of a buoy using the solar energy according to the present invention,

2 is an internal configuration diagram of FIG. 1;

FIG. 3 is a block diagram illustrating a control system of an isogram using solar energy according to FIG. 1.

<Description of the symbols for the main parts of the drawings>

100: buoy

10: first body 11: top mark

111: light receiving sensor 12: light emitting means

13: GPS module 131: GPS transmitter / receiver

14: solar cell 15: remote control unit

20: second body 21: storage battery

22: wireless repeater

30: third body 31: water pressure sensor

32: weight balance 50: buoyancy material

200: base station 300: central control room

According to the present invention, the buoy body is made of a multi-stage independent buoyancy module, which can be height-adjusted according to a place (for example, an inner port or an outer port) which is not easily installed, and also generates power by solar light, thereby allowing remote control with self-luminous. Through the light emitting means can be controlled, and also through the GPS module to check the position, and through the pressure sensor to determine whether the storage of the buoy due to the damage to the buoy using a solar energy structure.

In general, buoys are installed in the ocean, and are usually formed to emit light at night, and are used for locating marine farms, offshore structures, etc., and guiding safe routes of ships.

Recently, it is also used for marine observation to explore marine ecological environment.

Such a buoy should normally be constructed so that the lamp can emit light with its own power. In the related art, it is inconvenient to frequently change the battery since the lamp can emit light depending only on a built-in battery.

Also, conventionally, the buoy is a structure that finds its position by causing the positioning to be reflected by the reflection plate attached to the buoy through the propagation direction detector. Therefore, the conventional buoy has a disadvantage that it is not possible to determine the position of the buoy in real time, it is not known whether the buoy is damaged or whether the head.

In addition, since the buoy body consists of a single body, the buoy body has a problem in that the buoy's function is reduced because the light of the sea surface and the buoy body is close to the buoy body so that the buoy body is close to the buoy body.

Therefore, the height of the buoy is composed of a multi-stage body that can be installed high according to the installation site, the buoy can generate power by itself to generate power, and in addition to control whether the light emitting means mounted in real time, and buoy According to the situation where a buoy is inclined or buried according to the damage of the buoy in real time to check the state of the buoy, and the structure of the buoy to know the exact position of the buoy through the GPS is required.

The present invention has been made in view of the above problems, an object of the present invention is to produce a power source by sunlight and can control the light emitting means through remote control with self-luminous, and also GPS module By checking the position, and through the pressure sensor to provide a buoy using the solar energy of the structure that can determine whether the storage of the buoy.

Furthermore, an object of the present invention is to adjust the height of the buoy body according to the place where the buoy body is composed of standardized multi-stage independent buoyancy module to improve the visibility of the light well, and even if any part is damaged It does not provide a buoy using the solar energy of the structure.

To solve the above technical problem is a buoy using solar energy,

In the buoy provided with a top mark on the top and a light emitting means under the

The upper part is provided with a light emitting means, the outer circumferential surface four sides of the rectangular first body in which the solar cell is mounted, and the cylindrical second body is mounted in the lower portion of the first body and stored in the battery by the solar cell inside And a third body configured to have a relatively larger diameter than the second body, floating in water, connected to the lower part of the second body, and having a weight balance protruding from the bottom surface thereof to be connected to the weight through the wire. Buoy body to be separated; consisting of, the first body, the second body and the third body is filled with a buoyant material of polyurethane foam, respectively, therein has an independent buoyancy module, the first body and the second The body is equipped with a GPS module and a remote control unit to check the position of the inside of the sun, characterized in that to remotely adjust the position of the buoy body and whether the light emitting means in real time Paper is achieved by using light buoy.

In the above, the buoy body is preferably a polyethylene material that absorbs shock, has excellent buoyancy, and is resistant to ultraviolet rays.

Preferably, any one of the first body and the second body is mounted with a wireless repeater electrically connected to the remote control unit.

The buoy body is preferably a polyethylene material that absorbs shock, has excellent buoyancy, and is resistant to ultraviolet rays.

In the third body, a plurality of pressure sensors are attached to the third body, and preferably configured to detect whether or not the damage of the back buoy according to the partial head or the full head of the buoy body.

The top mark is preferably equipped with a light receiving sensor that can blink the light emitting means itself.

The invention will become more apparent through the preferred embodiments described below with reference to the accompanying drawings. Hereinafter will be described in detail to enable those skilled in the art to easily understand and reproduce through embodiments of the present invention.

1 is a configuration diagram of an equal buoy using solar energy according to the present invention, Figure 2 is an internal configuration diagram of FIG.

As shown in Figure 1 and 2, the present invention can produce power by the sun light to control the light emitting means through remote control with self-luminous, and also to check the position through the GPS module, the water pressure sensor Through the buoy using solar energy of the structure that can determine whether the storage of the buoy through the buoy.

The back buoy consists of three parts, which are easy to disassemble and assemble, so that even if any part is broken, the buoy body (100) consisting of a multi-stage independent buoyancy module and the buoy body ( GPS module 13 embedded in 100, and a remote control unit 15 for remotely controlling the light emitting means (12).

Here, the buoy body 100 has a top mark 11 is formed at the upper end and the first body 10 is provided with a light emitting means 12 at the bottom, and a second body (in which the storage battery 21 is embedded) 20) and a structure that is separated into a third body 30, the weight balance 32 is connected to the bottom surface.

The buoy body 100 of the present invention is a three-stage independent module structure consisting of three separate bodies in an embodiment, but a plurality of the same body as the second body 20 depending on the place (for example, the inner or outer port) is installed. It can be configured to selectively change the height of the buoy body.

Such a structure has an advantage of increasing visibility of the buoy body 100 by increasing the height of the buoy body 100 when the buoy buoy is installed in the outer port of digging severely, since the light of the sea level and the buoy buoy is near.

Here, the top mark 11 formed at the upper end of the first body 10 is equipped with a light receiving sensor 111 that can blink the light emitting means 12 when sunlight is not irradiated at night. Any one of a CDS element made of a compound of cadmium (Cd) and sulfur (S), a phototube or a phototransistor can be selected and used.

In addition, the first body 10 is formed of a quadrilateral is formed in a square, the outer circumferential surface is a structure in which the solar cell 14 is mounted to convert the light energy into electrical energy in four directions. Since the solar cell 14 is in surface contact with the first body 10, the solar cell 14 is not damaged by external force.

In addition, the first body 10 has a structure in which the GPS module 13 capable of confirming the position of the buoy and the remote control unit 15 for controlling the blinking of the light emitting means 12 are embedded.

In addition, the second body 20 has a cylindrical shape and has a structure in which a storage battery 21 capable of storing electrical energy by the solar cell 14 is embedded therein. Therefore, the battery 21 of the second body 20 is the light receiving sensor 111, the solar cell 14, the light emitting means 12, the GPS module 13 and the remote control unit 15 of the first body 10. It is electrically connected with the structure.

The third body 30 is connected to the lower portion of the second body 20 and has a relatively larger diameter than the second body 20 so that the cross-sectional area in close contact with water can be smoothly floated in the water. It is configured to have a weight balance 32 is projected to the bottom surface is connected to the weight 33 stored on the bottom surface through a wire.

At this time, a plurality of pressure sensors 31 are attached to the outer circumferential surface of the water line of the third body 30 so that the buoy body 100 is inclined or damaged according to the water pressure detected by each pressure sensor 31. It is configured to detect the collection in real time.

At this time, the water pressure sensor 31 can be detected by the crest, it can be mounted on the first body 10 or the second body 20 is a matter of course. Here, the water pressure sensor 31 is also connected to the storage battery 21 and the remote control unit 15.

On the other hand, the first body 10, the second body 20 and the third body 30 is filled with a buoyancy material 50 of the polyurethane foam, respectively, each of which is configured to have a three-stage independent buoyancy module damaged any part Even if it is not easily built.

The polyurethane foam is sealed by the external impact by sealing the remote control unit 15, the battery 21, and the GPS module 13, which are built in contact with water, even if each body 10, 20, 30 is damaged. It can protect the structure.

In addition, the buoy body 100 is preferably made of a polyethylene material that absorbs shock, excellent buoyancy, and resistant to ultraviolet rays.

In addition, one of the first body 10 and the second body 20 of the buoy body 100 is preferably equipped with a wireless repeater 22 electrically connected to the remote control unit 15. The radio repeater 22 functions to transmit / receive data through the base station 200 on the ground.

Therefore, it is configured to control whether the light emitting means 12 is blinking through the remote control unit 15 wirelessly in the central control room 300 on the ground.

Meanwhile, since the buoy body 100 is divided into three bodies 10, 20, and 30, the function is limited to "back" to exclude the second body 20, and the first body 10 There is an advantage that can be used only by combining with the third body 30 has the advantage of very excellent compatibility.

In addition, as the technology is developed, the first body 10 and the third body 30 may be combined to be used while incorporating the above-described parts due to the miniaturization of the device.

In addition, although the GPS module 13 and the remote controller 15 have been described in the embodiment mounted on the first body 10, the GPS module 13 and the remote control unit 15 may be mounted on the second body 20.

In addition, as described above, the height of the back buoy may be increased by combining the fourth body (not shown), the fifth body (not shown), and the sixth body (not shown) to the upper and lower portions of the second body. .

FIG. 3 is a block diagram illustrating a control system of an isogram using solar energy according to FIG. 1.

As shown in FIG. 3, the GPS module 13 of the book list according to the present invention is equipped with a GPS transmitter / receiver 131 and is configured to independently identify data on the ground by transmitting and receiving data to and from a GPS satellite. .

In addition, the remote control unit 15 is configured to transmit / receive data with the base station 200 on the ground through the wireless repeater 22 embedded in the buoy body 100. In addition, the base station 200 on the ground is a structure that transmits / receives the central control room 300 that can control the remote control unit 15 of the book.

Therefore, the remote control unit 15 is configured to control whether the light emitting means 12 blinks separately from the ground, apart from the light receiving sensor 111 attached to the top mark 11 of the first body 10.

In addition, the back table of the present invention is configured so that the remote control unit 15 sends the data output from the plurality of water pressure sensors 31 to the ground to transmit the data to the central control room (300).

Accordingly, in the central control room 300, the data output from the respective hydraulic sensors 31 can be compared to determine whether the back mark is broken or the back of the back mark when the pressure falls below the standard water pressure.

As described above, according to the back buoy using the solar energy according to the present invention, it is possible to control the light emitting means through remote control in addition to the self-luminous power to produce power by the sunlight, and also to check the position through the GPS module, The water pressure sensor is characterized by the presence of the buoy due to the damage to the buoy.

In addition, the buoy body is composed of three-stage independent buoyancy module is easy to disassemble and assembly, there is an advantage that even if any one part is not broken.

In addition, when the back buoy is installed in a severe digging port, the fourth body, the fifth body, and the sixth body which are the same as the second body can be combined with the buoy body to prevent the light of sea level and the back buoy from being close to each other, thereby improving the visibility of the light. There is a characteristic.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

Claims (5)

In the buoy in which the top mark 11 is formed at the top and the light emitting means 12 is provided at the bottom thereof, The upper part is provided with a light emitting means 12, the outer circumferential surface four sides of the first body 10 is mounted to the solar cell 14 is mounted, the lower body of the first body 10 is mounted inside the solar cell ( The second body 20 of the cylindrical body in which the battery 21 for storing the electrical energy generated by the 14 and the built-in, having a relatively larger diameter than the second body 20 is suspended in water, Buoy body 100 is connected to the lower portion of the second body 20, the weight balance 32 is protruded to the bottom and separated into a third body 30 is connected to the weight 33 through a wire; Including but not limited to, The first body 10, the second body 20 and the third body 30 is filled with a buoyancy material 50 of polyurethane foam, respectively, to have an independent buoyancy module, The first body 10 has a GPS module 13 and a remote control unit 15 mounted therein to check the position of the buoy body 100 in real time and whether the light emitting means 12 emits light remotely. To the The third body 30 has a plurality of pressure sensors 31 are attached to the solar energy, characterized in that configured to detect the damage of the back buoy according to the partial or complete head of the buoy body 100 The back chart used. The method of claim 1, The buoy body 100 absorbs shock, excellent buoyancy, and back buoy using solar energy, characterized in that the polyethylene material resistant to ultraviolet rays. The method of claim 1, One of the first body (10) and the second body (20) of the back of the solar energy, characterized in that the wireless repeater 22, which is electrically connected to the remote control unit 15 is mounted. The method of claim 1, The top mark 11 is a back table using solar energy, characterized in that the light receiving sensor 111 that can flash the light emitting means 12 itself is mounted. delete

Images