KR20120032124A - A ocean buoy - Google Patents

Abstract

PURPOSE: An ocean buoy is provided to stably moor an oceanographic observation device in the water and protect the oceanographic observation device from damage. CONSTITUTION: An ocean buoy comprises a float(1), a tension sensor(12), a driving source, a float inner pipe(20), and a device connection loop(24). The float is floated on the sea surface. The tension sensor senses the tension of a rope connected to the bottom of the float. The driving source provides power to move the rope in a vertical direction in response to a signal from the tension sensor. The float inner pipe is installed in the vertical direction inside the float and allows the rope to be passed and wound around the float. The device connection loop is installed on one side of the rope and holds an oceanographic observation device.

Description

A marine buoy

The present invention relates to an ocean buoy, and more particularly, to an ocean observing device such as a data logger for physics and stoichiometric observation of seawater, such as seawater flow, water temperature, salinity, and electrical conductivity. The present invention relates to a marine buoy for use in preventing foam diffusion that may occur.

Conventional marine buoys have usually been used by connecting styrofoam parts or spherical plastic buoys directly on the anchor wire. However, when mooring marine observation equipment using these buoys, it is difficult to connect the observation equipment to the buoys, and it was not easy to recover the equipment after the observation. And the fishing buoys commonly used by fishermen were not easy to identify.

In addition, it was difficult to obtain reliable data as buoys moved by various environments such as tides and waves. In addition, the observation equipment is suspended above the floating body and hangs down to the surface of the water, causing the rope hanging from the floating body and the observation equipment to be broken by friction or the rope hanging from the anchor line and the observation equipment. Or there is a problem that can not make accurate observation because the posture of the observation equipment is unstable.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, to facilitate the installation and recovery of the observation equipment during the underwater mooring of the observation equipment and to avoid the horizontal movement of the marine buoy by the algae and waves, etc. To provide a marine buoy that can minimize the displacement of the marine buoy.

Another object of the present invention is to provide a marine buoy that can solve the problem that the connected string is broken or entangled due to the torsional moment in use by connecting a plurality of buoys.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

According to a feature of the present invention for achieving the object as described above, the present invention is a floating body that is supported on the sea surface; A tension sensor for sensing the tension of the rope connected to the lower end of the float; A driving source receiving power from the tension sensor and providing power for moving the rope in a vertical direction; A floating inner tube installed to penetrate the inside of the floating body in a vertical direction, the moving rope passing through the floating body along the outer surface of the floating body; It is mounted on one side of the moving rope, and includes an equipment connecting hook to the marine observation equipment.

The floating inner tube is installed in a straight or curved shape inside the floating body.

The outer surface of the floating body is characterized in that at least one or more sensors for detecting the position of the connection ring is mounted.

An upper sensor and a lower sensor for detecting the position of the equipment connection ring are mounted at portions adjacent to the upper and lower portions of the floating body, respectively.

A motor having a motor shaft connected to the moving rope is installed inside the floating body to provide power required for the movement of the moving rope.

When the upper sensor and the lower sensor detects the position of the equipment connection ring is characterized in that for transmitting the stop signal to the motor.

A solar cell is installed at an upper end of the floating body, and a battery receiving electric power from the solar cell is installed in the floating body to transfer power to the driving source.

Rope connectors are connected to the side of the float is connected to the rope, the rope connector is characterized in that rotatably connected via a bearing shoe.

According to another feature of the invention, the present invention is a floating body that is buoyant; A tension sensor for sensing the tension of the rope connected to the lower end of the float; A driving source receiving power from the tension sensor and providing power for moving the rope in a vertical direction; A moving belt wound and moved around a roller rotatably installed on upper and lower outer surfaces of the floating body; It is mounted on one side of the moving belt is moved together in accordance with the movement of the moving belt, and includes an equipment connecting hook to the marine observation equipment.

According to the present invention, the equipment link provided at the bottom of the floating body is designed to move up to the proper position for mooring and move back to its original position so that the marine observation equipment can be stably moored in water and reduce the possibility of damage by others and recover the equipment. It has an easy effect.

In addition, according to the present invention, by attaching a bearing shoe bell to the rope connector to interconnect the buoys there is an effect that can be prevented from being broken or entangled due to the torsion moment when using a plurality of buoys connected.

1 is a side view schematically showing an ocean buoy according to an embodiment of the present invention.
Figure 2 is a side view schematically showing a marine buoy according to another embodiment of the present invention.

Hereinafter, an embodiment of a multipurpose marine buoy according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a side view schematically showing a marine buoy according to an embodiment of the present invention.

Referring to this, the overall appearance of the marine buoy according to the present invention is formed by a spherical floating body (1) that is supported on the sea surface. The floating body 1 is made by, for example, joining two hollow hemispheres, and the floating body 1 is generally made of a metal or plastic material of steel or alloy having strength and corrosion resistance. In addition, the inside of the floating body 1 is filled with foamed styrofoam to maintain the required buoyancy and rigidity.

The radio receiver 2 is provided at the upper end of the floating body 1. In addition, a night indicator 4 is provided at the top of the floating body 1 so that the viewer can easily identify the position of the marine buoy at night by emitting light at night. In addition, various types of photovoltaic cells 6 using solar energy as an energy source are provided at the upper end of the floating body 1. Of course, various things, such as a battery, can be used as said energy source.

The battery 8 charged by the photovoltaic cell 3 is installed in the interior space of the floating body 1. The battery 8 is an energy source for driving the motor 10 installed at the lower end of the floating body 1, and the motor 10 is driven by receiving a signal from the tension sensor 12. That is, the tension sensor 12 detects the tension of the rope 14 connected to the motor shaft 11 to allow the rope 14 to be unwound or wound depending on the size of the tide or the wave. For example, when the tension sensor 12 is above a predetermined reference value according to the magnitude of the tide or the wave, the motor 10 is driven in the forward direction to wind the rope 14 connected to the anchor and the motor 10 when the reference value is less than the reference value. Can be driven in the reverse direction to loosen the rope (14).

Next, a floating inner tube 20 is installed inside the floating body 1. The floating inner tube 20 is installed to penetrate the interior filled with styrofoam, may be installed in a curve inside the body 1 as shown in Figure 1 or may be installed in a straight line inside the body (1). have.

The moving rope 22 penetrates and is mounted on the floating inner tube 20. The moving rope 22 penetrates through the floating inner tube 20 and is mounted along the outer surface of the floating body 1. One side of the moving rope 22 is equipped with an equipment connecting ring (24). The equipment connecting ring 24 is connected to the ocean observation equipment such as seawater flow, water temperature, salinity and electrical conductivity, such as data logger for physics, stoichiometry of seawater. Observation equipment connected to the equipment connection ring 24 can be stably moored in water because it can be moved up and down as needed.

The equipment connecting ring 24 can be moved up and down along the outer surface of the floating body 1 by the movement of the moving rope 22, the moving radius of the equipment connecting ring 24 and the upper portion of the floating body (1) and As shown in FIG. 1, the lower one side moves between the upper end and the lower end of the floating inner tube 20. The movement of the equipment connecting ring 24 is made by driving the motor 26 installed inside the floating body 1. The motor 26 may be installed on one side of the floating inner tube 20 or may be installed inside the floating body 1 filled with styrofoam. The moving rope 22 is connected to the motor shaft 27 of the motor 26, and the moving rope 22 of the floating body 1 of the floating inner tube 20 is driven by the driving of the motor 26. It moves along the outer surface. On the other hand, although the motor 26 is presented as a driving source in this embodiment, it is not limited thereto, and various kinds of driving sources may be used.

At this time, the vertical movement trajectory of the moving line 22 is made by the upper sensor 30 and the lower sensor 31 installed adjacent to the upper and lower ends of the floating inner tube (20). The upper sensor 30 and the lower sensor 31 serves to detect the position of the equipment connecting ring 24. That is, the upper sensor 30 detects when the equipment connecting ring 24 is moved to the upper end (top) of the floating inner tube 20 to the motor 26 through a separate control unit (not shown) The stop signal is transmitted. Alternatively, the upper sensor 30 may transmit a reverse signal to the motor 26. Similarly, the lower sensor 31 detects this when the equipment connection 24 moves to the bottom (lower end) of the floating inner tube 20.

In the above description, only the upper sensor 30 and the lower sensor 31 are described as an example of a sensor for detecting the position of the equipment connecting ring 24. However, a plurality of the sensors are installed along the outer surface of the floating body 1. It can also be configured to detect each location.

Next, an external power supply device 32 capable of supplying external power for driving the motor 26 by a person located outside such as a ship may be provided. The external power supply device 32 to drive the motor 26 only by a specific code is to prevent theft of the observation equipment, if there is no risk of theft due to long-term mooring of the observation equipment Instead of the supply device 32, a wireless remote control or the like may be used.

On the other hand, the portion where the tension sensor 12 is installed and the floating inner tube 20 may be sealed by a sealing material so that water does not penetrate from the outside.

In addition, the rope connector 34 is installed on the side of the floating body (1). The rope connector 34 may be provided in plural on the side of the floating body (1). The rope connector 34 is a part to which a rope for connecting a plurality of marine buoys floating on the water surface is connected to each other through a bearing shoe (not shown) to prevent the connected rope from being broken or entangled due to a torsional moment. It is rotatably installed. As such, since the bearing shoe is rotated as a medium, the torsional moment between the marine buoys does not work due to other factors such as tidal currents, and thus the rotation of the marine buoys is not subjected to resistance by the connected rope. The bearing shoe is already known, and a detailed description thereof will be omitted.

Next, another embodiment of the multipurpose marine buoy according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a side view schematically showing an ocean buoy according to another embodiment of the present invention. Referring to this, in the present embodiment, unlike the above-described embodiment, a separate floating inner tube 20 is not installed inside the floating body 1.

In this embodiment, the movable belt 22 is installed on the outer surface of the floating body 1 to be movable. The moving belt 22 may be moved by a motor 26 installed inside the floating body 1, and may be wound and moved on a roller 23 installed on an outer surface of the floating body 1. The roller 23 may be connected and rotated by the motor 26 and a motor shaft (not shown).

And, one side of the movable belt 22 is equipped with an equipment connecting ring (24). The equipment connecting ring 24 is moved up and down by the rotation of the roller 23 so that the observation equipment is up to the appropriate position and can be moved to the original position.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self evident.

1: floating body 2: wireless receiver
4 night light 6 solar cell
8: battery 10: motor
11: motor shaft 12: tension sensor
14 rope 20 floating body inner tube
22: mobile rope 24: equipment connection ring
26: motor 27: motor shaft
30: upper sensor 31: lower sensor
32: external power supply device 34: rope connector

Claims (15)

Float floating on the sea level;
A tension sensor for sensing the tension of the rope connected to the lower end of the float;
A driving source receiving power from the tension sensor and providing power for moving the rope in a vertical direction;
A floating inner tube installed to penetrate the inside of the floating body in a vertical direction, the moving rope passing through the floating body along the outer surface of the floating body;
Mounted on one side of the moving rope, the marine buoy including an equipment connecting hook to the marine observation equipment. The method of claim 1,
The buoy inner tube is a marine buoy, characterized in that installed in a straight or curved shape inside the float. The method of claim 1,
An outer surface of the floating body buoy characterized in that at least one sensor for detecting the position of the equipment connection is mounted. The method of claim 3, wherein
Marine buoys, characterized in that the upper and lower sensors for detecting the position of the equipment connection ring is mounted on the upper and lower portions of the floating body, respectively. The method of claim 4, wherein
A marine buoy is installed in the floating body, wherein a motor having a motor shaft connected to the moving rope is installed to provide power required for the movement of the moving rope. The method of claim 5, wherein
The marine buoy, characterized in that for transmitting the stop signal to the motor when the upper sensor and the lower sensor detects the position of the equipment connection ring. The method of claim 1,
A photovoltaic cell is installed at an upper end of the floating body, and a battery receiving power from the photovoltaic cell is installed inside the floating body to transfer power to the driving source. The method of claim 1,
The side of the floating rope is connected to the rope connector is installed, the rope connector is characterized in that the rotatable connection via a bearing shoe bell. Float floating on the sea level;
A tension sensor for sensing the tension of the rope connected to the lower end of the float;
A driving source receiving power from the tension sensor and providing power for moving the rope in a vertical direction;
A moving belt wound and moved around a roller rotatably installed on upper and lower outer surfaces of the floating body;
Mounted on one side of the moving belt is moved together in accordance with the movement of the moving belt, marine buoy including an equipment connecting hook to the marine observation equipment is walked. The method of claim 9,
An outer surface of the floating body buoy characterized in that at least one sensor for detecting the position of the equipment connection is mounted. The method of claim 10,
Marine buoys, characterized in that the upper and lower sensors for detecting the position of the equipment connection ring is mounted on the upper and lower portions of the floating body, respectively. The method of claim 11,
An inner buoy is provided with a motor connected to the shaft of the roller to rotate the roller, the marine buoy, characterized in that to provide the power required for the movement of the moving belt. The method of claim 12,
The marine buoy, characterized in that for transmitting the stop signal to the motor when the upper sensor and the lower sensor detects the position of the equipment connection ring. The method of claim 9,
A photovoltaic cell is installed at an upper end of the floating body, and a battery receiving power from the photovoltaic cell is installed inside the floating body to transfer power to the driving source. The method of claim 9,
The side of the floating rope is connected to the rope connector is installed, the rope connector is characterized in that the rotatable connection via a bearing shoe bell.

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