KR101062617B1 - Spill oil substitute test equipment for offshore oil monitoring experiment - Google Patents

Abstract

The present invention relates to an effluent oil substitute test equipment for marine oil spill monitoring experiments, and in particular, a plurality of buoyancy bodies having buoyancy in any of a plurality of floating bodies that are being accumulated in two or more layers, and the floating body It is formed by pressing the edge of the periphery of the buoyancy body and connected to the satellite signal transmitting device to one end of the floating body is put or recovered on the sea through a transport test line, the position transmitted from the satellite signal transmitting device from the satellite The present invention relates to an outflow oil substitute experimental equipment for off-shore oil spill monitoring experiments characterized in that the transmission and flow direction of the floating body taken from the signal and satellite are transmitted to the ground monitoring system.

Spill, oil, marine, monitoring, experiment

Description

A substitute for spilt oil on the sea with an accident}

The present invention relates to an effluent oil substitute test equipment for marine oil spill monitoring experiments, and in particular, a plurality of buoyancy bodies having buoyancy in any of a plurality of floating bodies that are being accumulated in two or more layers, and the floating body It is formed by pressing the edge of the periphery of the buoyancy body and connected to the satellite signal transmitting device to one end of the floating body is put or recovered on the sea through a transport test line, the position transmitted from the satellite signal transmitting device from the satellite The present invention relates to an outflow oil substitute experimental equipment for off-shore oil spill monitoring experiments characterized in that the transmission and flow direction of the floating body taken from the signal and satellite are transmitted to the ground monitoring system.

In general, marine transportation is gradually increasing due to the increase of industrial movement, and there are frequent marine accidents caused by collision of ships or other stranding of ships along with the increase of large ships. Due to the high speed, marine pollution is serious.

These oil spills occur about seven times a year on average, and large-scale marine pollution accidents occur due to the stranding or sinking of oil tankers. Focusing on the development of response strategy information system, development is underway at each research institute.

In addition, the knowledge of knowledge and technology are led by the United Nations Organizations IMO, ITOPF, and the US Environmental Protection Agency EPA, reviewed through international conferences, and standardized by the application of Coast Guard and international control organizations in each country. .

And, when oil spills, it is necessary to monitor the direction of oil diffusion and flow. In this monitoring, the surface of the sea is photographed and monitored in the sky to distinguish the color difference between oil and the sea, and the roughness of the sea is reflected by the radar. It is used to distinguish the Ladder reflection signal difference by measuring the signal and checking the roughness difference between ocean and oil.

However, it is necessary to anticipate the phenomenon of oil leakage caused by the oil spill accident in the ocean and the direction of oil flow in advance to install a barrier and neutralize and remove the oil spilled through the control operation. Because the computer simulation is used to predict the diffusion direction and the flow direction of the system, it is impossible to predict the exact movement of the current, and also the forecast may be wrong due to the factors that change from time to time. There is a problem that can not be spread to great damage.

In order to solve the above problems, a plurality of floats made of a waterproof material are laminated, and a buoyant body is inserted into a plurality of positions of the float, and the float is put into the ocean by a transport test ship and the float The purpose of the present invention is to provide a petroleum surrogate test equipment for marine effluent monitoring experiments by monitoring the flow of fluid by radar of satellite or carrier test vessels.

In order to solve the above problems, the present invention relates to an experimental equipment for effluent oil substitute for offshore oil monitoring experiments, and a plurality of layers of floating materials made of a waterproof material are laminated, and a buoyancy body is inserted at a plurality of positions of the floating body. And compresses the periphery of the buoyancy body and the edge of the floating body, connects a satellite signal transmitting device to one end of the floating body and injects it into the ocean by a transport test ship, and the floating body flows in the ocean. Observed by the radar equipment of the satellite and the transport test ship is configured to transmit to the monitoring system installed on the ground.

The present invention constitutes a floating body to replace the outflow oil in order to predict the oil spill occurring in the sea and put it on the sea, people through the monitoring system to monitor the phenomenon that the floating body flows by the flow of sea water This observation can be used to predict the actual oil spill.

In addition, since the actual oil can not be used in the experiment, it can be replaced by the experiment. The satellite signal solving device is connected to prevent loss or loss, thus preventing marine pollution.

As shown in Figures 1 to 2 and 4, the present invention in the equipment for monitoring the flow direction of oil according to the oil spill accident in the ocean, made of a waterproof material, laminated in two layers, the edge is compressed A floating body 10 which is sealed; A buoyant body 20 inserted into the floating body 10 to improve the floating force of the floating body 10; A satellite signal transmitting device 30 connected to one portion of the floating body 10 and transmitting positional information of the floating body 10; A transport test ship 40 for inputting or recovering the float 10 to the sea, and having radar equipment installed thereon to wirelessly transmit flow direction information of the float 10; A satellite (50) for receiving a signal from the satellite signal transmitting device (30) and photographing the floating object (10) on the sea and transmitting it wirelessly; The ground monitoring system that receives the information signal transmitted from the satellite 50, displays the position and current shape of the floating body 10, and receives and displays the information transmitted from the transport test ship 40. 60, including.

At this time, as shown in Figures 2 to 3, the floating body 10 is compressed by sealing the periphery of the buoyancy body 20, the buoyancy body 20 is inserted.

And, as shown in Figures 2 to 3, the floating body is a plurality of so that the seawater flows into the upper side of the floating body 10 in any position on the plane so that the floating body 10 is submerged in a certain water level ocean. Inlet holes are formed.

In addition, as shown in FIG. 2, the inlet hole has a hole formed in the center thereof, and a reinforcement part 11 for reinforcing the inlet hole is inserted, and the periphery of the reinforcement part 11 is compressed to form the floating body 10. It is fixed to).

As shown in FIG. 3, the floating body 10 is connected to each other in arbitrary numbers desired by the user and is configured as one colony.

In addition, the arbitrary number is connected to each other floating body 10 consisting of a single colony is connected to each individual at a long distance.

In addition, the floating body 10 is connected to the transport test line 40 and a long line.

In addition, as shown in Figure 5, the floating body is composed of a plurality of layers of waterproof material is laminated.

That is, the present invention will be described in more detail with reference to one embodiment.

As shown in Figures 1 to 2 and 4, the floating body 10 made of a waterproof material is made of two or multiple layers, buoyancy body 20 having buoyancy at any of a number of positions is inserted into the edge is thermally compressed or heat Is joined by a method such as fusion, etc., the satellite signal transmitting device 30 is connected to a portion of the float 10 by a line of a predetermined length to send the current position information of the float 10 to the satellite 50 Receiving a signal transmitted from the satellite signal transmitting device 30 from the satellite 50, the satellite 50 and the satellite signal transmitting device and the information photographing the shape and flow direction of the floating body (10) The signal of 30 is transmitted to the monitoring system 60 on the ground to check the monitoring system 60.

In this case, as shown in FIG. 3, a transport test ship 40 is used to feed or recover the floating body 10 and the satellite signal transmitting device 30 to the sea, and a radar is used for the transport test ship 40. The equipment is installed to observe the flow direction of the floating body 10 to the radar equipment and transmit to the ground monitoring system 60.

As shown in FIG. 2, the floating body 10 compresses and seals the periphery of the buoyancy body 20 into which the buoyancy body 20 is inserted. As a result, the buoyancy body 20 may be sealed. It does not move inside the fluid 10.

In addition, as shown in Figure 2, the floating body 10 is a plurality of so that the seawater flows into the upper side of the floating body 10 in any position on the plane so that the floating body 10 is submerged in a certain water level ocean. An inlet hole is formed, and a hole is formed in the inlet hole, and a reinforcement part 11 for reinforcing the inlet hole is inserted, and the periphery of the reinforcement part 11 is compressed and fixed to the floating body 10. do.

In addition, the floating body 10 may be configured as one colony by connecting any number desired by the user in close proximity to each other, and the floating body 10 consisting of one colony by the arbitrary number is connected to each other. It can be connected remotely between objects.

In addition, the floating body 10 is connected to the transport test line 40 and a line of the distant so that it can be easily recovered at the time of recovery of the floating body (10).

And, when the floating body 10 is made up of a plurality of colonies, the strings connecting the floating bodies 10 connect the connecting portions formed at the edge of the floating body 10 to one of the strings. By adjusting the length, the floating body 10 can be approached or spread widely to monitor the phenomenon of oil diffusion.

In addition, the floating body 10 is made of a material having waterproofness and fluidity such as vinyl or plastic, and the buoyancy body 20 is made of a strong buoyancy material such as styrofoam or air bag.

1 is an overall configuration diagram of the effluent oil substitute test equipment for the marine oil spill monitoring experiment according to the present invention,

Figure 2 is a perspective view showing the floating body of the effluent oil substitute experimental equipment for marine oil spill monitoring experiment according to the present invention,

Figure 3 is a perspective view showing that the floating body is connected to a plurality of floating body of the effluent oil substitute test equipment for the marine oil spill monitoring experiment according to the present invention, the colony is connected to the transport test ship,

Figure 4 is a cross-sectional view showing that the buoyancy body is inserted into the floating body of the effluent oil substitute test equipment for marine oil spill monitoring experiment according to the present invention,

Figure 5 is a cross-sectional view showing the floating body formed of a plurality of floating oil substitute test equipment for marine oil spill monitoring experiment according to the present invention.

Description of the Related Art [0002]

10; Float 20: Buoyancy Body

30: satellite signal transmission device 40: transport test ship

50: satellite 60: monitoring system

Claims (8)

In the equipment for monitoring the flow direction of oil according to the oil spill accident in the ocean, Floating body 10 made of a waterproof material, laminated in two layers, the edge is compressed and sealed; A buoyant body 20 inserted into the floating body 10 to improve the floating force of the floating body 10; A satellite signal transmitting device 30 connected to one portion of the floating body 10 and transmitting positional information of the floating body 10; A transport test ship 40 for inputting or recovering the float 10 to the sea, and having radar equipment installed thereon to wirelessly transmit flow direction information of the float 10; A satellite (50) for receiving a signal from the satellite signal transmitting device (30) and photographing the floating object (10) on the sea and transmitting it wirelessly; The ground monitoring system that receives the information signal transmitted from the satellite 50, displays the position and current shape of the floating body 10, and receives and displays the information transmitted from the transport test ship 40. (60); outflow oil substitute experimental equipment for offshore oil monitoring experiments, characterized in that is configured to include. The method of claim 1, The floating body (10) is a spilled oil substitute experimental equipment for marine oil spill monitoring experiments, characterized in that the sealing by pressing the periphery of the buoyancy body 20 is inserted into the buoyancy body (20). The method of claim 1, The floating body 10 is characterized in that a plurality of inlet holes are formed so that the sea water flows into the upper side of the floating body 10 at any position on the plane so that the floating body 10 is immersed in a certain level sea. Experimental equipment for spilled oil for offshore oil monitoring experiments. The method of claim 3, The inlet hole is formed in the center of the reinforcement portion 11 is inserted into the reinforcing the inlet hole, the periphery of the reinforcement portion 11 is characterized in that it is fixed to the floating body 10 Effluent substitute test equipment for offshore oil monitoring experiments. The method of claim 1, The floating body (10) is a spilled oil substitute experimental equipment for offshore oil monitoring monitoring, characterized in that any number desired by the user is connected to each other is configured as one colony. The method of claim 1, Experimental equipment for outflow oil substitute for marine outflow oil monitoring experiment, characterized in that the floating body 10 is connected to the transport test line 40 and a string. The method of claim 1, The floating body (10) is a spill oil substitute experimental equipment for offshore oil spill monitoring experiment, characterized in that a plurality of layers of waterproof material is laminated. delete

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