KR100936469B1 - Data collection system - Google Patents

Abstract

PURPOSE: A data acquisition system about submarine topography and geographic information is provided to protect a communication line and a power line with a lifting wire. CONSTITUTION: A data acquisition system about submarine topography and geographic information comprises an undersea photograph device(100) and an undersea image correction device(200). The undersea photograph device comprises a discovery ship(110), a drive unit(120), a lifting unit, an underwater detector, a communications line and a power line. The discovery ship comprises a discovery ship body(111), a supporter(112), a horizontal object(113) and a guide body(114). The drive unit rotates a rotor and is installed in the bottom of the discovery ship body. The lifting unit consists of a drive motor, a cover, and a lifting wire. The underwater detector comprises a wire fixing unit in which first and the second wires are fixed. The undersea image correction device comprises a calibrator body(210), a storage, a receiver, an input unit and an output unit. The calibrator body is installed in the discovery ship of the undersea photograph device.

Description

Data Collection System for Submarine Terrain and Geographic Information

The present invention relates to a data collection system for undersea topography and geographic information.

In order to obtain the seabed topography information, the Republic of Korea registration (20-0415471; underwater detector) was invented.

However, the underwater detector is moved up and down during data collection by external force such as waves when moving underwater. When the underwater detector moves up and down, there is a change in the reference point at which the ultrasonic wave of the ultrasonic sensor is sent, so that the ultrasonic sensor cannot accurately measure the distance from the bottom of the sea, and thus, accurate subsea data cannot be obtained.

In addition, the underwater detector, the operation of the underwater detector is finished, the underwater data record can be confirmed only when the underwater detector is exposed to the outside, it was not possible to confirm and correct the seabed data in real time.

The present invention is to solve the above problems, to solve the problem to provide a data collection system for the seabed topography and geographic information that can collect the accurate seabed data.

The present invention for solving the above problems, the probe body body 111 moving on the water surface, the support body 112 is installed in the vertical direction on the probe body body 111 and the support body 112 An exploration vessel 110 having a horizontal body 113 installed in a horizontal direction and a plurality of guide bodies 114 installed on the support body 112 or the horizontal body 113; A driving device (120) installed in the probe ship body (111) to rotate the support body (112); A drum 131 rotatably installed on the probe body 111, a drive motor 132 installed on the probe body 111 and rotating the drum 131, and a cover wound around the drum 131 ( 133a and a lifting wire having a pair of first and second wires 133b and 133b 'which are internally opposed to the cover 133a and whose both ends are exposed to the outside of the cover 133a and whose one end is fixed to the drum 131. A lifting device 130 composed of 133; A detector body having a wire fixing part 141a for opening to the outside and detachably fixed to the first and second wires 133b and 133b ', and an airtight member inserting part 141b communicating with the wire fixing part 141a. 141 and the hollow part into which the other end of the lifting wire 133 is inserted are inserted into the hermetic member inserting part 141b, and the ultrasonic sensor 142 installed on the bottom of the detector body 141. ), The underwater camera 145 installed on the bottom of the detector body 141, the pressure sensor 146 is installed on the detector body 141 and measures the water pressure and outputs a water pressure signal, the detector body 141 Position tracking device 143 and the detector body 141 is installed in the ultrasonic signal of the ultrasonic sensor 142 and the video signal of the underwater camera 145 and the hydraulic pressure signal and position tracking device of the pressure sensor 146 ( An underwater detector 140 having a transmitter 144 for transmitting a position signal of the unit 143; It is built in the cover 133a of the lifting wire 133 and is disposed between each of the first and second wires 133b and 133b 'to have a smaller diameter than the first and second wires 133b and 133b'. A communication line 150 electrically connected to the transmitter 144 of the 140; A power line installed in the cover 133a of the lifting wire 133 and disposed between each of the first and second wires 133b and 133b 'with a smaller diameter of the first and second wires 133b and 133b'. A subsea photographing apparatus 100 including a 160 and a correction device body 210 installed on the probe 110 of the subsea photographing apparatus 100; A storage unit 220 installed in the calibrating body 210 and storing a seabed image; The receiver 230 is installed in the correction device body 210 and electrically connected to the communication line 150 to receive an ultrasonic signal, an image signal, a water pressure signal, and a position signal from the transmitter 144 of the underwater detector 140. )Wow; It is installed in the correction device body 210, the operation of the storage unit 220, receiving the ultrasonic signal and the hydraulic pressure signal from the receiver 230 to correct the error value according to the water depth change of the underwater detector 140 To generate an undersea image by receiving an image signal from the receiving unit 230, and indicating a position of the collected undersea image by receiving a position signal from the receiving unit 230, and according to a control signal of the input unit 250. A controller 240 for deleting or correcting an image; An input unit 250 installed in the correction device body 210 and operated and controlled by the controller 240 to input a control signal to the controller 240; It is installed on the correction device body 210, the operation is controlled by the control unit 240, characterized in that consisting of a subsea image correction device 200 having an output unit 260 for displaying a subsea image.

According to the present invention as described above, accurate marine information can be obtained through the hydraulic pressure sensor, the communication line is wired, the communication efficiency is high, and the communication line and the power line are protected by the lifting wire and are not disconnected. Of course, it is also possible to obtain accurate marine information through underwater cameras.

Hereinafter will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a data collection system for the seabed topography and geographic information according to the present invention, Figure 2 is a schematic diagram showing a data collection system for the seabed topography and geographic information according to the present invention, Figure 3 Figure 4 is a cross-sectional view showing the lifting wire of the present invention, Figure 4 is a partial cross-sectional view showing the lifting device of the present invention, Figure 5 is a view showing an underwater detector according to the present invention, Figure 6 is a view showing a portion A of FIG. .

1 and 2, the data collection system for the seabed topography and geographic information according to the present invention receives an ultrasonic signal from the seabed photographing apparatus 100 and the seabed photographing apparatus 100 to correct the seabed image. It consists of an image correction apparatus 200.

Referring to FIGS. 2 and 3, the underwater imaging apparatus 100 will be described below.

The subsea imaging apparatus 100 includes a probe vessel 110 moving on the surface of the water, a drive unit 120 installed on the probe vessel 110, and a lifting device 130 installed on the probe vessel 110. , An underwater detector 140 connected to the probe ship 110 to move underwater, a communication line 150 to which communication data is moved, and a power line 160 to which power is supplied.

The exploration vessel 110, the probe body 111 moving on the surface of the water, the lower body 116 is installed on the rear of the probe body body 111, rotatably installed on the upper portion of the lower body 116 The revolving body 117, the support body 112 vertically placed on the upper portion of the revolving body 117, the horizontal body 113 provided in the horizontal direction on the upper side of the support body 112, and the support body 112. Is composed of a plurality of guide body 114 is installed on the side or the lower surface of the horizontal body 113, the lifting device case 115 is installed on the upper portion of the lower body (116).

 As the drive device 120, a conventional motor using hydraulic pressure or electricity is used, and is built in the lower body 116 to rotate the swinging structure 117. On the other hand, the drive device 120 is used in a conventional crane device, the connection relationship between the drive device 120 and the swinging structure 117 will be omitted.

3 and 4, the lifting device 130, the drum 131 is rotatably installed in the lifting device case 115, and is installed in the lifting device case 115 to rotate the drum 131. The driving motor 132, one end is drawn into the drum 131, and the cover 133a of the cushioning material wound around the drum 131 and the cover 133a, but are installed opposite to each other and both ends are covered (133a). A lifting wire 133 having a pair of first and second wires 133b and 133b 'which are drawn out to one side and fixed to the drum 131.

In this case, a through hole 131a is formed in an upper portion of the drum 131, and one end of the first and second wires 133b and 133b ′ introduced into the through hole 131a is fixed to the inside of the drum 131. Meanwhile, the communication line 150 drawn into the drum 131 is electrically connected to the receiver 230 of the subsea image correction apparatus 200, and the power line 160 is a power supply unit (not shown) provided in the probe 110. Is electrically connected to At this time, the communication line 150 and the power line 160 are connected to the receiver 230 and the power supply so as not to interfere with the rotation of the drum 131.

In addition, the other end of the lifting wire 133 is drawn out of the lifting device case 115, guided by the guide body 114, is connected to the underwater detector 140.

5 and 6, the underwater detector 140 will be described.

The underwater detector 140 is a streamlined detector body 141 that moves underwater, an airtight member P installed in the detector body 141, and is installed on the bottom surface of the detector body 141 and ultrasonic wave to the sea bottom. Ultrasonic sensor 142 for transmitting the reflected wave and receiving the reflected wave, the underwater camera 145 is installed on the bottom of the detector body 141 and photographed the seabed topography, and installed on the bottom of the detector body 141 to reduce the water pressure of the seabed Water pressure sensor 146 to measure, the position tracking device 143 is installed on the detector body 141, the detector body 141 is installed on the ultrasonic signal of the ultrasonic sensor 142 and the video signal of the underwater camera 145 And a transmitter 144 for outputting a pressure signal of the pressure sensor 146 and a position signal of the position tracking device 143. At this time, the location tracking device 143 uses a conventional GPS technology.

The detector body 141 has a cover insertion portion 141b which is vertically penetrated at an upper portion thereof, an upper portion thereof is opened, and is connected to the cover insertion portion 141b so as to be installed in the tumbler body 141. 141a is provided.

The wire fixing part 141a has a case shape having a space formed therein, and an upper end thereof is fixed to an upper surface of the detector body 141, and a fixing body F is provided at an inner lower part thereof. At this time, the first wire 133b and the second wire 133b 'of the lifting wire 133 are fixed to the fixed body F.

At this time, the end of the first and second wires (133b, 133b ') is provided with a connecting member (R) having a hollow portion, the wire fixing portion (141a) of the detector body 141 via a separate fastening member (B) Removably fixed to).

On the other hand, the fastening member (B) is a screw or bolt, through the hollow portion of the connecting member (R) is threaded to the fixing portion (F). Therefore, when the probe 110 and the underwater detector 140 move, the tensions of the wires 133b and 133b 'generated by mutual movement are transmitted to the respective wire fixing parts 141a, and the inside of the cover 133a. Tension is not applied to the communication line 150 and the power line 160 in the communication line 150 and the power line 160 can perform their respective functions stably.

The hermetic member P has a hollow portion formed therein, and is inserted into the hermetic member inserting portion 141b to prevent foreign substances from entering into the wire fixing portion 141a.

The underwater camera 145 is to more accurately identify the terrain that is not measured by the ultrasonic sensor 142, is installed on the bottom of the detector body 141 to accurately photograph the seabed topography.

The water pressure sensor 146 is installed on the bottom of the detector body 141, measures the water pressure where the underwater detector 140 is located, and outputs a water pressure signal according to the water pressure change to the transmitter 144. At this time, the water pressure sensor 146 may be any one that can measure the water pressure of the seabed.

The transmitter 144, which is built in the detector body 141, is electrically connected to the ultrasonic sensor 142, the underwater camera 145, the water pressure sensor 146, and the position tracking device 143. The ultrasonic signal of 142, the video signal of the underwater camera 145, the water pressure signal of the water pressure sensor 146, and the position signal of the position tracking device 143 are output.

3 and 4, the communication line 150 and the power line 160 will be described below.

The communication line 150 is wrapped by a cover 133a, and both ends of the communication line 150 are connected to the transmitter 144 of the underwater detector 140 and the receiver 230 of the subsea image corrector 200 by passing through the cover 133a. do.

The power line 160 is wrapped by the cover 133a of the lifting wire 133, and both ends penetrate the cover 133a so that power is supplied to the underwater detector 140, so that power of the probe 110 is provided. The supply unit and the components of the underwater detector 140 are electrically connected.

Meanwhile, referring to FIG. 3, the communication line 150 and the power line 160 have a diameter smaller than that of the first and second wires 133b and 133b ', and the outer surface of the communication line 150 and the power line 160 is formed of the first and second wires 133b and 133b'. It is arranged up and down between the first and second wires 133b and 133b 'so as not to be exposed to the outside of the outer surface.

That is, the communication line 150 and the power line 160 are disposed to face up and down with respect to the line J connecting the centers of the first wire 133b and the second wire 133b ', and the communication line ( The outer diameters of the 150 and the power line 160 are disposed between the K and K 'lines so that the outer diameters of the first and second wires 133b and 133b' do not deviate from the lines K and K ', respectively. .

 Therefore, when an external force is applied to the lifting wire 133, the external force is primarily attenuated by the first and second wires 133b and 133b ', so that the external force does not directly act on the communication line 150 and the power line 160.

The subsea image correction apparatus 200 is installed in the correction device body 210, installed on the probe 110 of the subsea imaging device 100, the correction device body 210 is operated by the control unit 240 And a storage unit 220 for storing a seabed image, and a correction device body 210, and are electrically connected to the communication line 150 so that an ultrasonic signal, an image signal, a water pressure signal, and a position from the subsea photographing apparatus 100 are provided. Receiving unit 230 for receiving a signal, the control unit 240 is installed in the correction device body 210, the correction device body 210 is installed in the correction device body 210 is operated and controlled by the control unit 240 is a control signal to the control unit 240 It is provided with an input unit 250 for inputting, and an output unit 260 installed in the compensator body 210.

The controller 240 receives an ultrasonic signal from the receiver 230, reads the ultrasonic signal, and displays the seabed topography measured by the output unit 260 as a subsea image. At this time, the control unit 240 receives the water pressure signal from the receiving unit 230 to check the horizontal position change of the underwater detector 140, the underwater detector 140 checks the exact distance away from the sea floor, by the ultrasonic signal Calibrate the read seabed image.

In addition, the controller 240 receives an image signal from the receiver 230, reads the image signal, and outputs a subsea image through the output unit 260.

On the other hand, the control unit 240 indicates the position of the seabed terrain measured by receiving the position signal. In addition, the controller 240 deletes or stores the seabed image measured according to the control signal of the input unit 250.

The output unit 260 is a conventional display device, which is operated and controlled by the control unit 240 to display the measured or photographed submarine image and to display the submarine image of the storage unit 230.

7 and 8 are views showing the operation of the data collection system system for the seabed topography and geographic information according to the present invention, with reference to FIGS. 7 and 8 data collection system for the seabed topography and geographic information according to the present invention The operation of the stem is described as follows.

First, the subsea photographing apparatus 100 and the subsea image correcting apparatus 200 are disposed at a place to confirm the change to seawater, and then moved to the front of the probe 110 as shown in FIG. 1, the underwater detector 140 ) Is moved behind the probe while being guided by the probe 110 while being disposed behind the probe 110.

At this time, the ultrasonic sensor 142 transmits the ultrasonic wave to the sea bottom, receives the reflected wave back, measures the distance between the ultrasonic sensor 142 and the sea bottom, and transmits the ultrasonic signal indicating this to the transmission unit 144. Send it out. In addition, the underwater camera 125 photographs the seabed topography and transmits an image signal through the transmitter 144. In addition, the position tracking device 143 transmits a position signal indicating the current position to be measured or photographed by the transmitter 144. At this time, the water pressure sensor 146 transmits a water pressure signal indicating the current water pressure through the transmitter 144.

On the other hand, when the ultrasonic signal, the image signal, the position signal and the water pressure signal are output from the transmitter 144, the receiver 230 of the subsea image information apparatus 200 receives it and sends it to the controller 240.

In this case, the controller 240 displays the subsea image generated by reading the ultrasonic signal from the ultrasonic sensor 142 on the output unit 260, and converts the image signal from the underwater camera 125 into a subsea image. The output unit 260 shows the position of the subsea image measured or photographed according to the position signal from the position tracking device 143.

On the other hand, the ultrasonic sensor 142, to measure the distance between the ultrasonic sensor 142 and the bottom surface in order to generate a seabed image, the ultrasonic wave must be output to the bottom surface on the same horizontal reference line (A), accurate undersea image Can be generated.

However, when the probe 110 moves while dragging the underwater detector 140, the speed of the probe 110 is not constant, and the underwater detector 140 may change its horizontal position. In addition, a sudden wave occurs in the water, the horizontal position of the underwater detector 140 is also changed.

Therefore, when the ultrasonic output position of the ultrasonic sensor 142 is changed as described above, the distance between the ultrasonic sensor 142 and the sea bottom is relatively changed, so that the exact distance is not measured.

On the other hand, in order to correct the incorrect measurement distance between the ultrasonic sensor 142 and the bottom surface as described above, in this embodiment is provided with a pressure sensor 146 for checking the position change of the underwater detector 140. .

Therefore, when the underwater detector 140 moves underwater, if a sudden wave occurs in the water, the horizontal position of the underwater detector 140 changes to 'B' as shown in FIG. 7, and the lifting wire 133 and the sea surface This angle is changed from θ to θ '. At this time, the water pressure sensor 146 measures the change in water pressure in real time and outputs a water pressure signal according to the water pressure change, and the water pressure signal is output through the transmitter 144 of the underwater detector 140 and the subsea image correction apparatus 200. It is delivered to the receiving unit 230, the control unit 240 receives the hydraulic pressure signal via the receiving unit 230.

At this time, the control unit 240 of the subsea image correction apparatus 200 receives the ultrasonic signal from the ultrasonic sensor 142 together with the hydraulic pressure signal of the hydraulic pressure sensor 146.

The control unit 240 receiving the pressure signal of the pressure sensor 146 and the ultrasonic signal of the ultrasonic sensor 142, the bottom surface distance (B) indicating the distance between the ultrasonic sensor 142 and the bottom surface through the ultrasonic signal Then, the error distance D is calculated by subtracting the sea bottom distance B from the absolute distance C representing the distance from the sea level to the horizontal reference line A. At this time, the controller 240 calculates the measurement distance E from the horizontal reference line A to the bottom by subtracting the error distance D from the bottom distance B.

Therefore, even if the horizontal position of the underwater detector 140 changes, the control unit 240 of the underwater image correcting apparatus 200 can accurately measure the measurement distance E from the horizontal reference line A to the bottom of the sea, so that the accurate seabed An image can be generated.

On the other hand, when the measured or photographed subsea image is the same as the existing submarine image, the manager controls the control unit 240 via the input unit 250, deletes the measured or photographed subsea image, measured or photographed If the seabed image is not the same as the existing seabed image, the controller 240 is controlled through the input unit 250 to delete the existing seabed image of the storage unit 230 and then store the newly created seabed image.

On the other hand, the power supply unit is installed on the probe ship 110 to supply power to the underwater detector 140 is electrically connected to the underwater detector 140 via the power line 160, and the underwater detector transmitter 144 and The receiver 230 of the subsea image information apparatus 200 is connected in a wired manner through the communication line 150 to increase communication efficiency.

Therefore, when an external force is applied to the communication line 150 and the power line 160 by a net or the like, the communication line 150 and the power line 160 are disconnected, and thus the function cannot be performed smoothly.

However, in the present invention, when an external force acts on the lifting wire 133, the cover 133a primarily buffers the external force. In particular, while the communication line 150 and the power line 160 are disposed between the first and second wires 133b and 133b ', the first and second wires 133b before the external force acts on the communication line 150 and the power line 160. , 133b ') acts as a buffer, so that no external force acts directly on the communication line 150 and the power line 160. In addition, the lifting wire 133 is provided with a cover 133a to prevent corrosion of the first and second wires 133b and 133b ', the communication line 150 and the power line 160.

Meanwhile, when lifting the underwater detector 140, the underwater detector 140 may be lifted through the lifting device 130 and then seated on the probe 110 as shown in FIG. 8.

As described above, in the data collection system for the seabed topography and geographic information according to the present invention, it is possible to obtain accurate seabed topography information through the water pressure sensor 146, and the external force is directly applied to the communication line 150 and the power line 160. Because it does not act as a, there is no fear of disconnection, there is an effect that the seabed information can be obtained in a stable seabed topography. In addition, through the underwater camera 125 it is possible to determine the exact seabed topography has the effect of obtaining more accurate seabed topography information.

1 is a block diagram showing a data collection system for the seabed topography and geographic information according to the present invention,

2 is a schematic diagram showing a data collection system for the seabed topography and geographic information according to the present invention,

3 is a cross-sectional view showing the lifting wire of the present invention,

4 is a partial cross-sectional view showing the lifting device of the present invention,

5 is a view showing an underwater detector according to the present invention,

6 is a view showing a portion A of FIG.

7 and 8 are views showing the operation according to the present invention.

-Explanation of terms for main parts of attached drawings-

100; Subsea imaging apparatus 110; Probe

120; Drive device 130; Lifting device

140; Underwater detector 145; Underwater camera

146; Water pressure sensor 150; Communication line 160; Powerline 200; Subsea image correction apparatus 210; Compensator body 220; Storage 230; Receiver 240; A controller 250; An input unit 260; Output

Claims (1)

A probe body 111 moving on the surface of the water, a support body 112 installed vertically on the probe body body 111, a horizontal body 113 installed horizontally on the support body 112, A probe vessel 110 having a plurality of guide bodies 114 installed on the support body 112 or the horizontal body 113; A driving device (120) installed in the probe ship body (111) to rotate the support body (112); A drum 131 rotatably installed on the probe body 111, a drive motor 132 installed on the probe body 111 and rotating the drum 131, and a cover wound around the drum 131 ( 133a and a lifting wire having a pair of first and second wires 133b and 133b 'which are internally opposed to the cover 133a and whose both ends are exposed to the outside of the cover 133a and whose one end is fixed to the drum 131. A lifting device 130 composed of 133; A detector body having a wire fixing part 141a for opening to the outside and detachably fixed to the first and second wires 133b and 133b ', and an airtight member inserting part 141b communicating with the wire fixing part 141a. 141 and the hollow part into which the other end of the lifting wire 133 is inserted are inserted into the hermetic member inserting part 141b, and the ultrasonic sensor 142 installed on the bottom of the detector body 141. And, the underwater camera 145 is installed on the bottom of the detector body 141, the detector body 141 is installed on the pressure sensor 146 and the detector body 141 to measure the water pressure and output a water pressure signal Installed position tracking device 143, and the detector body 141 is installed, the ultrasonic signal of the ultrasonic sensor 142, the video signal of the underwater camera 145 and the hydraulic pressure signal and position tracking device 143 of the pressure sensor 146 An underwater detector (140) having a transmitter (144) for transmitting a position signal of; It is installed in the cover 133a of the lifting wire 133 and is arranged between the first and second wires 133b and 133b 'with a diameter smaller than that of the first and second wires 133b and 133b'. A communication line 150 electrically connected to the transmitter 144 of the 140; A power line installed in the cover 133a of the lifting wire 133 and disposed between each of the first and second wires 133b and 133b 'with a smaller diameter of the first and second wires 133b and 133b'. Subsea photographing apparatus 100 comprising a 160, A correction device body (210) installed on the exploration vessel (110) of the subsea imaging device (100); A storage unit 220 installed in the calibrating body 210 and storing a seabed image; The receiver 230 is installed in the correction device body 210 and electrically connected to the communication line 150 to receive an ultrasonic signal, an image signal, a water pressure signal, and a position signal from the transmitter 144 of the underwater detector 140. )Wow; It is installed in the correction device body 210, the operation of the storage unit 220, receiving the ultrasonic signal and the hydraulic pressure signal from the receiver 230 to correct the error value according to the water depth change of the underwater detector 140 To generate an undersea image by receiving an image signal from the receiving unit 230, and indicating a position of the collected undersea image by receiving a position signal from the receiving unit 230, and according to a control signal of the input unit 250. A controller 240 for deleting or correcting an image; An input unit 250 installed in the correction device body 210 and operated by the control unit 240 to input a control signal to the control unit 240; It is installed on the correction device body 210, the operation is controlled by the control unit 240, subsea image correction device 200 having an output unit 260 for displaying a subsea image, Data collection system for submarine topography and geographic information, characterized in that consisting of.

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