KR101489685B1 - System predicting coastal change - Google Patents

Abstract

The present invention relates to a system to predict a coastal change by monitoring tidal current and tide of a coastal area. The system includes: a tidal level measuring apparatus (T) including a support (100), an identifying device (600), a guide bar (200), a buoyant body (300) in the shape of a disk, an impurity removing device (400) having a spring (440) to elastically support a moving part (420), a distance measuring device (500) having a control unit (530) which calculates the distance from which the buoyant body (300) moves, a tidal level measuring unit (700) which measures a tidal level, and a transmitter (800) which transmits tidal level data; and a coast change predicting apparatus (S) including a receptor (S1) which receives tidal level data from the transmitter (800) of the tidal level measuring apparatus (T), a storage DB (S2) to store coast line location data based on the tidal level, and a coast line setting unit (S3). According to the present invention, coastal change can be predicted; and a more correct coast data can be provided by the prediction.

Description

{SYSTEM PREDICTING COASTAL CHANGE} System for predicting coastal change through coastal tidal and tidal observations

The present invention relates to a coastal change prediction system through coastal tidal and tidal observations.

Sea water is constantly flowing, and sea level height changes over time.

The change in height of sea level is caused by various causes. Especially, the change of height of sea level caused by algae and tidal phenomenon due to interaction of sun, moon, and stars is called tide change. Measuring the height is called tidal observation.

On the other hand, as the climate changes and thus the height of the sea level changes, coastal changes frequently occur and if the coastal changes can not be identified immediately, the working environment on the coast becomes very dangerous.

In addition, if the coastal changes are not immediately reflected on the map, it is difficult to provide correct coastal information to the map user because the accuracy of the map is poor.

Registration Utility Model 20-0154364

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a system for predicting a coastal change quickly by measuring a buoyant tide, do.

According to an aspect of the present invention,

A supporting part 110 provided at the upper end of the supporting part 110 and a fixing part 120 provided at the upper end of the supporting part 110 and having a locking part 120, A support 100 having a streamlined mounting portion 130 located at a higher position; A rotation part 610 installed on the mounting part 130 of the support 100 so as to be rotatable in a clockwise or counterclockwise direction, a panel-shaped wing part 620 provided on the side of the rotation part 610 and equipped with reflection paper, And a control unit 640 installed at an upper portion of the rotation unit 610 to allow the light emitting unit 630 to be located at an upper portion and to make the light emitting unit 630 blink at night, (600); And has a through hole 211 penetrating up and down in the inside of the support 100 and a retaining groove 212 formed in the upper inside of the support 100 to receive the retaining part 120 of the support 100, An inserting portion 210 rotatably inserted into the supporter 110 in a clockwise or counterclockwise direction, a lower engaging portion 220 protruding outward at a lower end of the inserting portion 210, (200) having an upper latching part (230) protruded outward from an upper end of the guide base (200); And a foreign material removing mechanism mounting groove 320 which is opened downward and inwardly and communicates with the through hole 310 at a lower portion of the inserting hole 310, A buoyant body 300 of a circular plate shape inserted into the body 210 in a vertically movable manner and disposed between the lower latching part 220 and the upper latching part 230 of the guide pedestal 200; A guide portion 410 provided in the foreign material removing mechanism mounting groove 320 of the buoyant body 300 and having an opening groove 411 opened to the inside of the guide portion 410, A movable member 420 which is movably installed, a foreign matter removing member of elastic material having one end thereof meshed with the periphery of the inserting portion 210 of the guide base 200, A foreign matter removing mechanism 400 installed in the opening groove 411 of the guide part 410 and having a spring 440 elastically supporting the moving part 420 downward; A reflector 510 installed on the upper portion of the buoyant body 300 and a reflector 510 provided below the mounting portion 130 of the support 100 and opposed to the reflector 510 and extending from the mounting portion 130 to the buoyant body 300 A laser distance measuring mechanism 520 for measuring a distance between the buoyant body 300 and the buoyant body 300 and a laser distance measuring mechanism 520 for measuring the distance from the buoyant body 300 A distance measuring instrument 500 having a control unit 530 for calculating the distance traveled by the buoyancy body 300 by subtracting a distance; Is installed on the mounting part 130 of the support 100 and receives the calculated distance from the control unit 530 of the distance measuring device 500 and corrects the calculated distance from the existing tide data, A tilt measurement unit 700 for measuring the tilt of the tilt sensor 700; And a transmitter 800 installed at the installation part 130 of the support 100 for transmitting the tide data measured by the tide measurement unit 700. The tide measuring machine T comprises:

A receiver S1 for receiving the tide data from the transmitter 800 of the tie meter T; A storage DB S2 for storing coastline location information according to tide; A shoreline setting unit (S3) for searching a shoreline position corresponding to a tide received from a receiver (S1) from a storage DB (S2) and setting the searched shoreline position as a shoreline for the tide;

And a control unit.

According to the present invention as described above, it is possible to estimate the coastal change by setting the position of the shoreline for the tide after measuring the tide changing by the tide and the tide, and to provide more accurate coastal information through the prediction There is an effect that can be.

In addition, the present invention has the effect of preventing the collision of a ship or the like with the tide measuring device since the position of the tide measuring device can be easily checked.

1 is a system diagram for explaining the present invention,
2 is a view showing the installation of the tread height measuring instrument according to the present invention,
3 is a cross-sectional view of the tie meter according to the present invention,
Figs. 4 and 5 are views showing a part of Fig. 3 in detail,
6 is a plan view for explaining the marking mechanism of the present invention,
Fig. 7 is an enlarged view of a portion A in Fig. 4,
8 is a cross-sectional view taken along line XX of Fig. 7 for explaining a foreign substance removing mechanism according to the present invention,
9 to 11 are operation diagrams for explaining the operation of the coastal change prediction system according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.

3 is a cross-sectional view of a tread height measuring instrument according to the present invention, and Figs. 4 and 5 are sectional views of the tread depth measuring apparatus according to the present invention. Fig. 3 is a system diagram for explaining the present invention, 6 is a plan view for explaining the marking mechanism of the present invention, Fig. 7 is an enlarged view of a portion A in Fig. 4, and Fig. 8 is a view for explaining a foreign substance removing mechanism according to the present invention 7 is a cross-sectional view taken along line XX of FIG. 7, and the present invention will be described with reference to FIGS. 1 to 8. FIG.

The system for predicting the coastal change through coastal tide and tidal observations according to the present invention is performed through a tidal meter (T) and a coastal change predictor (S).

The tread height measuring device T includes a support table 100, a marking device 600, a guide table 200, a buoyancy device 300, a foreign material removing device 400, a distance measuring device 500, A unit 700, and a transmitter 800. Fig.

The support 100 includes a support 110 having a circular elongated shape and a lower end fixed to the seabed, a retaining part 120 provided at an upper end of the support 110, And a streamlined mounting part 130 located above the locking part 120. [ At this time, it is preferable that the lower end of the supporting part 110 is formed in a tip shape so as to be easily fixed to the seabed, and the supporting part 110 can be fixed to the water, Here, the support 110 may be fixed to the object in a fastening manner suitable for the structure of the object to be secured.

On the other hand, the support portion 110 has a circular long shape, in order to receive a minimum resistance when the seawater flows. In addition, the mounting portion 130 is streamlined to receive minimal resistance to wind.

The marking mechanism 600 includes a rotation unit 610 installed on the mounting unit 130 of the support 100 so as to be rotatable clockwise or counterclockwise and a panel 610 provided on the side surface of the rotation unit 610, And a controller 630 which is disposed on the upper portion of the rotary unit 610 and in which the light emitting unit 630 is located at the upper portion and the light emitting unit 630 is flickered at night 640).

One end of the rotation part 610 is rotatably installed on the mounting part 130 of the support 100 and the other end of the rotation part 610 protrudes upward from the mounting part 130.

A plurality of wings 620 are provided, one end of which is provided on the periphery of the rotation part 610, and the other end of which protrudes outward.

The control unit 640 is installed at an upper portion of the rotation unit 610 and operates the light emitting unit 630 to control the light emitting unit 630 to blink at night. At this time, the controller 640 has a timer, and the night time is set according to the timer setting.

The light emitting unit 630 has its own battery, is controlled by the control unit 640, and is located above the control unit 640.

The guide base 200 has a circular elongated shape and includes an insertion portion 210 which is rotatably inserted into the support portion 110 of the support 100 in a clockwise or counterclockwise direction, And a top engaging part 230 protruding outward from an upper end of the inserting part 210. The upper engaging part 230 is provided with a protruding upper engaging part 220,

The insertion portion 210 is provided with a through hole 211 penetrating up and down and an engagement groove 212 formed in the upper portion of the insertion portion 210 and into which the engagement portion 120 of the support 100 is inserted. At this time, the latching part 120 of the support 100 is inserted into the latching groove 212 of the insertion part 210, and the guide pedestal 200 is stably installed on the support 100.

Here, the lower latching part 220 and the upper latching part 230 limit the up and down movement range of the buoyancy body 300, thereby preventing the buoyancy body 300 from being detached.

The buoyant body 300 is provided with a through hole 310 penetrating upward and downward therein and a foreign body removing mechanism mounting groove 320 opened downward and inwardly and communicating with the through hole 310 at a lower portion thereof, And is disposed between the lower engaging part 220 and the upper engaging part 230 of the guide base 200 so as to be vertically movably inserted into the insertion part 210 of the guide 200. At this time, the buoyant body 300 is made of a buoyancy material, and a disk shape is formed to minimize resistance by seawater.

The foreign material removing mechanism 400 includes a guide portion 410 provided in the foreign material removing mechanism mounting groove 320 of the buoyant body 300 and having an opening groove 411 opened to the inside, A moving part 420 installed vertically movably in the opening groove 411 and a driving part 420 having one end thereof meshed with the periphery of the insertion part 210 of the guide pedestal 200 having a serrated shape and the other end fixed to the moving part 420 And a spring 440 which is installed in the opening groove 411 of the guide part 410 and supports the moving part 420 in a downward direction and elastically supports the foreign material removing device 430. [ (320).

The guide part 410 is installed on the upper part of the foreign material removing mechanism mounting groove 320 and protrudes downward and the moving part 420 is installed in the opening groove 411 of the guide part 410 and protrudes inward .

One end of the spring 440 is installed on the upper part of the opening groove 411 of the guide part 410 and the other end is installed on the upper part of the moving part 420 to elastically support the moving part 420 downward.

Since the one end of the foreign material removing member 430 has a saw tooth shape, the foreign material removing member 430 can abut against the periphery of the insertion portion 210 of the guide base 200 and effectively rub against the surface of the insertion portion 210 when moving up and down. The surface of the insertion portion 210 is pressed against the surface of the insertion portion 210 more effectively when it rubs against the surface of the insertion portion 210 because it is made of an elastic material. The other end of the foreign material removing member 430 may be rounded to correspond to the surface of the insertion portion 210 so that the other end of the foreign material removing member 430 can be closely attached to the surface of the insertion portion 210 of the circular bar shape.

The distance measuring instrument 500 includes a reflector 510 installed on the upper portion of the buoyant body 300 and a reflector 510 installed on the lower portion of the mount 130 of the support 100 and facing the reflector 510, A laser distance measuring instrument 520 for measuring a distance to the buoyant body 300 from the laser distance measuring instrument 520 and a distance measuring device 520 for measuring the distance from the buoyant body 300 to the buoyant body 300, And a control unit 530 for calculating the distance traveled by the buoyancy body 300 by subtracting the distance measured at the position where the buoyant body 300 has moved. In the present embodiment, the distance measuring apparatus 500 uses laser technology, but various techniques such as ultrasonic waves and infrared rays can be used as long as the distance can be measured.

The tide measuring unit 700 is installed in the installation part 130 of the support 100 and receives the calculated distance from the control unit 530 of the distance measuring device 500 and calculates the calculated distance from the existing tide data And measures the tilt at the position.

The transmitter 800 is installed in the installation part 130 of the support 100 and transmits the tide data measured by the tide measurement unit 700.

The coastal change predictor S includes a receiver S1 for receiving the tide data from the transmitter 800 of the tide meter T, a storage DB S2 for storing coastline location information according to tide, And a shoreline setting unit S3 for searching a shoreline position corresponding to the received tide from the storage DB S2 and setting the searched shoreline position as a shoreline for the tide.

9 to 11 are views for explaining the operation of the coastal change prediction system according to the present invention. The operation of the coastal change prediction system will be described with reference to FIGS. 9 to 11. FIG.

First, a toughening meter T is installed as shown in Fig.

At this time, in the daytime, as shown in FIG. 9, light is reflected to the wing portion 620 of the marking mechanism 600 and the installation position of the tide measuring instrument T is recognized well by the surrounding vessel, Collision is prevented. In addition, at night, the light emitting unit 630 blinks as shown in FIG. 9, and the position of the tidal meter T is known to the surrounding vessel.

On the other hand, when the tide measuring device according to the present invention is installed as shown in FIG. 2, when the tide is changed, the buoyant body 300 moves upward by a distance as shown in FIG. At this time, the laser distance measuring instrument 520 measures the distance between the buoyant body 300 and the mounting portion 130 of the support 100.

The control unit 530 of the distance measuring instrument 500 receives the distance signal from the laser distance measuring instrument 520 and measures the distance between the buoyant body 300 measured at the initial position of the previously stored buoyant body 300 and the support 100, The distance between the buoyant body 300 measured at the position where the buoyant body 300 has moved and the mounting portion 130 of the support 100 is subtracted from the distance between the mounting portions 130 of the buoyant body 300, And calculates the moved distance a.

Thereafter, the tide measuring unit 700 receives the calculated distance from the control unit 530 of the distance measuring unit 500, corrects the calculated distance from the existing tide data, and measures the tide at the corresponding position. At this time, the transmitter 800 wirelessly transmits the tide data measured by the tide measurement unit 700.

The receiver S1 of the coastal change predictor S receives the tide data from the transmitter 800 of the tide meter T and the coastline setting unit S3 receives the coastline position corresponding to the tide received from the receiver S1 From the storage DB (S2) and sets the searched coastline position as a coastline for the tide.

Meanwhile, in the tread height measuring apparatus T according to the present invention, the mating surface of the buoyancy body 300 and the inserting portion 210 of the guide base 200 can be mossed with time.

However, according to the present invention, when the buoyant body 300 is moved up and down, the foreign substance removing member 430 of the foreign substance removing mechanism 400 rubs against the surface of the insertion portion 210 of the guide pedestal 200, Remove the moss.

11, when the seawater flows into the foreign material removing mechanism mounting groove 320 of the buoyant body 300, the moving part 420 of the foreign material removing mechanism 400 is moved upward by buoyancy, The moving part 420 moves downward by the spring 440 of the foreign material removing mechanism 400 so that the removal of the moss by the foreign material removing body 430 of the foreign material removing mechanism 400 can be more easily removed.

In addition, since the foreign substance removing member 430 of the foreign substance removing mechanism 400 is elastic, when the foreign substance removing member 430 is in friction with the insertion portion 210 of the guide member 200, Lt; RTI ID = 0.0 > 210 < / RTI >

As described above, according to the present invention, it is possible to estimate the coastal change by setting the position of the coastline with respect to the tide after measuring the tide changing by the tide and the tide. have.

In addition, the present invention can prevent the ship or the like from colliding with the tread height measuring device T because the position of the tread depth measuring device T is easy to check.

Also, according to the present invention, the moss attached to the insertion portion 210 of the guide base 200 is removed at any time, thereby allowing the buoyant body 300 to stably ascend and descend even after a long period of time.

100; A support 110; Support
120; A locking part 130; Installation part
200; Guide base 210; The insertion portion
220; Lower engaging portion 230; The upper fastening portion
300; A buoyant body 310; Through hole
320; A foreign material removing mechanism mounting groove 400; Foreign matter removal mechanism
410; Guide portion 420; The moving part
430; A foreign matter removing body 500; Distance meter
510; Reflector 520; Laser distance measuring instrument
530; A control unit 600; Marker
610; A rotating portion 620; Wing portion
630; Emitting portion 640; The control unit
700; Tilt measurement unit 800; transmitter
T; Tachometer S; Coastal Change Predictor
S1; Receiver S2; Storage DB
S3; Coastline setting unit

Claims (1)

A supporting part 110 provided at the upper end of the supporting part 110 and a fixing part 120 provided at the upper end of the supporting part 110 and having a locking part 120, A support 100 having a streamlined mounting portion 130 located at a higher position; A rotation part 610 installed on the mounting part 130 of the support 100 so as to be rotatable in a clockwise or counterclockwise direction, a panel-shaped wing part 620 provided on the side of the rotation part 610 and equipped with reflection paper, And a control unit 640 installed at an upper portion of the rotation unit 610 to allow the light emitting unit 630 to be located at an upper portion and to make the light emitting unit 630 blink at night, (600); And has a through hole 211 penetrating up and down in the inside of the support 100 and a retaining groove 212 formed in the upper inside of the support 100 to receive the retaining part 120 of the support 100, An inserting portion 210 rotatably inserted into the supporter 110 in a clockwise or counterclockwise direction, a lower engaging portion 220 protruding outward at a lower end of the inserting portion 210, (200) having an upper latching part (230) protruded outward from an upper end of the guide base (200); And a foreign material removing mechanism mounting groove 320 which is opened downward and inwardly and communicates with the through hole 310 at a lower portion of the inserting hole 310, A buoyant body 300 of a circular plate shape inserted into the body 210 in a vertically movable manner and disposed between the lower latching part 220 and the upper latching part 230 of the guide pedestal 200; A guide portion 410 provided in the foreign material removing mechanism mounting groove 320 of the buoyant body 300 and having an opening groove 411 opened to the inside of the guide portion 410, A movable member 420 which is movably installed, a foreign matter removing member of elastic material having one end thereof meshed with the periphery of the inserting portion 210 of the guide base 200, A foreign matter removing mechanism 400 installed in the opening groove 411 of the guide part 410 and having a spring 440 elastically supporting the moving part 420 downward; A reflector 510 installed on the upper portion of the buoyant body 300 and a reflector 510 provided below the mounting portion 130 of the support 100 and opposed to the reflector 510 and extending from the mounting portion 130 to the buoyant body 300 A laser distance measuring instrument 520 for measuring a distance and a distance measuring system 520 for measuring a distance from the laser distance measuring instrument 520 to a position at which the buoyant body 300 has moved at a distance measured at the initial position of the buoyant body 300 A distance measuring instrument 500 having a control unit 530 for calculating the distance traveled by the buoyancy body 300 by subtracting a distance; Is installed on the mounting part 130 of the support 100 and receives the calculated distance from the control unit 530 of the distance measuring device 500 and corrects the calculated distance from the existing tide data, A tilt measurement unit 700 for measuring the tilt of the tilt sensor 700; And a transmitter 800 installed at the installation part 130 of the support 100 for transmitting the tide data measured by the tide measurement unit 700. The tide measuring machine T comprises:
A receiver S1 for receiving the tide data from the transmitter 800 of the tie meter T; A storage DB S2 for storing coastline location information according to tide; A shoreline setting unit (S3) for searching a shoreline position corresponding to a tide received from a receiver (S1) from a storage DB (S2) and setting the searched shoreline position as a shoreline for the tide;
And a coastal area estimation unit for estimating a coastal change of the coastal area based on tidal observations.

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