KR101682535B1 - surface current measuring drifter - Google Patents

Abstract

The present invention relates to a drifting buoy for observing a flow of surface water, which comprises: a box-shaped observer body; a floating body in a form of a donut, which surrounds the observer body; and a resistive plate body detachably attached to one surface of the observer body. The drifting buoy can analyze a flow of surface water having an arbitrary water depth by changing a length of the resistive plate body arbitrarily.

Description

A surface current measuring drifter observing surface water flow.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drift section for observing the surface water flow, and more particularly, to a drift section capable of observing the surface water flow at a water depth of 0 to 60 cm under the water surface.

Generally, an ocean current is a flow of seawater flowing in a certain direction. Once the current is known, it can be used as a resource to adequately respond to typhoons or tsunamis that could cause human casualties. In addition, fishermen moving along with ocean currents can be used as basic data for fisheries.

The ocean currents can be observed by using Eulerian measurement methods to measure and measure observation instruments such as an anemometer at a specific location, and Lagrangian knowledge measurement method using a buoyant buoy to observe ocean currents.

In particular, the Lagrangian method of measurement is an efficient method of measuring ocean currents to determine the spatial mobility of currents. Conventionally, a drift buoy as shown in Fig. 1 has been utilized to perform the Lagrangian method.

However, since the conventional drift portion is manufactured in a state in which the water depth to be measured is determined, various sizes of drift buoys have been required in order to analyze the ocean current at an arbitrary depth corresponding to the surface of water or the surface of water.

In addition, the conventional drifting part has a part protruding above the sea surface due to the shape characteristic, and the influence of the wind is excessively calculated, so that the flow of the pure surface layer current could not be observed. In other words, the reliability of the ocean current observation was low because the conventional drifting part drifted due to the influence of strong winds other than the ocean current.

Korean Registered Patent No. 10-1559491 (October 5, 2015)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a drift section for observing surface water flow capable of analyzing surface water movement of a surface layer and a specific water depth (0 to 60 cm under water surface).

In addition, the present invention provides a drift section that observes the surface water flow, which is less influenced by wind than conventional drift sections and improves the reliability of an ocean current observation.

According to an aspect of the present invention, there is provided a drift section for observing a surface water flow in an embodiment of the present invention. The drift section includes a box-shaped observer body, a donut-shaped floating body surrounding the observer body, And a resistance plate.

In addition, the observer body may further include an electromagnet disposed inside the observer body to incorporate an iridium communication module, a GPS tracker, a battery module, and a magnetic switch, and to operate the magnetic switch.

In addition, the resistance plate body includes a first plate body having one side detachably attached to one surface of the observer body so as to pass through the center of the observer body, a second plate body having one side detachably attached to one surface of the observer body, And a third plate member which is symmetrical with respect to the first plate member with respect to the first plate member and in which one side of the observer body is detachably attached to one side of the first plate member so as to be in close contact with the first plate member.

Further, a long guide groove for inserting one side of the first plate body is formed on one surface of the observer body, and a short guide groove for inserting one side of the second plate body or the third plate body is formed so as to be symmetrical about the long guide groove have.

Further, an opening is formed at one end in the longitudinal direction of the long guide groove or the short guide groove, and one side of the first plate body, one side of the second plate body, and one side of the third plate body, May be formed.

In addition, a shield for preventing the slide from being detached from the long guide groove or the short guide groove may be provided on the observer body.

In addition, the resistance plate includes a rectangular tube-shaped coupling part having one side contact with one surface of the observer body and a length-extending part inserted into the coupling part, and the length of the resistance plate is variable as the length- .

Also, a plurality of concentric length extension portions in the form of a multi-stage antenna may be inserted into the coupling portion.

In addition, a weight may be added to the longitudinal end of the resistance plate to be symmetrical with the observer body.

According to the drift section for observing the surface water flow of the present invention as described above, it is possible to analyze surface water movement at an arbitrary depth by arbitrarily changing the length of the resistance gate.

Particularly, the observer body is formed in a box shape so that the portion projecting to the upper part of the sea surface is minimized, and the floating body is attached to the outer periphery thereof, so that the height can be minimized and the buoyancy can be maximized. Thus, it is possible to observe the sea currents on the surface of the seawater by excluding the influence of the wind. Ultimately, the influence of the wind is eliminated and the reliability of the ocean current observation is improved.

1 is a schematic view of a conventional buoyant buoy,
Figure 2 is an illustration of a drift buoy that observe the surface water flow of an embodiment of the present invention,
FIG. 3 is an exemplary view of an observer body provided in a drift section for observing the surface water flow of FIG. 2;
FIG. 4 is an exemplary view of an observer body provided in a drift section for observing the surface water flow of FIG. 2;
FIG. 5 is an exemplary view of a floating body provided in a drift section for observing the surface water flow of FIG. 2;
FIG. 6 is a main part view of an observer body provided in a drift section for observing the surface water flow of FIG. 2;
FIG. 7 is an exemplary view of a resistance plate provided in a drift portion observing the surface water flow of FIG. 2; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals whenever possible.

In describing the present invention, a detailed description of related arts will be omitted in order not to obscure the gist of the present invention.

2 to 4, a drift unit for observing the surface water flow of an embodiment of the present invention includes a box-shaped observer body 100, a donut-shaped floating object 200 (see FIG. 2) surrounding the observer body 100, And a resistance plate body 300 detachably attached to one surface of the observer body 100.

In one embodiment of the present invention, the observer body 100 is fabricated in the form of a bobbin. An iridium communication module 110, a GPS tracker 120, a battery module 130, and a magnetic switch 140 are embedded in the observer body 100. In addition, one embodiment of the present invention further includes an electromagnet 400 positioned outside the observer body 100 to actuate the magnetic switch 140.

Due to the resistance generated when the sea water hits the resistance plate body 300, the drift portion of the embodiment of the present invention is moved in the same manner as the sea current at the depth of the water hit against the resistance plate body 300. At this time, the movement path observed through the GPS tracker 120 is transmitted to the observer through the iridium communication module 110.

When the electromagnet 400 is attached to the observer body 100, the magnetic switch 140 is operated to transmit an OFF signal to the Iridium communication module 110 and the GPS tracker 120. When the electromagnet 400 is moved to the observer body 100, The magnetic switch 140 is operated to transmit the ON signal to the Iridium communication module 110 and the GPS tracker 120. [

It is preferable that the electromagnet 400 is repeatedly pressed on and separated from the observer body 100 until the iridium communication module 110 can transmit and receive data normally with the satellite.

That is, by turning on and off the iridium communication module 110 and the GPS tracker 120 by using the magnetic switch 140 and the electromagnet 400, it is possible to control the iridium communication module 110 and the GPS tracker 120, The body 100 need not be separated. In addition, since the switch is not exposed to the outside of the observer body 100, breakage of the electric circuit by seawater is prevented.

The resistance plate body 300 includes a first plate body 310 having one side detachably attached to one surface of the observer body 100 so as to pass through the center of the observer body 100, A second plate member 320 having one side detachably attached to one surface of the observer body 100 and a second plate member 320 symmetrical to the second plate member 320 with respect to the first plate member 310, And a third plate body 330 having one side detachably attached to one surface of the observer body 100 so that one side is closely contacted.

In an embodiment of the present invention, the first plate 310, the second plate 320, or the third plate 330 is fabricated to have a height of 15 centimeters to 25 centimeters.

On the one surface of the observer body 100, a long guide groove 150 into which one side of the first plate body 310 is inserted is formed. A guide groove 160 is formed on one surface of the observer body 100 to insert a second plate 320 or a third plate 330 so as to be symmetrical about the long guide groove 150 .

Openings 151 and 161 are formed at one end in the longitudinal direction of the long guide groove 150 or the short guide groove 160. The one side of the first plate body 310, the one side of the second plate body 320 and the one side of the third plate body 330 are respectively inserted into the long guide grooves 150 or the short guide grooves 160 through the openings 151, The slides 311, 321 and 331 to be inserted are formed.

The observer body 100 is provided with shielding openings 152 and 162 for preventing the slides 311, 321 and 331 from being separated from the long guide groove 150 or the short guide groove 160. The shielding members 152 and 162 may be safety clip members that penetrate the long guide groove 150 or the short guide groove 160 and the first plate member 310 and the second plate member 320 or the third plate member 330 have. Alternatively, the latches that move in the width direction of the long guide grooves 150 or the short guide grooves 160 are attached to the openings 151 and 161, and the latches are always engaged with the latches to close the openings 151 and 161 It is also possible to form the shielding openings 152 and 162 by providing the latch with an elastic body for applying an elastic force.

The first plate member 310, the second plate member 320 and the third plate member 330 according to an embodiment of the present invention may be mounted on the long guide groove 150 or the short guide groove 160, And a length-extending portion 302 inserted into the engaging portion 301. The length-extending portion 302 is inserted into the engaging portion 301, and the length- The lengths of the first plate 310, the second plate 320 and the third plate 330 are varied as the length of the elongated portion 302 is moved in the height direction of the engaging portion 301.

A plurality of lengthwise extending portions 302 concentric with each other in the form of a multistage antenna may be inserted into the coupling portion 301 to form the first plate 310, the second plate 320 and the third plate 330 .

At the longitudinal end of the resistance plate 300, a weight 340 is provided so as to be symmetrical with the observer body 100. The weight 340 reduces the center of gravity of the buoyant buoy in one embodiment of the present invention, thereby preventing an embodiment of the present invention from escaping from seawater by external forces present in the waves and wind.

According to an embodiment of the present invention configured as above, the surface water movement at an arbitrary depth of water can be analyzed by arbitrarily changing the length of the resistance plate member 300.

Particularly, since the observer body 100 is formed into a cylindrical shape and the floating body 200 is attached to the outer periphery thereof, the height can be minimized and the levitation force can be maximized. Thus, it is possible to observe the sea currents on the surface of the seawater by excluding the influence of the wind. Ultimately, the surface water can more accurately observe the sea currents on the surface of the sea more accurately, and the sea currents of the shallow water, which are similar to the surface of the sea, can be observed without the influence of the wind.

As described above, the drift unit observing the surface water flow according to the present invention has been described with reference to the drawings. However, the present invention is not limited to the embodiments and drawings disclosed in the present specification, It is to be understood that various modifications may be made by those skilled in the art.

100: Observer body
110: Iridium communication module
120: GPS tracker
130: Battery module
140: Magnetic switch
150: Long guide groove
151: opening
152: shield
160:
161: opening
162: shield
200: Floating object
300: Resistance sheet
301:
302: length extension portion
310: first plate body
311: Slide
320: second sheet body
321: Slide
330: Third plate
331: Slide
340: Weights
400: electromagnet

Claims (9)

A box-shaped observer body;
A floating object in the form of a donut that surrounds the observer body; And
And a resistive plate detachably attached to one surface of the observer body,
The resistive plate member may include:
A rectangular tube-shaped coupling part having one side in contact with one surface of the observer body;
And a length extending portion inserted into the engaging portion,
Wherein the length of the resistance plate is variable as the length extension portion is moved in the height direction of the engagement portion.
The method according to claim 1,
In the observer body,
Iridium communication module, GPS tracker, battery module and magnetic switch,
Further comprising an electromagnet positioned outside the observer body to actuate the magnetic switch.
The method according to claim 1,
The resistive plate member may include:
A first plate having one side detachably attached to one surface of the observer body so as to pass through the center of the observer body;
A second plate having one side detachably attached to one surface of the observer body so that one side is in close contact with the first plate;
And a third plate which is symmetrical with respect to the first plate body with respect to the second plate body and one side of which is detachably attached to one surface of the observer body so that one side is in close contact with the first plate body, buoy.
The method of claim 3,
A long guide groove into which one side of the first plate is inserted is formed on one surface of the observer body,
And a step guide groove into which the one side of the second plate member or the third plate member is inserted so as to be symmetrical about the long guide groove is formed.
5. The method of claim 4,
An opening is formed at one end in the longitudinal direction of the long guide groove or the short guide groove,
And a slide inserted into the long guide groove or the short guide groove through the opening at one side of the first plate, one side of the second plate, and one side of the third plate are observed.
6. The method of claim 5,
And a shield for preventing the slide from being detached from the long guide groove or the short guide groove is provided in the observer body.
delete The method according to claim 1,
Wherein a plurality of longitudinal extension portions concentric with each other in the form of a multi-stage antenna are inserted into the coupling portion to observe the surface water flow.
The method according to claim 1,
And a drift portion for observing the surface water flow, the drift portion being provided at an end portion of the resistance plate in the longitudinal direction so as to be symmetrical with the observer body.

Images