KR20150092781A - Mooring boat type flow measurement equipment buoy - Google Patents

Abstract

The present invention relates to a mooring type hull-shaped buoy for a flow rate measurement device. The purpose of the presen tinvenoitn is to enable a measurement device to smoothly be installed since various measurement devices are installed. To achieve the purpose, the present invention comprises: a hull-shaped buoyant body penetrated by an opening; an upper frame having an upper fixing piece; a lower frame having the lower fixing piece; a fixing bolt fixating an upper and a lower frame to an upper and a lower surface of the hull-shaped buoyant body; a cover frame coupled and fixated to an upper portion side of the upper fixing piece; an equipment installation container having a transmitter and a battery therein; a fixing frame coupled and fixated to the inside of the opening; an ADCP support frame; an ADCP protection frame; and a bow reinforcement frame.

Description

[0001] Mooring boat type flow measurement equipment buoy for flow measurement equipment [

More particularly, the present invention relates to an anteroposterior linear body part for measuring a flow velocity, and more particularly, to an anteroposterior linear body part formed by integrally forming an isosceles triangular prism part before and after a rectangular body, (ADCP) installed on the upstream side of the mooring so as to be positioned upstream of the mooring buoyant body, thereby reducing the hydraulic pressure applied to the moored buoyant body to enable stable mooring.

In general, the flow velocity of a river or ocean is measured by measuring the surface velocity of the buoy by measuring the velocity of the buoy, or measuring the velocity of the water by measuring the feed rate .

However, since the flow velocity distribution by the water depth can not be uniform regardless of the river or the ocean, it is not possible to grasp the entire flow velocity distribution only by the surface flow velocity, and the measurement error due to the surface flow velocity in the case of the rod float, But also a flow rate of a specific water depth can be measured, but there is a limit in which only a flow rate of about three points can be obtained.

Therefore, it is possible to grasp the flow velocity distribution by the depth of the water such as the acoustic Doppler flowmeter or the optical Doppler flowmeter, but also a flowmeter having a high precision is developed and used. However, these flowmeters have a problem that a structure capable of installing a flowmeter such as a bridge or a ship is required.

Since the structure itself having the flow velocity meter such as a bridge or a ship as described above affects the flow of the surrounding fluid, the accuracy of the measurement itself is excellent, but the measurement value does not reflect the actual behavior of the water area do.

In particular, it is difficult to secure fixed facilities such as bridges. In the case of ocean flow measurement, it is necessary to use the vessel, which is very costly and it is virtually impossible to sufficiently separate the vessel and the anemometer. A problem arises.

In addition, the above-described structures such as bridges and ships can act as a kind of wave-proof or so-called wave structure, which can have a profound effect on wave measurement.

Therefore, it is possible to consider using a drift type or a stream type to connect a measuring device such as an anemometer to the bottom of a buoy, to transmit measurement values, or to collect a recording medium later. However, Drift type measurement is not possible in the river where the flow velocity measurement is required, and there is a risk that the mooring line is broken or the loss risk due to the hydraulic pressure even in the case of the floating type buoy.

The above-described damage or loss of risk is a problem in which the wave is observed not only in the flow velocity measurement but also in the waves such as wave, wave, and wave using the acceleration sensor. Therefore, It can be said that the damage caused by the breakage or the loss is greater.

In particular, when an anemometer is installed in the lower part of the buoy, it is impossible to measure the upper water level of the anemometer, that is, the surface velocity and the velocity immediately under the water surface. In wave measurement, the motion of the buoy by the wave is called an acceleration sensor Since the sensor is difficult to closely follow, there are many problems in securing measurement accuracy.

In order to solve the above-mentioned problems, a hull-type flow velocity and wave measuring apparatus (patent publication No. 2013-0074436 (published on July 31, 2014)) and a buoyant flow velocity and wave measuring apparatus 2013-0074478 (published on July 31, 2014)) was filed and filed. However, such a hull type measuring device occasionally broke the buoyant body at a strong flow velocity in the mooring area and was damaged.

In addition, since the sound wave velocity meter (ADCP) provided on the opening of the buoyancy body is exposed to a strong flow velocity as it is, the prior art measurement apparatus according to the related art as described above is not affected by a strong flow velocity, There is a problem that an error occurs in the measurement due to attachment of shellfish such as a barnacle.

1. Korean Patent Publication No. 2010-0094131 (published on Aug. 26, 2010) 2. Korean Patent Laid-open No. 2013-0074436 (Released on July 4, 2013) 3. Korean Patent Laid-Open No. 2013-0074478 (Released on July 4, 2013)

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve all of the problems of the prior art, and it is an object of the present invention to provide a frame structure on a top surface and a bottom surface of a linear body-like buoy body formed integrally with an isosceles triangular- The present invention is directed to providing a hydrofoil-type piping for a flow measuring instrument that enables the installation of a measuring instrument by allowing the piping system to be installed and fixed.

Another object of the present invention is to provide a buoyant buoyant body which covers a lower portion of an opening formed on a central portion of a linear-shaped buoyant body formed integrally with an isosceles triangular-shaped fore and aft body before and after a rectangular body, And to protect the measuring equipment.

In addition, the technique according to the present invention can prevent damage to the buoyant body from a strong flow velocity by providing a protective frame on the forefront of a linear-shaped buoyant body integrally formed with an isosceles triangular- There is a purpose.

Further, in the technique according to the present invention, the isosceles buoyant body formed integrally with the isosceles triangular-shaped forefoot portion before and after the rectangular trunk is formed so that the forefoot portion is positioned upstream of the mooring, thereby reducing the hydraulic pressure acting on the snout- The purpose is to make stable mooring possible.

The present invention configured to achieve the above-described object is as follows. That is, the mooring type bulb-type part for measuring the flow velocity according to the present invention is formed by integrally forming an isosceles triangular-shaped bow part before and after a rectangular body, and having a certain thickness through which an opening is vertically passed through the center part of the body; An upper frame formed in an isosceles triangle shape in front of and behind the rectangle corresponding to the upper surface shape of the linear body floating body, the upper fixing piece having a predetermined length in the diagonal direction of the rectangle; A lower frame formed in the shape of an isosceles triangle in front of and behind the same rectangle as the upper frame and having a lower fixed piece formed in a rectangular diagonal direction corresponding to the upper fixed piece; A fixing bolt fixing the edges of the upper and lower frames to the upper and lower surfaces of the linear body buoyancy body through engagement with the fixing nut, the fixing bolt fixing rings being formed at the lower ends thereof; A cover frame fixedly coupled to the upper portion of the upper fixing piece through a rod-fixing bolt for vertically coupling the upper and lower fixing pieces, the cover frame being formed at a corner corresponding to the upper fixing piece of the upper frame; An apparatus mounting barrel fixed to the upper side of the cover frame and having a water dropping groove formed at a lower end thereof and a cover window covering the upper end thereof, the transmitter and the battery being mounted inside; A fixed frame having a fixed engagement piece formed at an edge thereof corresponding to the upper and lower fixed pieces of the upper and lower frames and coupled to the inside of the opening through the rod-shaped fixing bolt, An ADCP support frame installed at the lower part of the fixed frame and supporting a sound wave velocity meter (ADCP) on the center part so as to be rotatable in the front, An ADCP protection frame having an edge to be fixed to the lower fixing part and having an acoustic wave transmission window at a central portion through which the edge is penetrated; And a bow reinforcement frame covering each of the fore and aft bow portions of the linear body buoyant body and reinforcing the forward portion and the body by a strong flow velocity or floating object.

In the structure according to the present invention as described above, each of the lower fixing pieces of the lower frame may be configured to be rotatable about a fixing bolt as a rotation axis.

In the configuration according to the present invention as described above, the fixing bolt is formed by combining six corners of each corner of the trunk with the tip corner of the forefront of the front and rear isosceles triangle, but the fixing bolt is formed at each of the corners of the lower frame And a fixing nut is fastened to the upper end of the upper body through the upper coupling hole formed in each of the corners of the upper frame through the lower body coupling hole, And the lower frame may be fixed.

In addition, the upper end of each of the fixing bolts constituting the present invention may have a structure in which a crane lifting hook is provided to allow a cable to be hooked when lifting the hull-shaped portion by using a crane.

Meanwhile, in the structure according to the present invention, the ADCP support frame is installed on the lower part of the fixed frame, A rotary ring provided on the inner ring surface of the support plate so that both outer sides or front and rear sides of the outer ring are rotatable about the hinge axis in the forward, An inner ring coupling ring which is provided on the inner ring surface of the rotary ring so as to be rotatable on the front and rear sides of the outer diameter or on both sides through the hinge shaft in the left or right or front and rear directions and is divided into two parts and joined at both sides of the outer periphery of the upper body of the sound wave flowmeter ADCP; And the inner ring coupling ring are divided into two halves to complete a single ring through tightening of both sides to thereby support the sound wave flowmeter ADCP.

In the construction according to the present invention as described above, the linear portion is connected to the fixing rope fixing ring formed at the lower end of each of the fixing bolts and is moored to the water surface of the mooring region through a fixing rope fixed to the sea floor, As shown in Fig.

Further, in the structure according to the present invention, the forward portion reinforcing frame may be integrally fixed to the upper and lower frames by fixing bolts.

In addition to the above-described configuration, a bolt through-hole is further extended in the diagonal direction of the body in the opening of the linear-shaped buoyant body, and the upper end and the nut of the rod-shaped fixing bolt penetrate through the bolt through- A lower fixing part of a lower frame installed on a lower surface of the linear body-shaped buoy body by a lower end of the rod-shaped fixing bolt and a nut; The edge of the ADCP protective frame may be fixedly coupled and the fixed joint of the fixed frame may be coupled and fixed by a rod fixing bolt and a nut at the inside of the opening.

In addition, in the structure according to the present invention, when the cover frame is installed and fixed to the upper part of the upper frame, a shock absorbing damper for absorbing and dispersing an impact may be further disposed between the upper fixing part of the upper frame and the cover engaging piece of the cover frame .

The upper and lower CTD fasteners integrally formed on the same line from the center of the isosceles triangle bottom of one of the upper and lower frames to the vertex of the upper and lower frames, respectively; A CTD insertion hole formed vertically above and below the bow of the linear type buoyant body between the upper and lower CTD fixing pieces, into which a water temperature saline water depth recorder (CTD) is inserted; A CTD coupling piece coupled to the upper or lower end of a water temperature saline water depth recorder (CTD) inserted into the CTD insertion hole; And a CTD fixing means composed of a CTD fixing screw and a nut for fastening and fixing the CTD coupling piece to the upper or lower CTD fixing piece.

Further, according to the present invention, there is provided an OBS fixture integrally formed on one side of a frame forming an anterior isosceles triangle of a lower frame, which is close to a lower CTD fixing fixture, to integrally fix an optical backscattering sensor (OBS); And an OBS fixing means composed of a bracket fastened and fixed on the OBS fixing piece and fastening and fixing the optical backscattering sensor (OBS).

In addition, the present invention may further comprise a flashing light support frame fixedly coupled to one side of the equipment mounting barrel or one side of the upper frame to fix and support the flashing light.

Further, the present invention provides an auxiliary frame which is formed by extending a predetermined length to both sides of a linear body-like buoyant member along the upper and lower side upper surfaces of a rectangular portion of an upper frame; And an overturning preventing means provided on each of both sides of the auxiliary frame, the overturning preventing means being provided in the longitudinal direction in the longitudinal direction to prevent overturning of the linear-shaped buoyant body.

According to the technique of the present invention, by providing a frame on the upper and lower surfaces of a linear body-like buoyant body formed integrally with an isosceles triangular-shaped fore and aft body before and after a rectangular body, various measurement equipment can be installed and fixed, The advantage of enabling installation is manifested.

In addition, the technique according to the present invention has the advantage that the measuring equipment can be protected from strong flow velocity, floating substances and shellfish through a protective cover covering the lower side of the opening formed on the central portion of the linear body-like buoyant body.

In addition, the technique according to the present invention can prevent damage to the buoyant body from a strong flow velocity by providing the reinforcing frame on the forefront of the linear body-like buoyant body formed integrally with the isosceles triangular-shaped foregin part before and after the rectangular body.

Further, in the technique according to the present invention, the isosceles buoyant body formed integrally with the isosceles triangular-shaped forefoot portion before and after the rectangular trunk is formed so that the forefoot portion is positioned upstream of the mooring, thereby reducing the hydraulic pressure acting on the snout- It is advantageous that stable mooring is possible.

FIG. 1 is a perspective view showing a mooring type hull-like part for a flow measuring instrument according to the present invention. FIG.
FIG. 2 is a perspective view showing a mooring type hull type joint for a flow measuring instrument according to the present invention. FIG.
FIG. 3 is a side view showing the flow-type hull-shaped member for measuring a flow velocity according to the present invention. FIG.
FIG. 4 is a plan view showing an upper frame of a hydrofoil hull type buoy for a flow measuring instrument according to the present invention. FIG.
FIG. 5 is a bottom view showing a lower frame of a moored hull type buoy for a flow measuring instrument according to the present invention. FIG.
6 is a cross-sectional view taken along the line A-A '' in Fig. 3;
FIG. 7 is a bottom view showing an ADCP support frame of a hydrofoil hull type buoy for a flow measuring instrument according to the present invention. FIG.
FIG. 8 is a perspective view showing another embodiment of a floating type hull type buoy for a flow measuring instrument according to the present invention. FIG.

Hereinafter, a mooring type hull-shaped part for measuring a flow velocity according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing a mooring type hull-like part for measuring a flow velocity according to the present invention, FIG. 2 is a perspective view showing a combined mooring hull type part for measuring a flow velocity according to the present invention, Fig. 4 is a plan view showing a top frame of a mooring type hull type buoy for a flow measuring instrument according to the present invention, Fig. Fig. 6 is a cross-sectional view taken along the line A-A 'in Fig. 3, and Fig. 7 is a sectional view taken along the line A-A' of the flow velocity measurement equipment according to the present invention. FIG. 8 is a perspective view showing another embodiment of a hydrofoil hull type buoy for a flow measuring instrument according to the present invention. FIG. 8 is a bottom view showing an ADCP support frame of a hull type buoy.

As shown in FIGS. 1 to 7, in the flow-type hull type buoy 100 for a flow measuring instrument according to the present invention, a forefront bulged portion 112 is integrally formed before and after a rectangular body, Shaped bodily buoyant body 110 having a predetermined thickness formed by vertically passing through the opening 114 and an isosceles triangular shape in front of and behind the rectangle corresponding to the upper surface shape of the bodily buoyant body 110, An upper frame 120 formed with a fixed length of upper fixing piece 122 and an upper frame 120 are formed in the shape of an isosceles triangle before and after the same rectangle as the upper frame 120, The upper and lower frames 120 and 130 are fixed to the upper and lower surfaces of the lower body frame 130 in which the fixing pieces 132 are formed and the upper and lower surfaces of the body 10 through the coupling with the fixing nuts 144, There A fixing bolt 140 having fixing rods 142 formed thereon and cover engaging pieces 152 formed at corners corresponding to the upper fixing pieces 122 of the upper frame 120. The upper and lower fixing pieces 122, A cover frame 150 fixedly connected to the upper side of the upper fixing piece 122 through a rod fixing bolt 200 which vertically couples the upper and lower fixing frames 122 and 132 to each other, And a cover window 164 covering an upper end of the upper frame 120 and the lower frame 120. The upper frame 120 and the upper frame 120 are provided with a detachable groove 162 and a cover window 164 for covering the upper end, A fixed frame (172) is formed at a corner corresponding to the lower fixing pieces (122, 132) and fixedly coupled to the inside of the opening through a bar-shaped fixing bolt, 170), and a sound wave velocity meter (ADCP) 30 provided on the lower portion of the fixed frame 170 on a central portion thereof An ADCP protective frame 180 having an acoustic wave transmission window 182 at a central portion through which the respective corners are fixedly coupled to the lower fixing piece 132, And a skeleton reinforcing frame 190 covering each of the front and rear skirts 112 of the buoyant body 110 to reinforce the skirts 112 and the body by a strong flow velocity or floating object.

The buoyant buoy 100 according to the present invention constructed as described above is constructed such that the bow portion 112 is positioned in the same direction as the mooring flow of the mooring region, and the fixing rods 142 formed at the lower end of each of the fixing bolts 140, And is fixed to the water surface of the mooring area through a fixing rope 60 fixed to the sea floor.

As described above, the fixed frame 170 and the ADCP 170 are provided in the opening 114 of the linear body-shaped buoy body 110 constituting the linear type buoy 100 moored to the water surface of the mooring area through the fixed rods 60, Since the sound wave velocity meter ADCP 30 supported by the support frame 174 is protected by the ADCP protective frame 180 which is fixedly coupled to the rectangular portion of the lower frame 130 and covers the lower portion of the opening 114, It is possible to prevent the flow velocity and the damage from the floating object.

As described above, since the sound wave velocity meter (ADCP) 30 is coupled to the rectangular portion of the lower frame 130 and is protected by the ADCP protective frame 180 covering the lower portion of the opening 114, Can be prevented from being adhered to the sound wave generation site, thereby preventing a problem that a measurement error may occur due to attachment of the shellfish.

The bow-shaped buoy 100 according to the present invention comprises a bow-side reinforcement frame 190 covering the entire side end portion of the bow portion 112 forming the front and rear of the linear-shaped buoyant body 110 and a part of the side end portion of the body It is possible to prevent tearing or breakage due to a strong flow velocity or collision with a floating object.

Each component constituting the mooring type hull type buoy 100 for the flow measuring instrument according to the present invention will be described in more detail as follows. First, as shown in FIGS. 1 to 6, the linear body-like buoyant body 110 constituting the present invention is suspended and floated on the sea surface so that the linear body-like buoyant body 110 can be moored before and after the rectangular body An isosceles triangle-shaped bow portion 112 is integrally formed, but the opening portion 114 is vertically passed through the central portion of the body.

As described above, the linear body-shaped buoyant body 110, which is formed integrally with the isosceles triangular-shaped fore-and-aft part 112 before and after the rectangular body, and the opening part 114 is vertically passed through the central part of the body, Even with the measuring equipment installed, it should be of sufficient thickness to allow sufficient buoyancy to float on the surface of the sea.

On the other hand, the opening 114 formed on the rectangular center portion of the above-mentioned linear body-shaped buoyant body 110 is formed as a rectangular shape through the upper and lower portions. At this time, an elongated bolt through-hole 116 is further formed in the opening 114 of the linear-shaped buoyant body 110 in the diagonal direction of the body. That is, the bolt through holes 116 are formed in the diagonal direction of the body from each of the corners of the opening 114 formed in a rectangular shape. The bolt through-holes 116 of such a groove are also formed to pass through the top and bottom.

As described above, the bolt through holes 116 formed in the shape of the grooves in the corners of the opening 114 will be described later.

The upper frame 120 constituting the present invention reinforces the linear-shaped buoyant body 110 together with the lower frame 130 installed on the lower surface of the upper portion of the linear-shaped buoyant body 110, 1 to 6, the upper frame 120 is formed in an isosceles triangle shape in front of and behind the rectangle corresponding to the upper surface shape of the linear-shaped buoyant body 110, And a fixing piece 122 is formed.

As described above, the upper frame 120 configured as described above is formed in an isosceles triangle arrangement in front of and behind a rectangle, such as the upper surface shape of the linear-shaped buoyant body 110. At this time, the upper frame 120 is not formed in a plate shape covering the entire upper surface of the linear body-shaped buoyant body 110 but has a frame shape.

On the other hand, the upper fixing piece 122 formed in the rectangular diagonal direction of the upper frame 120 configured as described above is formed to have a predetermined length in the diagonal direction inside the corner of the rectangle.

The lower frame 130 constituting the present invention reinforces the linear body buoyant body 110 together with the upper frame 120 installed on the lower side of the linear body buoyant body 110, 1 to 6, the lower frame 130 is formed in the shape of an isosceles triangle in front of and behind the same rectangle as the upper frame 120, and is formed in a shape of an isosceles triangle in the diagonal direction of the rectangle corresponding to the upper fixing piece 122 And a fixing piece 132 is formed.

As described above, the lower frame 130, which is formed in the shape of an isosceles triangle before and after the same rectangle as the upper frame 120, has the same shape and size as the upper frame 120. The lower fixing piece 132 formed in the rectangular diagonal direction of the lower frame 130 is fixed to the upper and lower frames 120 and 130 for fixing the upper and lower frames 120 and 130 on the upper and lower surfaces of the linear- And is configured to be rotatable from side to side with the fixing bolt 140 as a rotation axis.

Meanwhile, the lower frame 130 configured as described above is also formed in a shape in which isosceles triangles are arranged before and after a rectangle such as the lower surface shape of the linear body-shaped buoyant body 110, as described above. At this time, the lower frame 130 is not formed in a plate shape covering the entire lower surface of the linear body-shaped buoyant body 110 but has a frame shape.

The fixing bolts 140 constituting the present invention are for fixing the upper and lower frames 120 and 130 on the upper and lower surfaces of the linear buoyant body 110, As shown in FIGS. 1 to 6, the upper and lower frames 120 and 130 are fixed to the upper and lower surfaces of the linear-shaped buoyant body 110 through engagement with the fixing nut 144, And the fixing rope fixing ring 142 is formed.

The fixing bolt 140 configured as described above has a longer length than the combined thickness of the linear body buoyant body 110 and the upper and lower frames 120 and 130. The fixed bolt 140 is formed by six corner portions of the rectangle of the body of the linear body portion 110 and an end edge of the fore and aft isosceles triangle,

Each of the fixing bolts 140 is inserted through the lower coupling hole 134 formed at each corner of the lower frame 130 and is formed in correspondence with the position of the lower coupling hole 134, Through holes on the substrate 110. The fixing bolts 140 penetrating through the through holes on the linear body member 110 are formed in the upper fitting holes 124 formed in the corners of the upper frames 120 positioned on the upper surface of the linear body- ).

The fixing nut 144 is fastened to the upper ends of the fixing bolts 140 passing through the lower frame 130, the linear body buoyant body 110 and the upper frame 120, The lower frame 130 is tightly fixed on upper and lower surfaces of the linear body-shaped buoyant body 110. As a result, the shape of the linear body-shaped buoyant body 110 is reinforced and held by the upper and lower frames 120 and 130.

As described above, the fixing rods 142 are formed at the lower ends of the fixing bolts 140 for fixing the upper frame 120 and the lower frame 130 on the upper and lower surfaces of the linear-shaped buoyant body 110, The fixed rope 60 is connected to the seabed so that the bow-shaped boats 100 according to the present invention are moored to the water surface of the mooring area.

Next, the cover frame 150 constituting the present invention is for covering the upper portion of the opening 114, and the cover frame 150 is formed by covering the upper portion of the opening portion 114 as shown in FIGS. 1, 2, 4, A cover engagement piece 152 is formed at an edge corresponding to the upper fixing piece 122 of the frame 120. The cover engagement piece 152 is fixed to the upper and lower fixing pieces 122, And is fixedly coupled to the upper side of the upper fixing piece 122.

The cover frame 150 as described above is fixedly coupled to the upper side of the upper fixing piece 122 through the rod-fixing bolts 200 which vertically couple the upper and lower fixing pieces 122 and 132, 110, and the equipment mounting cylinder 160, which will be described later, is installed at the upper center.

1 to 4 and 6 illustrate an apparatus mounting cylinder 160 according to the present invention for mounting a transmitter 10 and a battery 20 therein. As shown in the figure, the cover frame 150 is fixed to a central portion of the upper side of the cover frame 150, and includes a water dripping groove 162 formed at the lower end and a cover window 164 covering the upper end.

The equipment mounting cylinder 160 configured as described above is fixed on the cover frame 150 via a mounting bar fixing piece 166 which is positioned above the center of the cover frame 150 and installed at a predetermined interval at the lower end.

As described above, the transmitter 10 installed in the equipment mounting cylinder 160 transmits the positions of the linear type buoy 100 moored on the sea surface at intervals of one hour. In the present invention, the CDMA transmitter is used Respectively. A battery 20 for supplying power to the CDMA transmitter 10 is mounted in the equipment mounting case 160.

In the case where water is introduced into the equipment mounting cylinder 160 due to rain or high waves, the water dropping grooves 162 formed at regular intervals on the lower end of the equipment mounting cylinder 160 constituted as described above, To the outside.

Next, the fixed frame 170 constituting the present invention supports the ADCP support frame 174, which will be described later, to support the sound wave velocity meter (ADCP) 30, A fixing engagement piece 172 is formed at an edge corresponding to the upper and lower fixing pieces 122 and 132 of the upper and lower frames 120 and 130 as shown in FIGS. 4 and 6, 200 through the center of the opening 114, but the central portion of the opening 114 passes through the central portion.

The fixed frame 170 constructed as described above is fixed to the upper and the lower fixing pieces 122 of the upper frame 120 by fastening the bar fixing bolt 200 and the nut . Such a rod fixing bolt 200 will be described later.

Next, the ADCP support frame 174 constituting the present invention supports an acoustic Doppler current profiler (ADCP) in a manner such that it can rotate back and forth and right and left within a certain range within the opening 114 of the hull type buoyancy body 110 1, 6, and 7, the ADCP support frame 174 is installed at a lower portion of the fixed frame 170, and supports a sound wave velocity meter (ADCP) 30 in the front, back, And is rotatably supported in a certain range.

More specifically, the above-described ADCP support frame 174 is mounted on a lower portion of the fixed frame 170, as shown in Figs. 6 and 7, and is provided with a support plate 174a-1 through which an opening hole 174a- A rotating ring 174b provided on the inner ring surface of the supporting plate 174a so as to be rotatable forward or rearward or right and left via the hinge shaft on both sides of the outer diameter or on the inner and outer surfaces of the rotating ring 174b, The inner ring coupling ring 174c and the inner ring coupling ring 174c, both of which are rotatably installed on the left and right or front and rear sides of the hinge shaft, are divided into two halves and are coupled at both sides of the outer peripheral surface of the upper body of the sound wave velocity meter (ADCP) And a tightening means 174d for tightening the both ends of the ring to complete a single ring to support the sound wave velocity meter ADCP30. The tightening means 174d are bolts and nuts.

The ADCP support frame 170 configured as described above is configured to support and support a sound wave velocity meter (ADCP) 30 through an inner ring coupling ring 174c to generate a sound wave velocity meter (ADCP: 30) can be rotated around the front, rear, left and right by a certain range, so that the sound wave velocity meter (ADCP: 30) according to the flow velocity can be offset.

Next, the ADCP protective frame 180 constituting the present invention is used to protect the sound wave velocity meter (ADCP) 30 located inside the opening 114 of the linear-shaped buoyant body 110 by the ADCP support frame 174 As shown in FIGS. 1, 3, 5 and 6, the ADCP protective frame 180 is fixedly coupled to the lower fixing piece 132 by respective corners, and is provided with a sound transmission window 182 As shown in FIG.

The ADCP protective frame 180 constructed as described above covers the underside of the opening 114 of the linear body buoyant body 110 so that a strong flow velocity does not act on the acoustic wave velocity meter ADCP 30, So that the same shell does not adhere to the portion where the sound wave below the sound wave velocity meter (ADCP) 30 is generated.

Meanwhile, the sound wave transmission window 182 of the ADCP protection frame 180 configured as described above is a window that allows sound waves generated from the sound wave velocity meter (ADCP) 30 to be easily transmitted. The sound wave transmission window 182 ) Is made of a synthetic resin material.

The ADCP protective frame 180 which is fixed to the lower fixing piece 132 on the lower frame 130 as described above is formed in a state in which each corner portion overlaps the lower fixing piece 132 of the lower frame 130 And is fixed by fastening the nut and the rod fixing bolt 200 as described above.

Next, the bow portion reinforcing frame 190 constituting the present invention is to prevent the bow portion 112 of the linear-shaped buoyant body 110 from being torn or broken from a strong flow velocity or floating object, and such a bow portion reinforcing frame 190 As shown in FIGS. 1 to 6, each of the fore and aft forehead portions 112 of the linear body-like buoyant body 110 is covered to reinforce the forehead portion 112 and the body by a strong flow velocity or floating object.

The fore-aft reinforcing frame 190 as described above covers the entire side end portion of the fore-end portion 112 forming the front and rear of the linear-shaped buoyant body 110 and a part of the side end portion of the body so that a strong flow velocity, It is possible to prevent tearing or breakage caused by the above. At this time, the bow portion reinforcing frame 190 is integrally fixed to the upper and lower frames 120 and 130 by the fixing bolts 140 described above.

In other words, the bow portion reinforcing frame 190 as described above is mounted on the upper and lower frames 120 and 130 by the fixing bolts 140 formed by three front and rear parts, which are connected to the front and rear corners of the linear body buoyant body 110, As shown in FIG.

The boats 100 according to the present invention constructed as described above are connected to the fixing rods 142 formed at the lower ends of the fixing bolts 140 and are fixed to the sea floor through the fixing rods 60, It is moored to the surface of the water. At this time, the boat type buoy 100 is installed so that the bow sides on both sides are positioned in the flow direction of the mooring.

Therefore, by placing the fixed cutting-off hooks 142 of the hull-shaped buoy 100 in the mooring area through the fixing rods 60 so that the both sides of the bow are moored in the same direction as the mooring flow direction, (100) minimizes the resistance to mooring and can prevent overturning of the bow-type boom (100).

In the configuration of the linear vane 100 according to the present invention, the fixing bolts 140 are formed by joining six corners to each of the corners of the rectangle of the body of the linear body-shaped buoyant body 110 and the end edges of the fore and aft isosceles triangles, . The fixing bolts 140 are inserted through the lower coupling holes 134 formed at the respective corners of the lower frame 130 and pass through the linear body buoyant body 110, The upper and lower frames 120 and 130 are fixed on the upper and lower surfaces of the linear-shaped buoyant body 110 by fastening the fixing nut 144 to the upper end thereof while passing through the hole 124.

In addition, in the technology according to the present invention, in addition to the above-described structure, a crane lifting ring 146 is provided at the upper end of each of the fixing bolts 140 to allow the cable to be lifted when lifting the hull- . At this time, the crane lifting ring 146 is engaged and fixed to the upper end of the fixing bolt 140 through a screw connection.

In addition to the above-described configuration, bolt through holes 116 are formed in the openings 114 of the linear-shaped buoyant body 110 in the diagonal direction of the body. That is, as shown in FIGS. 1, 2, and 6, bolt through holes 116 are formed in the corners of the opening 114 formed in a rectangular structure in the rectangular diagonal direction of the body.

On the other hand, the bar-shaped fixing bolts 200 and the nuts are formed up and down through the bolt through holes 116 formed as described above. That is, the upper fixing piece 122 of the upper frame 120 installed on the upper surface of the linear-shaped buoyant body 110 by the upper end of the rod-shaped fixing bolt 200 passing through the bolt through- And a lower frame 130 provided on a lower surface of the linear body-shaped floating body 110 by a lower end of the rod-shaped fixing bolt 200 and a nut, The ADCP protective frame 180 and the lower fixing member 132 of the fixing frame 170 are fixedly coupled to each other by the rod fixing bolts 200 and the nuts at the inner side of the opening 114, 172 are coupled and fixed.

When the cover frame 150 is fixed to the upper part of the upper frame 120 according to the present invention, the upper fixing part 122 of the upper frame 120 and the cover engaging pieces 152 of the cover frame 150 The shock absorbing damper 210 may be further constructed.

By providing the shock absorbing damper 210 between the upper fixing piece 122 of the upper frame 120 and the cover engaging piece 152 of the cover frame 150 as described above, The shock caused by the collision with the ship is absorbed and dispersed by the shock absorbing damper 210 so that the impact to the equipment mounting cylinder 160 through the cover frame 150 can be reduced. Thus, the impact on the transmitter 10 and the battery 20 can be minimized.

In addition, the present invention further comprises a CTD fixing means for fixing a water temperature saline water depth recorder (CTD) as shown in FIG. At this time, the CTD fixing means includes upper and lower CTD fixing pieces 126 and 136 integrally formed on the same line from the center of the isosceles triangle bottom side of each of the upper and lower frames 120 and 130 to the vertex, upper and lower CTD fixing The CTD insertion hole 118 and the CTD insertion hole 118 are formed on the bow portion 112 of the linear body buoyant body 110 between the pieces 126 and 136 so as to be inserted into the water depth saline water depth recorder A CTD fastening screw 220 for fastening the CTD coupling piece 220 and the CTD coupling piece 220 to the upper or lower CTD fastener to be coupled to the upper or lower end of the water temperature saline water depth recorder (CTD) And a nut (222).

As described above, the bow-shaped buoy 100 according to the present invention has a frame structure in which not only a sound wave velocity meter (ADCP) 30 but also a water temperature saline water depth recorder (CTD) 40 can be installed as described above.

Furthermore, the present invention further comprises OBS fixing means for fixing the optical backscattering sensor (OBS) 50 as shown in Fig. The OBS fixing means is integrally formed on one side of the frame forming the forefront side of the isosceles triangle of the lower frame 130, which is close to the lower CTD fixing piece 136, to fix the OBS fixation (OBS) And a bracket 232 fastened and fixed on the OBS fixture 230 and the OBS fixture 230 to fix the OBS 50 thereto.

As described above, as described above, the optical body backbone 100 according to the present invention is provided with an optical backscattering sensor (OBS) 30, which is a so-called turbidimeter, as well as a sound wave velocity meter (ADCP) 30 and a water temperature salinity water depth recorder : 50) can be installed.

The present invention further includes a flashing support frame 240 fixed to one side of the equipment mounting case 160 or one side of the upper frame 120 to fix and support the flashing lamp 242.

Furthermore, as shown in FIG. 8, the linear type buoy 100 according to the present invention further comprises a rollover prevention means for preventing the overturning of the linear type buoy 100 when it is moved. The rollover preventing means includes an auxiliary frame 250 extending along both sides of the linear body-shaped buoy body 110 along the upper and lower upper surfaces of the rectangular portion of the upper frame 120, And an auxiliary buoyant body 252 installed longitudinally in the front and rear direction to prevent overturning of the linear body buoyant body 110.

The rollover prevention means configured as described above can be rolled over when the fixed barrel 60 is removed from the linear barriers 100 and the linear barriers 100 are moved using a ship. At this time, the rollover prevention means prevents the rollover-type buoy 100 from being rolled over from side to side.

As described above, according to the present invention, the frames 120 and 130 are installed on the upper and lower surfaces of the linear body-shaped buoy body 110 formed integrally with the isosceles triangle- So that the measurement equipment can be installed smoothly, and the damage of the linear-shaped buoyant body 110 can be prevented from a strong flow velocity. In addition, it is an object of the present invention to enable stable mooring by reducing the hydraulic pressure acting on the boat-shaped buoy 100.

The present invention is not limited to the above-described embodiments, and various modifications may be made within the scope of the technical idea of the present invention.

10. Transmitter 20. Battery
30. Acoustic Doppler Current Profiler (ADCP)
40. Water temperature salt depth recorder (CTD) 50. Optical backscattering sensor (OBS)
100. Line type buoy 110. Line type buoyancy type
120. Upper frame 130. Lower frame
140. Fixing bolt 150. Cover frame
160. Equipment mounting bucket 170. Fixing frame
172. Fixed coupling 174. ADCP support frame
180. ADCP protective frame 190. Reinforcement frame

Claims (13)

A linear body-shaped buoyant body having a predetermined thickness formed integrally with an isosceles triangular-shaped forward portion before and after a rectangular body and having an opening vertically penetrating the central portion of the body;
An upper frame formed in an isosceles triangle shape in front of and behind the rectangle corresponding to the upper surface shape of the linear body-like buoyant body, the upper fixed piece having a predetermined length in a rectangular diagonal direction;
A lower frame which is formed in the shape of an isosceles triangle in front of and behind the same rectangle as the upper frame and in which a lower fixing piece is formed in a rectangular diagonal direction corresponding to the upper fixing piece;
A fixing bolt fixed to the upper and lower surfaces of the linear body-shaped buoy body through upper and lower frame edges through engagement with a fixing nut, the fixing bolt fixing hooks being formed at the lower ends thereof;
A cover frame fixedly coupled to the upper portion of the upper fixing piece through a rod-fixing bolt for vertically coupling the upper and lower fixing pieces, the cover frame being formed at a corner corresponding to the upper fixing piece of the upper frame;
A device mounting barrel fixed to the upper side of the cover frame and having a water dropping groove formed at a lower end thereof and a cover window covering the upper end thereof,
A stationary frame having a fixed engaging piece formed at an edge thereof corresponding to upper and lower stationary pieces of the upper and lower frames and fixedly coupled to the inside of the opening through the rod fixing bolt,
An ADCP support frame installed at a lower portion of the fixed frame and supporting a sound wave velocity meter (ADCP) on the center portion so as to be rotatable in the front,
An ADCP protection frame having a plurality of corners fixedly coupled to the lower fixing piece, And
And a bow reinforcement frame covering each of the fore and aft forward portions of the linear body buoyant body and reinforcing the forward portion and the body by a strong flow velocity or floating object. [3] The buoy according to claim 1, wherein each of the lower fixing pieces of the lower frame is rotatable about the fixing bolt as a rotation axis. The fixing bolt according to claim 1, wherein the fixing bolt is formed by combining six corners of each corner of the rectangle of the body and an end corner of a forefront of the front and rear isosceles triangle, Through the upper coupling hole formed in each of the corners of the upper frame through the linear body-shaped buoyant body, the fixing nut is fastened to the upper end, Fixed bottom frame for flow measuring equipment. [4] The buoy according to claim 3, wherein a crane lifting hook is provided at an upper end of each of the fixing bolts to allow the cable to be lifted when lifting the hull using a crane. [2] The apparatus according to claim 1, wherein the ADCP support frame is installed on a lower portion of the fixed frame,
A rotary ring installed on the inner ring surface of the support plate so as to be rotatable forward or rearward or right and left via both sides of the outer diameter or the front and rear sides of the hinge shaft;
An inner ring coupling ring which is installed on the inner ring surface of the rotary ring so as to be rotatable on the front and rear sides of the outer diameter or on both sides through the hinge axis in the left or right or front and rear directions and is divided into two halves and joined at both sides of the outer periphery of the upper side body of the sound wave flowmeter ADCP; And
And a fastening means for completing the configuration divided into two halves of the inner ring coupling ring by tightening both sides to form a single ring so that the sound wave flowmeter ADCP is coupled and supported. Body shape. [2] The apparatus according to claim 1, wherein the linear portion is moored to the water surface of the mooring region through a fixing rope fixed to the sea floor by being connected to a fixing rope fixing ring formed at a lower end of each of the fixing bolts, Wherein the buoy is mounted so as to be located at a predetermined distance from the buoy. [3] The buoy according to claim 1, wherein the buckling reinforcement frame is integrally fixed to the upper and lower frames by the fixing bolts. [7] The apparatus according to any one of claims 1 to 7, wherein a bolt through-hole is further formed in the opening of the linear body-shaped buoyant body in a diagonal direction of the body so as to extend vertically through the bolt through- The upper fixing piece of the upper frame and the cover engaging piece of the cover frame, which are provided on the upper surface of the above-mentioned linear body buoyancy body, are fixedly coupled by the upper end and the nut of the fixing bolt, The lower fixed piece of the lower frame provided on the lower surface of the buoyant body and the edge portion of the ADCP protective frame are coupled and fixed and the fixed joint of the fixed frame is fixedly coupled to the inside of the opening by the rod- Buoys for flow measurement equipment of flow type. The shock absorber according to claim 8, further comprising a shock absorbing damper for absorbing and dispersing an impact between the upper fixing piece of the upper frame and the cover engaging piece of the cover frame when the cover frame is fixed to the upper portion of the upper frame. Buoy for flow measurement equipment. The CTD fixing device according to claim 8, further comprising: upper and lower CTD fasteners integrally formed on the same line from the center of the isosceles triangle bottom of one of the upper and lower frames to the vertex;
A CTD insertion hole formed vertically on the forefront of the linear body-like buoyant body between the upper and lower CTD fixing pieces and into which a water temperature saline water depth recorder (CTD) is inserted;
A CTD coupling piece coupled to the upper or lower end of the water temperature saline water depth recorder (CTD) inserted into the CTD insertion hole; And
And a CTD fixing means comprising a CTD fixing screw and a nut for fastening and fixing the CTD coupling piece to the upper or lower CTD fixing piece. [12] The OBS fixture of claim 10, further comprising: an OBS fixture integrally formed on one side of a frame forming an isosceles triangle of the lower side of the lower frame, which is close to the lower CTD fixing fixture, to fix the optical backscattering sensor OBS; And
And an OBS fastening means composed of a bracket fastened and fixed on the OBS fastening piece and fastening and fixing an optical backscattering sensor (OBS). The buoy according to claim 11, further comprising a blinking light supporting frame fixedly coupled to one side of the equipment mounting barrel or one side of the upper frame to fix and support the blinking light. [12] The apparatus of claim 12, further comprising: an auxiliary frame extending along the upper and lower sides of the rectangular portion of the upper frame by a predetermined length to both sides of the linear body-shaped buoyant body; And
And an overturning preventing means provided on each of both sides of the auxiliary frame, the overturning preventing means being provided in the longitudinal direction in the longitudinal direction to prevent overturning of the linear-shaped buoyant body.

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