KR200321440Y1 - Tide sensing installation structure and manufacture system - Google Patents

Abstract

The present invention allows the tide detection sensor to measure the tidal difference between the tidal flow and the flow direction and the flow velocity stably on the bottom of the sea, so that the tide detection sensor can detect the tide situation more accurately It relates to a mounting structure for mounting a sensor.

According to a feature of the present invention, a plurality of fixed piles fixedly coupled to the rock layer of the sea bottom; A support plate fixedly coupled by a coupling means by maintaining a horizontal state at the upper end of the plurality of fixed piles; A sensor housing which is fixedly coupled by a fixing means by maintaining a horizontal state on an upper surface of the support plate, and a tidal sensor is mounted on the upper surface of the support plate; The tide is installed on the bottom of the support plate so that the plurality of fixed piles are partially embedded, the tidal vortex prevention block is installed, characterized in that composed of a tidal vortex prevention block to prevent the tidal flat layer surrounding the support plate is being pied by the tide Installation structures are provided.

Description

TIDE SENSING INSTALLATION STRUCTURE AND MANUFACTURE SYSTEM}

The present invention relates to an installation structure for mounting the marine tide sensor, and more specifically, the tide detection sensor by allowing the tide detection sensor for measuring the tidal difference and the flow direction and flow rate can be stably fixed to the seabed The present invention relates to an installation structure for mounting a marine tide sensor, which is configured to more accurately detect a tide situation and output data.

In general, when the tide sensor is installed in the sea to measure the difference between tidal flow and the flow direction of the tidal flow and the flow rate of the tidal flow coming in or coming out of the tide in the sea as shown in FIG. The rectangular installation structure 10 is made of concrete but relatively heavy, and is made out of sea water, and then a diver carries the installation structure 10 in water and rests on the sea bottom 20, and then the top surface of the installation structure 10. Tide sensor 30 was fixed to.

However, such a conventional installation structure 10 is not installed in the rock bed layer 22 of the solid seabed surface 20, but the state is settled on the undiluted tidal flat layer 21, such as the west coast is severe difference In this case, the seawater that enters or exits along the sea bottom 20 is seated on the tidal-flat layer 21 on the side end portion of the tidal flat layer 21 in the process of repeating high tide where the surface of the sea water increases or low tide that the surface of the sea water decreases. By vortexing and vortexing to excavate the tidal-flat layer 21 which is the seabed surface 20 on which the end of the installation structure 10 is seated, the horizontal state of the installation structure 10 is inclined to the top surface of the installation structure 10. There was a problem that the correct position of the tide detection sensor 30 mounted is disturbed because the tide detection sensor 30 is not correctly made.

The present invention has been proposed in view of the problems described above, the purpose of which is to install the tide detection sensor mounting structure is fixed to the rigid strata of the sea floor so that the tide mounted on the installation structure by the tide The purpose of the present invention is to provide an installation structure for mounting the marine tide sensor, which is configured to detect the tide situation more accurately.

According to a feature of the present invention for achieving the above object, a plurality of fixed pile that is vertically fixed to the rock layer of the sea bottom; A support plate fixedly coupled by a coupling means by maintaining a horizontal state at the upper end of the plurality of fixed piles; A sensor housing which is fixedly coupled by a fixing means by maintaining a horizontal state on an upper surface of the support plate, and a tidal sensor is mounted on the upper surface of the support plate; The tide is installed on the bottom of the support plate so that the plurality of fixed piles are partially embedded, the tidal vortex prevention block is installed, characterized in that composed of a tidal vortex prevention block to prevent the tidal flat layer surrounding the support plate is being pied by the tide Installation structures are provided.

1 is a configuration diagram showing an installation structure equipped with a conventional tide sensor.

Figure 2 is a perspective view showing the installation structure for mounting the marine tide sensor according to an embodiment of the present invention.

Figure 3 is a block diagram showing the installation structure for mounting the marine tide sensor according to the present invention.

Figure 4 is a partially enlarged perspective view of the main portion of the installation structure for mounting the marine tide sensor according to the present invention.

<Explanation of symbols for the main parts of the drawings>

20: seabed 21: tidal flats

22: rock layer 30: tidal sensor

100: installation structure

110: fixed file 111: hook fixing bracket

112: screw hole 113: bolt

120: coupling means 121: screw portion

122: coupling hole 123: support nut

124: fixing nut 130: support plate

131: horizontal gauge 140: fixing means

141: support line 142: turnbuckle

150: sensor housing 151: screw hole

152: height adjustment bolt 153: lock nut

160: tidal vortex prevention block 161: support surface

162: spiral winding hole 163: screw hole

164: joiner 170: anchor

171: tension line 172: turnbuckle

Hereinafter will be described in detail with reference to the accompanying drawings, the installation structure for mounting the marine tide sensor according to the present invention.

Figure 2 is a perspective view showing the installation structure for mounting the marine tide sensor according to an embodiment of the present invention, Figure 3 is a block diagram showing the installation structure for mounting the marine tide sensor according to the present invention, Figure 4 is the marine design A perspective view showing a partially enlarged main part of an installation structure for mounting a tide sensor.

The installation structure 100 for mounting the marine tide detection sensor according to the present invention as shown is a plurality of fixed piles 110 that are vertically fixed to the rock layer 22 passing through the tidal flat layer 21 of the sea bottom 20 And, while maintaining the horizontal state on the upper end of the plurality of fixing pile 110, the support plate 130 is fixedly coupled by the coupling means 120, and the fixing means by maintaining a horizontal state on the upper surface of the support plate 130 The sensor housing 150 is fixedly coupled by the 140 and the tide detection sensor 30 is mounted on the upper surface of the sensor housing 150, and the plurality of fixed piles 110 are partially installed at the bottom of the support plate 130 so as to be partially embedded therein. The tidal flat layer 21 of the bottom surface 20 around the support plate 130 is composed of a tidal vortex prevention block 160 that prevents the tidal flats from being blown by the tides.

The sensor housing 150 is preferably formed in a polygonal or circular pyramid shape so that fishing nets or other foreign substances are not caught, and the support plate 130 is circular or square or octagonal according to the shape of the sensor housing 150. It is preferable that it is formed in a plate shape such as.

Horizontal gauges (131, 151) for checking the horizontal state is formed on the side of the support plate 130 or the sensor housing 150, so that the diver in the fixed plate 110 of the support plate 130 and the sensor housing It is desirable to facilitate the installation.

The coupling means 120 has a screw portion 121 is formed at the end of the fixed pile 110, the coupling hole is inserted into the fixed file 110 is inserted into the support plate 130 corresponding to the fixed pile 110. (122) is formed, the support plate 130 is fitted with a support nut 123 for receiving the support plate 130 and the coupling hole 122 in the fixing file 110 in the screw portion 121 of the fixing file 110. Fixing nut 124 is fixed to the) is configured.

The fixing means 140 is fixed to a plurality of support lines 141 surrounding the edge of the sensor housing 150 is fixed to the upper surface of the support plate 130, the turn buckle 142 is coupled to the support line 141 As the turn buckle 142 rotates, the support string 141 is tightened or released to fix or release the sensor housing 150 seated on the support plate 130.

A screw hole 151 is formed at the edge of the sensor housing 150, a height adjusting bolt 152 is fastened to the screw hole 151, and a lock nut 153 is fastened to the height adjusting bolt 152. Being configured to finely adjust the height of the sensor housing 150 is disposed on the upper surface of the support plate 130.

The mudflat vortex prevention block 160 is formed in a cone shape having a support surface 161 partially exposed to the upper end of the plurality of fixing piles 110 fixed to the upper surface of the rock-solid layer 22, the outer periphery The spiral winding hole 162 for winding the cable connected to the tide detection sensor 30 is inserted into the spiral is formed spirally from the upper end to the lower end along the circumference, and the cable inserted into the spiral winding hole 162 is formed at the lower edge The upper opening storage groove 165 is formed and configured to be partially wound and stored.

The tidal vortex prevention block 160 is preferably formed of high weight concrete without being corroded by seawater, and in some cases, may be formed of a material such as stainless steel or epoxy.

A locking fixing bracket 111 is formed at a lower portion of the fixed pile 110 fixed to the rock layer 22 so that the bottom surface of the tidal vortex prevention block 160 is supported and fixed to the locking fixing bracket 111. Screw holes 112 and 163 are formed on the bottom surface of the tidal vortex prevention block 160 so that the bolt 113 is fastened to the matching threaded holes 112 and 163 to form the tidal vortex prevention block 160. It is configured to be easily coupled to the fixed pile 110 by underwater, wherein the tidal vortex prevention block 160 is formed with a coupling hole 164 into which the fixed pile 110 is fitted.

An anchor 170 is fixedly coupled to the surrounding rock layer 22 of the tidal vortex prevention block 160 in which the fixed pile 110 is partially embedded and coupled to the tidal vortex prevention block 160 and the anchor 170. There is a tension line 171 is coupled, the tension line 171 is coupled to the turnbuckle 172 to adjust the tension, the tidal vortex prevention block 160 and the fixed pile 110 is more than the rock layer 22 It is configured to be firmly fixed.

When installing the installation structure for mounting the marine tide detection sensor 100 of the present invention, such as hitting the fixed pile 110 with a pile-type in the sea first to put in the rock layer 22 or the diver using a perforator underwater By fixing the fixing pile 110 to the rock layer 22.

Thereafter, after installing the formwork around the fixing pile 110, the concrete is poured into the form to form a tidal vortex prevention block 160 to expose only the upper portion of the fixing pile 110.

After fastening the supporting nut 123 to the threaded portion 121 of the fixing pile 110, and then the coupling hole 122 of the supporting plate 130 is fitted to the fixing nut 110 to be seated on the supporting nut 123. The fixing nut 124 is fastened to the screw part 121 of the fixing file 110 to fix the support plate 130 to the fixing file 110.

Thereafter, the sensor housing 150 is seated on the upper surface of the support plate 130, and then the turn buckle 142 of the fixing means 140 is rotated so that the support line 141 is mounted on the support plate 130. To be fixed.

After anchoring the anchor 170 to the surrounding rock layer 22 of the tidal vortex prevention block 160, and coupled to the tension line 171 to the anchor 170 and the tidal vortex prevention block 160, respectively When the tension line 171 is tightly connected to the turnbuckle 172, the construction of the installation structure for mounting the marine tide sensor 100 is completed.

At this time, the sensor housing 150 and the sensor housing 150 using the height adjusting bolt 152 fastened to the support nut 123 and the screw hole 151 of the sensor housing 150 fastened to the fixing file 110. ) To adjust the horizontal level of the tidal sensor 30 is installed.

On the other hand, the mud flat vortex prevention block 160 is molded by concrete from the outside, not underwater in some cases, lifted by equipment such as a crane and embedded in the rock pile layer 22, the tidal flat in the fixed pile 110 The coupling hole 164 of the vortex prevention block 160 is inserted, and then formed on the bottom surface of the screw hole 112 and the tidal vortex prevention block 160 formed in the locking fixing bracket 111 of the fixed pile 110 (163). The bolt 113 is fastened to the construction can be constructed in such a way that the tidal vortex prevention block is coupled to the fixed pile.

As described above, the installation structure for mounting the marine tide detection sensor according to the present invention has a fixed pile fixedly coupled to a rock layer, which is a relatively hard ground, past the tidal layer of the sea bottom, and prevents cone tidal vortex around the fixed pile. Block is installed, the support plate is coupled to the fixed pile fixed to the rock layer, and the support housing is coupled to the sensor housing to be mounted on the tide detection sensor on the upper surface of the tide flow due to tidal difference flow In addition, since the fixed pile and the support plate and the sensor housing are not shaken and the tidal flats of the sensor housing are not lost due to the flow of the tide, the support plate coupled to the fixed pile and the sensor housing disposed on the upper surface of the support plate and The tidal sensor mounted on the sensor housing is stable without being eccentric. As it is possible to maintain the exact position, the tide sensor can more accurately detect the flow of the tide.

Claims (5)

A plurality of fixed piles 110 fixedly coupled to the rock layer 22 of the sea bottom 20; A support plate 130 fixedly coupled by the coupling means 120 by maintaining a horizontal state at the upper end of the plurality of fixed piles 110; A sensor housing 150 which is fixedly coupled by the fixing means 140 by maintaining a horizontal state on the upper surface of the support plate 130 and on which the tide detecting sensor 30 is mounted; Tidal vortex prevention is installed in the lower portion of the support plate 130 so that the plurality of fixed pile 110 is partially embedded to prevent the tidal flat layer 21 surrounding the support plate 130 is dug by the tide flows Installation structure for mounting the marine tide sensor, characterized in that consisting of blocks (160). According to claim 1, The tidal vortex prevention block 160 is formed in a cone shape having a support surface 161, the upper end of the plurality of fixed pile 110 is partially exposed on the upper surface, the tide sensing on the outer periphery Installation structure for installing the marine tide detection sensor, characterized in that the spiral winding hole 162 for inserting the cable connected to the sensor 30 is wound in a spiral form from the upper end to the lower end along the circumference. According to claim 2, The tidal vortex prevention block 160 is installed structure for mounting the marine tide sensor, characterized in that the concrete is formed by curing curing. The method of claim 1, wherein the anchor pile is fixed to the peripheral rock layer 22 of the tidal flat anti-block block 160, the buried pile 110 is partially embedded, the tidal vortex prevention block 160 ) And anchor 170 is coupled to the tension line 171, the tension line 171 is coupled to the turnbuckle 172 to adjust the tension, the tidal vortex prevention block 160 and the fixed pile 110 is arm Installation structure for mounting the marine tide sensor, characterized in that configured to be more firmly fixed to the ground layer (22). According to claim 2, wherein the bottom edge of the tidal vortex prevention block 160 is formed by the upper opening storage groove 165 is formed so that the cable inserted into the spiral winding hole 162 is partially wound and stored. An installation structure for mounting a marine tide sensor.