KR200276631Y1 - Tide sensing installation structure and manufacture system - Google Patents

Abstract

The present invention relates to an installation structure for mounting the marine tide detection sensor is configured so that the tide detection sensor for measuring the difference between the tidal wave and the flow direction and flow rate of the ocean tide can be stably installed on the sea floor.

According to a feature of the present invention, the bottom layer is fixedly coupled to the rock layer of the sea bottom, and the mat layer for tidal-layer cutoff is uniformly flat at the bottom of the buried hole of the support pipe having a certain length exposed from the sea bottom. The inside of the buried hole of the support pipe, which is the upper part of the mat layer, has a granite layer in which a plurality of unit fine stones are stacked at a predetermined height on the upper surface of the mat layer, and the steel frame is formed in the buried hole of the support pipe that is the upper part of the Built-in concrete layer is formed from the upper surface of the fine stone layer to the upper end of the support pipe, the tidal vortex prevention layer is formed on the surrounding bottom surface of the support pipe to prevent the surrounding tidal layer of the support pipe is dug by the tidal flow In the installation structure for mounting a conventional marine tide sensor, the tidal vortex prevention layer is inserted into the support pipe perpendicular to the center The marine tide is characterized in that the spiral winding hole for the cable connected to the tide detection sensor is wound on the outer circumferential surface of the cone-shaped weight skirt formed through the insertion fixing hole is formed spirally while connecting from the upper end to the lower end along the circumference A mounting structure for mounting a sensor is 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. Even though the support plate 10 is made of a relatively heavy concrete in the sea water to produce a rectangular support plate (10) outside the seabed to install the tide support plate 10 to the tide detection sensor 310, and then the support plate (10) On the upper surface of the tide detection sensor 310 is fixed by using an anchor bolt or turnbuckle while adjusting the horizontal state of the housing 320 is mounted.

However, such a conventional tide sensor installation structure is a process in which the high tide of low tide or low tide of low sea water is repeated in the case of the West Coast where tidal flats are not compacted but the difference between tidal sea Seawater entering or exiting the shoreline vortexing while striking the side end portion of the support plate 10 seated on the tidal-flat layer 21 to dig the sea bottom, that is, the tidal-flat layer 21 on which the end of the support plate 10 is seated. As the horizontal state of the support plate 10 is inclined, the correct position of the tidal sensor 310 mounted on the upper surface of the support plate 10 is disturbed, thereby detecting the tidal force detected by the tidal sensor 310. Not only is the data inaccurate, but in severe cases, tidal-flat layers 21 around the support plate 10 scattered by the seawater cover the tide detection sensor 310 to help the tides. There is a problem that may be subject to removal from the function of the assistant detection sensor 310 for detecting the state.

On the other hand, in order to solve the problems described above, the cause of the present proposed a tide detection sensor mounting structure for mounting the tide detection sensor safely and accurately as in Utility Model Registration No. 206534, the configuration is shown in FIG. As shown, the bottom portion is fixedly coupled to the rock layer 210 of the sea bottom, and the tidal flat layer 220 below the buried hole 111 of the support pipe 110 having a predetermined length exposed from the sea bottom. Blocking mat layer 120 is formed to be a certain thickness flat, the fine layer of a plurality of unit fines 131 is laminated in the buried hole 111 of the support pipe 110, the upper portion of the mat layer 120 ( 130 is formed at a predetermined height on the upper surface of the mat layer 120, the concrete layer 140, the steel frame 141 is embedded in the buried hole 111 of the support pipe 110, which is the upper portion of the fine layer 130 The upper end of the support pipe 110 on the top surface of the fine layer 130 Is not formed are formed.

In addition, the fence fence to prevent the external object collides with the tide detection sensor housing 320 and the tide detection sensor 310 on the upper peripheral edge of the concrete layer 140 is fixed to the tide detection sensor 310 housing ( 150 is formed, excavation groove 161 of a predetermined depth is formed on the bottom surface around the upper end of the support pipe 110, a plurality of unit weight bag 162 is stacked in the excavation groove 161 tidal vortex The prevention layer 160 is formed and comprised.

However, such a conventional installation structure for mounting the tide sensor is a tidal vortex prevention layer formed to prevent the tidal flat layer 220 is vortexed by the tidal flow flowing in the construction process to prevent the surrounding surrounding the support pipe 110 As the 160 is formed by loading a plurality of unit weight bag 162, the divers carry a plurality of weight bag 162 repeatedly to be stacked on the sea floor around the support pipe 110 to work underwater The relatively long time made construction difficult and required improvement.

The present invention has been proposed in view of the problems described above, and its purpose is to allow the tide sensor to measure the tidal difference between the tidal flow and the flow direction and flow rate, so that the tide sensor can be stably installed on the seabed It is to provide an installation structure for installing the marine tide sensor installed so that the construction of the marine tide detection sensor mounting structure to more accurately detect the tide situation to output the data.

According to a feature of the present invention for achieving the above object, the bottom portion is fixedly coupled to the rock layer of the sea bottom, and the upper end portion for the mud flat layer blocking in the buried hole side of the support pipe having a certain length exposed to a certain height from the sea bottom The mat layer is formed to have a uniform thickness, and the inside of the embedding hole of the support pipe, which is the upper part of the mat layer, has a granite layer in which a plurality of unit fines are stacked at a predetermined height on the upper surface of the mat layer, and is supported on the top of the granite layer In the buried hole of the pipe is a concrete layer embedded with steel frame is formed from the top surface of the fine stone layer to the upper end of the support pipe, the tidal layer surrounding the support pipe by the tidal flow to the surrounding bottom surface of the support pipe In the installation structure for mounting a conventional marine tide sensor is formed, the tidal vortex prevention layer is formed, the tidal vortex prevention layer is the center The spiral winding hole for winding the cable connected to the tidal sensor is wound on the outer circumferential surface of the cone-shaped weight skirt formed by penetrating the insertion fixing hole into which the support pipe is inserted perpendicularly to the spiral shape while being connected from the upper end to the lower end along the circumference. There is provided an installation structure for mounting the marine tide detection sensor, characterized in that configured.

1 is a configuration diagram showing a structure for installing a conventional tide sensor.

Figure 2 is a configuration diagram showing a conventional installation structure for mounting the tide sensor.

Figure 3 is a schematic view showing the installation structure for mounting the marine tide sensor according to an embodiment of the present invention.

Figure 4 is a perspective view showing a weight skirt which is a main part of the installation structure for mounting the marine tide sensor according to the present invention.

Figure 5 is a perspective view showing another example of the weight skirt which is the main part 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>

100: Installation structure for mounting marine tidal sensor

110: support pipe 111: buried hole

112: locking bracket 112a: screw hole

113: Bolt 120: Mat layer

130: fine stone layer 131: fine stone

140: concrete layer 141: steel frame

160: tidal vortex prevention layer 163: insertion hole

163a: gradient side 164: weight skirt

164 ': unit weight skirt 164a: screw hole

165: spiral winding hole 166: hollow part

166 ': unit hollow 166a: inlet hole

166a ': unit inlet hole 166b: outlet hole

166b ': unit outlet hole 167: sealed cap

168: coupling means 168a: coupling bracket

168b: screw hole 169: bolt

210: rock layer 220: tidal flat layer

310: tide sensor

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 3 is a block diagram showing the installation structure for mounting the marine tide sensor according to the embodiment of the present invention, Figure 4 is a perspective view showing a weight skirt which is the main part of the installation structure for mounting the marine tide sensor.

As shown, the bottom portion is fixedly coupled to the rock layer 210 of the sea bottom, and the tidal flat layer 220 below the buried hole 111 of the support pipe 110 having a predetermined length exposed from the sea bottom. Blocking mat layer 120 is formed to be a certain thickness flat, the fine layer of a plurality of unit fines 131 is laminated in the buried hole 111 of the support pipe 110, the upper portion of the mat layer 120 ( 130 is formed at a predetermined height on the upper surface of the mat layer 120, the concrete layer 140 is built in the steel frame 141 in the buried hole 111 of the support pipe 110, which is the upper portion of the fine stone layer 130 It is formed from the upper surface of the fine stone layer 130 to the upper end of the support pipe 110, the peripheral tidal layer 220 of the support pipe by the tide flows to the peripheral bottom of the support pipe 110 Installation structure for mounting a conventional marine tide sensor is formed (100) In the above, the tidal vortex prevention layer 160 is the tide detection sensor on the outer circumferential surface of the cone-shaped weight skirt 164 formed through the insertion fixing hole 163 through which the support pipe 110 is inserted perpendicular to the center Spiral winding hole 165 for winding the cable (not shown) connected with 310 is formed in a spiral form while being connected from the upper end to the lower end along the circumference.

The weight skirt 164 is preferably molded of high weight stainless steel or epoxy without corrosion to seawater.

A cone-shaped hollow portion 166 is formed along the circumference of the weight skirt 164, and an inlet hole 166a and an outlet hole for allowing water to be introduced or discharged into the lower and upper ends of the hollow portion 166. 166b is formed, and the inlet hole 166a and the outlet hole 166b may be configured to be opened and closed by the closure cap 167.

The outer circumferential surface of the support pipe 110 is formed with at least two fastening brackets 112 to which the bottom surface of the weight skirt 164 inserted into the support pipes 110 is fixed and supported, and the fastening brackets 112 And the thread holes 112a and 164a are formed at the bottom of the weight skirt 164 so that the bolts 113 are fastened to the matching threaded holes 112a and 164a so that the weight skirt 164 is supported by the support pipe. 110, it is configured to be firmly fixed.

A gradient surface 163a is formed at the lower end of the insertion fixing hole 163 of the weight skirt 164 so that the weight skirt 164 can be easily inserted into the support pipe 110.

As shown in FIG. 5, the weight skirt 164 is divided into at least two unit weight skirts 164 ′ radially around the insertion fixing hole 163 and coupled by the coupling means 168. The coupling means 168 is a coupling bracket 168a having a threaded hole 168b at the end of each unit weight skirt 164 'which is in contact with each other, and the coupling means 168 is formed. , The bolt 169 is fastened to the screw hole 168b of the matching coupling bracket 168a so that the unit weight skirt 164 'may be integrally coupled, wherein each unit weight Inside the skirt 164 ′, a unit hollow part 166 ′ having a unit inlet hole 166a ′ and a unit outlet hole 166b ′ that is opened and closed by the closure cap 167 is preferably formed.

The installation structure for mounting the marine tide sensor 100 according to the present invention configured as described above is a tidal flat around the support pipe 110 in order to prevent the surrounding sea bottom of the support pipe 110 from being pigged by the tidal flow. When the vortex prevention layer 160 is formed, first, the weight skirt 164 is manufactured on land.

After lifting the weight skirt 164 by a crane, etc., the insertion fixing hole 163 of the weight skirt 164 is embedded in the rock layer to be inserted into the support pipe 110, and then the weight skirt 164 is lowered to the weight. After the skirt 164 is lowered along the support pipe 110, the weight skirt 164 is seated on the bottom surface of the skirt 164. Then, the bracket and the bottom surface of the weight skirt 164 of the support pipe 110 are bolted to 169. When tightened to complete the construction of the tidal vortex prevention layer 160.

When the weight skirt 164 is lifted into the support shaft and lifted, the weight skirt 164 is lowered so as to be immersed in seawater by opening the inlet hole 166a and the outlet hole 166b of the weight skirt 164 to the weight skirt 164. ) Is submerged in the seawater and the seawater flows into the hollow portion 166 of the weight skirt 164, so that the weight skirt 164 can be smoothly lowered along the support pipe 110 to be seated on the sea bottom. After the weight skirt 164 is seated on the bottom of the sea, the inlet hole 166a and the outlet hole 166b of the weight skirt 164 are sealed in the seawater by sealing the cap 167. Prevent impurities or foreign substances from entering.

On the other hand, when the weight skirt 164 is formed of a plurality of unit weight skirt 164 ′ and configured to be integrally coupled by the coupling means 168, the diver may directly use the multiple unit weight skirt 164 ′ without using a crane. ) Is integrated into the periphery of the support pipe 110 adjacent to the sea bottom surface by moving it underwater, so that the construction of the tidal vortex prevention layer 160 can be easily performed, that is, the diver unit unit weight skirt 164 '. ) When directly transported into the water and assembled in the water, the unit inlet hole 166a 'and the unit outlet hole 166b' formed in the unit weight skirt 164 'are opened and closed to unit the unit weight skirt 164'. By adjusting the air to remain at the same time as the inlet of the appropriate seawater in the hollow portion 166 'allows the diver to properly adjust the weight by the buoyancy of the unit weight skirt 164' submerged in the water This allows the diver to facilitate the transport and assembly of the unit weight skirt 164 '.

The installation structure for mounting the marine tide sensor according to the embodiment of the present invention as described above has a tidal vortex prevention layer around the support pipe in order to prevent the surrounding bottom surface of the support pipe from being piped by the tide flows. In case of construction, the weight skirt is formed on the outside of the sea surface, and then lifted by the crane and the insertion pipe of the weight skirt is inserted into the support pipe embedded in the rock layer to be seated on the sea floor. In addition to simplifying the construction, it is possible to reduce the construction time and cost of the marine tide sensor mounting installation structure by simplifying the construction of the marine tide sensor mounting installation structure.

Claims (6)

The mat layer for blocking the mud flat layer 220 below the buried hole 111 of the support pipe 110 having a fixed length at which the lower end is fixedly coupled to the rock layer 210 of the sea bottom and has a predetermined length exposed from the sea bottom. The flat layer 120 is formed to have a predetermined thickness, and the fine layer 130 in which a plurality of unit fines 131 are stacked is formed in the embedded hole 111 of the support pipe 110, which is the upper portion of the mat layer 120. A predetermined height is formed on the upper surface of the layer 120, and the concrete layer 140 having the steel frame 141 is formed in the buried hole 111 of the support pipe 110, which is the upper portion of the fine stone layer 130. It is formed from the upper surface of the support pipe 110 to the upper end of the support pipe 110, the peripheral bottom surface of the support pipe 110 to prevent the tidal layer 220 of the support pipe 110 from being pigged by the tidal flow In the installation structure 100 for mounting a conventional marine tide sensor is formed in the tidal vortex prevention layer 160, The tidal-flat vortex prevention layer 160 is connected to the tidal sensor 310 on the outer circumferential surface of the cone-shaped weight skirt 164 formed by the insertion fixing hole 163 through which the support pipe 110 is vertically inserted into the center. Installation structure for installing the marine tide sensor, characterized in that the spiral winding hole 165 for winding the cable is formed in a spiral form while being connected from the upper end to the lower end along the circumference. According to claim 1, Cone-shaped hollow portion 166 is formed along the inner circumference of the weight skirt 164, the inlet hole (166a) to allow water to be introduced or discharged to the lower end and the upper end of the hollow portion 166 And a discharge hole (166b) is formed, wherein the inlet hole (166a) and the discharge hole (166b) is configured to open and close by a closed cap (167). According to claim 1 or 2, wherein the outer peripheral surface of the support pipe 110 has at least two fastening fixing bracket 112, the lower surface of the weight skirt 164 inserted into the support pipe 110 is supported fixed The installation structure for mounting the marine tide sensor, characterized in that formed above. According to claim 1 or 2, wherein the lower end of the insertion hole 163 of the weight skirt 164 has a gradient surface 163a is formed so that the weight skirt 164 is easily inserted into the support pipe 110. Installation structure for mounting the marine tide sensor, characterized in that configured to be. The weight skirt 164 is divided into at least two unit weight skirt 164 'radially around the insertion hole 163, and is formed by the coupling means 168. The installation structure for mounting the marine tide sensor, characterized in that configured to be separated and integrally combined. The method of claim 5, wherein the coupling means 168 is formed with a coupling bracket 168a having a screw hole 168b at the end of the unit weight skirt 164 'which is in contact with each other, the coupling bracket 168a The bolt hole (169b) is fastened to the screw hole (168b), the unit weight skirt (164 ') is configured to be coupled to the integrated structure of the marine tide detection sensor, characterized in that configured to be integrated.