KR101134800B1 - Breakwater structure capable of controlling amount of flowing water, control apparatus and method therefor - Google Patents

Abstract

PURPOSE: A breakwater structure capable of controlling water flow, an apparatus for controlling the water flow, and a control method thereof are provided to control water flow so that waves flowing into inland sea is blocked when the height and the pressure of the wave are high, and seawater smoothly moves between the inland sea and open sea when the height and the pressure of the wave are low. CONSTITUTION: A breakwater structure capable of controlling water flow comprises a support plate(110), a plurality of unit structures(120), a cover plate(140), partition walls(210), at least one movable partition plate(220). The support plate is installed under the sea. The unit structures are filled with receiving bodies in rectangular frames and seawater flows through air gaps between each receiving bodies. The cover plate covers the top of the uppermost floor of the unit structures. The partition walls are formed in predetermined width and vertically arranged in the side of the breakwater structure in predetermined intervals. The partition walls are fixed by the support plate and the cover plate. The movable partition plate is constituted with frames having a height lower than the partition walls. Second partition walls are formed inside the frame in same intervals with the partition walls. The movable partition plate is supported by the support plate and the cover plate in the side of the partition walls and installed to move horizontally.

Description

Breakwater Structure Capable of Controlling Amount of Flowing Water, Control Apparatus and Method therefor}

The present invention relates to a breakwater structure capable of adjusting the flow rate, a flow rate control device and a control method thereof, and more specifically, to prevent waves flowing into the inland sea when the wave height or wave pressure is high, and when the wave height and wave pressure is low, It relates to a breakwater structure that can adjust the flow rate so that the sea water moves smoothly between, the flow rate control device and a control method.

In general, breakwaters are almost essential to ports and coasts, and they are installed in various forms and construction methods.

In the early days, breakwaters were installed at a height that could prevent some high waves, so that the sections where the breakwaters were installed were blocked by the inland and the open seas. However, the construction of the breakwater in the form of confining the sea water, so that the inflow and outflow of the sea water is not made smoothly, the sea water of the inland sea is contaminated, and various kinds of dirt accumulate, severe odor is generated. It is no exaggeration to say that this would completely destroy the tidal flats and seabed ecosystems on the Inland Sea.

Moreover, the above-mentioned breakwater has a great repulsion force in the seawater hit by the breakwater, and the seawater coming in succession is combined to hit the breakwater with more energy. have.

To remedy this problem, various structures of breakwaters have been proposed to allow seawater to be distributed. One of them is a breakwater using the "unit block for building breakwater" of Korean Patent No. 770238.

1 is a schematic front view of a breakwater constructed by using a unit block for constructing a breakwater according to the prior art.

Referring to FIG. 1, the unit block is integrally formed by connecting the upper plate 10 and the lower plate 20 by a plurality of pillars 30, and is coupled to the upper and lower surfaces of the upper plate 10 and the lower plate 20. The pit 15 and the pit 25 for the is formed.

The breakwater is first laminated on the frame 50 in which the bite jaw 55 protrudes such that the bite groove 25 of the plurality of unit blocks is engaged with the bite jaw 15 of the frame 50. The plurality of unit blocks are secondary so that the respective bite jaws 15 and the bite grooves 25 of the plurality of unit blocks that are stacked on the first unit block are engaged with each other so as to deviate from each other. In this manner, a plurality of unit blocks are vertically stacked in this manner. As a result, the breakwater facilitates the communication of birds through the space between the pillars of the respective unit blocks.

However, since the breakwater structure as described above includes a plurality of horizontal plates, that is, the upper plate 10 and the lower plate 20, the waves that vertically move inwardly enter the inner space of the breakwater and the vertical direction of the breakwater is There is a problem that can not use all the internal volume of the breakwater can not be delivered.

In addition, since the breakwater of the structure as described above induces the flow of the sea water only in the horizontal direction of the wave, reflected waves due to the components of the breakwater do not effectively attenuate the wave energy of the wave in an irregular three-dimensional motion As a result, the resistance received by the components of the breakwater has a relatively large effect, which adversely affects the safety of the entire structure.

Moreover, the breakwater of the structure described above only attenuates a part of the wave energy and the remaining energy is transferred toward the inshore sea. As a result, when the weather deteriorates such as a typhoon, the breakwater does not absorb or disperse the wave energy and delivers it to the harbor, thereby causing a problem that the facilities or the vessels in the berth are damaged.

The present invention was devised to solve the above problems, and when the wave height or wave pressure is high, it prevents the waves flowing into the inland sea, and when the wave height and wave pressure is low, the flow rate can be adjusted so that the seawater moves smoothly between the inland sea and the outer sea. It is an object of the present invention to provide a breakwater structure, a flow rate control device and a control method thereof.

Breakwater structure according to an embodiment of the present invention for achieving the above object, the support plate is installed on the seabed; A unit structure filled with a container including at least one of a plurality of spherical and polyhedrons in a rectangular parallelepiped frame, wherein a flow path of seawater is formed through pores between each spherical or polyhedron; A cover plate covering the upper surface of the unit structure of the uppermost layer after forming the structure wall by stacking the unit structures into a plurality of layers; A plurality of partition walls having a predetermined width and arranged vertically at predetermined intervals on a side of the formed structure wall and fixed by a support plate and a cover plate; And a frame having a height equal to or less than the height of the partition wall, wherein a plurality of second partition walls having the same width as the width of the partition wall are arranged in the frame at the same interval as the gap of the partition wall, and the support plate and the cover plate at the side surfaces of the partition wall. It is characterized by including; at least one movable partition plate which is supported by the movable movable plate in the horizontal direction.

Breakwater structure according to another embodiment of the present invention for achieving the above object, the support plate is installed on the seabed; A unit structure having a plurality of pillar members connecting upper and lower plates, upper and lower plates, each of which has a plurality of holes formed therein, and a flow path of seawater formed through the space between the pillar members and the holes of the upper and lower plates; A cover plate covering the upper surface of the unit structure of the uppermost layer after forming the structure wall by stacking the unit structures into a plurality of layers; A plurality of partition walls having a predetermined width and arranged vertically at predetermined intervals on a side of the formed structure wall and fixed by a support plate and a cover plate; And a frame having a height equal to or less than the height of the partition wall, wherein a plurality of second partition walls having the same width as the width of the partition wall are arranged in the frame at the same interval as the gap of the partition wall, and the supporting plate and the cover plate at the sides of the plurality of partition walls. It is characterized by including; at least one movable partition plate which is supported by the movable movable plate in the horizontal direction.

Each partition may be arranged at intervals less than or equal to the width of the partition.

In this case, the movable partition plate moves leftward and rightward within the width of the partition.

Each partition may be arranged at a wider interval than the width of the partition.

In this case, two or more movable partition plates are sequentially installed on the side of the partition wall, and each movable partition plate is left and right within the range of the partition width x (N-1) (N is an integer indicating the order from the partition wall) from the partition wall. Can move in the direction.

It is preferable that the some partition and the movable partition plate are formed in the side surface of an inner sea side.

An apparatus for controlling the flow rate of a breakwater structure according to an exemplary embodiment of the present invention for achieving the above object includes a plurality of partition walls having a predetermined width and arranged vertically at predetermined intervals on a side thereof, and a width equal to the width of the partition walls in a frame. With respect to the breakwater structure provided with at least one movable partition plate having a plurality of second bulkheads arranged at the same interval as the space of the partition wall and moving from side to side in a plurality of partition walls, the breakwater structure is provided with wave pressure and wave height. Wave pressure wave height measuring unit for measuring at least one of; A partition driving unit for moving the movable partition plate in a horizontal direction; And a movement control unit for controlling a moving distance of the moving partition plate by controlling the partition driving unit.

The movement control unit may set the control reference values of the wave pressure and the wave height step by step, and adjust the moving distance of the moving plate according to at least one of the wave pressure and the wave height measured by the wave pressure wave height measurement unit.

The movement control unit increases the width of the partition wall on the sea side of the breakwater structure as at least one of the wave pressure and the wave height measured by the wave pressure wave measurement unit exceeds each set control reference value.

In addition, the movement control unit reduces the width of the partition wall on the sea side of the breakwater structure as at least one of the wave pressure and the wave height measured by the wave pressure wave measurement unit becomes equal to or less than each set control reference value.

The movement control unit may move control the moving partition plate in the left and right direction within a width of the partition wall.

In addition, when two or more movable partition plates are installed in the side of a partition, the movement control part each moves within the range of the width x (N-1) of a partition (N is an integer which shows the order from a partition) from a partition. The partition plate can be controlled to move in the horizontal direction.

Flow rate control method of the breakwater structure according to an embodiment of the present invention for achieving the above object comprises the steps of setting a control reference value of wave pressure and wave height; On the side surfaces, a plurality of partition walls having a constant width and vertically arranged at predetermined intervals, and a plurality of second partition walls having a width equal to the width of the partition walls in the frame are arranged in a plurality of intervals at the same interval as the spacing of the partition walls in the side of the plurality of partition walls Measuring at least one of wave pressure and wave height on a side of the sea of the breakwater structure, the breakwater structure having at least one movable partition plate moving in a horizontal direction; And adjusting the moving distance of the moving partition plate of the breakwater structure by comparing at least one of the wave pressure and the wave height measured by the measuring step with a control reference value set by the setting step.

The movement distance adjusting step may increase the width of the partition wall on the sea side of the breakwater structure as at least one of the wave pressure and the wave height measured by the measuring step exceeds each set control reference value.

In addition, the movement distance adjusting step, as at least one of the wave pressure and the height measured by the measuring step is less than the respective control reference value can be set to reduce the width of the partition wall on the sea side of the breakwater structure.

According to the present invention, when the wave height or wave pressure is high, the width of the bulkhead of the breakwater structure can be increased to reduce the waves flowing into the inland sea, thereby preventing damage to the sea due to the waves.

In addition, according to the present invention, when the wave height and wave pressure is low, the width of the partition wall of the breakwater structure is narrowed so that the seawater can smoothly flow into the inland sea, thereby preventing the sea water from accumulating and causing the environmental pollution. It becomes possible.

In addition, according to the present invention, when a tsunami or the like is measured on the offshore side of the breakwater structure, the damage of the breakwater structure is minimized by minimizing the width of the partition wall to reduce the wave pressure through the pillar of the receptor or the unit structure to minimize the damage on the inshore side. You can do it.

1 is a schematic front view of a breakwater constructed by using a unit block for constructing a breakwater according to the prior art.
2 is a view showing a cross-sectional view of the width direction of the breakwater structure according to an embodiment of the present invention.
3 is a diagram illustrating an example of a unit structure used in the breakwater structure of FIG. 2.
Figure 4 is a view showing an example of (a) the partition wall, and (b) a moving partition plate used in the breakwater structure of the present invention.
5 is a view showing another example of (a) the partition wall, and (b) the movable partition plate used in the breakwater structure of the present invention.
Figure 6 is a view showing another example of (a) the partition wall, and (b) a moving partition plate used in the breakwater structure of the present invention.
7 is a view showing still another example of (a) the partition wall, and (b) the movable partition plate used in the breakwater structure of the present invention.
8 is a view showing a cross-sectional view of the width direction of the breakwater structure according to another embodiment of the present invention.
FIG. 9 is a diagram illustrating an example of a unit structure used in the breakwater structure of FIG. 8.
10 is a view schematically showing a flow rate control device of the breakwater structure according to an embodiment of the present invention.
11 is a flowchart illustrating a flow rate control method of a breakwater structure according to an exemplary embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the breakwater structure, the flow rate control device of the breakwater structure and its control method according to an embodiment of the present invention.

2 is a view showing a cross-sectional view of the width direction of the breakwater structure according to an embodiment of the present invention.

2, the breakwater structure according to the embodiment of the present invention includes a support plate 110, a plurality of unit structures 120, a cover plate 140, a partition wall 210, and at least one movable partition plate 220. It includes.

The support plate 110 is installed on the seabed. At this time, the support plate 110 may be stacked on the base ground (100). Here, the foundation ground 100 is made of the foundation work of the bottom of the sea floor, the top surface of the seabed is unstable topography, the groove may be formed on the upper surface so that the support plate 110 can be fixedly fixed. have. Alternatively, as shown in FIG. 2, after the supporting plate 110 is stacked on the upper end of the base ground 100, the coated seat 115 is fixed to cover the base ground 100 while fixing the stacked support plates 110. It may be formed.

 The foundation ground 100 is installed after a groove having a predetermined depth is installed on the sea bottom, or a lower fixed core of a predetermined length is installed on the bottom surface of the foundation ground 100, and the foundation ground is inserted into the sea bottom to insert the foundation ground 100 on the sea bottom. After fixing, the upper surface of the foundation ground 100 can be made flat. In addition, the base ground 100 may be provided with a fixing groove or fixing jaw for fixing the support plate 110 on the upper surface. Alternatively, the support plate 110 may be integrally formed with the base ground 100 and the covering stone 115. However, the installation method of the support plate 110 is not limited to the described method, but may be installed in various modified ways. In addition, the support plate 110 may be made of concrete, but is not limited thereto, and various materials may be utilized.

The unit structure 120 is filled with a plurality of receptors 130 including at least one of a polyhedron and a spherical body in a rectangular parallelepiped frame, and a flow path of seawater is formed through the pores between the respective receptors 130. .

That is, as shown in FIG. 3, the unit structure 120 stands four side frames 122 having a lattice shape, and joins the bottom frame 123 having a lattice shape to the bottom of each side frame 122. Then, the container 130 including a plurality of spherical or polyhedral to be filled in the frame consisting of the side frame 122 and the bottom frame 123 is filled, and the upper end of the grid shape to cover the plurality of spherical or polyhedron Frame 124 may be bonded to the top of each side frame 122. In this case, the side frame 122, the bottom frame 123 and the top frame 124 may be formed by arranging a plurality of vertical members or a plurality of horizontal members at regular intervals instead of having a grid shape. In this case, the side frame 122, the bottom frame 123 and the top frame 124 is preferably made of stainless steel or reinforced concrete excellent in corrosion resistance.

A plurality of such unit structures 120 are arranged to form a layer, and a plurality of unit structures 120 are arranged on a layer of the formed unit structure 120, and the layers are repeatedly formed to form layers in the unit structure 120. It may form a breakwater structure through which water can flow through the pores between the receptors 130. In this case, when the two or more unit structures 120 are glued together, the joining surfaces of the unit structures 120 may be fixed to each other using the bonding member 125. In addition, the bonding member 125 may be bonded by fixing at least one unit structure 120 to the upper surface of the support plate 110. In addition, when the unit structures 120 of different layers are stacked on the unit structures 120 arranged in one layer, the unit structures 120 may be stacked to alternate with each other between the layers of the unit structures 120. The bonding surfaces of the stacked unit structures 120 may be bonded by using the bonding member 125.

The cover plate 140 covers the top surfaces of the unit structures 120 of the uppermost layer with respect to the unit structures arranged in the plurality of layers. The cover plate 140 may be made of concrete, but is not limited thereto, and may use various materials. For example, the cover plate 140 may be formed of a transparent acrylic plate having a predetermined thickness, and may be implemented to visually check the distribution of seawater inside the breakwater. The cover plate 140 may be used as a road and a road at the same time to prevent the rise of seawater from the inside of the breakwater structure.

The partition wall 210 is provided in plurality, each having a constant width, as shown in Figure 4 (a) is arranged perpendicular to the side of the breakwater structure at a predetermined interval. At this time, each partition wall 210 is fixed by the support plate 110 and the cover plate 140. Here, each partition wall 210 may be arranged at intervals less than or equal to the width of the partition wall, or may be arranged at intervals wider than the width of the partition wall. At this time, the spacing between each of the partitions 210 is preferably set equally. In this case, each partition wall 210 is preferably installed on the sea side of the breakwater structure.

As shown in (b) of FIG. 4, the movable partition plate 220 is formed of a frame having a height equal to or less than the height of the partition wall 210, and has a width equal to the width of the partition wall 210 in the frame. The partition wall 222 is formed in plural at the same interval as the spacing of the partition wall 210, is supported by the support plate 110 and the cover plate 140 on the side of the partition wall 210 is installed to be movable in the left and right directions. . To this end, a rail 230 for guiding the movement of the movable partition plate 220 is installed on the upper surface of the support plate 110, or a motor (not shown) for moving the movable partition plate 220 along the rail 230. Can be installed.

When each partition wall 210 is arranged at intervals less than or equal to the width of the partition wall 210, the movable partition wall plate 220 may move in the left and right directions within a range of the width of the partition wall 210. In this case, when the movable partition plate 220 is moved by the maximum distance through the structure, the entire side surface of the breakwater structure is completely closed through the partition wall 210 and the second partition wall 222, and thus the inflow of seawater from the open sea to the inland sea. Is blocked. In addition, when the partitions 210 and the second partition 222 of the mobile partition plate 220 overlap each other, the seawater can be smoothly distributed to the space between the partitions 210, thereby This will prevent sea water from contaminating in the sea.

In addition, each partition wall 210 has a constant width and is arranged perpendicular to the side of the breakwater structure at a predetermined interval, as shown in Figure 5 (a), the movable partition plate 220 is shown in Figure 5 (b). As shown in FIG. 2, the second partition wall 222 having a width equal to the width of the partition wall 210 and smaller than the height of the partition wall 210 is formed in a frame having a height equal to or smaller than the height of the partition wall 210. Plural numbers may be arranged at the same interval as the interval. At this time, the movable partition plate 220 is supported by the support plate 110 and the cover plate 140 on the side of the partition 210 is installed to be movable in the left and right directions, the lower end of the second partition 222 is moved Regardless of the movement of the partition plate 220, the seawater may be introduced through a gap between the partition walls 210. In this case, the height of the second partition wall 222 may be set in consideration of the depth of the area where the breakwater structure is installed, the average depth that the breakwater structure is submerged in seawater. As a result, the breakwater structure according to the embodiment of the present invention allows the seawater to always flow between the outer sea and the inland sea at the lower end submerged in seawater, and adjusts the moving distance of the moving partition plate according to the wave pressure or the wave height at the upper end above the sea level. You can control how much sea breeze or waves enter the inland sea.

On the other hand, when each partition wall 210 is arranged at intervals wider than the width of the partition wall 210, as shown in Figure 6 (a), the movable partition plate 220 is shown in Figure 6 (b) As provided in plurality, each of the movable partition plates 220 may be sequentially installed on the side surfaces of the partition walls 210. At this time, each movable partition plate 220 is a width x (N-1) of the partition from the partition, as shown in Fig. 6 (b) (where N is an integer indicating the order from the partition 210). It can move left and right within the range of. In this case, the number of the movable partition plates 220 sequentially installed on the side surfaces of the partition wall 210 is obtained by raising the value obtained by dividing the distance between the partition wall 210 and the partition wall 210 by the width of the partition wall 210. It is preferable to provide more than an integer. In addition, the height of the partition wall 210 may be set to be equal to or less than the distance between the upper end and the lower end in the frame of the movable partition plate 220, in which case the thickness of the partition wall 210 is the thickness x (moving of the movable partition plate 220) The number of partition plates 220 + 1) may be set. As a result, the breakwater structure according to the embodiment of the present invention may reduce the width of the partition wall 210 and widen the gap between the partition walls 210, and thus, when all the movable partition plates 220 overlap each other, Large quantities of seawater can be smoothly distributed at a time. In addition, the moving partition plate 220 may be sequentially moved in the order from the partition wall 210 to reduce the distance between the partition walls 210, and each of the movable partition plate 220 to the maximum range that can be moved In case of moving, the distribution of seawater between the open sea and the inland sea can be completely blocked.

In addition, each partition wall 210 has a constant width and is arranged perpendicular to the side of the breakwater structure at a predetermined interval as shown in Fig. 7 (a), the mobile partition plate 220 is shown in Fig. 7 (b). As shown in FIG. 2, the second partition wall 222 having a width equal to the width of the partition wall 210 and smaller than the height of the partition wall 210 is formed in a frame having a height equal to or smaller than the height of the partition wall 210. Plural numbers may be arranged at the same interval as the interval. At this time, the lower end of the second partition 222 has a structure in which seawater can be introduced through the gap between the partitions 210 regardless of the movement of the movable partition plate 220. The moving partition plate 220 having such a structure is sequentially installed in a plurality of side surfaces of the partition wall 210, and each of the moving partition plate 220 is supported by the support plate 110 and the cover plate 140 to be in the left and right directions. Can be moved to. In this case, the moving range of each moving partition plate 220 is as described with reference to FIG. 6. In addition, the partition wall 210 may have a thickness corresponding to the second partition wall 222 to be equal to or greater than the thickness x of the movable partition plate 220 (the number of the movable partition plate 220 + 1). In addition, the height of the second partition wall 222 may be set in consideration of the depth of the area where the breakwater structure is installed, the average depth of the breakwater structure is submerged in seawater. As a result, the breakwater structure according to the embodiment of the present invention allows the seawater to always flow between the outer sea and the inland sea at the lower end submerged in seawater, and adjusts the moving distance of the moving partition plate according to the wave pressure or the wave height at the upper end above the sea level. You can control how much sea breeze or waves enter the inland sea.

8 is a view showing a cross-sectional view of the width direction of the breakwater structure according to another embodiment of the present invention.

Referring to FIG. 8, the breakwater structure according to the embodiment of the present invention includes a support plate 110, a cover plate 140, a plurality of unit structures 150, a partition wall 210, and at least one movable partition plate 220. Include. Here, the configuration and operation of the support plate 110, the cover plate 140, the partition wall 210 and the movable partition plate 220 is the same as the case of the breakwater structure of FIG. Detailed description will be omitted.

As shown in FIG. 9, the unit structure 150 includes a lower plate 152 and an upper plate 154, and the lower plate 152 and the upper plate 154 may be connected by a plurality of pillar members 160. At this time, it is preferable that a plurality of holes 156 are formed in each of the lower plate 152 and the upper plate 154. In addition, at least one intermediate plate (not shown) may be installed between the lower plate 152 and the upper plate 154. In this case, the pillar member 160 penetrates the intermediate plate to lower plate 152 and the upper plate ( 154) can be connected. At this time, it is preferable that a plurality of holes are formed in the intermediate plate similarly to the lower plate 152 and the upper plate 154. As a result, the unit structure 150 forms a flow path of seawater through the space between the pillar members 160 and the holes of the lower plate 152 and the upper plate 154.

On the other hand, the bottom surface of the lower plate 152 is formed with a groove, the upper surface of the upper plate 154 may be formed with a projection of the depth of the groove at a position corresponding to the groove of the lower plate 152, such grooves and protrusions A plurality of unit structures 150 may be stacked by interlocking with each other. Alternatively, through holes are formed at corresponding positions of the lower plate 152 and the upper plate 154, and the plurality of unit structures 150 are engaged by engaging the through holes of the different unit structures 150 and fixing them with screws or rivets. It may be laminated. However, the fastening structure of each unit structure 150 is not limited to the described method, and various types of fastening structures may be used.

10 is a view schematically showing a flow rate control device of the breakwater structure according to an embodiment of the present invention.

2 to 10, the flow rate control device of the breakwater structure according to an embodiment of the present invention includes a wave pressure wave height measuring unit 610, a partition driving unit 620 and the movement control unit 630.

The wave pressure wave height measuring unit 610 may be installed on an outer side of the breakwater structure according to the embodiment of the present invention to measure at least one of wave pressure and wave height. That is, the wave pressure wave height measuring unit 610 may be made of a wave pressure gauge for measuring the wave pressure of the wave hitting the breakwater structure, wave height gauge for measuring the wave height of the wave that is pushed into the breakwater structure, and thus the wave at the offshore side of the breakwater structure Measure at least one of wave pressure and crest of.

The partition driving unit 620 moves the movable partition plate 220 installed in the breakwater structure according to the embodiment of the present invention in a left and right direction. That is, the partition driving unit 620 may be configured as a step motor, and moves the movable partition wall 220 in the left and right directions along the guide rail 230 installed on the support plate 110.

The movement control unit 630 controls the moving distance of the moving partition plate 220 by controlling the partition driving unit 620. In this case, the movement controller 630 sets the control reference values of wave pressure and wave height step by step, and controls the movement distance of the moving partition plate 220 according to at least one of the wave pressure and wave height measured by the wave pressure wave height measurement unit 610. can do. In this case, the movement control unit 630 sets the moving distance of the moving partition plate 220 step by step, or sets the moving order for the plurality of moving partition plate 220 step by step, to the wave pressure wave height measurement unit 610. The total area formed by the partition wall 210 and the second partition wall plate 222 is increased on the inshore side of the breakwater structure whenever at least one of the wave pressure and the wave height measured by each exceeds the respective control reference values set in steps. The movement distance of the partition plate 220 may be controlled.

Similarly, whenever at least one of the wave pressure and wave height measured by the wave pressure wave height measurement unit 610 falls below each control reference value set in stages, the partition wall 210 and the second partition wall plate 222 on the sea side of the breakwater structure. It is possible to control the moving distance of the moving partition plate 220 to reduce the total area formed by.

At this time, the movement control unit 630 sets a threshold reference value for the wave pressure and wave height, and if at least one of the wave pressure and wave height measured by the wave pressure wave height measurement unit 610 exceeds the threshold reference value stepwise breakwater structure according to the degree The moving distance of the movable partition plate 220 may be controlled to reduce the total area formed by the partition wall 210 and the second partition wall plate 222 at the side of the sea. That is, when a tsunami occurs on the offshore side of the breakwater structure, seawater can be smoothly distributed from the offshore side to the inshore sea through the breakwater structure, thereby minimizing damage to the breakwater structure due to wave pressure and dug of the tsunami. . At this time, the wave pressure and wave height due to the tsunami, etc. by the structure of the unit structure of the breakwater structure is reduced in force into the inland sea, it is possible to minimize the damage on the inshore side.

11 is a flowchart illustrating a flow rate control method of a breakwater structure according to an exemplary embodiment of the present invention.

2 to 11, the movement control unit 630 may set the control reference values of wave pressure and wave height step by step (S710).

When at least one of the wave pressure and wave height measured by the wave pressure wave measurement unit 610 rises (S720), the movement controller 630 compares the value measured by the wave pressure wave height measurement unit 610 with each control reference value. . At this time, when at least one of the wave pressure and wave height measured by the wave pressure wave height measurement unit 610 exceeds the respective control reference value set in stages, the movement control unit 630 is the partition wall 210 and the first side on the sea side of the breakwater structure. The moving distance of the moving partition plate 220 is controlled to increase the total area formed by the second partition plate 222, or the respective movements to the plurality of moving partition plate 220 are controlled so that The entire area of the partition wall may be controlled to be increased (S730).

 In addition, when at least one of the wave pressure and the wave height measured by the wave pressure wave height measurement unit 610 falls below each control reference value set in step (S740), the movement control unit 630 is a partition wall at the sea side of the breakwater structure ( Breakwater structure by controlling the moving distance of the movable partition plate 220 to reduce the total area formed by the 210 and the second partition plate 222, or by controlling the respective movement to the plurality of movable partition plate 220. It is possible to reduce the total area of the partition wall on the side of the sea (S750).

At this time, the movement control unit 630 sets a threshold reference value for the wave pressure and wave height, and if at least one of the wave pressure and wave height measured by the wave pressure wave height measurement unit 610 exceeds the threshold reference value stepwise breakwater structure according to the degree The moving distance of the movable partition plate 220 may be controlled to reduce the total area formed by the partition wall 210 and the second partition wall plate 222 at the side of the sea. That is, when a tsunami occurs on the offshore side of the breakwater structure, seawater can be smoothly distributed from the offshore side to the inshore sea through the breakwater structure, thereby minimizing damage to the breakwater structure due to wave pressure and dug of the tsunami. .

110: support plate 120, 150: unit structure
130: receptor 140: cover plate
160: pillar member 210: partition wall
220: moving partition plate

Claims (17)

A support plate installed on the sea floor;
A unit structure filled with a container including at least one of a plurality of spherical bodies and polyhedrons in a rectangular parallelepiped frame, wherein a flow path of seawater is formed through pores between each of the spherical bodies and the polyhedrons;
A cover plate stacking the unit structures in a plurality of layers to form a structure wall, and then covering an upper surface of the unit structure of the uppermost layer;
A plurality of partition walls having a predetermined width and arranged vertically at predetermined intervals on a side of the formed structure wall and fixed by the support plate and the cover plate; And
And a plurality of second partition walls having a height equal to or less than the width of the partition walls, the plurality of second partition walls having the same width as that of the partition walls, arranged at the same interval as the gap of the partition walls, At least one movable partition plate supported by the support plate and the cover plate and movable in a horizontal direction;
Breakwater structure comprising a. A support plate installed on the sea floor;
And a plurality of pillar members connecting the upper and lower plates, each of which has a plurality of holes formed therein, and the upper and lower plates, and a flow path of seawater is formed through the space between the pillar members and the holes of the upper and lower plates. Unit structure;
A cover plate stacking the unit structures in a plurality of layers to form a structure wall, and then covering an upper surface of the unit structure of the uppermost layer;
A plurality of partition walls having a predetermined width and arranged vertically at predetermined intervals on a side of the formed structure wall and fixed by the support plate and the cover plate; And
And a plurality of second partition walls having a height equal to or less than the width of the partition walls, the plurality of second partition walls having the same width as that of the partition walls, arranged at the same interval as the gap of the partition walls, At least one movable partition plate supported by the support plate and the cover plate and movable in a horizontal direction;
Breakwater structure comprising a. The method according to claim 1 or 2,
Breakwater structure, characterized in that each of the partition wall is arranged at intervals less than the width of the partition wall. The method of claim 3,
The movable partition plate is a breakwater structure, characterized in that to move in the left and right direction within the width of the partition wall. The method according to claim 1 or 2,
Breakwater structure, characterized in that each of the partitions are arranged at intervals wider than the width of the partition. The method of claim 5,
Two or more said movable partition plates are installed in the side of the said partition, each said movable partition plate is the range of the width x (N-1) (N is an integer which shows the order from the said partition) from the said partition. Breakwater structure, characterized in that to move in the left and right direction. The method of claim 6,
The movable partition plate is a breakwater structure, characterized in that installed by the number greater than the integer value when the distance between the partition wall and the partition and then raised. The method according to claim 1 or 2,
A plurality of the partition wall and the movable partition plate breakwater structure, characterized in that formed on the side of the sea side of the structure wall. On the side surfaces, a plurality of partition walls having a constant width and vertically arranged at predetermined intervals, and a plurality of second partition walls having a width equal to the width of the partition walls in the frame are arranged in a plurality at the same interval as the interval of the partition wall a plurality of the partition walls A wave pressure wave height measurement unit installed on at least one side of an outer sea of the breakwater structure to measure at least one of wave pressure and wave height;
A partition driving unit for moving the movable partition plate in a horizontal direction; And
A movement control unit controlling the movement distance of the moving partition plate by controlling the partition driving unit;
Flow rate control device of the breakwater structure comprising a. The method of claim 9, wherein the movement control unit,
And a step of setting a control reference value of the wave pressure and the wave height step by step, and adjusting the movement distance of the moving plate according to at least one of the wave pressure and wave height measured by the wave pressure wave height measurement unit. The method of claim 10, wherein the movement control unit,
The flow rate control device of the breakwater structure, characterized in that for increasing the width of the partition wall on the side of the sea of the breakwater structure when at least one of the wave pressure and the wave height measured by the wave pressure wave measuring unit exceeds each of the set control reference value. The method of claim 10, wherein the movement control unit,
And at least one of the wave pressure and the wave height measured by the wave pressure wave measuring unit is equal to or less than each set control reference value, thereby reducing the width of the partition wall on the side of the seawater of the breakwater structure. The method of claim 10, wherein the movement control unit,
The flow rate control device of the breakwater structure, characterized in that for controlling the movement of the movable partition plate in the left and right direction within the width of the partition wall. The method of claim 10, wherein the movement control unit,
When two or more of the movable partition plates are sequentially installed at the side surfaces of the partition wall, each of the movements within the range of the width x (N-1) (N is an integer representing an order from the partition wall) of the partition wall from the partition wall. Flow rate control device of the breakwater structure, characterized in that for controlling the movement of the partition plate in the horizontal direction. Stepwise setting control reference values of wave pressure and crest;
On the side surfaces, a plurality of partition walls having a constant width and vertically arranged at predetermined intervals, and a plurality of second partition walls having a width equal to the width of the partition walls in the frame are arranged in a plurality at the same interval as the interval of the partition wall a plurality of the partition walls Measuring at least one of wave pressure and wave height is installed on the outer sea side of the breakwater structure with respect to the breakwater structure having at least one movable partition plate moving in the left and right directions from the side of the; And
Adjusting the moving distance of the moving partition plate of the breakwater structure by comparing at least one of the wave pressure and the wave height measured by the measuring step with a control reference value set by the setting step;
Flow rate control method of the breakwater structure comprising a. The method of claim 15, wherein the moving distance adjusting step,
The flow rate control method of the breakwater structure, characterized in that for increasing the width of the partition wall on the side of the sea of the breakwater structure when at least one of the wave pressure and the height measured by the measuring step exceeds the respective control reference value. The method of claim 15, wherein the moving distance adjusting step,
The flow rate control method of the breakwater structure, characterized in that the width of the partition wall on the side of the sea of the breakwater structure is reduced as at least one of the wave pressure and the height measured by the measuring step is less than each of the set control reference value.

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