KR102460426B1 - caisson that can be equipped with floating wave power generation unit - Google Patents

Abstract

The present invention relates to a caisson to which a floating wave power generation unit can be mounted. According to the present invention, when side walls of caissons are arranged adjacent to each other in contact with each other, a side wall center portion of the caisson is made to enter width direction inward of the <b>caisson</b> so that a space part extending in the vertical direction is formed between adjacent side walls. In addition, a cutout part which goes width direction inward of the caisson is formed at a side wall portion which collides with a wave of a seawater so that the seawater enters and leaves the space part. In addition, the floating wave power generation unit may be mounted on the space part. Provided is the caisson in which the floating wave power generation unit can be safely and effectively installed using a wave power which is a renewable energy source.

Description

caisson that can be equipped with floating wave power generation unit

The present invention relates to a caisson, and more particularly, to a caisson in which a floating wave power generation unit can be mounted.

A caisson is a hollow structure made on land or water to build an underwater structure or foundation, and it sinks to a predetermined position by applying its own weight or external force.

Types of caisson include an open caisson (well barrel, orthodox foundation) that sinks while excavating the inside of a bottomless cylindrical box, creating an airtight work space under the caisson and excluding groundwater with compressed air in the manpower or special machinery There is a pneumatic caisson that sinks using a pneumatic caisson, and a box caisson that makes a hollow box-shaped caisson on land, floats it on water, drags it using a boat, and then loads it and sinks it.

Among the various caisson types, a box caisson is disclosed in Korean Patent Registration No. 10-1694524 as an example.

The box caisson disclosed above includes: each side wall formed in an arcuate shape so that the convex portions on both sides between the front and rear vertical walls face each other; each main bulkhead formed in an arch shape so that a convex part faces the front and rear vertical walls between the front and rear vertical walls and between each of the arched side walls; a plurality of main compartments formed by a plurality of first auxiliary vertical bulkheads formed to cross each other between each of the sidewalls and each of the main bulkheads; auxiliary compartments formed to have different areas by second auxiliary vertical bulkheads connected between each of the main bulkheads and the front and rear vertical walls; and a vertical contact surface formed between both ends of each of the arch-shaped side walls and both ends of the front and rear vertical bulkheads so that front and rear both side ends of each caisson come into contact with each other.

When the disclosed box caisson rescues an underwater structure, in a state in which a plurality of the disclosed caisson are arranged in a line so that adjacent vertical contact surfaces are in surface contact with each other, the plurality of main compartments and the plurality of auxiliary compartments are filled with rocks, and neighboring The space formed between the side walls in the form of an arch is filled with sandstone.

By such a configuration, a minimum of compartments are formed and, while having high responsiveness to the lateral pressure of rocks filled in each compartment, the weight is minimized compared to the same cross-sectional size and light weight, so that the caisson manufacturing cost and mounting cost can be significantly reduced. It provides an effect that can maximize the durability, stability, and economy of the caisson structure, and damage to each bulkhead due to lateral pressure can be minimized.

However, the disclosed caisson has a problem in that it is applied only to an underwater structure used for underwater projects such as construction and engineering, particularly bridge or dam construction, and is not applied to a power generation device using wave power as a renewable energy source.

The present invention has a problem in solving the above problems.

In the present invention, when the sidewalls of the caisson abut each other and are arranged adjacent to each other, the central portion of the sidewall of the caisson enters in the width direction of the caisson so as to form a space portion extending vertically between the adjacent sidewalls. ; forming a cut-out that enters inward in the width direction of the caisson on the side wall portion colliding with the waves of seawater so that seawater enters and exits the space; And it is possible to solve the above problems by mounting the floating wave power unit in the space.

The present invention can safely and effectively install a floating wave power generation unit using wave power, a renewable energy source, by securing a space within the breakwater section while sufficiently maintaining the function as a breakwater by an underwater structure by means of solving the problems as described above. A caisson can be provided.

1 is a perspective view showing a state in which the caisson of an embodiment according to the present invention is overlapped next to each other and arranged in a row;
Figure 2 is a plan view of Figure 1;
3 is a front view of FIG. 1 , and
Figure 4 is a perspective view showing a portion of the space of Figure 1 cut out.

Hereinafter, a caisson of an embodiment according to the present invention will be described in detail with reference to FIGS. 1 to 4 .

In Fig. 1, the caisson of this embodiment is indicated by reference numeral 100. As shown in Figs.

The caisson 100, as shown in Figures 1 and 2, a pair of horizontal vertical walls 10 disposed before and after with respect to the wave direction; A pair of vertical walls 20 having both ends coupled to both ends of the horizontal and vertical wall 10 and having a pair of curved side walls 21 concave inward in the longitudinal direction of the pair of horizontal and vertical walls 10 in the middle portion ); A convex portion between the pair of vertical and vertical walls 20 and between the pair of horizontal and vertical walls 10 extends in an arcuate form to face the pair of horizontal and vertical walls 10, so that both ends of the pair of curved sidewalls ( 21) a pair of curved partition walls 30; Ends extending in the horizontal and vertical directions so that a plurality of intermediate compartments S1 are formed in a grid pattern between the pair of curved sidewalls 21 and the pair of curved partition walls 30. The pair of curved sidewalls 21 ) and an intermediate partition wall 40 coupled to the pair of curved partition walls 30; And ends extending in the longitudinal direction so that a plurality of outer compartments (S2) are formed in a row between the pair of curved partition walls 30 and the pair of horizontal and vertical walls 10 are the pair of curved partition walls 30 and It includes a plurality of outer partition walls (50) coupled to the pair of horizontal and vertical walls (10).

The entire space of the intermediate compartment (S1) and the outer compartment (S2) is filled with sandstone.

The caisson 100 is vertical by the vertical vertical walls 20 and 20 adjacent to each other when a pair of vertical vertical walls 20 of the caisson 100 are arranged adjacent to each other in contact with each other. The space portion S3 extending in the direction is partitioned.

In the middle of the vertical vertical wall 20 disposed adjacent to the direction facing the wave, as shown in FIGS. 3 and 4, the length of the horizontal vertical wall 10 is smaller than the radius of the space portion S3. A concave portion 22 entering the longitudinal direction and having a height smaller than the height of the space portion S3 extends in the longitudinal direction and is formed to flow in the space portion S3, and a pair of horizontal and vertical walls ( In 10) of the concave portion 22, a cut-out portion 11 is formed to face the concave portion 22 and flow through the portion of the horizontal and vertical wall 10 facing and adjacent to the concave portion 22 .

In the space portion S3 , a gravel layer 60 filled with gravel stones is formed at a level lower than the height level of the concave portion 22 .

A floating wave power generation unit 70 is mounted in the space portion S3 on the sandstone layer 60 .

The floating wave power generation unit 70 is a plurality of chain-like chains having one end coupled to a bracket wall 71 integrally formed extending in the longitudinal direction to the curved side wall 21 defining the space portion S3. Since it is coupled to the traction line 72, it can be moved up and down according to the amount of seawater entering and leaving the space (S3).

The floating wave power generation unit 70 is a known unit, and as an example, the wave power device disclosed in Korean Patent Registration Nos. 1396513, 1258063, and 1376308 may be applied.

According to the caisson 100 configured as described above, while sufficiently maintaining the function as a breakwater by an underwater structure, the cutout portion of the vertical vertical wall 20 in contact with each other by securing the space portion (S) within the breakwater section Seawater enters and leaves the space S3 through the flow path L formed by (11) and the concave portion 22, and the floating wave power generation unit 70 disposed in the space S3 enters the space. According to the amount of seawater entering and leaving the part (S3), it vibrates up and down, whereby electricity can be efficiently produced.

In addition, according to the caisson 100 configured as described above, since the sandstone layer 60 is formed in the lower portion of the space portion S3 in a state in which the adjacent vertical and vertical walls 20 are in contact with each other, The frictional force between rocks can generate strong mutual support for waves, and the caissons connected by mutual support can disperse the partially concentrated wave power to the entire breakwater to prevent the destruction of the activity of a specific caisson, and In a situation where the caisson increases and is pushed out, the internal rocks first deform, reducing the stress, and as a result, the effect of increasing the stability of the caisson can be achieved.

DESCRIPTION OF SYMBOLS 10: horizontal vertical wall, 11: cut-out part, 20: vertical vertical wall, 21: curved side wall, 22: concave part, 30: curved bulkhead, 40: middle partition wall, 50: outer partition wall, 60: sandstone layer, 70: Floating wave power generation unit, 71: bracket wall, 72: tow line, 100: caisson, L: flow path, S1: intermediate compartment, S2: outer compartment, S3: space

Claims (6)

When the vertical vertical walls 20 of the caisson 100 abut each other and are arranged adjacent to each other, a space portion S3 extending in the vertical direction is formed between the adjacent vertical vertical walls 20, The central portion of the vertical vertical wall 20 of the caisson 100 enters in the width direction of the caisson 100;
A cut-out 11 that enters the width direction of the caisson 100 is formed in the horizontal and vertical wall 10 portion colliding with the waves of seawater so that seawater enters and exits the space S3; and
A floating wave power generation unit 70 is disposed in the space S3,
In the middle of the vertical vertical wall 20 disposed adjacent to the direction facing the wave, it enters the longitudinal direction of the horizontal vertical wall 10 with a length smaller than the radius of the space portion S3, and the space portion ( A concave portion 22 having a height smaller than the height of S3 extends in the longitudinal direction and is formed to flow in the space S3, and adjacent to the concave portion 22 and facing the horizontal and vertical wall 10 of A cut-out portion 11 is formed in the region to face the concave portion 22 and flow.
a rock layer 60 is formed by filling the space portion S3 with gravel at a level lower than the height level of the recess 22; and
A floating wave power generation unit 70 is disposed in the space portion S3 above the sandstone layer 60,
The floating wave power generation unit mountable caisson, characterized in that electricity is produced by vibrating up and down the floating wave power generation unit 70 according to the amount of seawater entering and exiting the space (S3). delete delete The method of claim 1,
The caisson 100 is
A pair of horizontal and vertical walls 10 disposed before and after with respect to the wave direction;
A pair of vertical walls 20 having both ends coupled to both ends of the horizontal and vertical wall 10 and having a pair of curved side walls 21 concave inward in the longitudinal direction of the pair of horizontal and vertical walls 10 in the middle portion );
A convex portion between the pair of vertical and vertical walls 20 and between the pair of horizontal and vertical walls 10 extends in an arcuate form to face the pair of horizontal and vertical walls 10, so that both ends of the pair of curved sidewalls ( 21) a pair of curved partition walls 30;
Ends extending in the horizontal and vertical directions so that a plurality of intermediate compartments S1 are formed in a grid pattern between the pair of curved sidewalls 21 and the pair of curved partition walls 30. The pair of curved sidewalls 21 ) and an intermediate partition wall 40 coupled to the pair of curved partition walls 30; and
Ends extending in the longitudinal direction are formed such that a plurality of outer compartments S2 are formed in a row between the pair of curved partition walls 30 and the pair of horizontal and vertical walls 10 are the pair of curved partition walls 30 and the It includes a plurality of outer partition walls (50) coupled to a pair of horizontal and vertical walls (10),
When a pair of vertical walls 20 are arranged adjacent to each other in contact with each other, the space portion S3 extending in the vertical direction by the vertical vertical walls 20 and 20 adjacent to each other is partitioned. A caisson that can be equipped with a floating wave power unit. 5. The method of claim 4,
A caisson capable of mounting a floating wave power generation unit, characterized in that the entire space of the intermediate compartment (S1) and the outer compartment (S2) is filled with sandstone. The method of claim 1,
The floating wave power generation unit 70, so that it can move up and down according to the amount of seawater entering and leaving the space S3, one end is coupled to the wall defining the space S3. A caisson capable of mounting a floating wave power unit, characterized in that it is coupled to the traction line (72).

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