KR102290326B1 - Movable-type Parpet Structure - Google Patents

Abstract

The movable parapit structure of the present invention is for securing the stability of port structures such as breakwaters and shorelines and preventing overbursts. ) provided inside, including a movable part 210 having a hollow structure, and a bucket 240 connected to the movable part 210 and a wire (W); In normal use, it is folded, so it is possible to easily secure the view, in case of overtaking, it can stand up automatically to block the overtaking, and the main point is to increase the stability of the structure by the number of overtaking trapped in the water tank.

Description

Movable-type Parpet Structure

The present invention relates to a movable parapet structure, and more particularly, to a movable parapet structure that is installed on a breakwater or a shore, and automatically stands up by an overturning wave, thereby blocking the overtaking.

Breakwaters are roughly classified into caisson-type (upright) breakwaters, sandstone breakwaters, and mixed breakwaters in terms of their structure. Since there is a concern about damage to the back, the structure of the standing concrete is known so that the wave can block the overtaking while increasing the height of the concrete to prevent the wave from overtaking the breakwater.

1 is a schematic view of a conventional caisson breakwater.

As shown, the conventional caisson-type breakwater is deep in water and in order to prevent excessively large amount of sandstone, the foundation sandstone (1) is built up to a certain height, and after installing a plurality of caisson (4) thereon , by filling the inside of the caisson 4 with sand, etc., to achieve the stability of the wall, and the uppermost structure is installed at the top of the caisson 4. The configuration in which the parapet 11 is installed is known. Reference numeral 2, which is not described, denotes covered stone.

However, in the structure of the conventional breakwater as above, the height of the parapet 11 is always constant without a separate means to adjust the height of the parapet 11 above the seawater surface. There is a problem that not only the castle is deteriorated, but also the construction cost is high.

In addition, when the parapet 11 is lowered above the surface of the seawater during initial construction, the wave height is increased due to a storm or typhoon, and the phenomenon of breaking the breakwater cannot be prevented, so there is a problem that the role of the breakwater cannot be properly performed.

Publication No. 10-2011-0021231 (published on March 4, 2011)

The present invention is to enable the parapet installed in the breakwater or the shore to be folded in normal times to easily secure the view, and to automatically stand up to block the overwave.

The movable parapit structure according to the present invention is a parapit for securing stability of port structures such as breakwater and shoreline and preventing over-wave, the parapet includes a water tank made by excavating the upper part of the upper concrete, and is provided inside the water tank, and is hollow A movable part having a structure of, and a bucket connected to the movable part by a wire; It is characterized in that it is folded in normal times, so it is possible to easily secure the view, in case of overtaking, it can stand up automatically to block the overtaking, and it is characterized by increasing the stability of the structure by the number of overtaking trapped in the water tank.

In addition, the movable part is characterized in that it is installed so that the center of gravity is formed in the outer sea side around the hinge.

In addition, it is characterized in that the ring portion for supporting by coupling the wire to the upper surface of the movable part is formed.

In addition, it is characterized in that it is provided with a pulley that protrudes from the outer wall of the inner sea side of the upper concrete and guides the wire coupled to the ring part.

In addition, it is characterized in that a guide roller is provided in the opening formed in the upper concrete on the inner sea side.

In addition, it is characterized in that micro-holes are formed in the bottom surface of the bucket.

In addition, a large-diameter through-hole is formed on the bottom surface of the bucket, and a leaf spring is provided on one side of the large-diameter through-hole to maintain elastic force in an upwardly inclined state.

In addition, the fixing means is further provided; The fixing means is formed on one side of the movable part, a cut-out groove for smooth elastic deformation is formed in the center, a fixing piece having an inclined surface on the outer surface, and a depression in one surface of the upper concrete, and inclined on the inner wall surface It is characterized in that it consists of a fixing groove formed on the inner surface.

In addition, it is characterized in that one end of the cut-out groove is provided with an arc-shaped groove for preventing stress concentration and smooth elastic deformation.

The movable parapet installed on the breakwater or the shore of the present invention is normally folded, so it is possible to easily secure the view, and it has the effect of automatically standing up and blocking the overtaking when overtaking, It has the effect of increasing the stability of the structure by using it as its own weight.

1 is a schematic diagram of a conventional caisson breakwater
Figure 2 is an ordinary plan sectional view of the movable parapet of the present invention.
Figure 3 is a normal right side view of the movable parapet.
4 is a plan cross-sectional view of the movable parapet in a standing state during a storm.
5 is a plan sectional view of the movable parapet in which the standing state is completed during a storm.
6 is a plan view of a second embodiment of the movable parapet in a normal state.
7 is a cross-sectional view and a partially enlarged view of a normal bucket drainage structure.
8 is a cross-sectional view and a partially enlarged view of a bucket drainage structure during a storm.
9 is a schematic perspective view of the fixing means of the present invention;
Figure 10a is a cross-sectional view of a state before coupling of the fixing means of the present invention. Figure 10b is a cross-sectional view of the coupled state of the present invention fixing means.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. For reference, sizes of components, thicknesses of lines, etc. shown in the drawings referenced to describe the present invention may be expressed somewhat exaggeratedly for convenience of understanding.

In addition, the terms used in the description of the present invention are defined in consideration of the functions in the present invention, and thus may vary according to user, operator intention, custom, and the like. Therefore, the definition of this term should be made based on the content throughout the present specification.

And in the present application, terms such as 'comprise' and 'have' refer to the existence of a specific number, step, operation, component, part, or combination thereof described in the specification, but one or more other It is to be understood that this does not preclude the possibility of addition or presence of features or numbers, steps, operations, components, parts, or combinations thereof.

In addition, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only this embodiment allows the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art It is provided for complete disclosure.

Therefore, the present invention can be made various changes and can have various forms, implementation examples (態樣, aspect) (or embodiments) will be described in detail in the specification. However, this is not intended to limit the present invention to a specific disclosed form, and it should be understood to include all changes, equivalents or substitutes included in the technical spirit of the present invention, and the expression in the singular used herein is clearly different from the context. Unless otherwise indicated, plural expressions are included.

However, in describing the present invention, detailed descriptions of well-known or well-known functions or configurations will be omitted in order to clarify the gist of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

2 is a plan view of the movable parapet of the present invention, FIG. 3 is a normal right side view of the movable parapet, FIG. 4 is a plan sectional view of the movable parapet in a standing state during a storm, and FIG. 5 is a standing state of the movable parapet during a storm. is a completed plan view.

As shown, the movable parapet 200 of the present invention, which secures the stability of port structures such as breakwaters and shorelines and prevents overburden, is a water tank 130 made by excavating the upper part of the existing upper concrete 120, and a movable part that automatically stands up when an overturn occurs 210 is included, and on the outer wall of the inner sea side of the water tank 130, a drain pipe 150 is formed, and the water tank 130 is communicated with the inner sea, which is an outside.

Specifically, the movable parapet 200 includes a movable part 210 , a ring part 220 , a pulley 230 , a bucket 240 , and a wire W .

The movable part 210 is provided inside the water tank, has a hollow structure, has a structure to form buoyancy, and is installed such that the center of gravity is formed toward the outer sea side around a hinge 211 to be described later.

One end of the movable part 210 is in contact with and supported on the upper surface of the outer wall of the outer water tank, and the other side portion is rotatably coupled to a hinge 211 fixed to the upper surface of the inner wall of the inner water tank.

The ring part 220 is formed on the outer sea side with the hinge 211 as the center on the upper surface of the movable part 210, and functions to support the wire (W) to be described later by coupling.

The wire (W), one end of which is coupled to the ring portion 220, penetrates through the opening 160 formed in the inner sea side upper concrete and is guided by the pulley 230, while the bucket 240 is coupled to the other end. has become (See Fig. 2, Fig. 3)

The pulley 230 is formed to protrude from the inner sea side outer wall of the upper concrete 120 , and serves to guide the wire W coupled to the ring part 220 .

The bucket 240 has a rectangular structure with an open top, and the wire coupled to the ring part 220 is coupled to the end guided by the pulley 230 .

A micro-hole 241 is formed in the bottom surface of the bucket 240, and after a storm passes, it functions to slowly drain the overpass water built into the bucket into the micro-hole. (See Fig. 8)

Looking at the working relationship of the above configuration,

When a wave overtake occurs due to a storm or typhoon, the water tank 130 is filled with water, and the bucket 240 is also filled with water by hitting the waves through the opening 160 of the Sangchi concrete. When the water tank and the bucket are filled with water, the buoyancy force acts on the movable part 210 by the water cold in the water tank, and due to the weight of the overwater filled in the bucket, the bucket descends, and when the bucket descends, the bucket and the wire ( The movable part 210 connected by W) is rotated and stood around the hinge 211 .

After the storm passes, the water in the bucket connected to the pulley is also gradually drained through the micro-holes 241 after the overpass water exits through the drain pipe 150, so that the movable part returns to its original position by its own weight.

Therefore, the parapit has the effect of being able to easily secure the view because it is normally folded, and the effect of automatically standing up to block the overtaking when overtaking, and the effect of increasing the stability of the structure by the number of overtaking trapped in the water tank there is

Hereinafter, a second embodiment of the movable parapet of the present invention will be described.

6 is a plan view of a second embodiment of the movable parapet, which is an ordinary plan view.

As shown, the configuration characteristic of this embodiment is that the guide roller 250 is provided in the opening 160 formed in the upper concrete on the inner sea side. A description of the configuration is omitted.

The guide roller 250 has a function and effect of preventing the wire W from being damaged due to sagging due to its own weight, contact with the inner surface of the opening, and abrasion by guiding while supporting the wire (W).

Hereinafter, the drainage structure of the bucket will be described.

7 is a cross-sectional view and a partially enlarged view of a bucket drainage structure in normal times, and FIG. 8 is a cross-sectional view and a partially enlarged view of a bucket drainage structure during a storm.

As shown, a drainage structure is provided on the bottom surface of the bucket 240 , and the drainage structure includes a fine through hole 241 , a large diameter through hole 242 , and a leaf spring 243 .

A plurality of micro-holes 241 are formed by penetrating through the bottom surface of the bucket 240, and since the diameter of the through-holes is small, the water is slowly drained, so that the water that overflows into the inside of the bucket 240 during a storm and fills up. The amount of draining is small, so the water inside the bucket is not drained immediately and can remain full.

Therefore, during a storm, the bucket is kept full of water and weight can be given, and since there is no overpassing water in normal times, the water is gradually drained through the micro-holes and has a function to drain all the water in the bucket. .

The large-diameter through-hole 242 is formed through the bottom surface of the bucket 240, and the large-diameter through-hole 242 has a function of quickly draining the water in the bucket.

Of course, the large-diameter through-holes 242 may be formed in one or a plurality according to the need for rapid drainage.

The leaf spring 243 is provided on one side of the large-diameter through hole 242 on the bottom of the bucket in a structure in which the elastic force is maintained in a state inclined upward.

Since the leaf spring 243 is filled with water due to overpass in the bucket, the leaf spring is elastically deformed by the weight of the water to shield the large-diameter through-hole 242. This will prevent the water in the bucket from draining out.

If the storm does not pass and the overpass is not achieved, the water in the bucket is gradually drained through the micro-holes, and when the water inside the bucket is reduced, the leaf spring is restored to its original position due to the elastic force. The water inside can be drained quickly.

Hereinafter, another embodiment of the present invention will be described with respect to the fixing means.

Figure 9 is a schematic perspective view of the fixing means of the present invention, Figure 10a is a cross-sectional view of the state before coupling of the fixing means of the present invention. Figure 10b is a cross-sectional view of the coupled state of the present invention fixing means.

As shown, the fixing means 140 is divided into a fixing piece 141 formed on one side of the movable part 210 and a fixing groove 142 formed on one surface of the upper concrete.

The fixing piece 141, a cut-out groove 141a is formed in the center, and an arc-shaped groove 141b for preventing stress concentration and smooth elastic deformation is formed at one end of the cut-out groove 141a. , an inclined surface 141c is provided on the outer surface of the fixing piece.

The fixing groove 142 has a structure recessed in one surface of the upper concrete 120, and an inclined inner surface 142c is formed on the inner wall surface.

Looking at the operation relationship of the above fixing means,

The fixing means 140, when the movable part 210 is supported on the upper surface of the outer wall of the upper-floor concrete in a state in which there is no over-wave, or when the movable part 210 stands up by the over-wave and is in contact with the upper-mounted concrete, the movable body Since the fixing piece 141 formed on one side of the starting unit 210 is elastically deformed so as to be expanded or contracted by the incision groove 141a, it is inserted into the fixing groove 142 in a reduced state. When it is fully inserted, it expands and is fixed by the inclined inner surface 142c, so that the movable body 131 can be fixed at a certain position of the upper concrete.

Hereinafter, another embodiment of the fixing means of the present invention will be described.

In this embodiment, the movable part 210 is formed of a metal material, and the fixing means 140 formed on the standing concrete 120 is characterized in that it is formed of a permanent magnet.

In this embodiment, the movable part 210 rotates outside the magnetic force of the permanent magnet, which is the fixing means, due to the buoyancy force and the weight of the bucket, and in the standing state, only the difference is that the standing posture is maintained by the magnetic force of the fixing means. The configuration is not different from the above-described embodiment.

As described above, the movable body installed on the breakwater or the shore of the present invention is normally folded, so it is possible to easily secure the view, and in the case of overtaking, it automatically stands up to block the overtaking effect and the overwater channel trapped in the water tank. This has the effect of increasing stability.

110: Caison 120: Sangchi Concrete
130: tank 140: fixing means
141: fixed piece 141a: incision groove
141b: arc-shaped groove 141c: inclined surface
142: fixed groove 150: drain pipe
160: opening 200: para fit
210: movable part 211: hinge
220: loop 230: pulley
240: bucket 241: micro through hole
242: large bore hole 243: leaf spring
250: guide roller W: wire

Claims (9)

In a parapit for securing the stability of port structures such as breakwaters and shorelines and preventing over-waves,
The parapet 200 is,
A water tank 130 made by excavating the upper part of the upper concrete 120,
A movable part 210 provided in the water tank 130 and having a hollow structure,
including a bucket 240 connected to the movable part 210 and a wire (W);
A micro through hole 241 and a large diameter through hole 242 are formed in the bottom surface of the bucket 240,
One side of the large-diameter through-hole 242 is provided with a plate spring 243 in which the elastic force is maintained in an upwardly inclined state,
Movable parapet structure, characterized in that it can be folded in normal use to easily secure the view, can stand up automatically to block the overtaking, and increase the stability of the structure by the number of overpassing trapped in the water tank. 2. The method of claim 1,
The movable part 210 is a movable parapet structure, characterized in that it is installed such that the center of gravity is formed toward the sea side with the hinge 211 as the center. 3. The method of claim 2,
A movable parapet structure, characterized in that a ring portion 220 supporting the wire (W) is formed on the upper surface of the movable portion 210 . 4. The method of claim 3,
A movable parapet structure, characterized in that it is provided with a pulley 230 protruding from the inner sea side outer wall of the upper concrete 120 and guiding the wire W coupled to the ring part 200 . 5. The method of claim 4,
Movable parapet structure, characterized in that the guide roller (250) is provided in the opening (160) formed in the inner sea side upper concrete. delete delete 2. The method of claim 1,
Doedoe fixing means 140 is further provided;
The fixing means 140 is
A fixing piece 141 formed on one side of the movable part 210, an incision groove 141a for smooth elastic deformation is formed in the center, and an inclined surface 141c formed on the outer surface,
Movable parapet structure, characterized in that it is formed by being depressed in one surface of the upper concrete (120), and comprising a fixing groove (142) having an inclined inner surface (142c) formed on the inner wall surface. 9. The method of claim 8,
Movable parapet structure, characterized in that one end of the cut-out groove (141a) is provided with an arc-shaped groove (141b) for preventing stress concentration and smooth elastic deformation.

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