KR200460617Y1 - Combination unit for combining of structure - Google Patents

Abstract

The present invention relates to a coupling unit for binding the structure. The present invention is a coupling unit (C) for binding between the safety tetrapod 100 including cylindrical bodies extending in a plurality of directions from the center and formed through holes 118, the coupling passing through the through holes 118 A first coupling piece 500 having a wire 400, one end of both ends of the coupling wire 400, and a first screw part 502 formed thereon, and the other end of the coupling wire 400. It is configured to include a second coupling piece 600 is formed with a second screw portion 602 to be screwed to the first screw portion 502. According to the present invention, since a plurality of structures are bound by screwing the coupling unit (C) passing through them, the binding work between the structures is easy to improve the workability and the state that the solid state is firmly maintained have.

Structure, coupling unit, screwing

Description

Combination unit for combining of structure

The present invention relates to a coupling unit, and more particularly to a coupling unit for binding the structure for binding between a plurality of structures, such as building structures or offshore structures.

Structures used in the fields of construction, civil engineering, machinery, etc. generally have a very large load, and in some cases, they may be used in sets of several, and in particular, may be firmly bound to each other by separate coupling units.

Figure 1 shows one of these structures, Tetrapod, one of the offshore structures.

Tetrapod is a tetrahedral structure that protects breakwaters from waves and tsunamis by destroying or reducing the force of waves by overcoming strong algae or water pressure, and the porosity is about 50%. Tetrapod (T.T.P) is a concrete block with the necessary conditions as a sofa block by hydraulic and field experiments over the years, and was used by NEYRICP in 1949.

Typical tetrapods are formed by connecting four cylindrical bodies in a direction of symmetry, as shown. That is, when any one of the four body is upward, each shape is the same shape.

This form is intended to maintain stability even when installed without special orientation during installation.

At this time, each of the body is formed in a smooth cylindrical shape, more precisely has a tapered shape that narrows in diameter from the inner side to the outer side.

In addition, when a plurality of such tetrapods are stacked, a binding unit is bound to an adjacent tetrapod by using a separate coupling unit, for example, a steel wire. This is to ensure that the plurality of tetrapods are firmly bound to withstand strong algae or water pressure.

However, there are the following problems in the coupling unit for binding the structure as described above.

Once a plurality of structures such as tetrapods are installed, they must be firmly bound between them, and this work is also performed using a rope or steel wire. However, due to the large weight of the structure, it is not easy to bind each structure, and in particular, it is very difficult to tie both ends of the rope after connecting a plurality of structures using the rope.

In addition, even if a plurality of structures are firmly bound by a rope, resonance may occur in the structure by a repetitive load having a constant cycle applied to the structure, for example, waves or wind, and such resonance may cause waves or wind power. By causing the overlap of the, applying a huge external force to the structure, there is a problem of destroying the structure itself and the rope.

The present invention is devised to solve the conventional problems as described above, an object of the present invention is to be easily bound by a coupling unit between a plurality of installed structures, and to ensure that the bound state is firmly maintained.

Another object of the present invention is to provide a coupling unit in which a predetermined flow range is allowed between installed structures.

According to a feature of the present invention for achieving the object as described above, the present invention is a coupling unit for engaging between the safety tetrapods including cylindrical bodies extending in a plurality of directions from the center and formed through holes, the through hole A coupling wire passing through, a first coupling piece provided at either end of the coupling wire and having a first screw portion formed therein, and a second screw portion provided at the other end of the coupling wire and screwed to the first screw portion; It is comprised including the 2nd engagement piece formed.

The first coupling piece and the second coupling piece are provided to be movable along the coupling wire, respectively, and stoppers are provided at both ends of the coupling wire, respectively, to prevent separation of the first coupling piece and the second coupling piece. .

Internal spaces are formed in the first coupling piece and the second coupling piece, respectively, and when the first and second coupling pieces are screwed together, the stopper is positioned in the internal space, and the sum of the lengths of the two stoppers is equal to the above. It is formed smaller than the length of the inner space is formed between the two stopper to move the stopper is movable.

The stopper includes a base member coupled to the outer surface of the coupling wire, and an outer member coupled to and compressed to surround the outer surface of the base member.

The base member is composed of a flexible metal plate member having an embossing formed thereon or a wire rod of metal surrounding the coupling wire in the form of a cylindrical spring.

An inner space of the first coupling piece and the second coupling piece and the stopper are formed in a cylindrical shape, and outer surfaces of the first coupling piece and the second coupling piece are formed in a polygonal shape.

The first coupling piece and the second coupling piece are each provided with a tapered portion whose diameter decreases toward one end thereof.

In the coupling unit for binding the structure according to the present invention as described above can be expected the following effects.

In the present invention, since a plurality of installed structures are bound by a coupling unit passing therethrough, the binding work of the structure is facilitated, thereby improving workability.

In particular, in the present invention, since both ends of the coupling wire constituting the coupling unit are screwed by the first and second coupling pieces, the coupling wire can be fastened with a relatively small force and the fastened state can be maintained firmly. Therefore, the effect of improving stability can also be expected.

In addition, in the present invention, since the proper clearance is formed between the stoppers provided at both ends of the coupling wire, the structure is allowed to flow within a certain range, so that the resonance does not occur in the structure even by repeated loads such as waves or wind whose period is constant. . Therefore, the excessive tension of the coupling wire is prevented from being applied, thereby preventing damage to the coupling wire, and as a result, there is an effect that the binding between the structures can be more firmly maintained.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the coupling unit for the structure binding according to the present invention as described above in detail.

Figure 2 is a perspective view of the tetrapod bound by the preferred embodiment of the coupling unit for binding the structure according to the present invention, Figure 3 is a perspective view of the configuration of the tetrapod bound by the coupling unit according to the present invention 4, the configuration of the present invention is shown in a plan view, and in FIG. 5, the internal configuration of the present invention is shown in a partially cutaway plan view. Hereinafter, among the structures, it will be described taking as an example the safety tetrapod for the coastal structure.

For convenience of description, the safety tetrapod 100 will be described first. As shown in FIGS. 2 and 3, the safety tetrapod 100 is formed by connecting four cylindrical bodies 110 in a positive symmetry direction. Here, the positive symmetry refers to a shape such that the four bodies 110 have the same angle with respect to the adjacent body 110, respectively. This is to maintain stability even when the safety tetrapod 100 is installed without special orientation when installed.

And each of the body 110 is formed in a cylindrical shape, has a tapered shape that narrows in diameter toward the outside from the inner side (coupling portion of the body (110)).

On the other hand, a portion of the outer peripheral surface of the body 110 is formed with a flat surface 112. At this time, the flat surface 112 is to be easy to maintain the stability when a person rises, it is formed on the outer periphery of the body 110 including a center point that the outer periphery of the three body (110).

The flat surface 112 is formed with a non-slip groove 114 for preventing the movement of people, the pedestrian slips. The non-slip groove 114 is formed by digging at a predetermined depth horizontally along the flat surface 112 at a predetermined interval. That is, it is formed in a form similar to the speed preventing groove of the highway.

In addition, the body 110, if a person falls, the gripping groove 116 is formed so that the fallen person or rescue personnel can easily go down or climb up the safety tetrapod 100. The gripping groove 116 is formed along the longitudinal direction of the body 110 on the outer periphery of the body 110.

On the other hand, the outer portion of the body 110 of the safety tetrapod 100 is formed with a through hole 118 penetrating the outer portion of the body (110).

The through hole 118 allows for easy and safe construction of the mounting process of the safety tetrapod 100, and at the same time after the safety tetrapod 100 is mounted, the safety tetrapod using the coupling unit C to be described later ( 100) Make sure the tightness between them.

That is, the support rope 210 is inserted into the through hole 118 to mount the safety tetrapod 100 or the coupling wire 400 constituting the coupling unit C is inserted into the safety tetrapod 100. There is a bond between them.

In this case, the through hole 118 may be formed on the flat surface 112, as shown in FIG. 3, but may be formed on the outer circumference of the body 110 other than the flat surface 112. .

Next, when describing the coupling unit (C) for binding the safety tetrapod 100, the coupling unit (C) is for binding the safety tetrapod 100 towed to the shore, large coupling wire (400) ) And the first coupling piece 500, and the second coupling piece 600.

The coupling wire 400 is made of a material having high tensile strength including a general steel wire rope (鋼 索), and is a portion that substantially passes the through hole 118 of the safety tetrapod 100.

As shown in Figure 5, both ends of the coupling wire 400 is provided with a first coupling piece 500 and the second coupling piece 600, respectively. The first coupling piece 500 and the second coupling piece 600 are coupled to each other, such that both ends of the coupling wire 400 are coupled and tied together.

At this time, the first coupling piece 500 and the second coupling piece 600 are coupled to each other by screwing. Accordingly, after passing through the plurality of safety tetrapod 100, both ends of the coupling wire 400 in a state in which a large tension is applied can be more easily coupled.

That is, the first coupling piece 500 and the second coupling piece 600 are provided to be movable along the coupling wire 400, and are each provided with a female screw portion and a male screw portion to be screwed together.

Referring first to the first coupling piece 500, as shown in Figure 6 (a), the first coupling piece 500 is formed therein the inner space 501 along the longitudinal direction. The inner space 501 is a substantially cylindrical space through which the coupling wire 400 passes, and the first stopper 550 to be described below is located. Since the inner space 501 is formed in a cylindrical shape, the first coupling piece 500 may be used without directivity.

The first screw part 502 is provided in the inner space 501 of the first coupling piece 500. The first screw portion 502 is a portion that is screwed with the second screw portion 602 of the second coupling piece 600 to be described below, the female screw portion (second screw portion 602 is a male screw portion) or a male screw portion ( The second screw portion 602 may be composed of a female screw portion.

In the case of the second coupling piece 600, as shown in FIGS. 5 and 6 (b), a cylindrical inner space 601 is formed along the longitudinal direction, similar to the first coupling piece 500. At one end, a second screw portion 602 is formed. The second screw portion 602 is formed on the outer surface of the portion protruding in a ring shape from the second coupling piece 600, is inserted into the inner space 501 of the first coupling piece 500 is the first It is screwed with the threaded portion 502.

At this time, it is preferable that the outer surfaces of the first coupling piece 500 and the second coupling piece 600 are each formed in a polygonal shape. This is to allow the first coupling piece 500 or the second coupling piece 600 to be easily rotated by using a tool such as a spanner (even when the worker is gripped).

Meanwhile, stoppers 550 and 650 are provided at both ends of the coupling wire 400, respectively. The two stoppers 550 and 650 are for preventing the first coupling piece 500 and the second coupling piece 600 from being separated from the coupling wire 400. The first coupling piece 500 and the second coupling piece When the piece 600 is combined, the pieces 600 are positioned in the inner spaces 501 and 601.

More precisely, unlike the first coupling piece 500 and the second coupling piece 600, the two stoppers 550 and 650 are fixed to both ends of the coupling wire 400, respectively. Fixing of these stoppers (550, 650) will be described in detail below. Hereinafter, for convenience, the two stoppers 550 and 650 will be referred to as a first stopper 550 and a second stopper 650.

As shown in FIG. 5, the first stopper 550 and the second stopper 650 are positioned in the inner spaces 501 and 601 when the first coupling piece 500 and the second coupling piece 600 are coupled to each other. In this case, the sum of the lengths of the first stopper 550 and the second stopper 650 is smaller than the sum of the lengths of the first internal spaces 501 and 601 and the second internal spaces 501 and 601.

Accordingly, a predetermined gap (gap) is formed between the first stopper 550 and the second stopper 650. In addition, the first stopper 550 and the second stopper 650 are not fixed inside the first coupling piece 500 and the second coupling piece 600.

Therefore, when the safety tetrapod 100 receives an external force, the safety tetrapods 100 coupled to each other may move within a small range.

Therefore, even when a wave having a constant cycle repeatedly strikes, a resonance phenomenon is prevented from occurring due to the movement of the safety tetrapod 100.

That is, FIG. 5 illustrates a state in which tension is applied to the coupling wire 400 and the coupling wire 400 is pulled to both sides as much as possible. When the large tension is removed, the first stopper 550 and the second stopper 650 are removed. ) Can be flowed to some extent in the direction of approaching again, i.e., reducing the clearance G.

Hereinafter, a process of assembling the stopper on the coupling wire will be described with reference to FIGS. 8 and 9.

7 to 9 illustrate the working state of the first to third embodiments in which the stopper is coupled to the coupling wire. Hereinafter, a process of manufacturing the first stopper 550 will be described as an example.

First, according to the embodiment shown in FIG. 7, the manufacturer couples the first coupling piece 500 and the second coupling piece 600 to the appropriately cut coupling wire 400. At this time, the coupling wire 400 may also be combined with the washer (W).

Next, the manufacturer couples the outer member 410 to the base member 401 again. More precisely, it is to couple the outer member 410 to surround the coupling wire 400, wherein the outer member 410 is formed with a coupling hole 411, the coupling wire 400 is therein Is inserted. This appearance is shown in Figures 7 (a) and 7 (b).

At this time, in the present embodiment, the outer member 410 is made of a soft material such as lead, but not limited to the outer member 410 may be made of a variety of materials, including steel (steel).

In this state, the manufacturer presses the outer member 410 using a press or the like. Accordingly, the outer member 410 is firmly fixed to the coupling wire 400 while extending along the outer surface of the coupling wire 400. This pressing operation is performed in the process of manufacturing the coupling wire 400 in the factory.

7 (b) and 7 (c) illustrate a process in which the outer member 410 is compressed to the coupling wire 400.

Meanwhile, FIG. 8 sequentially shows a process of the second embodiment for coupling the stopper to the coupling wire.

According to this, the base member 401 is first coupled to the outer surface of the coupling wire 400. More precisely, the manufacturer removes the outer coating of one end of the bonding wire 400 and combines the base member 401 to surround the portion where the coating is removed. That is, as shown in FIG. 8B, the base member 401 is bent to wrap at least a portion of one end of the coupling wire 400.

At this time, the base member 401 is made of a metal plate of a flexible material formed with a plurality of embossing. That is, the bonding wire 400 is wrapped using a thin plate formed by embossing on a ductile metal such as copper or aluminum. The base member 401 is wrapped around the coupling wire 400 is shown in Figure 8c.

Next, the manufacturer is to squeeze the outer member 410 to the base member 401 as in the first embodiment described above.

At this time, the coupling between the coupling wire 400 and the outer member 410 by the base member 401 may be more robust. This is because the base member 401 by the embossed shape, the area in contact with each of the coupling wire 400 and the outer member 410 is widened, the embossed shape of the outer surface or the outer member 410 of the coupling wire 400 Press to deform it to some extent and improve the bonding force.

In addition, since the base member 401 is made of a soft material, the base member 401 may be deformed together with the outer member 410, thereby more firmly coupling the outer member 410 and the coupling wire 400.

In this case, the first stopper 550 is completed and the first stopper 550 is fixed to one end of the coupling wire 400.

On the other hand, Figure 10 is shown in sequence the process of the third embodiment for coupling the stopper to the coupling wire.

The third embodiment is also similar to the process of the first and second embodiments, but the material of the base member 410 is different. That is, a wire of metal is used in place of the metal plate as the material of the base member 410.

The wire of the metal is made of a metal material such as iron or copper, and is wound around the coupling wire 400 in a cylindrical spring shape. This is shown in Figure 9 (b).

As shown in FIG. 9C, the wire rod of the metal is compactly compressed so as to have a narrow width, and the outer member 410 is compressed in the state surrounded by the outer circumferential surface of the first stopper as in the first embodiment. 550).

Hereinafter, a method for constructing a coastal structure using tetrapods will be described in detail with reference to the accompanying drawings.

In order to construct a coastal structure using the safety tetrapod 100 according to the present invention, first, as shown in FIG. 11, the crushed stone layer 300 is formed on the sea bottom on which the safety tetrapod 100 is to be seated.

Formation of the crushed stone layer 300 is constructed by the same method as in the prior art will not be described in detail with the accompanying drawings.

10, after the crushed stone layer 300 is formed, the support rope 210 is inserted into the through hole 118 formed in the body 110 of the safety tetrapod 100, and the support rope ( The safety tetrapod 100 is moved above the basic crushed stone layer 300 by towing 210 using the crane 200.

And by repeating this method, the safety tetrapod 100 is sequentially seated on the crushed stone layer 300 to stack a multi-layered safety tetrapod 100.

Thereafter, the support rope 210 is removed and the seated tetrapod 100 is fixed through the coupling unit (C).

In more detail, the operator first passes through one of the plurality of through holes 118 different from each other, and then couples the other end of the coupling wire 400. That is, the first coupling piece 500 provided at one end of the coupling wire 400 is screwed to the second coupling piece 600 at the other end.

At this time, the first coupling piece 500 and the second coupling piece 600 are hooked to the first stopper 550 and the second stopper 650, respectively, to prevent the separation from the coupling wire 400, the first When the coupling piece 500 and the second coupling piece 600 are fastened, the first stopper 550 and the second stopper 650 are positioned in the inner spaces 501 and 601.

In addition, the first stoppers 550 and 650 and the second stopper 650 may flow in a predetermined range in the internal spaces 501 and 601. Accordingly, even if an external force such as a wave acts on the tetrapod 100 and the tension is applied to the coupling wire 400 according to the movement of the tetrapod 100, the coupling wire 400 may be prevented from being damaged such as breaking.

In particular, the tetrapod 100 may be resonated by a constant vibration caused by waves, but there is a gap between the first stopper 550 and 650 and the second stopper 650, so that damage to the coupling wire 400 may be prevented. Can be.

Thus, when the assembly of the coupling unit (C) is finished, the coastal structure using the safety tetrapod 100 is completed.

The appearance of such a coastal structure is shown in FIGS. 11 and 12. At this time, the layer and the number of columns of the safety tetrapod 100 may be formed in various ways depending on the construction conditions.

The rights of the present invention are not limited to the embodiments described above, but are defined by what is stated in the claims, and those skilled in the art can make various modifications and adaptations within the scope of the rights described in the claims. It is self-evident.

In the above embodiment, but described as an example of a safety tetrapod for marine structures, but not necessarily limited to this, the coupling unit for the structure binding according to the present invention is also applied to other civil structures, such as to allow a certain flow range between the structures Can be applied.

1 is a perspective view showing a conventional tetra pod.

Figure 2 is a perspective view showing a state in which the tetrapod bound by a preferred embodiment of the coupling unit for binding structures according to the present invention.

Figure 3 is a perspective view showing the configuration of the tetrapod bound by the coupling unit according to the present invention.

4 is a plan view showing a configuration of an embodiment of the present invention.

Figure 5 is a partially cutaway plan view showing the internal configuration of the present invention embodiment.

6 (a) and 6 (b) is a perspective view showing the configuration of the coupling wire, the first coupling piece and the second coupling piece constituting the embodiment of the present invention.

7 is a working state diagram showing the process of the first embodiment in order to couple the stopper constituting the embodiment of the present invention to the coupling wire.

8 is a working state diagram showing in sequence the process of the second embodiment for coupling the stopper constituting the embodiment of the present invention to the coupling wire.

9 is a working state diagram showing the process of the third embodiment to couple the stopper constituting the embodiment of the present invention to the coupling wire in sequence.

10 is an exemplary view showing a towing safety tetrapod.

11 and 12 are a front view and a plan view showing a coastal structure constructed using a safety tetra pod bound by a coupling unit according to the present invention.

Explanation of symbols on the main parts of the drawings

100: tetrapod 118: through hole

400: bonding wire 401,402: base member

410: outer member 500: first coupling piece

600: second coupling piece 550,650: first stopper, second stopper

C: coupling unit

500: first bonding piece

Claims (7)

In the coupling unit for binding between a plurality of structures formed through holes, Coupling wire passing through the through hole, A first coupling piece provided at either end of the coupling wire and having a first screw portion formed therein; And a second coupling piece provided at the other end of the coupling wire and having a second screw portion screwed to the first screw portion. The first coupling piece and the second coupling piece are provided to be movable along the coupling wire, respectively, and both ends of the coupling wire are provided with stoppers, respectively, to prevent separation of the first coupling piece and the second coupling piece. : Inner spaces are formed in the first coupling piece and the second coupling piece, respectively, and when the first and second coupling pieces are screwed together, stoppers provided at both ends of the coupling wire are positioned in the inner space, and the two stoppers are disposed. The sum of the lengths of the inner spaces is smaller than the length of the inner space so that the stopper is movable between the two stoppers are formed: The stopper is, A base member coupled to an outer surface of the coupling wire, Combination unit for the structure is configured to include an outer member that is coupled and compressed to surround the outer surface of the base member. delete delete delete 2. The coupling unit of claim 1, wherein the base member is formed of a flexible metal plate having embossing or a wire rod of a metal surrounding the coupling wire in the form of a cylindrical spring. The structure of claim 5, wherein the inner space of the first coupling piece and the second coupling piece and the stopper are formed in a cylindrical shape, and the outer surfaces of the first coupling piece and the second coupling piece are formed in a polygonal shape. Coupling unit for binding. 7. The coupling unit for structural binding according to claim 6, wherein the first coupling piece and the second coupling piece each have a tapered portion whose diameter decreases toward one end thereof.

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