KR101342635B1 - Floating pier of concrete having high strength - Google Patents

Abstract

The present invention relates to a high strength concrete floating pier which can maintain a parallel state by having a rectangular deck formed by placing concrete up to a predetermined thickness on the upper side thereof and by being provided with an accommodation space, which is divided into several parts filled with floating bodies, on the lower part thereof and which is stably disposed on the water by returning waves, which surge upon the high strength concrete floating pier, to the sea. The floating pier comprises multiple water tanks disposed at constant intervals evenly on both sides thereof and a parapet with a recessed groove shape on the lower part of the outside thereof for controlling the balance of the floating pier and for always keeping a parallel and horizontal state constantly regardless of choppy waves, wherein the parapet prevents sea water from flowing to the upper part of the floating pier for protecting items on the floating pier and the sea water from being collected on the upper part of the floating pier by returning wave, which surge upon the floating pier, to the sea.

Description

Floating pier of concrete having high strength

The present invention relates to a high-strength concrete Buzan Bridge, and more particularly, to control the balance of the Buzan Bridge used for ship berthing to be installed in the water to maintain a constant parallel and horizontal at all times regardless of the ripples of the waves, It relates to a high-strength concrete byzantine bridge equipped with a parapit that allows the blue waves to be returned to the sea to be installed stably on the surface of the water.

In general, the term "Busan bridge" refers to a bridge that floats by attaching an ark to a pier and floats freely up and down according to the height of the water.

It is also used for the purpose of holding a boat to the side of the Buzan Bridge.

In general, a number of concrete Buzan bridges generally used are connected in a row and installed in the water phase.

In the structure of the concrete secondary bridge as described above, concrete is formed on the upper surface of the stainless steel frame to form a deck surface, the lower portion is formed so that the receiving space portion is opened into the partition partition.

In addition, each receiving space is filled with a floating filler such as styrofoam.

However, according to the concrete Buzan Bridge as described above, due to the weight of the concrete placed on the upper surface as a deck surface, the Buzan Bridge was not easily leveled on the water surface and was easily inclined, so that it was kept inclined toward one side as a whole.

In addition, the phenomenon that the concrete byzantine bridge is put on the water surface has a problem that is not easily corrected even if the precision of the thickness distribution is considerably increased by maintaining the thickness of the concrete on the upper surface relatively constant.

As a conventional example for solving the above problems, in the concrete Buzan Bridge (1) as shown in Fig. 1 disclosed in Republic of Korea Patent Publication No. 10-0983798 (September 16, 2010), the concrete has a predetermined thickness on the upper surface In the concrete subzan bridge filled with styrofoam in the accommodating space portion 3, which is poured to form a rectangular deck surface 2, and an inner side thereof, the bottom portion is buried upwardly at four corners of the deck surface 2; Recessed groove casing (4); A storage tank having a front end open to receive and store the water supplied to the groove casing 4 and the rear end closed to extend in the longitudinal direction of the deck surface 2 while being symmetrical to four corners of the deck surface 2 ( 5) and; An inlet 6 for exposing the upper end of the recess casing 4 to the top end of the storage tank 5 so that the water stored in the recess casing 4 is moved to the storage tank 5 and stored; The rear end of the storage tank 5 is configured to pass through the lower portion of the partition wall 7 so as to prevent the end of the storage tank 5 from sagging downward, so that it can be easily leveled when installed in the water phase. .

However, in the concrete Buzan Bridge provided with the storage tank 5 as described above, the storage tank 5 is not only too small and uniformly provided in comparison with the size of the Buzan Bridge, and it is difficult to level it when it is actually installed in the water phase. Had a problem.

In addition, a phenomenon in which sea water flows into the upper surface of the Buzan Bridge occurs due to the blue waves of the waves. In order to prevent such a phenomenon, as a conventional example as shown in FIG. 2, Korean Patent Publication No. 10-1078656 ( And a plurality of pipes 120 extending in a longitudinal direction and a bracket 130 into which the pipes 120 are fitted and fixed, which is a Buzan bridge device disclosed in October 26, 2011) and a method of canceling waves using the same. Waves are canceled while passing through the gap size between the 120, at least one of the diameter size of the pipe 120, the arrangement shape of the pipes 120, the gap size between the pipes (120) The amount of offset of the waves can be adjusted by one.

However, in the byzantine device for offsetting such waves, when blue waves occur, the seawater that does not pass between the pipes 120 as they hit the upper part of the byzantine bridge soaks the objects placed thereon or even above the byzantine bridge. There was a problem that a phenomenon that can not be properly suspended due to the substantial amount of standing.

An object of the present invention for solving the problems as described above, by providing a plurality of water tanks in the Bujan Bridge that is installed in the water used for ship berthing to control the balance for the Bujan Bridge always constant regardless of the ripples of the waves In addition to maintaining parallelism and leveling, the parapets are provided to ensure that the blue waters flowing into the Byzantine bridge can be returned to the sea, so that the seawater does not flow in the upper part of the Byzantine bridge so that the Buzan bridge can be stably installed on the surface at all times. It is to provide high strength concrete bridge bridge.

In accordance with an embodiment of the present invention for achieving the object as described above, the concrete is poured into a predetermined thickness on the upper surface to form a rectangular deck, the lower portion is divided into a plurality of receiving space to be filled in the floating body on the water surface In the high-strength concrete Buzan Bridge, which allows the concrete bridge bridge to maintain parallelism and sends the blue waves flowing back to the sea to the sea stably so that the bridge bridge can be installed on the water surface. A plurality of water tanks are provided, and the parapet of the concave groove is provided on the outer lower portion of the secondary bridge.

According to an embodiment of the present invention, the water tank is installed so as to be accommodated in each of the receiving space portion in the four corners.

The Example  According to the water tank, a plurality of partition walls therein at predetermined intervals Spaced apart  A plurality of configured to receive water Compartment And formed to induce water at the upper end of the partition to precede Compartment  Through the following In compartment  Water filled Induction groove , remind Compartments  On top of each other If necessary Compartments  To drain the water contained in any one or more of the The cap  .

According to an embodiment of the present invention, the parafit is installed spaced apart from the upper surface of the deck at a predetermined interval, characterized in that provided in response to the height of the blue.

When using the high-strength concrete subzan bridge according to the embodiment of the present invention as described above, by providing a plurality of water tank and auxiliary water tank, it is possible to uniformly balance the Buzan bridge installed on the water surface and used for ship berthing Ensures constant parallelism and leveling at all times, no matter how ragged

In addition, by having a parapit on the bridge, the blue waves coming to the bridge can be returned back to the sea, thereby preventing the inflow of seawater to the upper portion of the bridge, thereby protecting the objects on the upper side and the seawater on the upper surface. It provides the effect of maintaining the original floating effect by preventing the high wage phenomenon of the.

1 is a side view showing a state in which a receiving tank is provided in a conventional Buzan bridge.
Figure 2 is a side view showing the Byzan bridge to offset the blue of the conventional waves.
Figure 3 is a perspective view showing a high-strength concrete secondary bridge with a balance control device and a parapit according to an embodiment of the present invention.
Figure 4 is a plan view showing a high strength concrete secondary bridge in accordance with an embodiment of the present invention.
Figure 5 is a side view showing a high-strength concrete secondary bridge in accordance with an embodiment of the present invention.
Figure 6 is a perspective view showing a state in which two high strength concrete secondary bridges connected in accordance with an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings for a preferred embodiment of a high-strength concrete secondary bridge in accordance with the present invention will be described in detail.

3 is a perspective view showing a high-strength concrete subzan bridge with a balance control device and a parapit according to an embodiment of the present invention, Figure 4 is a plan view showing a high strength concrete subzan bridge according to an embodiment of the present invention, Figure 5 is the present invention 6 is a side view showing the high strength concrete bridge bridge according to an embodiment of the present invention, Figure 6 is a perspective view showing a state in which two high strength concrete bridge bridge is connected according to an embodiment of the present invention.

First, in the drawings, it is noted that the same components or parts are denoted by the same reference numerals as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

As shown in Figures 2 to 5, the high-strength concrete secondary bridge in accordance with an embodiment of the present invention, the concrete is cast in a predetermined thickness, preferably 17mm on the upper surface to form a rectangular deck (11) and a plurality of lower In order to keep the concrete subzan bridge 10 parallel to the water surface by having a receiving space portion 12 to be divided into a dog to fill the floating body such as styrofoam, evenly spaced at predetermined intervals on both sides of the subzan bridge 10 It is installed so that a plurality of water tanks 20 to be injected through the water inlet 21 is provided.

That is, the water tank 20 is installed so as to be accommodated in each of the receiving space portion 12 in the four corners, so that it can be stably balanced on both sides of the byzan bridge (10).

Therefore, through the water tanks 20 spaced apart at precise intervals on both sides of the Buzan Bridge 10, the Buzan Bridge 10 can maintain horizontal / parallel, even if the wave of the wave occurs badly evenly at all times. It can be maintained.

As described above, by installing the water tanks 20 at both corners of the subzan bridge 10, it is possible to have a strength of 400 kgf / cm 2 or more.

As described above, when a plurality of water tanks 20 are installed at appropriate intervals so as to be balanced in one Buzan Bridge 10, the balance for the Buzan Bridge 10 is automatically controlled so that regardless of the ripples of the waves It will be able to maintain constant parallel and horizontal.

And, the water tank 20, as shown in Figure 7, in order to accommodate the water to receive a plurality of inside Partition 23  Equipped.

Therefore, in the water tank 20, a plurality of partition walls 22 therein at predetermined intervals. Spaced apart  A plurality of configured to receive water With partition 23 Is formed to induce water at the upper end of the partition 22 to precede Partition 23  Through the following In partition 23  Water filled Induction groove (25) , remind Compartments 23  On top of each other If necessary Compartments 23  To drain the water contained in any one or more of the Cap (27)  It is provided.

In addition, the seawater is prevented from being pushed into the upper portion of the upper portion of the byzantine bridge 10 through the blue waves colliding with the byzantine bridge 10 to return to the sea to ensure that the byzantine bridge 10 is stably installed on the water surface (30) ).

The parapits 30 are formed in the form of concave grooves having a curved shape at the outer lower portion of the byzantine bridge 10, and are installed to be spaced apart from the upper surface of the deck 11 at predetermined intervals to correspond to the height at which the blue waves occur. It was equipped with.

Therefore, the wave hitting the parapit 30 of the Buzan Bridge 10 is sent back to the sea so that the phenomenon that the sea water flows into the upper part of the Buzan Bridge 10 is not generated.

And, although not shown, by installing the auxiliary water tanks on the upper and lower portions of the Byzan bridge 10, it is also possible to make the Byzan bridge 10 more stably floating in the water.

Meanwhile, the high-strength concrete subzan bridges 10 having the water tank 20 and the parapits 30 as described above, as shown in FIG. 6, the coupling groove 15 formed in the deck 11 of the subzan bridges 10. It is accommodated in) so that the Byzan bridge 10 can be coupled to each other through the connecting device 40 to elastically flowable connection.

That is, the connecting device 40 which elastically connects the subzan bridge 10 has a plurality of through holes, and is firmly mounted in the coupling groove 45 of the deck 11 so that the elastic body 44 has the subzan bridge 10. Bracket 42 to be coupled to the deck (11) of the) and the bolts 43 provided on both sides with a predetermined length to pass through the through hole of the bracket 42 is fastened with the nut 41 is coupled It consists of an elastic body 44 which becomes.

In this case, the nut 41 may be loosened by severe swelling of the wave and may be configured in plural to be fastened to the bolt 43 so as to prevent the phenomenon of falling out of the bolt 43.

In addition, the elastic body 44 may be made of a coil spring made of metal in order to have rigidity that does not dismantle the coupling of the subzan bridges 10 connected to each other in response to the rumble of the wave.

Although the present invention has been described in connection with the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

10: Floating bridge 11: Deck
12: accommodation space
20: water tank 21: water inlet
22: partition 23: compartment
25: guide groove 27: cap
30: parafit
40: connector 41: nut
42: bracket 43: bolt
44: elastomer 46: coupling groove

Claims (4)

Concrete is poured into a predetermined thickness on the upper surface to form a rectangular deck (11), and the lower part is provided with a receiving space portion 12 to be filled with a floating body to be filled with a concrete subzan bridge 10 in water surface In order to return the blue waves pushed to the Buzan Bridge 10 back to the sea so that the Buzan Bridge 10 is stably installed on the water surface, both sides of the Buzan Bridge 10 are uniformly spaced at predetermined intervals. In the high-strength concrete subzan bridge is provided with a water tank 20, the parapit 30 of the concave groove is provided on the outer lower portion of the subzan bridge 10,
The water tank 20,
A plurality of partitions 23 formed to receive water by allowing a plurality of partitions 22 to be spaced apart at predetermined intervals therein;
An induction groove 25 formed to induce water at the upper end of the partition 22 to fill the next partition 23 through the preceding partition 23;
High strength concrete bridge bridge is provided on top of each of the partitions (23) is provided with a cap (27) for draining the water contained in any one or more of the partitions (23), if necessary. delete delete delete

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