KR101851933B1 - Concrete floating body - Google Patents

Abstract

A concrete float body is disclosed. In the present invention, a wave-breaking flange having a wave-breaking function protrudes on the upper surface of the float body, and a swivel unit having a rounded shape is formed at a portion connected to the float body below the wave-breaking flange. Accordingly, the present invention provides the concrete float body capable of buffering shocks when seawater floats on the rounded swivel unit and inducing the seawater to flow downward flexibly.

Description

CONCRETE FLOATING BODY [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a concrete float fluid, and more particularly, to a concrete float fluid used in a marine structure.

In recent years, marine structures have been increasingly installed by installing floats on the sea, such as sea, river, and lake.

These floating structures are typically used for offshore plants, marine fishing grounds, marine parks, etc., and the scale is also increasing.

For the structural efficiency of the float, a partition wall is usually provided at an interval in the inner space to form a plurality of hollow portions, or a float The buoyancy material may be filled in the inner space.

The above-mentioned concrete part fluid is produced by casting the concrete in the formwork at the factory and the site, and various additives such as aggregate are mixed in the concrete.

Also, a plurality of concrete floors are installed on the sea according to the structure and size of the sea structure, and the concrete floors are connected to each other through separate connecting devices.

These floating structures can be moved by vehicles or by tourists or users. Floating seawater floods above the concrete floors installed on the sea by waves or wails, resulting in freezing in winter. And there is a problem in that the shoes of the pedestrian may be wet in summer.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to solve the above-mentioned problems, and an object of the present invention is to provide a water- And is capable of absorbing the impact when the rounded swivel part buckles and inducing the seawater to flow downward flexibly.

To achieve the above object, according to the present invention, there is provided a vacuum cleaner comprising: a plurality of sub-fluids disposed adjacently to each other and each having a buoyant space formed therein to provide buoyancy; A buoyant material filled in the buoyant space to increase buoyancy of the buoyant; A connecting device for bufferably connecting the plurality of floatings; Coupling means formed on opposing surfaces of the respective sub-fluids so as to improve stability by directly coupling the plurality of sub-fluids, insertion means formed between the sub-fluids so as to fill the gaps between the sub- The coupling device comprising: a cushioning member groove formed symmetrically with respect to the mutually facing surfaces of the plurality of floatings in order to bufferably connect the plurality of floatings; A cushioning member inserted into the cushioning member groove and a connector installed to penetrate the cushioning member and having both ends fixed to the plurality of floatings with a nut, A portion of the lower portion of the air filtering flange that is connected to the float is formed with a rounded portion Wherein the coupling means comprises a recessed portion protruding in a tapered shape having a width smaller in the projecting direction on an opposing surface of the float and a convex portion recessed corresponding to the shape of the recessed portion, The upper portion of the portion is provided with a concrete float bar provided with a joint bar of an elastic material so as to prevent breakage of the corner.

Also, the wave breaking flange formed on the upper side of the float may be formed of concrete and may have a thickness of 10 cm to 30 cm.

The distance between the waveguide flange and the water surface may be 0.5 m to 1 m.

Further, the side surface of the float may extend vertically from the end of the swivel portion, and the swivel portion may be formed at an angle of 110 to 140 degrees.

In addition, the upper surface of the concrete float may be formed with an inclined surface which is lowered from the center to the lateral direction.

In addition, a plurality of drainage openings for rainwater drainage may be formed through the air discharge flange.

According to the concrete part fluid of the present invention described above, since the tapered concave portion and the convex portion recessed to correspond to the concave portion on the surface to which the floating body is coupled can be stably combined with the predetermined installation clearance, This has a convenient effect.

In addition, a portion connected to the float to the lower side of the propagating flange is formed with a rounded portion having a rounded shape to buffer the shock when the seawater caused by the waves or the swell wobbles the rounded swivel, It is effective.

In addition, a drain hole is formed in the deterioration flange so that seawater accumulated on the upper side of the concrete float can be guided to the drain port and introduced into the sea, thereby preventing a safety accident.

In addition, an elastic material joint bar is provided on the upper side of the portion where the floating bodies are engaged, thereby preventing breakage of corner portions due to frequent vibration.

1 is an exploded perspective view showing a concrete part fluid according to the present invention.
FIG. 2 is a perspective view showing a concrete part fluid according to the present invention. FIG.
FIG. 3 is a plan view showing a coupled portion of each sub-fluid in FIG. 2. FIG.
4 is a sectional view taken along line AA in Fig.
5 is a front view of Fig.
6 is a front view of a concrete section according to another embodiment of the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

First, as shown in Fig. 1, a concrete float 1 according to the present invention is a structure in which a plurality of floats are connected to each other such as sea, river, lake, etc., Marine structures (buildings), such as marine plants, marine fishing grounds, marine parks, marinas, marine facilities, etc., will be constructed.

The concrete float 1 includes float 10 and float 20, buoyant materials 12 and 22, a connecting device 30 and a connecting means 50.

The buoyant fluids (10, 20) are arranged adjacently to each other in the longitudinal direction or the width direction on the sea, and the buoyant space portions (11, 21) are formed in each of them to provide buoyancy.

The float (10, 20) is formed in a rectangular parallelepiped shape, and on the upper side, a deflection flange (14, 24) protruded so as to have a wave preventing function protruding to prevent overflow of seawater is formed. The float (10, 20) may be formed of a concrete material having a strong outer wall.

The buoyant members (12, 22) are filled in the buoyant space (11, 21) so as to increase buoyancy of the float (10, 20).

Styrofoam is preferably used as the buoyant materials 12 and 22, but various buoyant materials other than styrofoam may be used. Meanwhile, air filled in the buoyant space portions 11 and 21 may serve as a buoyant material even if no styrofoam is filled in the buoyant space portions 11 and 21.

In addition, when the inside of the float 10, 20 is filled with the buoyant 12, 22, if cracks occur in the external wall of the float 10, 20, As shown in Fig.

The connecting device 30 is for bufferably connecting the plurality of separated floatings 10 and 20 to each other so that the plurality of floatings 10 and 20 can be symmetrically A cushioning member 31 formed of an elastic material inserted into the cushioning member groove 34 and a cushioning member 31 provided between the plurality of cushioning members 10, And both ends of the connector 32 are fixed to the plurality of floatings 10 and 20 by the nuts 33, respectively.

The buffer member groove 34 is formed to be recessed on the surface of each floating body 10 and 20 facing each other. The shape of the buffer member groove 34 is formed in a shape corresponding to the buffer member 31 do.

In this case, the buffer member 31 is formed in a cylindrical shape, so that the external force can be efficiently dispersed. The buffer member groove 34 is recessed to correspond to the shape of the buffer member 31 into a space in which the buffer member 31 can be seated.

In this case, while the buffer member 31 is formed in a cylindrical shape and the buffer member groove 34 is formed so as to surround the buffer member 31 of the cylindrical column, the buffer member 31 31 may be formed as a rectangular parallelepiped.

A connection box 35 is formed at one end of each of the plurality of floats 10 and 20 so that the connector 32 can be installed. 35 are also formed with through-holes 36 so that the connector 32 passes therethrough.

One end of the connector 32 is connected to the penetrating portion 36 of the one side fluid 10 in a state where the connector 32 in which the buffer member 31 is fitted is positioned between the plurality of the floats 10, The other end of the connector 32 passes through the penetration portion 36 of the other fluid 20 and then the nut 33 is inserted into the connection box 35. Then, (33) to complete the connection.

Of course, the connection method of the connection device 30 is described as an example, and the connection method and procedure may be variously changed.

The coupling means 50, which is a main constituent of the present invention, is provided on each of the opposed faces of the respective floats 10, 20 so as to improve the stability by directly coupling the floats 10, . Specifically, the engaging means 50 includes a recess 51 protruding from each of the opposed faces of the plurality of floatings 10 and 20, a convex portion 52 recessed corresponding to the shape of the recess 51, , Convex portions). The concave portion 51 and the convex portion 52 are formed in the respective floats 10 and 20 and the float 10 and 20 can be stably engaged with each other.

A concave portion 51 and a convex portion 52 are alternately formed on one side surface of the float 10 and the float 10 is formed on the side surface of the other side fluid 20 facing the float 10. [ The concave and convex portions 51 and 52 are formed so that the concave portion 51 and the convex portion 52 are engaged with each other.

The concave portion 51 may have a tapered shape with a smaller width in the projecting direction. Accordingly, even when the float 10, 20 is shaken by the sea breeze when the float 10, 20 is engaged, it is not necessary to accurately engage.

Therefore, when the plurality of floatings 10, 20 are connected to each other through the connecting device 30, the concave-convex portions 15, 25 formed on the facing surfaces of the floatings 10, The fluid is prevented from flowing between the fluids 10 and 20 even when waves are hit, and the stability is further improved.

Further, a joint bar 16 made of an elastic material is provided on the upper side of the portion where the fluids 10, 20 are engaged. When a predetermined time has elapsed after completion of the concrete float 1, a gap between the float 10 and the float 20 may be generated due to corrosion of the connecting device 30 due to seawater. It is possible to prevent a safety accident because the gap can be worn, and also to prevent breakage of the corner portion due to frequent vibration during driving.

Although not shown in the drawings, the rubber material filling member may be inserted so as to fill the gap between the plurality of concave-convex portions 51, 52. In other words, in order to engage the concave-convex portions 51 and 52 of the plurality of the inflow fluids 10 and 20 in an interlocking manner, an assembly tolerance (clearance) is generated between the inflow fluids 10 and 20. In this gap, It is possible to further prevent the flow between the respective fluids 10 and 20, thereby maximizing the stability, and also to prevent breakage between the fluids 10 and 20.

Although the connecting device 30 and the coupling means 50 are provided only at one end of each of the floats 10 and 20 in the figure, The connecting device 30 and the coupling means 50 may be provided at both ends of the float 10, 20, respectively. Also, the number of connecting devices 30 and the coupling means 50 can be determined according to the width of the concrete float 1, depending on the design.

As shown in FIG. 5, on the upper side surfaces of the float bodies 10 and 20, a wave breaking flange 14, 24 is formed. The blocking wave flanges 14 and 24 are made of concrete, 30 cm. If the thickness (H1) is less than 10 cm, the durability is weak and the pedestrian may be damaged if it is poured into a specific area. If the thickness is more than 30 cm, the manufacturing cost is increased and the economical effect is decreased.

In addition, a rounded portion 15 having a rounded shape may be formed at a portion connected to the float 10, 20 below the air-tightening flanges 14, 24. This has the effect of buffering the shock when the seawater caused by the waves or the swell wobbles into the rounded swivel portion 15 and inducing the seawater to be downwardly flexible. In this case, the side surface of the float extends vertically from the end of the swivel portion 15.

In addition, the swirling unit 15 is provided to smoothly induce the side surface of the swirling unit 15, which is rounded with round water, to reduce the impact applied to the swirling unit 15 and to reduce the wear of the side surface of the float. May be formed to be not less than 110 degrees and not more than 140 degrees. 5, the swivel part 15 is roundly rounded with the ends of the wave-breaking flanges 14 and 24 of the float 10 and 20 as a starting point, and the rounded part 15 The point where the end meets the side surface of the float (10, 20) is taken as the end point. In other words, the forming angle A1 of the circularly rounded turning part 15 is an angle between the starting point and the ending point of the turning part 15 measured at the circular center of the circularly rounded turning part 15, The center of the swirling portion 15 is formed by a virtual line extending vertically from the end portions of the propagating flanges 14 and 24 of the float 10 and 20, A virtual line of a slanting line having a slope upward sloping is encountered at the point where the end point of the swivel portion 15 meets.

In this case, when the angle A1 of the swivel part 15 is less than 110 degrees, there is a problem that the seawater rotates on the swivel part 15 to wear the side wall of the float, When the forming angle A1 exceeds 140 degrees, there is a case where the doubler can hit the side wall of the float when riding on the float.

Accordingly, it is preferable that the distance (H2) from the surface to the water surface is 0.5 m to 5 m when the wave is kept quiet. When the interval H2 is less than 0.5 m, seawater can flow into the upper side of the concrete floors 1 even if the waves are low. If the interval H2 is more than 5 m, it is difficult to float the concrete floors 1 Follow.

Also, as shown in FIG. 6, the upper surface of the concrete float 1 may be inclined from the center to the side. Therefore, seawater can be introduced to the sea side by the load on the upper side of the concrete float (1). In addition, a drain hole 17 may be formed in the deterioration flanges 14 and 24, and an illumination or the like may be installed in the drain hole 17 to provide esthetics.

Hereinafter, the operation of the concrete float 1 according to the present invention will be described.

First, the concrete float 1 is manufactured by placing the concrete in a state where the buoyant materials 12 and 22 are positioned in the formwork. When the manufacturing is completed, the buoyant materials 12 and 22 are formed in the concrete float 1, Is built in.

The concrete float 1 thus manufactured is carried to the installation site (sea) and floated on the sea.

A plurality of floatings 10 and 20 floated in the sea are connected to each other through the connecting device 30, that is, the connector 32 in which the buffering member 31 is fitted is divided into a plurality of floats 10 and 20 One end of the connector 32 is passed through the penetration portion 36 of the one side fluid 10 and then the nut 33 is fastened in the connection box 35 and the connector 32 The other end of the fluid is passed through the penetration 36 of the fluid 20 and then the nut 33 is fastened in the connection box 35 to connect the fluids 10 and 20.

Although only two inflow fluids 10 and 20 are shown in the drawing, a plurality of inflow fluids may be sequentially or locally connected in the same manner.

Subsequently, when the plurality of floatings 10, 20 are connected to each other through the connecting device 30, the uneven portions 51, 52 formed on the facing surfaces of the floatings 10, By being engaged with each other, each of the floats 10, 20 is firmly engaged with each other, and flow between the floors 10, 20 is prevented. In this case, the concave-convex portion 51 has a tapered shape in the protruding direction, so that there is room for installation clearance, which is convenient in construction.

On the other hand, after the plurality of floats 10, 20 are connected, a floating structure (building) is constructed on the plurality of floats 10, 20. Of course, the plurality of floatings 10 and 20 may serve as various sea structures.

The concrete embodiments of the present invention described above are merely illustrative and those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. It will be possible. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: concrete float 10, 20: float
12, 22: Buoyant material 14, 24: Breakwater flange
15: turning part 16: connecting bar
17: drain hole 30: connection device
31: buffer member 34: buffer member groove
50: coupling means 51:
52:

Claims (6)

A plurality of floatings (10, 20) arranged adjacently to each other and having buoyant space portions (11, 21) sealed therein so as to provide buoyancy;
A buoyant material (12, 22) filled in the buoyant space (11, 21) to increase buoyancy of the float (10, 20);
A connecting device (30) for bufferably connecting the plurality of float (10, 20);
Coupling means (50) formed on the facing surfaces of the respective float (10, 20) so as to improve the stability by directly coupling the float (10, 20)
(10, 20) so as to fill a space between the plurality of floats (10, 20), characterized in that:
The connecting device (30)
A cushioning member groove 34 formed symmetrically with respect to the mutually facing surfaces of the plurality of floatings 10 and 20 for cushionably connecting the plurality of floatings 10 and 20; And a connector 32 which is installed to penetrate the buffer member 31 and has both ends fixed to the plurality of floats 10 and 20 by a nut 33, Including,
At the upper side of the float (10, 20), a wave breaking flange (14, 24) having a wave breaking function protrudes, and a portion connected to the float (10, 20) below the wave breaking flange A rounded portion 15 having a rounded shape is formed,
The coupling means (50)
A concave portion 51 protruding in a tapered shape having a width smaller in the protruding direction on the facing surface of the float 10 and 20 and a convex portion 52 recessed corresponding to the shape of the concave portion 51 ,
A joint bar 16 made of an elastic material is provided on the upper side of the portion where the floats 10 and 20 are engaged,
The side faces of the float (10, 20) extend vertically from the end of the turn portion (15)
The swivel part 15 is roundly rounded with the ends of the air-deficient flanges 14 and 24 of the float 10 and 20 as starting points, and the end of the circularly rounded swivel part 15 is floated 10, 20) is defined as an end point, and a forming angle (A1) formed by the starting point and the end point at the center of the circle is formed to be 110 to 140 degrees. The method according to claim 1,
The breakwater flanges (14, 24) formed on the upper side of the float (10, 20)
A concrete float formed of concrete and having a thickness (H1) of 10 cm to 30 cm. The method of claim 2,
Wherein the propagating flanges (14, 24) are formed with an interval (H2) from the water surface to 0.5 m to 5 m. delete The method of claim 3,
The upper surface of the concrete float (1) is formed with an inclined surface which is lowered in the lateral direction from the center,
The deflection flanges (14, 24)
Wherein a plurality of drain holes (17) for rainwater drainage are formed through the concrete drainage. delete

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