KR102220976B1 - Reinforcement structure for connector of silt protector - Google Patents

Abstract

Provided is a structure for reinforcing a connection part of a silt protector, which can increase binding force between membrane bodies in a multi-connection structure. To this end, the structure for reinforcing a connection part of a silt protector includes: floating bodies provided to float on a water surface; membrane bodies connected to lower ends of the floating bodies and lowered under the water to prevent silt water from being spread; and a reinforcing part reinforcing a connection part between the membrane bodies or the floating bodies.

Description

Reinforcement structure for the connection part of the antifouling membrane {REINFORCEMENT STRUCTURE FOR CONNECTOR OF SILT PROTECTOR}

The present disclosure relates to a reinforcing structure of the anti-pollution membrane connection part.

In general, the pollution prevention membrane is a marine structure installed to prevent the diffusion of polluted water generated during the operation of offshore construction and to induce the sedimentation of particulate matter contained in the polluted water.

The anti-pollution membrane includes a membrane body that prevents the diffusion of dirty water while maintaining an upright posture in water, and an anchor that keeps the floating body contamination prevention membrane installed on the top of the membrane in a predetermined place.

In the process of moving underwater by the current, the load is concentrated on the connecting portion of the membrane body and the membrane body is torn at the connecting portion.

Accordingly, the applicant of the present invention has developed an anti-pollution film capable of preventing tearing of the membrane body through a reinforcing structure for the membrane body connection part. Korean Patent No. 2086076 discloses an anti-pollution film including a reinforcing structure of a film body applied and registered by the present applicant.

In recent years, as the weather changes gradually become more severe, there is a growing need for an improved antifouling film capable of preventing tearing of the membrane even in a harsher environment. Accordingly, providing a reinforcing structure for the connection portion of the conventional anti-pollution film can provide many advantages to the user.

The present task is to provide a reinforcing structure for the connection part of the anti-pollution membrane to further increase the binding force between the membrane body and the membrane body with a multiple connection structure.

The present task is to provide a reinforcement structure for the anti-pollution membrane connection part that can be reinforced by binding the membrane body and the membrane body in multiple stages.

The anti-pollution membrane of this embodiment is a floating body provided to float on the water surface, a membrane body connected to the lower end of the floating body and lowered into the water to prevent the diffusion of dirty water, between the membrane body and the membrane body or between the floating body and the floating body It may include a reinforcing portion to reinforce the connection portion of.

The floating body may include a connection film bonded to an upper end of the membrane body, and a buoyancy tank installed at intervals along the connection film.

The membrane body has a quadrangular structure including top, bottom, left and right sides, and is sewn with the top, bottom, left, and right sides folded one or more times, so that reinforcing bands may be formed on the top, bottom, left and right sides.

A plurality of reinforcing coating layers may be laminated by applying a polyurea resin two or more times to the reinforcing strip formed on the upper side of the membrane body.

The reinforcing portion is disposed opposite to each other, a pair of reinforcing plates fixedly installed at the connecting portions between neighboring membrane bodies or connecting membranes of the floating body, a shackle binding between the pair of reinforcing plates, and a connection between the pair of reinforcing plates It may include a first chain and a second chain connecting the two reinforcing plates, and a first spring and a second spring connected between the pair of reinforcing plates to relieve a load applied to the connection portion.

The reinforcing plate has a flat plate structure, and a plurality of fastening holes for fixing to the membrane body on the front surface, a shackle hole in which a shackle is coupled to connect the shackle between neighboring reinforcing plates, and a chain connecting the neighboring reinforcing plates with a chain It may include a chain hole to which the chain is coupled, and a spring hole to which a spring is coupled to connect the adjacent reinforcing plates with a spring.

The chain hole includes a first chain hole and a second chain hole in which a first chain and a second chain are respectively installed, and the first chain hole and the second chain hole are horizontally spaced apart from the shackle hole and in the vertical direction. This can be arranged spaced apart.

The spring hole includes a first spring hole and a second spring hole in which a first spring and a second spring are respectively installed, and the first spring hole and the second spring hole are spaced apart from the shackle hole in the vertical direction. I can.

The first chain and the second chain may have different lengths.

The first spring and the second spring may have different structures.

As described above, according to the present embodiment, it is possible to further increase the binding force between the membrane body and the membrane body through the multiple connection reinforcement structure.

Through the multi-level binding structure, even if one chain is broken, the additionally connected chain continues to connect the membrane body, so that separation of the membrane body can be more effectively prevented.

By buffering the external impact energy in multiple stages, damage to the membrane body can be more effectively prevented.

1 is a schematic view showing an anti-pollution film according to the present embodiment.
2 is a schematic view showing a reinforcing plate of the anti-pollution film according to the present embodiment.
3 is a schematic view showing a connection structure of the reinforcing plate of the anti-pollution film according to the present embodiment.
4 is a schematic view showing the spring connection structure of the reinforcing plate according to the present embodiment.
5 is a schematic view showing a structure for connecting a reinforcing plate of an anti-pollution film according to another embodiment.

Hereinafter, an embodiment of the present invention will be described in detail. However, this is presented as an example, and the present invention is not limited thereby, and the present invention is only defined by the scope of the claims to be described later. The embodiments described later may be modified in various forms without departing from the concept and scope of the present invention. As far as possible, the same or similar parts are indicated using the same reference numerals in the drawings.

The terminology used below is only for referring to specific embodiments, and is not intended to limit the present invention. Singular forms as used herein also include plural forms unless the phrases clearly indicate the opposite. The meaning of "comprising" as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. However, the following examples are only preferred examples of the present invention and the present invention is not limited to the following examples.

1 shows an anti-pollution film according to this embodiment, and FIGS. 2 and 3 show a connection structure between a reinforcing plate and a reinforcing plate according to the present embodiment.

As shown, the anti-pollution film 100 of the present embodiment may include a reinforcing part 150 for reinforcing a connection part between the floating body 110, the film body 120, and the film body 120. In addition, an anchor 130 for fixing the anti-pollution film 100 may be further provided.

The floating body 110 may include a plurality of buoyancy cylinders 111 for generating buoyancy, and a connection film 112 connecting the plurality of buoyancy cylinders 111 to each other. The floating body 110 provides buoyancy for floating the pollution prevention film 100 on water. A plurality of buoyancy tanks 111 may be installed at intervals along the connection membrane 112. The connecting membrane 112 is a strip-shaped membrane structure in which the buoyancy tank 111 is installed, and the membrane body 120 is connected and installed at the bottom.

The membrane body 120 may be made of a waterproof cloth or a nonwoven fabric having low water permeability. The membrane body 120 of this embodiment may have a quadrangular structure including top, bottom, left and right sides. The membrane body 120 may be sewn with the top, bottom, left and right sides folded one or more times, so that a relatively thick reinforcing strip 122 may be formed on the top, bottom, left and right sides. The membrane body 120 is configured such that the reinforcing strip 122 formed on the upper side is sewn to the lower end of the connection membrane 112 to move together with the floating body 110. Between the connecting membrane 112 and the membrane body 120 may be further bound by, for example, a rope.

The membrane body 120 prevents the diffusion of dirty water while maintaining an upright posture underwater. At the lower end of the membrane body 120, a weight body 125 such as a reinforcing bar or a ring may be further installed to maintain a vertically unfolded posture in the water.

A plurality of reinforcing coating layers 140 may be laminated by applying a polyurea resin two or more times to the reinforcing strip 122 formed on the upper side of the membrane body 120.

The reinforcing coating layer 140 formed at the connection portion between the floating body 110 and the membrane body 120 increases the strength of the connection portion between the floating body 110 and the membrane body 120. In addition, since it provides a function of distributing the load acting on the connection portion between the floating body 110 and the membrane body 120 when the anti-pollution film 100 swings, the connection portion between the floating body 110 and the membrane body 120 is damaged. Can be prevented.

The anchor 130 is to fix the floating body 110 and the membrane body 120 to be located in a designated place, and may be composed of a rope 131 and an anchor 132.

The floating body 110 and the membrane body 120 are connected to each other to form a single anti-pollution film 100, and a plurality of anti-pollution films are continuously arranged and connected, so that the size thereof can be expanded.

A reinforcing part 150 may be installed at the connection part between the connection film 112 between the adjacent anti-pollution film 100 and between the film body 120. The reinforcing part 150 is installed at a connection part between the adjacent anti-fouling films 100 to physically bind the anti-fouling films 100 to each other to reinforce the bonding force.

To this end, the reinforcing portion 150 of the present embodiment is disposed opposite to each other and fixed to the connection portion between the connecting membrane 112 of the neighboring membrane body 120 or the floating body 110. A shackle 170 that binds between a pair of reinforcing plates 160, a first chain 181 and a second chain 182 connected between the pair of reinforcing plates 160 to connect the two reinforcing plates 160 , It may include a first spring 191 and a second spring 192 connected between the pair of reinforcing plates 160 to relieve a load applied to the connection.

The reinforcing part 150 is installed on the upper side of the connecting membrane 112, the upper and lower sides of the membrane body 120 to reinforce the binding force between the upper sides of the neighboring connecting membrane 112, the upper side and the lower side of the membrane body 120. I can. The reinforcing part 150 may be installed on the reinforcing strip 122, for example.

All of the reinforcing parts 150 installed on the upper side of the connecting membrane 112, the lower side of the membrane body 120, or the upper side of the membrane body 120 may have the same structure.

Hereinafter, the reinforcing part 150 installed on the upper side of the membrane body 120 will be described as an example.

The reinforcing plate 160 may have a rectangular flat plate structure. The two reinforcing plates 160 forming a pair have the same structure, are disposed opposite to each other, and are respectively installed on the neighboring membrane bodies 120.

The reinforcing plate 160 is made of a metal material and may have a thickness of 3 mm. By being formed in such a thick thickness to secure its own rigidity, it is possible to further increase the reinforcing force of the connection portion compared to the conventional one.

For convenience of explanation below, the x-axis direction in FIG. 2 is referred to as the front side toward the neighboring reinforcing plate, and the opposite side is referred to as the rear side. In addition, the y-axis direction is the upper side of the floating body, and the opposite side is called the lower side.

A plurality of fastening holes 161 for fixing to the membrane body 120 on the front side of the reinforcing plate 160, a shackle hole in which the shackle 170 is coupled to connect the adjacent reinforcing plates 160 with a shackle 170 (162), a chain hole 163 to which the chain 180 is coupled in order to connect between the neighboring reinforcing plates 160 with the chain 180, and connecting the spring 190 between the neighboring reinforcing plates 160 It may include a spring hole 166 to which the spring 190 is coupled.

A fastening hole 161 may be formed through the reinforcement plate 160 along the outer periphery. The fastening hole 161 may be, for example, a hole through which a bolt may pass for fastening a bolt.

The front lower end of the reinforcing plate 160 where the spring hole 190 is located may be cut and removed. Accordingly, the front end of the reinforcing plate 160 may be formed to be stepped along the vertical direction. Accordingly, since adjacent reinforcing plates are wider, it is possible to prevent the springs 190 installed between the spring holes from interfering with the reinforcing plates 160.

The shackle 170 is sandwiched between the shackle holes 162 formed in the reinforcing plate 160 of the two membrane bodies 120 disposed adjacent to each other to bind the reinforcing plate 160. The shackle 170 (SHACKLE) is a binding mechanism, and may have a structure that is inserted between two holes and coupled through a bolt nut. For example, the shackle 170 passes through the shackle hole 162 of the reinforcing plate 160 installed on one of the two membrane bodies 120 and the shackle of the reinforcing plate 160 installed on the other membrane body 120 By fastening to the hole 162 with a bolt or the like, the membrane body 120 and the membrane body 120 in which the two reinforcing plates 160 are installed can be bound.

As shown in FIG. 2, the shackle hole 162 is a hole for coupling the shackle 170 and may be formed to be biased from the front side of the reinforcing plate 160 to the upper side and the front side. Accordingly, as shown in FIG. 3, the shackle 170 may be connected between the shackle holes 162 facing each other between the reinforcing plates 160 immediately adjacent to each other without interference.

The chain 180 is connected between the shackle hole 162 and the chain hole 163 formed at a different position to bind the reinforcement plate 160.

The chain hole 163 is a hole for coupling the chain 180, and in this embodiment, the chain hole 163 is a first chain hole 164 in which the first chain 181 and the second chain 182 are respectively installed. And a second chain hole 165. The chain 180 may refer to both the first chain 181 and the second chain 182, and the chain hole 163 may refer to both the first chain hole 164 and the second chain hole 165. I can.

In this way, by forming the two chain holes 163 in the reinforcing plate 160, the reinforcing plate 160 can be connected with the two chains 180. Accordingly, even if one chain 180 is broken, the other chain 180 can continue to connect between the reinforcing plates 160, so that the binding force can be further increased.

As shown in FIG. 2, the first chain hole 164 and the second chain hole 165 are horizontally spaced apart from the shackle hole 162 and are spaced apart from each other in the vertical direction to penetrate through the reinforcing plate 160 Can be. A first chain hole 164 may be formed by being spaced a predetermined distance from the shackle hole 162 to the rear along the horizontal direction.

Since the first chain hole 164 and the second chain hole 165 are spaced apart along the vertical direction of the reinforcing plate 160, interference between the first chain 181 and the second chain 182 can be minimized. do. Accordingly, by connecting the two chains 180, the two reinforcing plates 160 may be more rigidly bound.

In this embodiment, the lengths of the first chain 181 and the second chain 182 may be different structures. For example, the length of the first chain 181 may be shorter than the length of the second chain 182. Since the length of the first chain 181 is relatively shorter than the length of the second chain 182, interference between the two chains 180 can be reliably prevented.

In addition, the membrane body 120 and the membrane body 120 are bound in multiple stages by two chains 180 having different lengths, so that separation between the membrane bodies 120 can be effectively prevented. Even if a load is applied to the first chain 181, the second chain 182 may not receive the load. Accordingly, even if the first chain 181 is broken by the load applied to the membrane body 120, the second chain 182 can sequentially support the load to maintain a bound state.

The spring hole 166 is a hole for coupling the spring 190 and includes a first spring hole 167 and a second spring hole 168 in which the first spring 191 and the second spring 162 are respectively installed. can do. The spring 190 may refer to both the first spring 191 and the second spring 162, and the spring hole 166 may refer to both the first spring hole 167 and the second spring hole 168. I can.

The spring 190 may be a structure to relieve a load concentrated on the connection portion between the membrane body 120 and the membrane body 120 by using elasticity. For example, the spring 190 may be a tension coil spring.

The spring 190 is disposed so as to be positioned between the reinforcing plate 160 of the two adjacent membrane bodies 120 so that each tip may be connected to the spring hole 166. As the gap between the two reinforcing plates 160 is opened by an external force applied to the membrane body 120, the spring 190 is elastically compressed, thereby exerting an elastic restoring force between the two reinforcing plates 160. Thus, the gap between the two reinforcing plates 160 may be returned to their original state by the elastic restoring force of the spring 190.

In this way, the tension force generated between the membrane body 120 and the membrane body 120 is transmitted to the spring 190 due to the movement of the membrane body 120 that oscillates in the wave traveling direction and the vertical direction, and the spring 190 performs compression. The tensile force generated between the two membrane bodies 120 is relaxed through the and bending operation.

Since two spring holes 166 are formed in the reinforcing plate 160, two springs 190 can be used to connect the reinforcing plates 160. Accordingly, even if one spring 190 is broken, the other spring 190 can continue to connect between the reinforcing plates 160, so that the binding force can be further increased.

As shown in FIG. 2, the first spring hole 167 and the second spring hole 168 may be arranged vertically by being spaced a predetermined distance downward from the shackle hole 162. The first spring hole 167 and the second spring hole 168 are disposed in front of the second chain hole 165 on the lower side of the shackle hole 162 and are spaced apart in the vertical direction to penetrate through the reinforcing plate 160. I can.

Since the first spring hole 167 and the second spring hole 168 are spaced apart along the vertical direction of the reinforcing plate 160, interference between the first spring 191 and the second spring 162 can be minimized. do. Accordingly, two springs 190 may be connected and installed to more securely bind between the two reinforcing plates 160.

In addition, the spring 190 installed between the spring holes 166 may be located between the first chain 181 and the second chain 182. Accordingly, it is possible to apply an elastic force to the two reinforcing plates 160 in a state in which the spring 190 is connected between the two reinforcing plates 160 without being interfered with the first chain 181 and the second chain 182.

As shown in FIG. 4, the spring 190 includes, for example, a first wire 193, a second wire 194, a first fixing plate 195, and a second fixing plate 196, and thus a reinforcing plate ( 160) can be installed between. The wire may refer to both the first wire 193 and the second wire 194. The fixing plate may refer to both the first fixing plate 195 and the second fixing plate 196.

The first wire 193 and the second wire 194 are connected to the spring hole 166 of each reinforcing plate 160, and a first fixing plate 195 and a second fixing plate 196 are installed at each wire end. , The spring 190 may be installed elastically between the two fixing plates by being inserted into the wire. The coupling structure of the spring 190 is a structure already disclosed in the prior literature and a detailed description thereof will be omitted.

In this embodiment, the elastic modulus of the first spring 191 and the second spring 162 may have different structures. For example, the elastic modulus of the first spring 191 may be smaller than that of the second spring 162. Accordingly, the first spring 191 is elastically deformed to buffer the relatively small impact energy, and the second spring 162 is elastically deformed for the large impact energy to buffer the impact.

To this end, the distance A between the wire tip fixing the first spring 191 and the fixing plate may have a structure in which the gap B between the wire tip fixing the second spring 162 and the fixing plate is different.

As shown in FIG. 4, in the first spring 191 having a small elastic modulus, the distance A between the fixing plate and the tip of the wire is the gap between the fixing plate and the wire tip in the second spring 162 having a relatively large elastic modulus ( It may have a shorter structure than B). Accordingly, the tension point of the first spring 191 and the second spring 162 with respect to the external impact energy is different.

Accordingly, when an external force is applied and the gap between the membrane body 120 is widened, the first spring 191 having a short distance A between the wire and the fixing plate may be first tensioned and the second spring 162 may be tensioned later.

Accordingly, when the impact energy is small, the first spring 191 having a small elastic modulus is stretched to buffer the load, and when the impact energy is increased, the second spring 162 is stretched to buffer the load.

In this way, as the elastic modulus of the first spring 191 and the second spring 162 are different from each other, the impact energy applied between the two membrane bodies 120 is buffered in various environments to effectively maintain the bound state between the membrane bodies 120. I can.

5 shows another embodiment of the reinforcement part.

Hereinafter, the same reference numerals are used for the same parts as those described above, and detailed description thereof will be omitted.

As shown in FIG. 5, the reinforcing plate 160 may be an overall rectangular flat plate structure. The stepped cut portion is not formed at the front lower end of the reinforcing plate 160, so that the overall shape is intact. Accordingly, the reinforcing plate 160 of the present embodiment is easier to manufacture, and can be combined more firmly by maximizing the bonding area to the membrane body in a rectangular shape.

In addition, the spring 190 installed in the spring hole 166 of the two reinforcing plates 160 may have a structure in which rings are integrally formed at both ends. Accordingly, the spring 190 may have a structure that is directly inserted into and coupled to the spring hole 166 of the reinforcing plate.

In addition to the above structure, the reinforcing plate 160 may have a separate hook 199 protruding from the reinforcing plate 160 to hang the loop at the tip of the spring 190. The hook 199 is sufficient as long as it has a structure capable of fastening the hook of the spring 190 and may be variously modified. The hook 199 may be integrally formed with the reinforcing plate or may be bonded to the reinforcing plate. By hooking the tip of the spring 190 to the hook 199, the spring can be easily fixed and installed between the reinforcing plates.

In this embodiment, the elastic modulus of the first spring 197 and the second spring 198 may have different structures. For example, the first spring 197 may have a smaller elastic modulus than that of the second spring 198.

Accordingly, springs having different modulus of elasticity are combined in various forms to buffer the impact energy applied between the two membrane bodies 120, thereby effectively maintaining a bound state between the membrane bodies 120.

Although the exemplary embodiments of the present invention have been shown and described as described above, various modifications and other embodiments may be made by those skilled in the art. These modifications and other embodiments are all considered and included in the appended claims and will not depart from the true spirit and scope of the present invention.

100: anti-pollution film 110: floating body
111: buoyancy tube 112: connecting membrane
120: membrane body 122: reinforcement strip
130: anchor 140: reinforcing coating layer
150: reinforcement part 160: reinforcement plate
161: fastening hole 162: shackle hole
163: chain hole 164: first chain hole
165: second chain hole 166: spring hole
167: first spring hole 168: second spring hole
170: shackle 180: chain
181: first chain 182: second chain
190: spring 191,197: first spring
192,198: second spring 193: first wire
194: second wire 195: first fixing plate
196: second fixing plate

Claims (4)

A floating body provided to float on the water surface, a membrane body connected to the lower end of the floating body and lowered into the water to prevent the diffusion of dirty water, a reinforcing part reinforcing a connection between the membrane body and the membrane body or between the floating body and the floating body Including,
The floating body includes a connection film bonded to an upper end of the film body, and a buoyancy tank installed at intervals along the connection film,
The membrane body is made of a quadrangular structure including top, bottom, left and right sides, and is sewn with the top, bottom, left and right sides folded one or more times to form a reinforcing strip on the top, bottom, left, and right sides, and a polyurea resin is added to the reinforcing strip formed on the upper side of the membrane. It is formed so that a plurality of reinforcing coating layers are laminated by applying two or more times,
The reinforcing portion is disposed opposite to each other, a pair of reinforcing plates fixedly installed at the connecting portions between neighboring membrane bodies or connecting membranes of the floating body, a shackle binding between the pair of reinforcing plates, and a connection between the pair of reinforcing plates A first chain and a second chain connecting the two reinforcing plates, and a first spring and a second spring connected between the pair of reinforcing plates to relieve a load applied to the connection,
The reinforcing plate has a flat plate structure, and on the front side, a plurality of fastening holes for fixing to the membrane body, a shackle hole to which a shackle is coupled to connect the shackle between neighboring reinforcing plates, and a chain connecting the neighboring reinforcing plates A chain hole to which the chain is coupled, and a spring hole to which a spring is coupled to connect the adjacent reinforcing plates with a spring,
The chain hole includes a first chain hole and a second chain hole in which a first chain and a second chain are respectively installed, and the first chain hole and the second chain hole are horizontally spaced apart from the shackle hole and in the vertical direction. Are spaced apart,
The spring hole includes a first spring hole and a second spring hole in which a first spring and a second spring are respectively installed, and a first spring hole and a second spring hole are spaced apart from the shackle hole in the vertical direction, ,
The first spring and the second spring installed between the spring holes are located between the first chain and the second chain,
The first chain and the second chain have different lengths,
The first spring and the second spring have different elastic modulus of the anti-pollution membrane connection reinforcing structure. delete delete delete

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