KR102337087B1 - Shock Absorbing Mooring Rope - Google Patents

Abstract

The present invention relates to a buffer mooring rope. More particularly, the present may provide a buffer mooring rope, which comprises: a first support part; a second support part which is spaced apart from the first support part by a predetermined distance; a first buffer part which is positioned between the first support part and the second support part, and in which a plurality of unit elastic members are stacked on one surface of the second support part; a second buffer part which connects the first support part and the second support part; and a rope part which has one end connected to the end of the first buffer part and the other end protruding from the second support part. Accordingly, when tensile force is applied between the other end of the rope part and the first support part, the first buffer part is compressed, and the second buffer part is tensioned to buffer the impact.

Description

Shock Absorbing Mooring Rope

The present invention relates to a buffer mooring rope capable of protecting an internal elastic member vulnerable to direct physical impact and buffering an impact against an external force.

Photovoltaic power generation is regarded as a synonym for future energy sources to reduce the use of fossil fuels and environmental pollution. However, since solar power generation requires a large installation area, there is a problem of damage to agricultural land or forest when installed on land. In particular, a country with a large number of mountainous areas and a large population compared to land area, such as Korea, lacks space for installing solar power plants. On the other hand, floating solar power generation, which installs power generation facilities on water such as reservoirs, freshwater lakes, and the sea, utilizes the idle water surface, so it is suitable for efficient use of the land. There are also advantages. Accordingly, the floating solar power generation market is growing rapidly.

However, while land photovoltaic power generation is a method of installing a foundation and building a structure, floating photovoltaic power generation requires a floating structure with a buoyant body installed instead of a foundation, so it is a fusion of photovoltaic power generation and floating structure.

On the other hand, it is one of the methods of mooring floating structures (berthing facilities, floating houses, artificial islands, floating footbridges, etc.) are using In this conventional mooring method, it is difficult to control the position of the floating structure itself in a place with a large tidal difference or a severe change in flow rate, such as in the ocean. device will be needed.

Registered Patent Publication No. 10-1979293 (2019.05.16. Announcement)

The mooring rope coupled to the existing mooring device contains an elastic material, but when the existing mooring rope is used in water, the elasticity of the elastic material is lowered, the durability is significantly reduced due to corrosion by salt, and the elastic member is horizontal. There is a problem in that it is vulnerable to physical shocks such as cutting, so that the elastic force of the elastic member is continuously maintained in the water, and it is necessary to develop a mooring rope with strong durability.

Accordingly, the present invention prevents the internal elastic member from being damaged by physical impact, blocks contact with salt to solve the problem of reduced durability due to corrosion, and utilizes the joint structure to provide flexibility from external impact. An object of the present invention is to provide a buffer mooring rope that is deformable and can respond.

In order to achieve the above object, the present invention is a first support portion 100; a second support part 200 spaced apart from the first support part 100; a first buffer part 300 positioned between the first support part 100 and the second support part 200 and in which a plurality of unit elastic members 310 are stacked on one surface of the second support part 200; a second buffer unit 400 connecting the first supporting unit 100 and the second supporting unit 200; And one end is fixed to the end of the first buffer unit 300, and the other end is a rope part 500 protruding from the second support part 200; including, the other end of the rope part 500 and the first support part When a tensile force is applied between (100), the first buffer unit 300 is compressed, and the second buffer unit 400 is tensioned to provide a buffer mooring rope 10 that cushions the impact.

In addition, the rope part 500 provides a buffer mooring rope 10 including an elastic material.

In addition, the buffer mooring rope according to the present invention further comprises a third buffer unit 600 , the third buffer unit 600 is disposed between the first buffer unit 300 and the first support unit 100 . A buffer mooring rope (10) is provided.

In addition, the unit elastic member 310 is provided with a buffer mooring rope 10 having a first protrusion 311 formed on one surface and a first groove portion 312 formed on the other surface.

In addition, the first buffer 300 and the second buffer 400 provides a buffer mooring rope 10 spaced apart by a predetermined distance.

In addition, the second buffer 400 provides a buffer mooring rope 10 that forms a wrinkle structure along the longitudinal direction.

In addition, the second buffer 400 is a buffer mooring rope 10 including a deformable member 410 to which a plurality of unit joint members 411 are connected and a first fixing member 420 surrounding the deformable member 410 . ) is provided.

In addition, the unit joint member 411 is provided with a buffer mooring rope 10 in which both ends are formed with second protrusions 412 bent in the vertical direction in the longitudinal direction.

In addition, the unit joint member 411 provides a buffer mooring rope 10 having a third protrusion 413 bent so that the end of the second protrusion 412 faces each other.

In addition, the first fixing member 420 has a fourth protrusion 421 for surrounding and fixing a pair of the second protrusions 412 or a pair of the third protrusions 413 disposed adjacent to each other is formed buffer A mooring rope (10) is provided.

In addition, the first fixing member 420 is formed in a shape corresponding to the shape of the first buffer part 300, and the fourth protrusion 421 provides a buffer mooring rope 10 formed in plurality in succession. .

In addition, a buffer mooring rope 10 having a first flow space 422 formed between the fourth protrusion 421 and the third protrusion 413 is provided.

In addition, the buffer mooring rope 10 according to the present invention further includes a second fixing member 430 , and the second fixing member 430 includes a buffer mooring rope 10 surrounding the fourth protrusion 421 . to provide.

In addition, a through hole is formed in the second support unit 200 , and a buffer mooring rope 10 is provided in which a packing member is disposed.

The buffer mooring rope according to the present invention can protect the elastic member vulnerable to physical shock, and when the buffer mooring rope receives an external force, it is possible to distribute the external force to the first buffer part and the second buffer part to alleviate the impact, and through this It is possible to reduce the impact on the water structure while allowing the water structure to be anchored stably in one place.

1 is a longitudinal sectional view showing a schematic configuration of a buffer mooring rope according to the present invention.
Figure 2 shows a schematic configuration of a buffer mooring rope according to the present invention in a longitudinal sectional view.
3 is a cross-sectional view showing a unit elastic member of the present invention.
4 is a cross-sectional view of the unit joint member of the present invention.
5 is a view showing a deformed form of the elastic mooring rope due to the tensile force acting on the elastic mooring rope according to the present invention.
6 is an enlarged view of the second buffer in the schematic configuration of the buffer mooring rope according to the present invention.
7 is a cross-sectional view showing a state in which the rope portion of the present invention is fixedly coupled to the coupling member.
Figure 8 is a perspective view showing the appearance of the buffer mooring rope according to the present invention.

The invention to be described below can have various changes and can have various embodiments, and specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the invention described below to specific embodiments, and it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the technology described below.

In the drawings, like reference numerals refer to like elements.

Throughout the specification, when a part "includes", "contains", or "has" a certain element, it means that other elements may be further included unless otherwise defined.

Terms such as 1st, 2nd, etc. are used to distinguish one component from another component, and the component is not limited by the above-mentioned terms.

When a part of a layer, membrane, etc. is said to be “above/on” or “below/below” another part, it means that the other part It includes not only cases where they are in contact with each other, but also cases where other parts exist in between. Conversely, when a part is said to be “just above/above” or “just below/below” another part, it means that there is no other part in the middle.

The mooring rope refers to a rope for connecting an aquatic structure to an underwater structure such as underwater concrete or an underwater ground. The floating structure means an arbitrary structure floating on the water, and may be a ship, an artificial island, a floating footbridge, a floating house, as well as a solar power generation device. In addition, the aquatic structure may include an offshore structure.

1 and 2 schematically show the configuration of a buffer mooring rope according to an embodiment of the present invention. 1 and 2, the buffer mooring rope 10 is a rope for buffering and enduring shocks such as tension, bending and vibration by being connected to a structure installed on the seabed or a water structure, and the first support part 100 , it may include a second support unit 200 , a first buffer unit 300 , a second buffer unit 400 , and a rope unit 500 .

The first support part 100 is formed in a plate shape, and may be a place for supporting tensile force, vibration, etc. by the rope part 500 . The plate may have a shape such as a circle, an oval, or a square.

One side of the first support unit 100 may be coupled to one end of the second buffer unit 400 along the periphery, and a ring unit 110 for connecting to the structure may be formed on the other side thereof.

The second support part 200 may be disposed to be spaced apart from the first support part 100 by a predetermined distance, and one surface of the second support part 100 may be coupled with the other end of the second buffer part 400 along the circumference. have.

A through hole is formed in the center of the second support part 200 so that the rope part 500 may protrude to the outside through the through hole. Since the buffer mooring rope 10 according to the present invention is located in a marine environment, the packing member 210 is provided in the through hole of the second support 200 so that water or seawater does not flow through the through hole of the second support 200 . can be placed.

The packing member 210 may wrap the rope part 500 along the longitudinal direction for a certain section, and may be in close contact with the rope part 500 . The packing member 210 has excellent abrasion resistance and mechanical strength so as not to be easily deformed due to friction because friction with the rope part 500 may occur due to the tension and contraction of the rope part 500. Graphite fiber, lubricating oil Teflon-impregnated fiber, Teflon fiber, Inconel pre-incorporated carbon fiber, Inconel pre-incorporated graphite fiber, aramid fiber, etc. may be included as a material.

The first buffer unit 300 is positioned between the first support part 100 and the second support part 200, and one end may be in contact with one surface of the second support part 200, and the other end of the rope part as a coupling member and a nut ( 500) and may be fixedly coupled. The first buffer unit 300 may be a place for dispersing the shock received by the rope unit 500 by buffering it against the tensile force between the rope unit 500 and the first support unit 100 .

Referring to FIG. 5 , the first buffer unit 300 may include a plurality of unit elastic members 310 . A plurality of unit elastic members 310 may be stacked on the first buffer unit 300 . The plurality of unit elastic members 310 are arranged in series so that the tensile force between the first fixing part 100 and the rope part 500 is distributed to each of the unit elastic members 310 to form the first buffer part 300 . Since it is compressed, it is possible to alleviate the shock received by the rope part 500 .

Referring to FIG. 3 , the unit elastic member 310 may include an elastically deformable rubber material so that it can be deformed by absorbing an impact and elastically restored to return to its original shape. Rubber materials include natural rubber, butadiene rubber (BR), styrene-butadiene rubber (SBR), acrylonitrile butadiene rubber, polychloroprene rubber, polyisoprene rubber Rubber), isobutylene isoprene copolymer, ethylene propylene rubber, ethylene vinyl acetate copolymer, chlorinated polyethylene rubber, chlorosulfonated polyethylene, acrylic rubber, ethylene acrylate copolymer ), fluororubber (Fluoroelastomer), silicone rubber (Silicone Robber), and may include one or more of polyurethane rubber (Polyurethane Elastomer).

A first protrusion 311 may be formed on one surface of the unit elastic member 310 , and a first groove portion 312 may be formed on the other surface of the unit elastic member 310 . Since the plurality of unit elastic members 310 are stacked, they may be stacked while the first protrusion 311 is inserted into the first groove 312 between adjacent unit elastic members 310 . By being stacked in this way, the plurality of unit elastic members 310 may receive a compression force uniformly, respectively.

6, the second buffer 400 connects between the first support part 100 and the second support part 200, and forms a wrinkle structure along the longitudinal direction of the buffer mooring rope against external force. It is deformed in shape and may be a place to dissipate the impact. The second buffer unit 400 may be extended in length when receiving a tensile force, and when receiving a bending force, one side receives a tensile force and the other side receives a compressive force to be bent.

The second buffer 400 may include a deformable member 410 , a first fixing member 420 , and a second fixing member 430 .

The deformable member 410 may include a plurality of unit joint members 411 , and the plurality of unit joint members 411 may be arranged along the longitudinal direction of the deformable member 410 , contact each other, and be connected. The unit joint member 411 is deformed with respect to an external force or forms a joint structure between the unit joint member 411 and the adjacent unit joint member 411, so that when a bending force acts on one side of the buffer mooring rope 10, an angle to each other It is formed and deformed, and through this, the impact can be alleviated.

When the buffer mooring rope 10 is bent under an external force, one side of the deformable member 410 may receive a compressive force, and the other end may receive a tensile force.

The unit joint member 411 located in the portion to which the tensile force is applied can be deformed while forming a curved surface according to the tensile force, and the plurality of unit joint members 201 form an angle with the adjacent unit joint member 411 and have a gap between them. It spreads and the deformable member 410 may form a continuous curved surface as a whole. The deformable member 410 forms a curved surface by the tensile force and may distribute an external shock to the plurality of unit joint members 411 .

The unit joint member 411 located in the portion to which the compressive force is applied can be deformed while forming a curved surface according to the compressive force, and the plurality of unit joint members 411 form an angle with the adjacent unit joint member 411 and have a gap between them. It spreads, and the deformable member 410 may form a continuous curved surface as a whole. The deformable member 410 forms a curved surface by the tensile force and may distribute an external shock to the plurality of unit joint members 411 .

Referring to FIG. 5 , the deformable member 410 surrounds the first buffer unit 300 , and the first buffer unit 300 and the deformable member 410 may be disposed to be spaced apart from each other. When a tensile force is generated between the rope part 500 and the first support member 100 and the first buffer part 300 is compressed along the longitudinal direction of the buffer mooring rope 10, the first buffer part 300 is laminated. It can be deformed in the direction of increasing the width of the cross-section as the height of the cross section decreases. That is, the unit elastic member 310 may be compressed and deformed flat in the longitudinal direction of the buffer mooring rope 10 . In addition, due to the tensile force, the second buffer 400 is also gradually extended in the longitudinal direction of the buffer mooring rope 10 to buffer the impact caused by the tensile force.

The deformable member 410 may form a joint structure in which the plurality of unit joint members 411 are continuously aligned to organically flow together with the adjacent unit joint members 411 .

The unit joint member 411 may be formed of a metal material in the form of a tube, and the unit joint member 411 is formed of a stretchable material so that the buffer mooring rope 10 according to the present invention provides bending force, compression force or tensile force, etc. When it receives and deforms, the plurality of unit joint members 411 may be deformed correspondingly to distribute bending force, compressive force, or tensile force.

The unit joint member 411 may include a metal material having excellent malleability and ductility, such as copper, aluminum, tungsten, and iron, to buffer an impact caused by an external force.

Referring to FIG. 4 , both ends of the unit joint member 411 may be bent in a vertical direction in the longitudinal direction to form second protrusions 412 protruding. The second protrusion 412 may come in contact with the second protrusion 412 of the other adjacent unit joint member 411, and when the buffer mooring rope 10 according to the present invention receives an external force, the second protrusion 412 and An interval, an angle, etc. between the adjacent second protrusions 412 may change, and the deformable member 410 may be deformed. The second protrusion 210 may expand a contact area between the first fixing member 420 and the deformable member 410 to distribute tensile force, compressive force, and bending force with respect to an external force.

The two second protrusions 412 formed at both ends of the unit joint member 411 may have third protrusions 413 bent so that the ends face each other and protrude. The second protrusion 412 and the third protrusion 413 may increase a contact area between the first fixing member 420 and the deformable member 410 to effectively disperse an impact caused by an external force applied from the outside. In addition, the third protrusion 413 may strengthen the fixing force between the first fixing member 420 and the unit joint member 411 .

Two second protrusions 412 and two third protrusions 414 formed in one unit joint member 411 may form a first accommodation space 414 .

The first fixing member 420 may be formed in a shape corresponding to the shape of the deformable member 410 , may be fixed while surrounding the deformable member 410 , and may be connected so that a plurality of unit joint members 411 are in contact.

At least a portion of the first fixing member 420 may be positioned in the first accommodating space 414 and may be formed in a shape corresponding to the shape of the first accommodating space 414 of the unit joint member 411 .

The first fixing member 420 may be formed in a shape corresponding to the shape of the pair of adjacent second protrusions 412 so as to wrap and fix the pair of second protrusions 412 adjacent to each other. A pair of adjacent second protrusions 412 may be formed on different unit joint members 411 , respectively.

The first fixing member 420 may be formed in a shape corresponding to the shape of the pair of adjacent third protrusions 413 so as to wrap and fix the pair of third protrusions 413 adjacent to each other. A pair of adjacent third protrusions 413 may be formed on different unit joint members 411, respectively.

Referring to FIG. 5 , a fourth protrusion 421 may be formed on the first fixing member 420 while surrounding and fixing a pair of adjacent second protrusions 412 or a pair of adjacent third protrusions 413 . can The fourth protrusion 421 may form a wrinkled structure in which the fourth protrusion 421 is continuously formed at regular intervals on the first fixing member 420 , and the wrinkle structure formed by the fourth protrusion 421 is buffered. When a tensile force is applied along the longitudinal direction of the mooring rope 10, the fourth protrusion 421 may be extended in the longitudinal direction.

A first flow space 422 may be formed between the first fixing member 420 and the pair of third protrusions 413 . The first flow space 422 is a space for the unit joint member 411 to flow, and when the adjacent buffer mooring rope 10 undergoes bending deformation due to an external force, the adjacent unit joint member 411 performs the first flow It flows in space 422 and can be deformed to correspond to bending deformation. A pair of adjacent second protrusions 412 may be spaced apart as the adjacent unit joint members 411 flow to form an angle therebetween, thereby reducing the impact.

The first buffering part 300 may be disposed in the inner space of the first fixing member 420 , and since the first fixing member 420 surrounds the first buffering part 300 together with the deformable member 410 , the first It can be sealed by blocking the buffer unit 300 from the outside, and can be protected from direct physical impact.

The first fixing member 420 is flexibly deformed by an external impact so as to distribute the impact, the first fixing member 420 may include a metal material having excellent malleability and ductility, such as copper, aluminum, tungsten, iron, nickel, or the like. A plastic material such as polycarbonate, polyethylene, polyimide, polypropylene, polystyrene, or polyvinyl chloride (PVC) may be included.

The second fixing member 430 may surround the fourth protrusion 421 . The second fixing member 430 may be formed of a rubber material and be in close contact with the fourth protrusion 421 to strengthen the fixing force of the fourth protrusion 421 to the second protrusion 412 and the third protrusion 413 .

Referring to FIG. 7 , the rope part 500 is fixed and coupled to one end by being inserted into the coupling member 510 , and a screw surface may be formed on an outer portion of the coupling member 510 . A uniform plate 520 may be disposed at one end of the first buffer unit 300 , and a coupling member 510 may pass through the center of the uniform plate 520 . The coupling member 510 protruding through the uniform plate 520 can fix the coupling member 510 and the uniform plate 520 by coupling a nut to the screw surface formed on the outer surface, and in this way, the rope part An end of the 500 and the end of the first buffer 300 may be fixed.

The rope part 500 may include an elastic material to alleviate the impact applied to the rope part 500 . The elastic material may be a rubber material that can restore elasticity, and the rubber material is natural rubber, butadiene rubber (BR), styrene-butadiene rubber (SBR), and acrylonitrile butadiene rubber (Acrylonitrile Butadiene Rubber). , chloroprene rubber, polyisoprene rubber, isobutylene isoprene copolymer, ethylene propylene rubber, ethylene vinyl acetate copolymer, chlorinated polyethylene rubber, chlorosulfonated polyethylene, acrylic rubber Rubber), ethylene acrylate copolymer, fluororubber (Fluoroelastomer), silicone rubber (Silicone Robber), and may include one or more of polyurethane rubber (Polyurethane Elastomer).

The rope part 500 may pass through the center of the uniform plate 520 and the center of the first buffer part 300 , and when a tensile force acts between the rope part 500 and the first support part 100 , the first buffer The portion 300 may be compressed along the longitudinal direction of the buffer mooring rope 10 .

The uniform plate 520 has a flat plate shape and may be formed in a circular, oval, quadrangular, or polygonal cross-sectional shape. One surface of the uniform plate 520 is in contact with one surface of the unit elastic member 310 , and the uniform plate 520 uniformly transmits a force to one surface of the unit elastic member 310 in contact with the first buffer unit 300 uniformly. make it compact.

The uniform plate 520 is preferably formed of a strong, corrosion-resistant metal material. Although not limited thereto, it may be, for example, stainless steel, titanium, or the like.

The buffer mooring rope 10 according to the present invention may further include a third buffer 600 . The third buffer unit 600 may be disposed on one surface of the uniform plate 520 between the first buffer unit and the first support unit 0 , and the third buffer unit 600 includes the rope unit 500 and the first When the first cushioning unit 300 is compressed by a tensile force acting between the supports 100 and the first cushioning unit 300 is compressed and then the tensile force is reduced and the compressed first cushioning unit 300 is rapidly elastically restored, the first supporting unit 100 and the protruding coupling By reducing the speed at which the elastic restoration proceeds after the third buffer unit 600 and the first support unit 100 come into contact with the third buffer unit 600 and the first support unit 100 to prevent the impact from being applied to the first support unit 100 due to the collision of the member 510, the rope It is possible to prevent an impact from being applied to the part 500 .

The third buffer unit 600 may include a spring or an elastic rubber material. One end of the third buffer unit 600 may be coupled to the uniform plate 520 .

8 is a perspective view showing the external appearance of the buffer mooring rope according to the present invention. In the buffer mooring rope 10 , the second buffer 400 is disposed between the first support 100 and the second support 200 , and the rope 500 may protrude from the second support 200 . . A wrinkle structure may be formed in the second buffer unit 400 , and the wrinkle structure may form a structure favorable to deformation in the second buffer unit 400 , thereby buffering an impact caused by an external force such as a tensile force.

Although the present technology has been described through the above embodiments, the present technology is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present technology, and those skilled in the art will recognize that such modifications and changes also belong to the present technology.

10: buffer mooring rope 100: first support
200: second support 210: packing member
300: first buffer 310: unit elastic member
311: first protrusion 312: first groove
400: second buffer part 410: deformable member
411: unit joint member 412: second protrusion
413: third protrusion 414: first receiving portion
420: first fixing member 421: fourth protrusion
422: first flow space 430: second fixing member
500: rope part 510: coupling member
520: uniform plate 600: third buffer unit

Claims (14)

a first support;
a second support part spaced apart from the first support part;
a first buffer part positioned between the first support part and the second support part, and in which a plurality of unit elastic members are stacked on one surface of the second support part;
a second buffer connecting the first support and the second support;
One end is fixed to the end of the first buffer portion, the other end is a rope portion protruding from the second support; and
a second fixing member;
When a tensile force is applied between the other end of the rope part and the first support part, the first buffer part is compressed, and the second buffer part buffers the impact by being tensioned,
The second buffer includes a deformable member connected to a plurality of unit joint members and a first fixing member surrounding the deformable member,
The unit joint member is formed with a second protrusion having both ends bent in a vertical direction in the longitudinal direction,
The unit joint member is formed with a third protrusion bent so that the end of the second protrusion faces;
A fourth protrusion is formed on the first fixing member to surround and fix a pair of the second protrusions or a pair of the third protrusions disposed adjacent to each other,
The second fixing member surrounds the fourth protrusion
buffer mooring rope. The method of claim 1,
The rope portion is a buffer mooring rope comprising an elastic material. The method of claim 1,
The buffer mooring rope further comprises a third buffer,
The third buffer mooring rope is disposed between the first buffer and the first support portion. The method of claim 1,
A buffer mooring rope having a first protrusion formed on one surface of the unit elastic member and a first groove portion formed on the other surface. The method of claim 1,
The buffer mooring rope the first buffer portion and the second buffer portion are spaced apart by a predetermined distance. The method of claim 1,
The second buffer mooring rope to form a wrinkle structure along the longitudinal direction. delete delete delete delete The method of claim 1,
The fourth protrusion is a buffer mooring rope continuously formed in plurality along the longitudinal direction. The method of claim 1,
A buffer mooring rope in which a first flow space is formed between the fourth protrusion and the third protrusion. delete The method of claim 1,
A through hole is formed in the second support part,
A buffer mooring rope in which a packing member is disposed in the through hole.

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