KR20110053740A - Anti-mtion foundation - Google Patents

Abstract

PURPOSE: An anti-motion foundation is provided to enable quick and stable loading/unloading of cargo between a floating body and a ship on the sea. CONSTITUTION: An anti-motion foundation is used for a smart port system and comprises a base(210), a plurality of fenders(220), a support plate(230), and a connection part(240). The base is installed in the seafloor. The fenders are expanded and raised by the buoyancy to contact the bottom surface of a floating body. The support plate fixes and supports the fenders from the bottom. The connection part controls the distance between the base and the support plate using a hydraulic cylinder.

Description

Anti-Motion Foundation {Anti-Mtion Foundation}

The present invention relates to an anti-motion foundation used in a smart harbor system, and in more detail, by loading the cargo and in contact with the bottom of the float floating on the sea to prevent the floating of the float, the shipment of cargo at sea and It relates to an anti-motion foundation that enables stable unloading.

Maritime transportation using ships as a means of moving goods remotely takes up a large part of international trade because it uses less energy and lowers transportation costs compared to other means of transportation.

In recent years, in marine transportation such as container ships, large-scale ships are used to improve the efficiency of transportation, which is intended to secure the economics of transportation by increasing the transportation volume of the vessel. Accordingly, more and more ports are required to have mooring and unloading facilities for docking large vessels.

However, harbors that can berth large container ships are limited at home and abroad, and the construction of such ports requires a lot of expenses due to dredging to maintain the necessary port depth, as well as a large place. In addition, due to the construction of a large port has a lot of influence on the surrounding environment, such as causing a traffic jam or destruction of the coastal environment, there are many restrictions on the construction of a large port.

Accordingly, the invention relates to a mobile port (mobile harbor) capable of loading and unloading cargo without anchoring a large vessel to the inner wall of the port and anchored at sea off the land, and a method for transferring the cargo using the patent ( Registration number 10-0895604).

Figure 1 shows a schematic view of the mobile port shown in the patent, the mobile port 10 can be carried out by using a transport means 20, such as a crane, Figure 1 (a) is moving The unloading between the port 10 and the large container ship 30 is shown, and FIG. 1 (b) shows the unloading between the mobile harbor 10 and the pier 40.

The mobile port 10 is a cargo transfer device having a platform having a space for loading cargo to be unloaded, a facility for unloading cargo between the vessel and the platform and a transport facility for transferring cargo on the platform; And a positioning device for acquiring information regarding the position of the platform, and a buffer connecting device for maintaining the connected state of the platform without colliding with the ship while unloading the cargo.

Since the cargo unloading operation is to move the cargo from several tons to tens of tons, it is urgently required to maintain the equilibrium of the ship or floating body serving as a mobile port, but at sea the vessels are affected by wind, blue, or tidal current. It is necessary to move the mobile harbor system with the structure that the equilibrium can be maintained during the operation at sea despite the fluctuations of.

The present invention has been made in consideration of the above problems, the present invention by reducing the fluctuation of the floating body due to the influence of wind, blue, or algae, quickly and accurately, between the floating body and the container ship or other vessels, etc. It is an object of the present invention to provide an anti-motion foundation that enables high speed and stable cargo loading.

The present invention, in the anti-motion foundation used in the smart harbor system, the base is installed on the bottom of the sea, a plurality of fenders coming into contact with the bottom surface of the floating body by rising in the sea surface, and fixing the plurality of fenders from below and It provides an anti-motion foundation, characterized in that it comprises a supporting plate and a connecting portion for connecting the base plate and the support plate to adjust the distance using a hydraulic cylinder.

In the anti-motion foundation according to the present invention, the connecting portion has an arm portion hinged to the base and one end hinged to the support plate, the other end of these two arm portions are pivotally coupled to each other, the hydraulic The distance between the base and the support plate is adjusted by rotating the arm around the pivot and the hinge using a cylinder.

In addition, in the anti-motion foundation according to the invention, the fender is characterized in that when the fluid is supplied therein expands and rises in the sea surface by buoyancy.

Furthermore, in the anti-motion foundation according to the present invention, the support plate is characterized by having a plurality of holes penetrating the main surface up and down.

On the other hand, in the anti-motion foundation according to the present invention, characterized in that it further comprises a shock absorbing member for mitigating the impact caused by the collision of the base, the support plate and the connecting portion.

In addition, the anti-motion foundation according to the present invention, the bottom member is fixed to the sea floor, the upper structure for supporting the bottom of the floating body, and the distance between the bottom member and the upper structure to each other and active distance between them It provides an anti-motion foundation, characterized in that it comprises a connecting member that can be adjusted to.

Furthermore, in the anti-motion foundation according to the invention, the connecting member is characterized in that for adjusting the distance by using a hydraulic cylinder.

On the other hand, in the anti-motion foundation according to the invention, characterized in that it further comprises a cushioning member for preventing a collision between the upper structure and the bottom member.

According to the anti-motion foundation according to the present invention, the foundation can be quickly and precisely raised, thereby enabling stable and high speed cargo loading between a floating body floating at sea and a container ship or another vessel.

The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated and described in the drawings. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In the following description of the present invention, if it is determined that detailed descriptions of related well-known technologies or functions may obscure the gist of the present invention, the detailed description thereof will be omitted.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings, and in the following description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and redundant description thereof will be omitted. Shall be.

2 is a diagram illustrating a schematic view of an entire smart harbor system including a foundation according to an embodiment of the present invention.

The smart harbor system has a space in which cargo C can be loaded and floats on the sea, and is installed on the bottom of the sea to be in contact with the bottom of the float 100, Foundation 200 to prevent rocking, and may be configured to include a crane 110 is installed on the floating body 100 to perform the loading and unloading of the cargo (C) between the container ship (S).

Floating body 100 may be a vessel provided with a propulsion device to be able to move itself, a floating body of various forms such as a general barge can be used. In this case, the floating body 100 may move to perform cargo unloading between the pier or other container ship of the land. On the other hand, the floating body 100 may have its own propulsion device or may not have power to move by itself. One or more sides of the floating body 100 may be formed in a structure capable of unloading the cargo (C) between the shuttle barge 300 and docked with the shuttle barge (300). Shuttle barge 300 is to move in the sea to perform the cargo unloading between the pier or other container ships of the land.

The foundation 200 reduces the fluctuation of the floating body 100 due to an external force such as wind, blue, or algae, in particular the rolling and pitching movement of the floating body 100, thereby reducing the amount of the floating body 100. The stable cargo unloading between container ships S is enabled, and the specific structure is mentioned later.

As the crane 110, an appropriate one can be selected and used from various types of cranes, such as a pedestal crane, a portal crane, and a gantry crane, for example.

On the other hand, the smart harbor system may further include a power hookup 140 for supplying power to the floating body 100 from the land and the oil hookup 150 for supplying oil to the container ship (S). Here, the power hook-up 140 functions to supply electricity to the propulsion device and the crane 110 of the floating body 100 and to supply a fluid such as compressed gas to the foundation 200.

Hereinafter, the configuration of the foundation 200 according to the present invention will be described in detail with reference to FIG. 3.

The foundation 200 is basically fixed to the bottom of the base 210 is installed on the bottom, and when fluid (eg, compressed gas) is supplied therein is expanded to rise in the sea surface by buoyancy to the bottom of the float 100 A plurality of fenders 220 which are in contact with each other, a support plate 230 which fixes the plurality of fenders 220 and supports the bottom, and a base 210 above and below the base 210. ) And the support plate 230 is configured to include a connecting portion 240 that can adjust the height between them.

When the fender 220 is supplied with a fluid therein, the fender 220 receives buoyancy acting around and expands to the bottom of the floating body 110 in the sea level. As long as the foundation 200 can perform the function of preventing the shaking of the floating body 110 by contacting the bottom surface of the floating body 110 with the expanded and raised fender 220, the type of the fender 220 and The specific shape is not particularly limited, but in one embodiment of the present invention, so-called sausage fender is used.

The support plate 230 is a plate-shaped structure for supporting and fixing the plurality of fenders 220 from below. At this time, it is preferable that a plurality of through holes 235 are formed on the main surface of the support plate 230 so as not to prevent the foundation 200 from rising in the sea level (see FIG. 4).

Next, the connection part 240 connects the upper surface of the base 210 and the lower surface of the support plate 230 to each other and can adjust the distance therebetween. The connecting portion 240 is provided near the ends of both sides of the base 210 and the support plate 230 in the longitudinal direction (hereinafter referred to as the front and the rear, respectively). Since the configurations are the same, the configuration of the front connecting portion 240 will be described below. Explain only.

When the foundation 200 is viewed from the front, the first arm portion 242 is hinged so that one end thereof is rotatable near the right end of the upper surface of the base 210, and the second arm portion 244 is one end thereof. The hinge is rotatably coupled to the vicinity of the right end of the upper surface of the first movable member 245 which is movable forward and backward on the base 210. In addition, the first arm portion 242 and the second arm portion 244 pivotally intersect with each other and cross each other like two blades of scissors. On the other hand, the third arm portion 246 is hinged so that one end thereof is rotatable near the right end of the lower surface of the support plate 230, the fourth arm portion 248 is one end is moved forward and backward on the support plate 230 The hinge is rotatably coupled to the right end of the lower surface of the second movable member (not shown, but having the same configuration as the first movable member 245 provided on the base 210). In addition, like the first arm portion 242 and the second arm portion 244, the third arm portion 246 and the fourth arm portion 248 are pivotally coupled to intersect with each other. Meanwhile, the other end of the first arm part 242 is pivotally coupled to the other end of the third arm part 246 so as to be rotatable, and the other end of the second arm part 244 is the fourth arm part 248. Pivotally coupled to the other end of the arm.

In addition, the first, second, third, and fourth arm portions 242 ', 244', 246 ', and 248' may also have a first, second, third, and fourth arm portion (left) of the foundation 200. 242, 244, 246, 248 are arranged to face.

A plate member 255 is provided between the third and third 'arm portions 246 and 246' and extends along these two arm portions and connects the two arm portions to each other, so that the pressure transmitted from the hydraulic cylinder 250 is provided. Receive. The pair of hydraulic cylinders 250 consists of a cylinder 251 and a rod 252 that can be linearly reciprocated with respect to the cylinder 251, respectively, the cylinder 251 of which is hinged to the upper surface of the base 210. The rod 252 is hinged to the plate member 255 at an end thereof.

In such a configuration, when the hydraulic cylinder 250 is operated to extend the rod 252 out of the cylinder 251, the rod 252 pressurizes the plate member 255, and the plate member 255 is It will rotate about the pivot axis. At this time, the first and second moving members are moved forward of the foundation 200 on the base 210 and the support plate 230, respectively, and the arm portions rotate about the hinge and the pivot, respectively, The upper structure, that is, the support plate 230 and the fender 220 are raised.

On the other hand, when the hydraulic cylinder 250 operates in reverse and the rod 252 contracts and enters the cylinder 251, the rod 252 pulls the plate member 255 so that the plate member 255 is raised when the upper structure is raised. And rotate about the pivot axis in the opposite direction. At this time, the first and the second moving member is moved to the rear of the foundation 200 on the base 210 and the support plate 230, respectively, while the arm parts are in the opposite direction as the upper structure is raised about the hinge and the pivot. By rotating to lower the support plate 230 and the fender 220.

In the above description, only the connection part 240 disposed in front of the foundation 200 has been described, but the connection part 240 configured in the same manner is provided at the rear of the foundation 200.

On the other hand, in the configuration of the connection portion 240, when the pressure sensor is provided in the hydraulic cylinder 250, it is transmitted to the hydraulic cylinder 250 through the fender 220 and the support plate 230 from the floating body (100) The pressure is measured, and the distance between the bottom face of the floating body 100 and the top face of the foundation 200 can be appropriately controlled based on the measured value. By doing so, it is possible to secure maximum stability in loading and unloading cargo at sea.

In addition, the foundation 200 of the present invention may include a plurality of shock absorbing members, such as rubber fenders 260, on the upper surface of the base 210. When the upper structure of the foundation 200 including the fender 200 and the support plate 230 descends rapidly toward the sea bottom, the base 210 and the connection part 240 disposed below are impacted to damage these members. There is a risk of making. Accordingly, the foundation 200 of the present invention is provided with a buffer member 260 to absorb the impact generated when the upper structure of the foundation 200 including the fender 220 and the support plate 230 is lowered, 210 and the connecting portion 240, etc. are not to be damaged.

On the other hand, as shown in Figure 2, the smart harbor system of the present invention as a configuration for supplying electricity to the propulsion device and the crane 110 of the floating body 100, and the fluid to the foundation 200, power hook-up 140 and various cables connected thereto (ie, fluid supply hoses and power supply cables, etc.) 270. The power hook-up 140 is preferably a buoy (buoy) that can be connected to the various cables 270 and can float on the sea surface using buoyancy. In addition, the various cables 270 are divided into a portion connecting the power hook-up 140 and the foundation 200, and a portion connecting the power hook-up 140 to a land power supply / fluid supply source (not shown). For reference, these cables 270 need not always be connected to the power hook-up 140 and / or the foundation 200 and the like, and may be separated from them as necessary.

When the cargo is unloaded between the smart harbor system and the container ship using the smart harbor system provided with the foundation 200 according to the present invention configured as described above, the foundation 200 is a cargo unloading work During this process, since the bottom surface of the floating body 100 is in contact with and prevents the shaking of the floating body 100, stable cargo unloading is possible. In addition, the foundation 200 according to the present invention, in addition to the buoyancy received while the fender 220 expands, the time required for raising and lowering the foundation 200 by actively raising and lowering the foundation 200 by the hydraulic cylinder 250. It has the advantage that it is possible to quickly unload cargo by minimizing.

As mentioned above, although specific embodiment of this invention was described, this is only an illustration and this invention is not limited to this, It should be interpreted that it has the broadest range based on the basic idea disclosed in this specification. Those skilled in the art can change the material, size, etc. of each component according to the application field, it is possible to implement the pattern of the shape not shown by combining or replacing the disclosed embodiments, but this also does not depart from the scope of the present invention will be. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, it is apparent that such changes or modifications are included in the scope of the present invention.

1 is a view showing a schematic view of a mobile port shown in the prior patent.

2 is a diagram illustrating a schematic view of an entire smart harbor system including a foundation according to an embodiment of the present invention.

3 is a perspective view of a foundation according to an embodiment of the present invention.

4 is a plan view of a foundation according to an embodiment of the present invention.

<Description of main parts of drawing>

10: transfer port 20: transfer means

30: container ship 40: pier

100: float 110: crane

140: power hookup 150: oil hookup

200: Foundation 210: Base

220: fender 230: support plate

235: through hole 240: connection portion

242: first arm part 242 ': first' arm part

244: second arm part 244 ': second' arm part

245: first moving member 246: third arm portion

246 ': 3rd arm part 248: 4th arm part

248 ': 4' arm part 250: hydraulic cylinder

251: cylinder 252: rod

255: plate member 260: buffer member

270: cable 300: shuttle barge

Claims (9)

In anti-motion foundation used for smart harbor system, The base installed in the sea bottom, A number of fenders that rise in sea level and come into contact with the bottom of the float; A support plate for fixing and supporting the plurality of fenders from below; It characterized in that it comprises a connection for connecting the distance between the base and the support plate by using a hydraulic cylinder Anti-Motion Foundation. The method of claim 1, The connection part includes an arm part hinged to the base and an arm part hinged to the support plate, and the other ends of the two arm parts are pivotally coupled to each other, and the pivot and hinge are centered using the hydraulic cylinder. Rotating the arm portion to adjust the distance between the base and the support plate Anti-Motion Foundation. The method according to claim 1 or 2, The fender expands when fluid is supplied therein and rises in sea level due to buoyancy. Anti-Motion Foundation. The method of claim 3, wherein The support plate is provided with a plurality of holes penetrating the main surface up and down Anti-Motion Foundation. The method according to claim 1 or 2, Further comprising a buffer member for mitigating the impact of the impact of the base, the support plate and the connecting portion Anti-Motion Foundation. The method according to claim 1 or 2, The connecting portion includes a pressure sensor for measuring the pressure applied to the hydraulic cylinder from the floating body, and adjusts the distance between the foundation and the floating body based on the measured value of the pressure sensor. Anti-Motion Foundation. In anti-motion foundation used for smart harbor system, A bottom member fixed to the bottom of the sea, An upper structure for supporting the bottom of the float, And a connecting member connecting the bottom member and the upper structure to each other and actively adjusting a distance therebetween. Anti-Motion Foundation. The method of claim 7, wherein The connecting member is characterized in that for adjusting the distance by using a hydraulic cylinder Anti-Motion Foundation. The method of claim 8, And a buffer member for preventing a collision between the upper structure and the bottom member. Anti-Motion Foundation.

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