KR101116525B1 - System controlling horizontal motion for floating movable quay wall - Google Patents

Abstract

Disclosed is a lateral displacement control apparatus for a floating temporary wall capable of quickly controlling a lateral displacement of a floating temporary wall. The transverse displacement control device of the floating temporary wall is for carrying out the unloading operation of the ship docked on the land quay, the at least two fixing holes penetrate the surface; And a base pile embedded in the seabed so as to correspond to the fixing hole of the wall, and a base pile which is lifted up by the hydraulic pressure from the foundation pile and lowered by its own weight when the pressure of the water is extinguished so as to control the transverse movement of the wall. It is composed of; a fixed member consisting of a fixed file that is fixed and released.

According to the lateral displacement control device of the floating temporary wall configured as described above, the lateral displacement is fixed so that the lateral wall is fixed to the sea during the unloading of the ship docked on the land quay, and the lateral displacement is movable after the vessel is unloaded. By controlling it quickly, it is possible to secure the structural stability according to the unloading of the vessel, it is possible to increase the utilization of the wall over the existing fixed floating quay.

Floating, double wall, transverse displacement, control

Description

Transverse Displacement Control Device for Floating Double Wall {SYSTEM CONTROLLING HORIZONTAL MOTION FOR FLOATING MOVABLE QUAY WALL}

The present invention relates to a lateral displacement control device for a floating temporary wall, and more particularly, to a lateral displacement control device for a floating temporary wall that can quickly control the lateral displacement of the floating temporary wall at sea. will be.

In general, shipping by container ship has advantages in that it has a large amount of transportation and low transportation cost compared to other means of transportation. In the peninsula countries such as Korea, many countries rely on shipping.

In particular, the recent shipping industry is pursuing large-sized vessels of ships, which is to secure economic feasibility by reducing the logistics cost by increasing the volume of ships, which is required to expand the mooring and unloading facilities of other ports. It is true.

Most of the ports are composed of straight land barriers, and due to the arrangement of various cranes centered only on such land barriers, container loading or unloading, and further, ship construction and various operations are inclined to be carried out by a single axis of the vessel.

In recent years, in order to compensate for this, floating hulls have been disclosed that can perform various crane operations at sea in response to onshore hulls.

The floating quay is installed in a fixed structure on the land quay or at sea for the unloading of vessels docked on the quay.

However, since the floating wall according to the prior art adopts a structure that is fixed to the land wall or the sea in order to perform the loading and unloading operation of the ship, it is impossible to move the wall during this time, so that the usability was large.

That is, since a plurality of ships arriving at the port had to wait for the order from the sea until the unloading work of the first arrived ships, there is a problem in that the time according to the unloading of the ship increases.

In addition, in order to shorten the unloading time of the ship, a number of floating barriers must be provided in the port, there is a problem that the unloading facility costs increase.

The present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to quickly control the transverse displacement of the floating temporary wall in the ocean to the transverse displacement of the wall during the unloading operation of the vessel The present invention relates to a lateral displacement control device of a floating double wall to achieve structural stability.

In order to solve the above technical problem, the present invention,
It is to carry out the unloading work of the ship docked on the shore wall,
At least two fixing holes 12 penetrating through the surface of the wall 10; And
A base pile 22 embedded in the seabed so as to correspond to the fixing hole 12 of the wall 10, and the fixing hole 12 is fixed and released to control the lateral movement of the wall 10. Transverse displacement control of the floating temporary wall, characterized in that it comprises a fixing member (20), which is raised by hydraulic pressure from the foundation pile (22) and lowered by its own weight when the hydraulic pressure is extinguished. Provide a device.

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In addition, the foundation pile is characterized in that connected to the pump provided on the ground for the lifting of the fixed pile.

The upper end of the fixing pile 24 is formed in a hemispherical shape, the inlet side of the fixing hole 12 is characterized in that the curved guide portion 14 for guiding the fixing pile 24 to the inside.

The fixing hole 12 is formed to have an inner circumference larger than the outer circumference of the fixing pile 24, characterized in that the cushioning material 16 is installed on the inner circumference to mitigate the impact of the contact of the fixing pile 24 along the circumference. It is done.

According to the apparatus for controlling the lateral displacement of the floating temporary wall according to the present invention, when unloading a ship docked on the land quay, the wall is fixed to the sea and the unloading of the ship is released after the ship is unloaded. By controlling the displacement quickly, it is possible to secure structural stability according to the loading and unloading of the ship, and there is a useful effect that can increase the utilization of the wall over the conventional fixed floating barriers.

In addition, by floating the floating wall is fixed after the ship unloading can be moved to another loading place there is also an effect that can reduce the cost of the unloading facility is unnecessary a number of unloading facilities in the port.

Hereinafter, the lateral displacement control device of the floating temporary wall according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a lateral displacement control device of the floating temporary wall according to a preferred embodiment of the present invention, Figure 2 is a plan view showing a floating temporary wall according to a preferred embodiment of the present invention, Figure 3 is 4 is a cross-sectional view of the fixing hole provided in the floating temporary wall illustrated in FIG. 2, and FIGS. 4 to 6 are views illustrating a process in which the lateral displacement of the floating temporary wall is controlled according to an exemplary embodiment of the present invention.

The transverse displacement control apparatus of the floating temporary wall according to the preferred embodiment of the present invention, as shown in Figures 1 to 3, and the double wall 10 for performing the unloading operation of the ship docked on the land quay, In the meantime, a fixing member 20 for fixing and releasing the lateral displacement of the wall 10 is controlled.

In more detail, during this time, the wall 10 has a rectangular structure and is provided in a floating state on the sea. In the meantime, the wall 10 is typically provided with at least one propeller 11 in order to be able to correct the movement and sea position. At this time, the propeller 11 is made of an azimuth thruster rotatable 360 °, during this time is installed in each corner region of the bottom surface of the wall 10. The azimuth thruster constituting such a propeller 11 is interlocked with the automatic adjustment system DSP provided in the adjustment chamber of the wall 10 during this time.

In the meantime, at least two fixing holes 12 penetrate the surface of the wall 10 for fixing and releasing by the fixing member 20. The fixing hole 12 is preferably formed in a quadrangular shape so as to provide stability when fixing the lateral displacement of the wall 10, but is not limited thereto.

That is, the fixing hole 12 may be formed in a variety of known shapes as long as it can stably fix the lateral displacement of the wall 10 during this time.

At least two fixing holes 12 should be provided to fix the lateral displacement of the wall 10 by the fixing member 20. Structural stability according to the fixing of the wall 10 during the unloading operation of the ship. Two or more may be provided to secure the. In this embodiment, it is shown that the fixing holes 12 are arranged in four rows at regular intervals by making two rows on the surface of the wall 10 during this time.

The fixing member 20 serves to control the lateral displacement of the wall 10 during this time, and for this purpose, the foundation pile 22 embedded in the sea floor so as to correspond to the fixing hole 12 of the wall 10, and the foundation It consists of a fixed pile 24 which is lifted up by the hydraulic pressure from the pile 22 and lowered by its own weight when the hydraulic pressure is extinguished, thereby being fixed and released to the fixing hole 12.

That is, the fixing member 20 is coupled to the fixing hole 12 while the fixing pile 24 is raised by the hydraulic pressure acting from the foundation pile 22 when performing the loading and unloading operation of the vessel, and fixes the wall 10 during this time, When the unloading work of the ship is completed, the fixed pile 24 is lowered to the foundation pile 22 by its own weight so as to be separated from the fixing hole 12 as the water pressure is extinguished, thereby releasing the fixing of the wall 10. .

The foundation pile 22 is formed in a tubular body having a rectangular structure in which the upper portion is opened so as to correspond to the fixing hole 12, and is embedded in the seabed. The foundation pile 22 is connected via a pump 28 and a pipe 28 provided on the ground to generate a hydraulic pressure for raising and lowering the fixed pile 24. At this time, the pipe 28 is connected to the lower end of the foundation pile (22).

The foundation pile 22 is operated by the pump 26, that is, the seawater is supplied when the forward rotation is generated, and the water pressure is generated, the seawater supplied during the reverse rotation of the pump 26 is discharged to the outside to eliminate the water pressure.

The fixed pile 24 is formed of a rectangular tube having a lower portion opening to correspond to the foundation pile 22, and is coupled to the foundation pile 22. At this time, the fixed file 24 is coupled so as to prevent the departure when raised from the base file (22).

The fixed pile 24 rises due to the water pressure generated in the foundation pile 22, and gradually descends due to its own weight when the pressure generated in the foundation pile 22 disappears.

At this time, since a constant suction force is generated due to the discharge of sea water by the pump when the water pressure within the foundation pile 22 is extinguished, the descending capacity of the fixed pile 24 may be improved.

In addition, the upper end of the fixed pile 24 is formed in a hemispherical structure. This is for the smooth guided by the curved guide portion 14 to be described later when fixing the fixing pile 24 in the fixing hole 12 of the wall (10).

In addition, the inlet side of the fixing hole 12 is formed with a curved guide portion 14 for guiding the fixing pile 24 to the inside. The curved guide portion 14 is formed to be curved outward from the inlet edge of the fixing hole 12. The curved guide portion 14 has a function of guiding the foundation pile 22 to smoothly flow into the fixing hole 12 during the fixing of the wall 10.

That is, the curved guide portion 14 is formed on the inlet side of the fixing hole 12 and the upper end of the fixing pile 24 is formed in a hemispherical shape, so that the fixing pile 24 fixes the lateral displacement of the wall 10 during this time. When coupled to the fixing hole 12 to be guided along the curved guide portion 14 can be coupled smoothly into the fixing hole 12.

In addition, the fixing hole 12 is formed to have an inner circumference larger than the outer circumference of the fixing pile 24, and the shock absorbing material 16 is provided along the circumference thereof. At this time, the buffer material 16 may be formed of various known buffer materials including rubber, foamed resin.

The shock absorbing material 16 has a function of cushioning the impact of the contact between the fixing pile 24 and the fixing hole 12 coupled into the fixing hole 12 when fixing the lateral displacement of the wall 10.

That is, the fixing pile 24 is coupled into the fixing hole 12 so that the lateral displacement of the wall 10 may be fixed during this time, but the fixing hole 12 may have a fixing pile (10) for smooth coupling of the fixing pile 24. Since the wall 10 is formed to have a larger area than 24), minute shaking may occur due to the influence of blue due to the gap between the fixing hole 12 and the fixing pile 24.

Therefore, the shock absorbing material 16 buffers the impact caused by the contact between the fixing hole 12 and the fixing pile 24 during the minute shaking of the wall 10.

The operation of the present invention having such a configuration will now be described.

The transverse displacement control apparatus of the floating temporary wall according to the preferred embodiment of the present invention controls the transverse displacement due to the wave of the transit wall 10 during the loading and unloading operation of the ship docked on the land quay. It is a structure to do.

First, as shown in Figure 4, when the vessel is docked to the land quay for unloading, the wall 10 is moved to the unloading position of the vessel by the propeller 11 interlocked with the automatic adjustment system.

That is, the propeller 11 moves the wall 10 to the unloading position of the ship so that the fixing hole 12 and the fixing member 20 installed on the sea bottom coincide with each other according to the pre-input information of the automatic adjustment system.

Then, when the ship moves to the unloading position, as shown in FIG. 5, the pump 26 is operated (forward rotation) to supply seawater into the foundation pile 22. Then, a certain amount of water pressure is generated in the foundation pile 22 to raise the fixed pile 24 by the seawater supplied, and the fixed pile 24 is fixed while being raised by the hydraulic pressure of the foundation pile 22. It is coupled into the ball 12 to fix the transverse displacement of the wall 10 during the unloading operation of the vessel.

At this time, the wall 10 is a slight lateral displacement is generated by the blue, so that the coincidence point between the fixing hole 12 and the fixing member 20, even in this case, the fixing pile 24 is curved guide portion 14 It can be coupled smoothly into the fixing hole 12 by).

The curved guide portion 14 is formed to be curved to the outside on the inlet side of the fixing hole 12, the upper end of the fixing pile 24 is formed in a hemispherical shape, the coincidence point of the fixing hole 12 and the fixing pile 24 Even when finely shifted, the upper end of the foundation pile 22 is guided to be coupled to the fixing hole 12 by the curved guide portion 14.

In addition, the fixing hole 12 is formed to have an inner circumference larger than the outer circumference of the fixing pile 24 so that the fixing pile 24 is smoothly coupled, and for this reason, the fixing pile 12 is fixed so that the lateral displacement of the wall 10 is fixed. Since the gap between the fixing hole 12 and the fixing pile 24 after the coupling 24 is affected by the blue wave, the shaking of the wall 10 may occur during this time.

The shock absorbing material 16 is installed on the inner circumferential surface of the fixing hole 12 to thereby cushion the impact caused by the contact between the fixing hole 12 and the fixing pile 24 during the minute shaking of the wall 10.

After the unloading operation of the vessel by the wall 10 is completed during this time, as shown in Figure 6, by operating (reverse rotation) of the pump 26 to discharge the seawater supplied in the foundation pile 22 to the outside . Then, in the foundation pile 22, the water pressure is extinguished by the discharge of sea water, and the fixed pile 24 is gradually lowered to release the coupling with the fixing hole 12 in accordance with the disappearance of the hydraulic pressure. Restoration of the wall 10 by the fixing member 20 can be released because it is restored into. At this time, when the discharge of the seawater in the foundation pile 22 is generated a constant suction force can be improved the falling capacity of the fixed pile 24.

When the wall 10 is released from the fixing member 20, the ship 10 is moved to the sea side by the propeller 11 so as to leave the onshore quay.

Such a lateral displacement control device of the floating temporary wall is fixed to the sea wall 10 by the fixing member 20 to stand in a floating state at the time of unloading of the vessel docked on the land quay and after unloading of the vessel. By releasing the fixing of the wall 10 during this time to be movable, the lateral displacement of the wall 10 can be quickly controlled.

The present invention has been described above by way of example, but the present invention is not limited to the above-described embodiment, and those skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Anyone can make a variety of variations.

1 is a block diagram showing a lateral displacement control device of the floating double wall according to an embodiment of the present invention,

2 is a plan view showing a floating double wall according to a preferred embodiment of the present invention,

3 is a cross-sectional view of the fixing hole provided in the floating double wall shown in FIG.

4 to 6 are views illustrating a process in which the lateral displacement of the floating temporary wall is controlled according to a preferred embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

10: wall while 12: fastener

14: curved surface guide 16: cushioning material

20: fixing member 22: foundation pile

24: fixed pile 26: pump

Claims (4)

It is to carry out the unloading work of the ship docked on the shore wall, At least two fixing holes 12 penetrating through the surface of the wall 10; And A base pile 22 embedded in the seabed so as to correspond to the fixing hole 12 of the wall 10, and the fixing hole 12 is fixed and released to control the lateral movement of the wall 10. Transverse displacement control of the floating temporary wall, characterized in that it comprises a fixing member (20), which is raised by hydraulic pressure from the foundation pile (22) and lowered by its own weight when the hydraulic pressure is extinguished. Device. The method of claim 1, The foundation pile (22) is a horizontal displacement control device of the floating double wall, characterized in that connected to the pump 26 provided on the ground for the lifting of the fixed pile (24). The method according to claim 1 or 2, The upper end portion of the fixing pile 24 is formed in a hemispherical shape, floating double wall, characterized in that the curved guide portion 14 for guiding the fixing pile 24 to the inside of the fixing hole 12 is formed Transverse displacement control device. The method of claim 3, The fixing hole 12 is formed to have an inner circumference larger than the outer circumference of the fixing pile 24, characterized in that the cushioning material 16 is installed on the inner circumference to mitigate the impact of the contact of the fixing pile 24 along the circumference. Lateral displacement control device of floating double wall.

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