KR101639213B1 - Elevating and desending device for a barge having legpipes easily lifted - Google Patents

Abstract

The present invention relates to a lifting device for a barge, capable of easily lifting a leg pipe up and down by including a footing to be easily lifted. The device comprises: a deck; multiple jack houses installed separately in the corners of the deck; multiple cylindrical leg pipes installed to penetrate the inside of the jack houses; and a lifting unit lifting the leg pipe up and down against the jack houses. The footing, fixed to the bottom of the leg pipe to support the barge on the ocean floor, includes: a connection part formed in an upper central part and connected with the leg pipe; an upper horizontal surface formed to have a predetermined area around the connection part; an upper taper surface formed to be inclined downward from an outer edge part of the upper horizontal surface; a lower horizontal surface formed in the lower part to be symmetrical to each other; and a lower taper surface formed to be inclined upward from an outer edge part of the lower horizontal surface. The present invention further includes a pumping machine supplying high pressure water into the footing to spray the water to the outside through a spray hole.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an elevating and lowering device for a barge having leg pipes,

The present invention relates to an elevating device for a barge, more particularly, to a device for easily lifting a footing in a state of being buried in a sea bed, as in a leg pipe, ≪ / RTI >

The barge is generally used to perform various tasks such as marine, bridge-related work or submarine excavation work. Such a barge includes a deck having a top surface in a planar shape and a plurality of leg pipes provided so as to be vertically movable up and down at the corner portion of the deck.

Such a barge is, for example, equipped with equipment and materials for performing bridge installation work or underwater surface excavation work at sea, moving to a marine construction site, and then a leg pipe installed at each corner of the hull of the barge And the barge line is fixed to the sea bottom (bottom surface) so that the barge line can not move. When the work is moved to another place such as the completion of the construction work, the leg pipe is raised so that the barge can move.

The mechanism for raising and lowering the leg pipe is a system using a hydraulic cylinder and a pin, and a system using a rack and pinion gear. In the type using a hydraulic cylinder and a pin, since the respective leg pipes are moved up and down according to the operation of the piston to move the barge up and down, the barge up / down operation in the cylinder type is not continuous, It is very difficult to fine-tune it.

The reason why such a barge line can be firmly supported in the ocean is that the footing provided at the lower end of the leg pipe provides a supporting force sufficient to be supported against the sea floor. Other conventional configurations for such footing are disclosed in various forms including U.S. Patent No. 4,112,863 and the like.

However, it is pointed out that the footing disclosed in the above-mentioned U.S. Pat. Patent is somewhat lacking in terms of stable support since the bottom surface forms a flat surface but the bottom surface does not have a sufficient area.

It can be said that such footing is supported after digging into a certain depth according to the situation of the sea floor (mud, sand, etc.). That is, due to the load of the barge, the footing supports the barge in a state where it is buried at a certain depth into the sea floor. Thus, the bottom surface of the bottom of the footing is sufficiently compressed by the load of the barge, so that it is possible to support the barge.

As the footing is buried at a certain depth on the sea floor, the work required for the barge line proceeds. As time elapses or depending on the condition of the sea floor, mud, sand or the like often flows down on the upper surface of the footing. When the bottom surface material (mud or sand) is piled up on the upper surface of the footing, it is inevitable that the leg pipe itself substantially moves upward.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a lifting and lowering apparatus capable of smoothly raising and lowering a leg pipe and capable of controlling a fine height.

It is another object of the present invention to provide a footing for a barge which can be carried out more smoothly, such as securing a supporting surface capable of sufficiently supporting a barge.

Another object of the present invention is to provide a footing surrounding structure for a barge which can minimize the resistance when the barge moves in the ocean.

According to an aspect of the present invention, there is provided a barge comprising a deck, a plurality of jack houses installed at corners of the deck, a plurality of cylindrical leg pipes installed through the jack house, And a lifting means for lifting the pipe up and down with respect to the jack house. The footing, which is fixed to the lower end of the leg pipe and supports the barge with respect to the sea floor, includes a connecting portion formed at the central portion of the upper surface and connected to the leg pipe, an upper horizontal surface formed to have a certain area about the connecting portion, An upper tapered surface formed to be inclined downward at an outer rim portion of the upper horizontal surface, a lower horizontal surface formed to be lowered to be symmetrical with the upper horizontal surface, and a lower tapered surface formed to be inclined upward at an outer rim portion of the lower horizontal surface .

Preferably, the upper tapered surface and the lower tapered surface are formed to have a predetermined inclination within a range in which footing can enter a pocket formed on the bottom surface of the barge.

According to another embodiment of the present invention, the footing is formed with a plurality of injection holes communicating the inside and the outside. A pumping means supported on the deck for pumping seawater at a high pressure and outputting the pumping water; and a plurality of supply lines for supplying high pressure water by the pumping means to the inside of the footing through the respective leg pipes . In this embodiment, it can be seen that the water supplied to the inside of the footing is configured to be spaced apart from the footing by the material that is in contact with the footing while being sprayed to the outside through the injection hole.

According to an embodiment of the pumping means, the supply line is constituted by a first pump and a second pump, wherein the supply line comprises a first supply line for supplying water in a pair of footings from the first pump, And a second supply line for supplying water by a pair of footing, respectively. Wherein the first pump is selectively connected to the second supply line and the second pump is selectively connectable to the first supply line.

And the outlet portion of the first pump is connected to a first supply line for supplying water in a pair of footings through the first branch portion and the outlet portion of the second pump is connected to the other pair of footing To the second supply line for supplying water to the second supply line. Here, the first branch portion and the second branch portion are connected through a connection line, and the connection line is provided with a valve for interrupting the flow of water.

According to another embodiment, the outlet portion of the first pump is connected to a first supply line, each of which supplies water in a pair of footings through a first branch portion, and the outlet portion of the second pump is connected through a second branch portion And connected to a second supply line for supplying water to each of the other pairs of pipettes. And the outlet portion of the first pump may be selectively connected to the second supply line and the outlet portion of the second pump may be selectively connected to the first supply line.

According to another embodiment of the pumping means, the pumping means is constituted by a plurality of pumps, the supply line consisting of a plurality of supply lines each supplying water in one pump to one or more footings; Each of the pumps may be selectively connected to a supply line other than the predetermined supply line.

According to the present invention as described above, the barge is raised and lowered by using a pinion gear rotated by a hydraulic motor and a rack gear installed on both sides of the leg pipe in a jack house provided at each corner of the hull of the barge Therefore, it can be said that there is an advantage that the barge can basically move up and down more smoothly. By using the pinion and the rack gear as described above, it is expected that the height of the barge can be controlled substantially accurately, and the barge can be controlled to a finer degree.

According to the present invention, it is understood that the bottom horizontal surface having a planar shape secures an area capable of sufficiently supporting the barge. By the lower tapered portion formed on the outer edge portion, it is expected that the setting of the leg pipe can be performed more quickly and efficiently.

In addition, the upper tapered surface inclined downward is formed on the upper edge of the footing of the present invention, so that it is guided to push the seabed material accumulated on the upper portion of the footing downward when the footing is moved upward. With this structure, it is possible to expect an advantage that the upward movement of the footing can be performed relatively quickly even when the seabed material is piled up on the top of the footing according to the long-term operation or the condition of the sea floor.

In the present invention, the upper and lower horizontal surfaces are formed and the upper and lower tapered surfaces having appropriate inclination are formed on the rim of the upper and lower horizontal surfaces, so that the putting whole does not protrude into the pockets formed on the bottom surface of the barge . Therefore, even when moving, it is possible to prevent the possibility of resistance due to footing beforehand and to expect effective operation.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view of a barge according to the present invention viewed from the front; Fig.
Fig. 2 is a plan view of the barge according to the present invention as seen from a plane. Fig.
3 is a plan view showing a state where a lifting device is coupled to a barge of the present invention in a plan view.
Fig. 4 is an exploded perspective view of the barge of the present invention in a state where the lifting device is separated; Fig.
5 is a sectional view showing a state in which the lifting device of the barge of the present invention is engaged.
6 is a sectional view taken along the line II in Fig.
FIG. 7 is a plan view showing a state in which the jack house and the inner diameter portion are engaged in the lifting device of the barge of the present invention in a plan view. FIG.
8 shows a footing of the present invention, wherein (a) is a plan view, and (b) is a front view.
9 is a plan view of a barge having a water injection device according to the present invention.
10 is a diagram illustrating a configuration example of a pumping mechanism of a water injection device according to the present invention;

 Hereinafter, a bar lifting and lowering apparatus according to the present invention will be described with reference to the embodiments shown in the drawings. First, the construction for ascending and descending the barge will be described with reference to FIGS. 1 to 7. FIG.

2 is a plan view of the barge according to the present invention viewed from a plane, and Fig. 3 is a plan view of the barge according to the present invention, Fig. 5 is a cross-sectional view showing a state where the lifting device of the present invention is coupled to the barge, Fig. 6 is a cross-sectional view taken along the line II And FIG. 7 is a coupled state view showing a state in which the jackhouse and the inner diameter portion are engaged with each other in the lifting device of the barge of the present invention in a plan view.

As shown in FIGS. 1 and 2, the barge 10 of the present invention is equipped with a deck 11 which is wide and flat to allow equipment and materials necessary for marine construction to be loaded. The deck 11 may be formed in a polygonal or circular shape such as a square or the like. Preferably, the deck 11 is provided with a rectangular-shaped deck 11 so that the marine construction is easy and the equipment and materials used in the marine- . As shown in FIG. 3, each corner of the deck 11 of the barge 10 is provided with a barge lifting device for moving the barge 10 up and down.

4 to 6, the deck 11 includes a jack house 20 at each corner. In the jack house 20, there is a barge 20, And the leg pipes 30 are lifted and lowered with respect to the main body 10, respectively. Each of the leg pipes 30 is formed in a cylindrical shape because the leg pipe 30 is formed of a cylindrical leg pipe 30 rather than a rectangular pipe shape or a ridge shape, to be.

On both side surfaces of each of the leg pipes 30, the rack gear 100 is fixed by, for example, welding. The jack house (20) is provided with a cylindrical portion (40) formed in the same shape as the outer peripheral surface of the leg pipe (30) inserted into the jack house (20). 4, the lower portion of the cylindrical portion 40 is integrally formed, and the upper portion connected to the integrally formed lower portion is formed of a pair of semicircular shapes having the same shape as the outer diameter of the leg pipe 30 have.

In addition, the opposite ends of the cylindrical portion 40 are formed to be open, that is, the respective ends of the pair of semicircular shapes positioned on the upper portion of the cylindrical portion 40 are spaced apart at regular intervals. The gear portion of each rack gear 100 is connected to the outside of the cylindrical portion 40 so that each of the rack gears 100 and the pinion gears 200 to be described later can be engaged with each other between the respective spaced- So as to protrude.

A plurality of engaging members 50 (50) for engaging and fixing the pair of cylindrical portions 40 to the jack house 20 are formed at the open both side portions of the cylindrical portion 40, that is, at the respective ends of the pair of cylindrical portions 40 As shown in FIG. 5, the engaging members 50 are spaced apart from the upper portion of the jack house 20 at equal intervals.

7, a plurality of fixing members (not shown) for firmly supporting and fixing the cylindrical portion 40 to the jack house 20 are provided between the inner surface of the jack house 20 and the outer surface of the cylindrical portion 40 And the fixing members 60 are positioned radially between the inner surface of the jack house 20 and the outer surface of the cylindrical portion 40. [

The upper surface of the coupling member 50 is engaged with the rack gears 100 coupled to both sides of the leg pipes 30 to move up and down the respective leg pipes 30, And a pinion gear 200 that rotates to reciprocate in the vertical direction. A hydraulic motor 210 for transmitting a driving force to the pinion gear 200 so as to reciprocate the rack gear 100 while rotating the pinion gear 200 engaged with the rack gear 100 is provided at the rear of the pinion gear 200, ).

The pinion gear 200 is rotated by the driving force generated by the hydraulic motor 210 and rotated by the rack gear 100 engaged with the pinion gears 200, The rack gear 100 is converted into a rectilinear motion reciprocating in the vertical direction so that the leg pipe 30 to which the rack gear 100 is coupled also linearly moves and the barge 10 And is vertically moved while reciprocating in the vertical direction. Each of the hydraulic motors 210 is connected to a control unit (not shown) for controlling the hydraulic motor 210 to drive and stop the hydraulic motor 210.

Next, the footing 70 fixed to the lower end of the leg pipe 30 will be described with reference to FIG. The footing 70 for a pants line according to the present invention includes an upper horizontal surface 72a and a lower horizontal surface 72b formed to form a horizontal surface and a rim portion 72c of the upper horizontal surface 72a and the lower horizontal surface 72b, And an upper tapered surface 74a and a lower tapered surface 74b, respectively. A connecting portion 80 is formed at a central portion of the upper horizontal surface 72a to connect (e.g., weld) the leg pipe of the barge.

The horizontal surfaces 72a and 72b described above in the present invention are formed on the upper and lower surfaces of the footing 70 and can be said to have a sufficient area. It can be seen that the upper horizontal plane 72a and the lower horizontal plane 72b have symmetrical shapes. Here, the lower horizontal surface 72b can be said to be a portion where the leg pipe of the barge line is lowered to come into contact with the sea bed surface.

The lower horizontal surface 72b is in contact with the sea floor and enters the bottom surface due to the load of the barge line. The bottom surface to be compressed is kept fixed at a depth sufficient to support the load of the barge line . In this way, when the footing 70 is supported on the underside surface, the lower horizontal surface 72b has a sufficient horizontal area, which is expected to be advantageous in terms of supporting the overall load of the barge.

The upper horizontal surface 72a is also formed to be symmetrical with the lower horizontal surface 72b. The lower horizontal surface 72b is formed symmetrically with the lower horizontal surface 72b. As shown in FIG. It can be seen that the lower horizontal surface 72b according to the present invention has a sufficient horizontal area so that it can be stabilized as a whole when supporting the load of the barge.

A lower tapered surface 74b is formed at an outer edge portion of the above-described lower horizontal surface 72b. In the illustrated embodiment, since the footing 70 itself has a rectangular shape, it can be seen that the lower tapered surface 74b is formed to have a constant width along the rectangular rim portion. The lower tapered surface 74b is formed such that when the bottom surface of the footing 70 contacting the bottom surface enters into the bottom surface, the material (mud or sand, etc.) forming the bottom surface is pushed out of the footing 70 .

In other words, the lower tapered surface 74b minimizes the reaction force due to the surrounding material except for the lower horizontal surface 72b of the central portion in contact with the sea floor, so that the footing 70, So as to be able to enter while pressing. By way of comparison, for example, it is more advantageous in the process described above that the bottom tapered surface 74b is molded as in the present invention, compared to the case where the entire bottom surface of the footing 70 is formed into a rectangular horizontal surface It can be understood.

Next, an upper tapered surface 74a formed on the upper surface to be symmetrical with the lower tapered surface 74b will be described. As mentioned in the prior art, when the footing 70 is positioned in a state of descending to a certain depth on the sea bed surface, depending on the passage of time or depending on the state of the material forming the sea floor, It often happens that the upper surface of the substrate 70 is covered.

When the bottom surface material is deposited on the upper surface of the footing 70, it is natural that the deposited material acts as a large resistance when the foot pipe is pulled up from the bottom of the sea. Therefore, in the present invention, the upper tapered surface 74a is formed at the upper edge of the footing 70. [ The upper tapered surface 74a serves as a guide to allow the seabed material deposited on the footing 70 to flow downward when the footing 70 is moved upward.

That is, when the footing 70 begins to move, the material accumulated on the upper surface thereof flows downward along the upper tapered surface 74a. When such submarine material flows outward, it is practically forced to flow outward due to the viscosity of the material and the self-attraction force (cohesive force) of the material at the center portion. As described above, the upper tapered surface 74a formed on the upper surface of the footing 70 induces the material accumulated on the upper tapered surface 74a to flow downward, thereby minimizing the resistance when the footing 70 rises have.

It is preferable to form the upper tapered surface 74a as large as possible in terms of the above-described points. However, the larger the tapered surface is, the higher the overall height of the footing 70 becomes. Substantially, the footing 70 must be fully inserted into the pocket formed in the bottom of the deck of the barge when the leg pipe is fully raised. If the footing 70 moves in the sea unless it enters the pockets on the bottom of the barge, footing will act as a very large resistance, which is undesirable.

Therefore, it is preferable that the upper horizontal surface 72a is formed on the upper surface of the footing 70 and the tapered surface 74a is formed only on the outer edge portion thereof. According to the footing 70 of the present invention, the upper tapered surface 74a is formed so as to be inclined downward as it goes outward, and the lower tapered surface 74b is formed so as to be inclined upward toward the outer side. It will also be understood that it has a function.

It can be seen that the footing of the present invention should have a height such that the entire height thereof can enter the pockets of the bottom of the barge. Accordingly, the upper and lower horizontal surfaces are formed, and only the outer side of the upper and lower horizontal surfaces can be inclined at an appropriate inclination angle (putting into the inside of the pocket, as well as within the range capable of performing the functions of the upper and lower tapered surfaces The angle of inclination).

That is, the height of footing of the present invention is designed so as to be less than the height of the pocket formed at the bottom of the barge to accommodate the footing, which has the same meaning that the footing does not protrude downward from the pocket of the barge. The footing according to the present invention having the above-described structure is formed of an iron plate, and a partition, a passage, and the like are formed in the inside thereof by the regulations. However, substantially the internal structure of the footing is not directly related to the present invention, so a detailed description thereof will be omitted.

Next, a water injection device of the present invention, which can be applied to the exemplary footing 70 as described above, will be described. The water injection device of the present invention can be said to be intended to smoothly raise the leg pipe by blowing the substance deposited on the footing 70 substantially on the upper surface of the footing.

As can be seen from Fig. 8, the footing 70 has a plurality of injection holes 78 formed therein for communicating the inside and the outside thereof. It can be said that the spray holes 78 are preferably formed not only on the upper surface of the footing 70 but also on the side surface and the bottom surface. The injection holes 78 are formed on the side surfaces of the footing 70 so that the material accumulated in the footing 70 has a shape that surrounds the footing as a whole and has a viscosity and an adsorption property. It is preferable that the water can be injected at a high pressure with respect to the entire side surface.

Next, a configuration for supplying water injected to the outside through the injection hole 78 after supplying high-pressure water into the footing 70 will be described with reference to FIGS. 9 and 10. FIG. 9 is an exemplary plan view of a barge to which the water jetting apparatus of the present invention is applied. As shown, a pumping mechanism 90 for supplying high-pressure water to the inside of the footing 70 described above is installed on the deck 11 of the barge.

The water supplied at a high pressure by the pumping mechanism 90 is supplied to the inside of the footing 70 through the inside of the leg pipe 30 and then discharged through the spray hole 78 in the footing 70 And is sprayed outside. In Fig. 9, reference numeral 52 is a pocket molded on the bottom of the barge to store footing.

This injection of water will remove the material deposited on the top of the footing 70 or float on top of the footing so as not to act as a rising footing resistance. In addition, not only the upper portion of the footing but also the water sprayed through the side surface and the bottom surface serves to facilitate the upward movement of the footing 70 and the leg pipe by separating the material around the footing 70 from the action of resistance .

 As shown in Fig. 10, the pumping mechanism 90 in this embodiment includes a first pump 62A for pumping water to a part of the footing 70, And a second pump 62B for pumping water to the putting. In the illustrated embodiment, the first pump 62A is for supplying high-pressure water to the two left footings of the drawing, respectively, and a plurality of first supply lines 94 (94a, 94a, And a plurality of second supply lines 96 (96a, 96b, 96b, 96b, 96b, 96b, 96b, 96b, and 96b) 96b.

Valves V1 and V2 for interrupting water are provided at the outlet of the first pump 62A and the second pump 62B respectively and branch portions 72 and 74 after the valves V1 and V2 are provided. 94a and 94b and the second supply lines 96 (96a and 96b), respectively. Valves V12 and V14 and valves V22 and V24 for intermittent water flow are respectively installed in the first supply lines 94a and 94b and the second supply lines 96a and 96b. Each of the valves V1, V2, V12, V14, V22, V24 is provided for interrupting the water at the installed point. The first supply lines 94a and 94b and the second supply lines 96a and 96b are connected to the pumps 62A and 62B provided on the deck D, To the inside of the footing 70 provided at the lowermost end.

The supply of water (seawater) to the first pump 62A and the second pump 62B starts at the pump side supply line 82 and starts at the pump side first line 82 branched from the pump side supply line 82 Through the supply line 82a and the pump-side second supply line 82b. It is needless to say that valves V8, V8a, and V8b for interrupting the water are also preferably provided on each of the lines 82, 82a, and 82b.

According to the structure as described above, the first pump 62A supplies the high pressure water to a large number (left and right) of the left footing 70 through the left (multiple) pair of supply lines 94a and 94b . And the second pump 62B supplies the high pressure water to a large number (right and left) of the right footing 70 through the right (multiple) pair of supply lines 94a and 94b.

However, if there is a failure in driving the actual pumping mechanism 90, if one of the pumps fails, the water can be supplied only to a part of the putting and the water can not be supplied to the remaining parting 70 . Therefore, in the present invention, even if one of the plural pumps fails, the high pressure water can be supplied to the other footing 70 by using a pump that operates normally.

According to the present invention, there is provided a connection line 88 connecting the first branch portion 72 and the second branch portion 74 to each other, and a connection line valve V3 is provided in the connection line 88 have. By means of this connection line 88 it is also possible to supply the water to be pumped by the first pump 62A to the second supply lines 96a and 96b and the water to be pumped by the second pump 62B to the first supply Lines 94a and 94b, respectively.

It can be seen that the connection line 88 is configured to supply water to the supply lines 94 or 96 on the opposite sides of the first pump 62A and the second pump 62B. The connection line 88 for supplying water to the supply lines on opposite sides is not limited to the illustrated embodiment, but may be modified in many other ways.

For example, the connection line for supplying water by the first pump 62A in the other embodiment starts from the outlet portion 76A of the first pump 62A and is connected to the outlet portion of the first pump 62B 76B, the second branch portion 74, or the second supply lines 96a, 96b. In this case, a valve for intermittent operation must be provided in the middle of the connection line. In this case, the connection line for supplying water by driving by the second pump 62B starts at the outlet portion 76B of the second pump 62B and is connected to the outlet portion 76A of the first pump 62A, To be connected to either the first branch portion 72 or the first supply lines 94a, 94b.

Hereinafter, the operation of the lifting apparatus of the present invention having the above-described structure will be described. It is possible to fix the barge 10 floating on the sea so that it can be constructed at the sea, such as installing a bridge at sea or excavating the sea floor, as well as fixing the barge 10 to a marine construction site or the like The barge 10 must be raised and lowered to change the height of the barge 10 according to the height of the sea surface.

That is, the joining member 50 and the pair of cylindrical members 40 are coupled to each other by the fixing members 60 in the jack house 20 provided at each corner of the deck 11 of the barge 10, A unit including a pinion gear 200 and a hydraulic motor 210 is coupled to a coupling member 50, which is vertically coupled to each end of a pair of cylindrical portions 40 spaced apart at the predetermined intervals.

A leg pipe 30 is inserted into a pair of cylindrical portions 40 of the jack house 20 and then a rack gear 100 welded to both sides of the leg pipe 30 in a lengthwise direction, Is inserted and inserted between the respective ends of the pair of cylindrical portions (40) so as to be engaged with the pinion gear (200). A control unit provided on the barge 10 elevates and lowers the barge 10 and a control signal is transmitted to a plurality of hydraulic motors provided in a jack house 20 provided at each corner of the deck 11 of the barge 10 210, respectively.

Then, in each of the hydraulic motors 210, a driving force is generated in accordance with a control signal, and the pinion gear 200 coupled to each hydraulic motor 210 is rotated by the generated driving force.

4 and 5, the rack gear 100 meshing with the pinion gears 200 receives a rotational motion of the rotating pinion gear 200 and performs a linear movement reciprocating upward and downward. The respective leg pipes 30 to which the rack gear 100 is coupled also reciprocate upward and downward around the deck 11 of the barge 10 by the respective leg pipes 30, The barge 10 also ascends and descends in the vertical direction.

That is, when each of the leg pipes 30 moves upwardly of the barge 10 around the jack house 20, the lower end of the leg pipe 30, which is in contact with the bottom of the river, So that the barge 10 can be moved. When each of the leg pipes 30 moves downwardly of the barge 10 with the jack house 20 as a center, if the lower end of the leg pipe 30 is in contact with and fixed to the bottom of the river, The barge 10 is fixedly installed at a certain place.

The deck 11 of the barge 10 is vertically moved up and down by means of a device for raising and lowering the barge 10, And a plurality of pinion gears 200 coupled to the jack house 20 and disposed in a pair of cylindrical portions 40 of each of the jack houses 20, And a rack gear 100 coupled to both sides of the leg pipe 30 and meshing with the pinion gear 200. The pinion gear 200 is provided with a leg pipe 30, The rack gear 100 and the leg pipe 30 are converted into linear motion reciprocating in the vertical direction according to the rotational motion of the barge 10 so that the barge 10 is also moved up and down while reciprocating in the vertical direction.

 Accordingly, not only the entire barge 10 can be raised and lowered smoothly at a constant speed and height, but also the barge 10 can be continuously lifted and lowered, It will be possible to fine-tune the distance.

The barge 10 is fixed to the sea floor at the time of marine construction such as bridge installation at sea or marine floor excavation by the elevating and lowering device, so that the construction at sea is smoothly performed and the marine construction is completed And the barge line 10 is moved smoothly to another construction site.

Hereinafter, the operation of the footing 70 moving together with the rising and falling of the leg pipe will be described. The leg pipe 30 descends and the footing 70 comes into contact with the sea bed surface. When the bottom surface of the footing 70 contacting the sea floor enters into the sea floor, the lower tapered surface 74b, (Mud or sand) can be pushed out of the footing 70 as described above.

In other words, the lower tapered surface 74b minimizes the reaction force due to the surrounding material except for the lower horizontal surface 72b of the central portion in contact with the sea floor, so that the footing 70, It can be seen that it has an action to push in while pushing.

Next, the operation of the upper tapered surface 74a when the leg pipe 30 is lifted will be described. When the leg pipe 30 is moved upward, the upper tapered surface 74a serves as a guide to allow the seabed material deposited thereon to flow downward when the footing 70 is moved upward. That is, when the footing 70 begins to move, the material accumulated on the upper surface thereof flows downward along the upper tapered surface 74a.

When such submarine material flows outward, it is practically forced to flow outward due to the viscosity of the material and the self-attraction force (cohesive force) of the material at the center portion. As described above, the upper tapered surface 74a formed on the upper surface of the footing 70 induces the material accumulated on the upper tapered surface 74a to flow downward, thereby minimizing the resistance when the footing 70 rises have.

According to another embodiment of the present invention having the water injection device, it can be seen that the high pressure water supplied into the footing 70 is injected to the outside of the footing 70 through the injection hole 78. This injection of water will remove the material deposited on the top of the footing 30 or make it float on top of the footing so as not to act as a rising footing resistance. In addition, the water sprayed through not only the upper portion of the footing but also the side and bottom surfaces serves to facilitate the upward movement of the footing 30 and the leg pipe by separating the material around the footing 30 from the material around the footing 30, Will be.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept as defined by the appended claims. It is reasonable in light of the provisions of the Patent Act.

10: Barge
11: Deck
20: Jack House
30: Leg pipe
40: My neck
50:
60: Fixing member
70: footing
80: Connection
90: Pumping mechanism
100: Rack gear
200: Pinion gear
210: Hydraulic motor

Claims (6)

A deck, a plurality of jack houses installed respectively at corners of the deck, a plurality of cylindrical leg pipes installed to penetrate the inside of the jack house, an elevating and lowering means for raising and lowering the leg pipes relative to the jack house, And a plurality of supply lines for supplying high pressure water by the pumping means to the inside of the footing through the respective leg pipes;
The footing fixed to the lower end of the leg pipe to support the barge against the sea floor has an upper horizontal surface formed to have a constant horizontal surface area at the center portion and an upper tapered surface formed at an outer edge portion of the upper horizontal surface, And a lower tapered surface formed so as to be inclined upward at an outer edge portion of the lower horizontal surface, wherein a plurality of injection holes for communicating the inner and outer portions are formed, Water may be injected through the injection hole to separate the material contacting the footing from the footing;
The pumping means may comprise a first pump and a second pump, wherein the supply line comprises a first supply line for supplying water in a pair of footings from the first pump, and a second supply line for supplying water in the other pair, And a second supply line for supplying the first supply line and the second supply line, respectively;
The outlet portion of the first pump is connected to a first supply line for supplying water in a pair of footings through the first branch portion and the outlet portion of the second pump is connected to the other branch through a second branch portion Each connected to a second supply line for supplying water;
The first branch portion and the second branch portion are connected to each other through a connection line 88. A connection line valve V3 for interrupting the flow of water is installed in the connection line, Wherein the first pump is capable of supplying water to the second supply line and the second pump is capable of supplying water to the first supply line. delete delete delete delete delete

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