JP2017094988A - Landing vessel and cargo handling method using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a landing vessel, mounted with a rampway bridging a gap between a vessel body and land with the same fell down to the land when the landing vessel berths or beaches, which enables the rampway to be bridged to a high quay wall while preventing a gravity center of the landing vessel from getting higher and to provide a cargo handling method using the landing vessel.SOLUTION: A lifting deck 5 and a lifting and lowering mechanism 6 which moves up and down the lifting deck 5 with respect to a vessel body are arranged between a vehicle deck 4 and a rampway 7. The rampway 7 is rotatably connected to a first hinge section 8 at one end of the lifting deck 5. An inclination angle θ1 of the rampway 7 is adjusted by changing a height of the first hinge section 8 with the lifting deck 5 moved in a vertical direction depending on an elevation of land to which the rampway 7 is bridged.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a ship for landing and a cargo handling method using the ship for landing, and more specifically, a ramp way is provided, and the ramp way is turned to the land by berthing or beaching and falling down toward the land. In a landing ship that bridges between the hull and the land, it is possible to bridge the rampway on a high quay, and the handling method using a landing ship and a landing ship with a low center of gravity of the ship. About.

  Conventionally, car carriers, car ferries, and RORO ships are known as cargo ships for transporting cars and trucks (hereinafter referred to as vehicles) loaded with cargo. This RORO ship is equipped with a rampway that connects and disconnects the hull and the land by passing from the ship to the quay and coast (hereinafter referred to as land), and the vehicle can be boarded and unloaded through this rampway. Can do. As described above, since the ramp way is provided to enable quick cargo handling, the ramp way is employed in many ships for the purpose of freight transportation (see, for example, Patent Document 1).

  Conventionally, a movable bridge (rampway) forms a part of the bow, and the outer plate part of the bow is movable so that the movable bridge can fall over the bow and lay on the land. There has been proposed a landing ship having a structure constituted by (see, for example, Patent Document 2).

  In a conventional landing ship having such a structure, as shown in FIG. 5, the vehicle deck is configured by a parallel plane substantially parallel to the planned draft, and the hinge portion of the portion where the vehicle deck and the rampway are connected is provided. It is arranged at the same height, and has a structure in which the vehicle deck and the conveyance port on the vehicle deck side of the ramp way are directly connected. In this way, since the vehicle deck and the rampway transport port are directly connected, the vehicle can move directly from the vehicle deck to the rampway transport port by itself, thus improving the efficiency and speed of the cargo handling work. Can be planned.

  However, in a ship for landing with such a conventional ramp way, there is a problem that it is difficult to bridge the ramp way to a high land because the height position of the hinge portion is fixed.

  That is, in order to bridge the ramp way to a high land, a method of increasing the inclination angle of the ramp way when the ramp way is bridged can be considered. However, in order to allow the vehicle to travel safely from the rampway to the land, it is necessary to keep the amount of change in the tilt angle within the predetermined angle range in the distance the vehicle travels, so a method for increasing the ramp angle Cannot be adopted.

  The allowable amount of change in the tilt angle varies depending on the type of vehicle passing through the rampway, but specifically, for an emergency vehicle used for disaster relief, etc., the tilt angle is downward. In the case of changing, the change in the inclination angle needs to be, for example, 16 degrees or less. When the angle is 16 degrees or more, there is a risk that the bottom of the vehicle hits the convex portion caused by the change in the inclination angle. On the other hand, when the rampway is crossed over a high land, if the angle between the rampway and the land is 16 degrees or more, the vehicle may not be able to travel. On the other hand, when the inclination angle changes upward, the change in the inclination angle needs to be 25 degrees or less, for example. This is because if the angle is 25 degrees or more, there is a risk of rubbing the bottom of the vehicle in the vicinity of the recess caused by the change in the inclination angle.

  Further, as another method for bridging the ramp way to a high land, a method of increasing the length of the ramp way can be considered. However, in this case, there is a problem that the weight of the rampway becomes heavy.

  As another method, a method of increasing the height of the conveyance port on the stern side of the ramp way is conceivable. However, in a conventional landing ship, the height of the vehicle deck and the height of the rampway transport port are the same, so if the height of the rampway transport port is increased, the vehicle deck is also placed at a higher position. Since it becomes a structure and the gravity center of a ship becomes a high position, the problem that stability of a ship decreases and stability deteriorates arises. Further, when the height of the rampway transport port is increased, there is a problem that the rampway becomes a downhill with a large inclination angle when it is bridged over a low coast.

  In this way, the landing ship having the conventional ramp way as shown in FIG. 5 is excellent in terms of efficiency and speed of the cargo handling work, but can be used to land the ramp way. There is a problem that it is difficult to widen the height range.

Special table 2011-521836 gazette JP 2002-114191 A

  The present invention has been made in view of the above situation, and an object of the present invention is to provide a ramp way, piercing or beaching and turning the ramp way toward the land so that the ramp way is connected to the hull and the land. In a landing ship that can be bridged between the two, it is possible to bridge a rampway on a high quay, and it is possible to suppress the increase in the center of gravity of the ship and maintain the ship's restoring force well. It is to provide a cargo handling method using a ship and a ship for landing.

  In order to achieve the above object, a ship according to the present invention includes a rampway, and is a landing ship that pierces or beaches and bridges the rampway between a hull and a land. Between the way, there is a lifting deck and a lifting mechanism for moving the lifting deck up and down with respect to the hull, and the ramp way is around a first hinge portion provided at one end of the lifting deck. It is connected to be rotatable.

  As described above, in the ship for landing according to the present invention, the vertical position of the first hinge part (ramp hinge part) is changed by moving the elevator deck provided between the vehicle deck and the ramp way up and down. It becomes possible. That is, at the time of cargo handling work, the highest point (highest position) at which the rampway can be bridged can be increased by moving the elevator deck upward to raise the position of the first hinge part. That is, even if the length of the rampway is the same, it is possible to bridge over a higher land (quay) than a conventional landing ship. In other words, if the conditions of the highest point where the rampway required for the landing ship can be bridged are the same, the landing ship of the present invention is compared with the conventional landing ship, The length of the rampway can be shortened.

  Furthermore, since the vehicle deck on which the vehicle is mounted can be arranged at a low position, the center of gravity of the ship can be lowered, and a stable landing ship with a high restoring force can be obtained.

  Further, in the ship of the present invention, the position of the first hinge portion can be moved in the vertical direction, so that the rampway can be bridged while keeping the rampway inclination angle within a predetermined angle range. The range can be remarkably widened, and a highly versatile landing ship can be obtained.

  In the above-mentioned ship for landing, an inclined vehicle deck formed by a part or all of the vehicle deck is rotatably connected around a second hinge portion provided at the other end of the lift deck. When the tilt angle of the tilted vehicle deck changes following the vertical movement of the lift deck, the vehicle deck, the deck portion, and the rampway are always in a continuous state. Even when the vehicle moves, when the rampway is laid over the land, the vehicle deck to the land is always continuous. Therefore, even when there is a difference between the height of the vehicle deck and the height of the lifting deck, the inclined vehicle deck and the deck portion are continuous by the second hinge portion (inclined vehicle deck hinge). There is no step. Therefore, the vehicle can freely travel between the vehicle deck and the land, and a large number of vehicles can be quickly handled by a single vertical movement of the elevator deck.

  In the above-mentioned ship for landing, when it is configured to include a ballast water control device that controls the amount of ballast water injected into the ship according to the height position of the elevator deck, the elevator deck by the vertical movement of the elevator deck The center of gravity of the ship changes depending on the height of the rampway, but the center of gravity of the ship is always kept at a low position by controlling the amount of ballast water injected by the ballast water adjustment device according to the height of the elevator deck Can do. In other words, even when the elevator deck is moved upward during cargo handling, the ballast water is transferred from the upper ballast tank to the lower ballast tank, or the amount of the ballast water in the lower ballast tank is increased. By doing so, the increase in the center of gravity of the ship can be suppressed, so that the stability of the ship can be maintained and the stability can be ensured.

  In order to achieve the above object, a cargo handling method using a ship of the present invention includes a rampway, and a ship for landing that has a rampway and pierces or beaches and bridges the rampway between the hull and the land. In the cargo handling method to be used, an elevator deck provided between a vehicle deck and the rampway is moved up and down with respect to the hull using an elevator mechanism, and the first hinge part at one end of the elevator deck is moved around The ramp way is connected rotatably, corresponding to the height of the land over which the ramp way is bridged, the elevator deck is moved up and down according to the height of the land over which the ramp way is bridged, By changing the height of the first hinge portion, the inclination angle of the rampway spanning the land is adjusted.

  According to this method, since the height of the first hinge portion can be changed according to the height of the land over which the ramp way is bridged, the vertical range over which the ramp way can be bridged can be remarkably widened. . Therefore, it is possible to bridge the rampway on land of various heights.

  Moreover, even if the length of the rampway is the same, it is possible to bridge over a higher land than a conventional landing ship. In other words, if the conditions of the highest point where the rampway required for the landing ship can be bridged are the same, the landing ship of the present invention is compared with the conventional landing ship, The length of the rampway can be shortened.

  Furthermore, since the vehicle deck on which the vehicle is mounted can be arranged at a low position, the center of gravity of the ship can be lowered, and the cargo handling operation can be performed in a state where stability is maintained while maintaining the restoring force.

  In the above cargo handling method using a ship for landing, the hull is controlled by controlling the amount of ballast water injection of the ship according to the height position of the elevator deck and suppressing the center of gravity of the ship from becoming higher. If the stability of the ship is secured, the center of gravity of the ship changes depending on the height of the elevator deck and rampway by the vertical movement of the elevator deck, but the amount of ballast water injection is controlled by the ballast water adjustment device according to the height of the elevator deck By doing so, the center of gravity of the ship can always be maintained at a low position. In other words, even when the lifting deck is moved upward, the center of gravity of the ship can be lowered by increasing the amount of water injected to the ballast water, so that the reduction in restoring force can be suppressed, and cargo handling can be carried out while ensuring stability. Work can be done.

  According to the landing ship and the cargo handling method using the landing ship of the present invention, a configuration in which an elevator deck is provided between the vehicle deck and the rampway, and the elevator deck and the rampway are connected via a hinge portion. The height of this hinge part can be changed according to the height of the land over which the rampway is bridged, so that the range of land height over which the rampway can be bridged is remarkably wide. In addition, the ship's center of gravity can be kept low to suppress a reduction in restoring force, and landing work can be performed while ensuring sufficient stability.

1 is a side sectional view schematically showing a ship according to an embodiment of the present invention. It is a front view which illustrates the condition at the time of navigation of the ship of FIG. It is a front view which illustrates the condition during the cargo handling work of the ship of FIG. It is a sectional side view which shows typically the ship of another embodiment which concerns on this invention. It is side sectional drawing which shows typically the ship provided with the conventional ramp way.

  DESCRIPTION OF EMBODIMENTS Hereinafter, a landing ship and a cargo handling method using a landing ship according to embodiments of the present invention will be described with reference to the drawings. The landing ship according to the embodiment of the present invention is in a state of being in contact with the land such as the coast or the riverbank, or beached (landing) so as to run from the bow side, and the bow is on the coast or riverbank. The present invention can be employed in the case of a landing boat, a landing ship, a landing ship, etc. for landing a crew member and / or an onboard vehicle in a state where it is on board.

  As shown in FIGS. 1 to 3, a landing ship 1 (hereinafter referred to as a ship 1) according to an embodiment of the present invention includes a rampway (bow lamp) 7 and a vehicle 20 such as an automobile or a truck. Deck (Funakura) 4 is provided. In this embodiment, the ramp way 7 is provided on the bow 2 side, and the vehicle deck 4 is arranged at a position H1 higher than the planned draft DWL in the hull.

  The ship 1 includes an elevator deck 5 and an elevator mechanism 6 that moves the elevator deck 5 up and down relative to the hull between the vehicle deck 4 and the ramp way 7. The ramp way 7 is rotatably connected around a first hinge portion (lamp hinge portion) 8 provided at one end of the elevator deck 5. In other words, the elevation position of the first hinge portion 8 together with the elevation deck 5 can be changed by moving the elevation deck 5 up and down with respect to the hull by the elevation mechanism 6.

  In the ship 1 of this embodiment, a base 11 fixed to the hull is provided below the lift deck 5, and a column lift type lift mechanism 6 is installed on the base 11. The lift deck 5 is connected to the pillar lift type lift mechanism 6 and can move up and down from the same height as the vehicle deck 4 (position H1 higher than the planned draft DWL) to a position higher by H2 than the vehicle deck 4. It has become. The lifting mechanism 6 is not limited to the column lift type lifting mechanism 6, but includes various other configurations such as a jack type lifting mechanism 6 and a lifting type lifting mechanism 6 composed of a wire and a winch. The elevating mechanism 6 can also be adopted.

  During navigation when the rampway 7 is not used as a cargo handling facility, the rampway 7 is set to the same height as the vehicle deck 4 and the rampway 7 is closed as shown in FIG. It functions as a part of the outer plate portion of the bow 2.

  When the ramp way 7 constitutes a part of the outer plate portion of the bow 2 as in the ship 1 of this embodiment, the elevator deck 5 is moved upward to move the first hinge portion 8 upward. As shown in FIG. 3, an opening is created below the first hinge portion 8. Therefore, the vertical distance (height) H1 from the planned draft DWL to the position of the first hinge portion 8 with the ramp way 7 closed, in other words, the vertical distance H1 from the planned draft DWL to the vehicle deck 4 is It is good to set it as the range of 0.5 m or more and 3.0 m or less. In this case, even when the first hinge portion 8 moves upward, the lower end of the opening generated below the first hinge portion 8 is at a position higher than the wave height. Water becomes difficult to enter. In addition, it is preferable to provide an infiltration prevention structure such as a screen for preventing a wave from entering from the opening as necessary.

  The ship 1 according to this embodiment further includes a ballast water control device 9 that controls the amount of water injected into the ballast water BW of the ship 1 according to the height position of the ballast tank 10 and the elevator deck 5. Specifically, the ballast water control device 9 detects the height position of the lifting deck 5 (height difference H2 between the vehicle deck 4 and the lifting deck 5), and according to the height position of the lifting deck 5, The ballast tank 10 has a function of changing the amount and position of the ballast water BW in the ballast tank 10.

  Next, a method for carrying out cargo handling using this ship 1 will be described. In addition, in the following description, the case where the vehicle 20 mounted on the vehicle deck 4 of the ship 1 is landed on the land (the quay Q or the coast B) will be described as an example.

  As shown in FIG. 1, when a ship 1 is berthing or landing (beaching) on the land from the bow 2 side and the ramp way 7 is used as a cargo handling facility, first, the vehicle 20 mounted on the vehicle deck 4 is moved up and down. Move to above 5. Then, in accordance with the height of the land over which the ramp way 7 is bridged, the elevation deck 5 is moved up and down to change the height of the first hinge portion 8 so that the slope of the ramp way 7 over the land is tilted. Adjust the angle θ1. Then, the vehicle 20 is moved from the elevator deck 5 to the land through the ramp way 7 in a state where the change amount of the inclination angle in the travel distance of the vehicle 20 is within a predetermined angle range (−16 degrees ≦ θ1 ≦ 16 degrees) Let it land.

  In other words, when the ramp way 7 is laid over the land, the ramp way 7 is set so that the amount of change in the inclination angle in the path along which the vehicle 20 travels from the elevator deck 5 to the land is within a predetermined angle range. The elevation difference between the land and the first hinge portion 8 is reduced by moving the elevation deck 5 up and down by the elevation mechanism 6 according to the height of the land to be bridged. Then, the ramp way 7 is bridged over the land in a state where the height difference between the land and the first hinge portion 8, that is, the change amount of the inclination angle θ1 is small.

  Furthermore, in this embodiment, the elevator deck 5 is controlled by controlling the water injection amount of the ballast water BW of the ship 1 by the ballast water adjusting device 9 in accordance with the height of the elevator deck 5 to be moved up and down during cargo handling. The stability of the hull is secured by suppressing the rise of the center of gravity of the hull due to the rise of the hull.

  That is, the position of the center of gravity of the hull changes due to the change in the height of the elevator deck 5 and the ramp way 7 due to the vertical movement of the elevator deck 5, but the height position of the elevator deck 5 is detected by the ballast water adjusting device 9 and detected. The center of gravity of the hull is always maintained at a low position by changing the water injection amount and the water injection position of the ballast water BW according to the height of the lifted deck 5.

  Specifically, when the elevator deck 5 is moved upward, the ballast water BW is transferred from the ballast tank 10 located above to the ballast tank 10 located below, or the ballast water BW of the ballast tank 10 located below is Increase the amount. Conversely, when the elevator deck 5 is moved downward, the ballast water BW is transferred from the lower ballast tank 10 to the upper ballast tank 10 or the ballast of the lower ballast tank 10 as necessary. Decrease the amount of water BW.

  Thus, in the ship 1 of the present invention, the vertical position of the first hinge portion 8 can be changed by moving the elevator deck 5 provided between the vehicle deck 4 and the ramp way 7 up and down. That is, when carrying out cargo handling, the highest point (highest position) at which the ramp way 7 can be bridged is raised by moving the elevator deck 5 upward to raise the position of the first hinge 8. Can do.

  That is, even if the length of the ramp way 7 is the same, it is possible to bridge over a land higher than the conventional landing ship 1X (hereinafter referred to as the ship 1X) as shown in FIG. In other words, if the conditions of the highest point where the required ramp way 7 can be bridged are the same, the ship 1 of the present invention has a shorter length of the ramp way 7 than the conventional ship 1X. can do.

  Furthermore, in the ship 1 of the present invention, the position of the first hinge portion 8 can be moved in the vertical direction, so that the ramp way 7 can be laid while keeping the inclination angle θ1 of the ramp way 7 within a predetermined angle range. The up-and-down range that can be passed can be remarkably widened, and the ship 1 for landing can be made highly versatile.

  That is, in the conventional ship 1X, when the position of the ramp hinge portion 8 is increased, the lowest point (lowest position) that can be bridged below the ramp way 7 is the height obtained by moving the first hinge portion 8 upward. However, in the ship 1 of the present invention, the first hinge portion 8 (ramp hinge portion) is moved to a low position. It becomes possible to bridge the ramp way 7 to a low position.

  Further, in the ship 1 of the present invention, since the vehicle deck 4 on which the vehicle 20 is mounted can be arranged at a low position, the center of gravity of the ship 1 can be lowered, and the ship 1 with high stability and stability can be obtained. can do.

  That is, in the conventional ship 1X, if the position of the ramp hinge portion 8 is arranged at a high position so that the ramp way 7 can be bridged to a higher position, the vehicle deck 4 is also arranged at a high position. There is a problem that the center of gravity of the ship 1X becomes high and the restoring force of the ship 1X becomes small. However, in the ship 1 of the present invention, the first hinge portion is used when carrying out cargo handling with the vehicle deck 4 placed at a low position. Since the position of 8 can be made high, it is possible to make it possible to bridge the ramp way 7 to a higher position while keeping the center of gravity of the ship 1 at a low position.

  Furthermore, since the ship 1 according to this embodiment includes the ballast water control device 9 that controls the water injection amount of the ballast water BW of the ship 1 according to the height position of the elevator deck 5, the elevator deck 5 is moved upward. Even in the case of moving to the position, the center of gravity of the ship 1 can always be maintained at a low position, and the reduction of the restoring force can be suppressed. Therefore, cargo handling work can be performed in a state where stability is ensured.

  In addition, in the ship 1 of this embodiment, the method of controlling the water injection amount of the ballast water BW of the ship 1 according to the height position of the elevator deck 5 by the ballast water control device 9 is adopted. The center of gravity position of the ship 1 can be lowered by artificially increasing the water injection amount of the ballast water BW during the handling operation without using the ballast water control device 9. This method has an advantage that the position of the center of gravity of the ship 1 at the time of cargo handling can be lowered by a simple operation without controlling the ballast water. However, if the amount of ballast water injection of the ship 1 is controlled by the ballast water control device 9 according to the height position of the elevator deck 5 as in this embodiment, the change in the position of the center of gravity of the ship 1 is reduced. Therefore, the fluctuation of the rolling state of the ship 1 due to the vertical fluctuation of the center of gravity during the cargo handling work can be reduced, and deterioration of workability can be prevented.

  1-3, since the vehicle deck 4 and the raising / lowering deck 5 are not connected, if the raising / lowering deck 5 moves up and down, there will be a level | step difference between the vehicle deck 4 and the raising / lowering deck 5. FIG. However, the vehicle deck 4 and the lifting deck 5 are always connected to each other by connecting the vehicle deck 4 and the lifting deck 5 as in the ship 1A according to another embodiment of the present invention shown in FIG. You can also

  A ship 1A according to another embodiment has a second hinge portion (inclined vehicle deck hinge) 4c in which an inclined vehicle deck 4a formed by a part of the vehicle deck 4 is provided at the other end of the elevator deck 5. Is connected so as to be able to turn around, and the inclination angle θ2 of the inclined vehicle deck 4a changes so as to follow the vertical movement of the elevator deck 5.

  In other words, the vehicle deck 4 of the ship 1A includes a fixed vehicle deck 4b that is fixed at a fixed position, and a tilted vehicle deck 4a that changes the tilt angle θ2 following the vertical movement of the lift deck 5. The fixed vehicle deck 4b and the inclined vehicle deck 4a are pivotally connected via a third hinge part (vehicle deck hinge) 4d, and the other end parts (first The end portion on the opposite side of the hinge portion 8) is rotatably connected via the second hinge portion 4c.

  That is, when the elevator deck 5 moves up and down and a difference occurs between the height of the elevator deck 5 and the fixed vehicle deck 4b, the inclined vehicle deck 4a rotates around the second hinge part 4c and the third hinge part 4d. The inclination angle θ2 of the inclined vehicle deck 4a with respect to the elevator deck 5 (fixed vehicle deck 4a) changes, and the inclined vehicle deck 4a functions as an inclined surface that continuously connects the elevator deck 5 and the fixed vehicle deck 4a.

  When the elevator deck 5 moves up and down, the distance between the second hinge portion 4c and the third hinge portion 4d changes, and therefore, the tilted vehicle deck 4a has a mechanism for expanding and contracting the length of the tilted vehicle deck 4a. The elastic part 4e which has is provided.

  The movable range of the tilted vehicle deck 4a with respect to the lift deck 5 is desirably set so that the tilt angle θ2 is −16 degrees or more and 16 degrees or less. By setting the inclination angle θ2 to 16 degrees or less, the risk of the vehicle 20 hitting the stomach can be reduced.

  As in the case of the ship 1A according to this embodiment, when the inclined vehicle deck 4a that changes the inclination angle θ2 following the vertical movement of the lifting deck 5 is provided, the vehicle deck can be moved even when the lifting deck 5 moves up and down. 4, the elevator deck 5 and the ramp way 7 are always continuous. That is, there is no step between the inclined vehicle deck 4a and the lift deck 5. Therefore, even when the lifting deck 5 moves up and down with respect to the vehicle deck 4, the vehicle 20 can travel freely between the vehicle deck 4 and the land, and is often moved up and down once. It becomes possible to quickly carry out the cargo handling of the number of vehicles 20.

  In the ship 1A of this embodiment, a part of the vehicle deck 4 is constituted by the inclined vehicle deck 4a, but all of the vehicle deck 4 can also be constituted by the inclined vehicle deck 4a. That is, when the lifting deck 5 moves up and down, the entire vehicle deck 4 can be inclined.

  Further, in the ship 1 and the ship 1A of the embodiment shown in FIGS. 1 to 3 and FIG. 4 described above, the case where the ramp way 7 constitutes a part of the outer plate portion of the bow 2 is illustrated. A ship in which the rampway does not constitute the outer plate part, specifically, for example, the lampway is housed in the hull, and the lampway can be bridged by opening the bow door. The configuration of the present invention can also be adopted in a ship. It can also be used when the rampway is provided on the stern side.

1, 1A Ship (ship for landing)
1X Conventional ship (ship for landing)
2 Bow 3 Stern 4 Vehicle deck (Hunakura)
4a Inclined vehicle deck 4b Fixed vehicle deck 4c Second hinge part (inclined vehicle deck hinge)
4d Third hinge (vehicle deck hinge)
4e Telescopic part 5 Elevating deck 6 Elevating mechanism 7 Rampway 8 First hinge part (ramp hinge part)
9 Ballast water control device 10 Ballast tank
11 base 20 vehicle (truck)
DWL Plan draft Q Quay B Coast BW Ballast water

Claims (5)

In a ship for landing that has a rampway, pierces or beaches and bridges the rampway between the hull and the land,
A first deck provided between a vehicle deck and the ramp way and a lifting mechanism for moving the lifting deck up and down relative to the hull, wherein the ramp way is provided at one end of the lifting deck. A ship for landing that is rotatably connected around a hinge part.   An inclined vehicle deck formed by a part or all of the vehicle deck is pivotally connected around a second hinge portion provided at the other end of the lift deck so that the lift deck can be moved up and down. The ship for landing according to claim 1, wherein the ship is configured to change the inclination angle of the inclined vehicle deck following the inclination.   The ship for landing according to claim 1 or 2, further comprising a ballast water control device that controls a water injection amount of the ship according to a height position of the elevator deck. In a cargo handling method using a ship for landing that has a rampway, pierces or beaches and bridges the rampway between the hull and the land,
The elevator deck provided between the vehicle deck and the rampway is moved up and down with respect to the hull using the elevator mechanism, and the rampway is rotated around the first hinge portion at one end of the elevator deck. Connect as possible
Corresponding to the height of the land over which the rampway is crossed, the elevation deck is moved up and down, and the height of the first hinge portion is changed to change the inclination angle of the rampway over the land. A cargo handling method using a ship for landing characterized by adjusting.   The amount of ballast water injection of the ship is controlled according to the height position of the lift deck to suppress an increase in the center of gravity of the hull and ensure the stability of the hull. 4. A cargo handling method using the ship for landing described in 4.

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