WO2011013883A1 - Balance-maintaining crane and vessels on which the same is mounted - Google Patents

Abstract

The present invention relates to a crane which can maintain its balance regardless of the rocking of a vessel by using the concept of zero moment, and to vessels on which the same is mounted and which can load and unload cargo at sea far from land. Provided is a crane comprising: a horizontal structure which is provided in such a way as to allow a trolley to move transversely; a first column which supports the horizontal structure at a point constituting moment zero in the transverse direction; a second column which is provided at a distance from the first column and supports one end of the horizontal structure; a second support which is provided on the second column so as to allow the vertical height of the second column to be adjusted; and a base which supports the first column and the second column. By means of support using the zero moment point, the present invention allows precise balance control because balance can be maintained even without applying substantial force to a hydraulic cylinder.

Description

Balancing crane and ship equipped with it

The present invention relates to a marine crane, a crane capable of maintaining a balance regardless of the shaking motion of the marine vessel by using the concept of zero moment, and a marine vessel equipped with the crane capable of unloading the marine vessel off the land.

As a means of transporting merchandise at remote locations, maritime transportation using vessels uses less energy than other means of transportation, and transportation costs are cheaper, so much of international trade relies on maritime transportation.

Recently, in the case of marine transportation such as container ships, a large-sized vessel is used in order to improve the efficiency of transportation. This is to secure the economical efficiency of transportation by increasing the volume of the vessel. As a result, there is a growing demand for ports with mooring facilities and loading facilities capable of berthing large ships.

However, ports that can berth large container ships are limited at home and abroad, and construction of such ports requires a lot of expenses as well as a large space. In addition, due to the construction of the large port, the surrounding environment such as the traffic congestion and the destruction of the coastal environment are greatly affected, and there are many restrictions on the construction of the large port.

Therefore, the invention relating to a moving port (mobile harbor, mobile harbor) and a cargo transfer method using the same, which can ship and freight freight without berthing a large ship at the seawall in the port, Registration No. 10-0895604).

1 and 2 show a schematic view of a moving port shown in the patent, wherein the moving port 10 can perform a loading operation using a crane 20, And the large container line 30, and Fig. 2 shows the unloading between the moving port 10 and the pier 40. As shown in Fig.

Cargo loading and unloading is a task to move cargoes ranging from several tons to several tens of tons. Therefore, it is urgently required to maintain equilibrium between a ship acting as a moving port and a crane installed in it. However, the influence of wind, It is necessary to have a crane having a structure in which the equilibrium can be maintained while the vessel is working in the sea despite the fluctuation.

It is an object of the present invention to provide a crane capable of stably loading and unloading with other vessels so that the horizontal or vertical position of the crane can be maintained in correspondence with the rolling, pitching or heaving motion of the vessel, and a vessel equipped with the same .

In order to achieve the above object, the present invention provides a trolley comprising: a horizontal structure in which a trolley is installed so as to be transported in a lateral direction; a first column supporting the horizontal structure at a point where a lateral moment becomes zero; A second column provided at an interval to support one end of the horizontal structure, a second column provided in the second column to adjust the height of the second column in the vertical direction, A crane comprising a base supporting two columns is provided. The second support base is height-controlled so as to maintain a horizontal state of the horizontal structure in correspondence with the rolling and pitching motion of the base, or the second base supports the trolley in a vertical position corresponding to the freezing motion of the base Can be controlled as high as possible.

The crane may further include a first support provided on the first column to adjust a height of the first column in a vertical direction. The first and second supports may be height-controlled so as to maintain the horizontal state of the horizontal structure and the vertical position of the trolley in correspondence with the rolling, pitching, or heaving motion of the base.

The crane may further include a zero moment body provided at a lower end of the first column and supported at a point where the longitudinal moment becomes zero. The zero moment body can be supported by a universal joint or a spherical joint at a point where the longitudinal moment becomes zero. Also, the zero moment body can be supported at one or both ends in the longitudinal direction by a height adjustable auxiliary support. A spring-damper structure may be provided in parallel with the auxiliary support to facilitate control of the auxiliary support. The auxiliary support may be height-controlled so that the zero moment body is kept horizontal in correspondence to the pitching motion of the base. On the other hand, the first pillar can be supported and supported by a vibration insulation part having a spring-damper structure.

Furthermore, the crane may further include a balance that can be transferred so that the lateral moment applied to the first column is zero. The base may include first and second movable bases supporting the first and second pillars, respectively. The distance between the first and second pillars including the first and second bases can be made very small. The present invention provides a ship on which the crane described above is installed. At this time, the first and second bases can be installed on both lateral sides of the ship and can be moved in the longitudinal direction. Specifically, the first and second bases have wheels, and the wheels can be designed to be movable on rails provided on both lateral sides of the ship but not separated from the rails.

According to another aspect of the present invention, there is provided a trolley comprising: a horizontal structure in which a trolley is installed so as to be transported in a lateral direction; a first column supporting the horizontal structure; a first column disposed at a lower end of the first column, A plurality of supports for supporting one end or both ends of the zero moment body in the transverse direction, one end or both ends of the longitudinal direction of the zero moment body so as to be adjustable in height, and a base for supporting the zero moment body and the plurality of supports Provide a crane containing.

The plurality of supports may be height-controlled such that a horizontal state of the horizontal structure or a vertical position of the trolley is maintained corresponding to at least one of movement, heaving, rolling or pitching of the base. Further, the zero moment body can be supported by a universal joint or a spherical joint at a point where the longitudinal moment becomes zero, and the first column can be vibration-isolated by the spring-damper structure. And may further include a transferable balance such that the lateral moment applied to the first column is zero.

In addition, the present invention is not limited to a crane but includes a lower body swinging, an upper body supported by the lower body at a position where a moment in a direction becomes zero, and upper and lower ends of the upper body The present invention provides a zero moment structure including a body support that allows directional height adjustment.

According to the present invention, there is also provided a pneumatic tire comprising: a swinging lower body; an upper body supported by the lower body at a point where a two-direction moment becomes zero; A zero moment structure is also provided that includes a body support that allows adjustment.

Here, the body support may be height-controlled to maintain the horizontal state of the upper body corresponding to the swinging motion of the lower body. The upper body is supported by a universal joint or a spherical joint at a moment where the moment becomes zero, and the upper body can be vibration-isolated by a spring-damper structure.

According to the crane of the present invention, the horizontal structure of the horizontal structure and the vertical position of the trolley are maintained in correspondence with the swinging motion of the base, so that a stable unloading operation is possible. According to the ship equipped with the crane according to the present invention, the horizontal or vertical position of the crane can be maintained in correspondence with the movement of the ship such as pitching, rolling or heaving, thereby enabling stable cargo unloading with other vessels.

The crane according to the present invention can maintain the equilibrium without applying a large force to the hydraulic cylinder through the support by the zero moment point, so that accurate equilibrium holding control becomes possible.

In addition, the ship according to the present invention can efficiently handle the cargo transportation of a very large ship requiring deep water depth, and can function as a moving port, thereby contributing to enhancement of the competitiveness of the port system in the future.

Further, the present invention can be applied to a case where the upper body supported by the lower body having the swing is a system in which there is no movement like a precision device, so that the horizontal state of the upper body can be maintained.

1 and 2 are views showing a schematic view of a moving port shown in a conventional patent.

3 and 4 are schematic diagrams showing the concept of equilibrium maintenance using zero moment points.

5 is a configuration diagram showing the structure of a balancing crane according to an embodiment of the present invention.

6 is a configuration diagram showing the structure of a ship equipped with a balancing crane according to an embodiment of the present invention.

7 is a view showing a ship performing a loading and unloading operation with another ship according to an embodiment of the present invention.

Hereinafter, the structure and operation principle of a balancing crane and a ship equipped with the balancing crane according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following specific embodiments are illustrative only of the zero moment structure, crane and vessel according to the present invention, and are not intended to limit the scope of the invention. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

3 and 4 are schematic diagrams showing the concept of equilibrium maintenance using zero moment points.

Referring to FIG. 3, the upper body 70 is installed on the lower body 60, and the upper body 70 is supported at a position where the weight is balanced and the moment becomes zero. A swingable body joint 65 connects the lower body 60 and the upper body 70 and both ends of the upper body 70 are supplementarily supported by a body support 75 such as a hydraulic cylinder. Here, the body support 75 need not always be present at both ends, but a more stable equilibrium holding can be made in the case of both end supports.

As shown in FIG. 4, a body support 75 such as a hydraulic cylinder is installed in another direction to maintain the balance of the upper body 70 three-dimensionally. At this time, the body joint 65 will be composed of a joint capable of turning in two directions, such as a universal joint.

A vibration isolating portion 68 having a spring-damper structure is added between the upper body 70 and the lower body 60 to vibrate and isolate the upper body 70 from high frequency vibrations, Control may be made easier. It is also possible to provide a vibration isolator 68 in parallel with the body support 75 to help balance the upper body 70 by reducing the control force of the body support 75. The spring-damper structure may be provided using a variety of methods such as a rigid spring or air cushion or rubber.

Although the upper body 70 is shown as an inverted triangle or an inverted pyramid for the sake of simplicity, the upper body 70 can be applied regardless of the shape of the upper body 70 as long as the moment is zero.

The upper body 70, through the body joint 65, has the most weight, if it is a support at the full zero moment point, all the weight is mathematically supported and less force is applied to both ends, It is possible to control the movement of the upper body 70 as well. Accordingly, the upper body 70 can be held in a precisely horizontal state despite the swinging motion of the lower body 60.

Here, the support at the zero moment point is a concept that includes not only the mathematical zero moment is fully applied but also the support at the center of gravity or near the center. As an application, the lower body 60 is a vessel such as a warship, and the upper body 70 can be applied to a system in which there is no movement, such as a precision device such as a radar or a projectile, Anything that uses the principles presented can be applied.

The present invention seeks to apply such a zero moment point concept (or center support concept) to a crane installed on a ship. At this time, the vessel swinging in the sea can be regarded as the lower body 60, and the crane installed on the vessel can be regarded as the upper body 70.

5 is a configuration diagram showing the structure of a balancing crane 100 according to an embodiment of the present invention. The coordinates define the x direction as the longitudinal direction and the y direction as the lateral direction.

The balancing crane 100 according to an embodiment of the present invention includes a horizontal structure 130 in which a trolley 138 is installed so as to be transported in a lateral direction and a horizontal structure 130 in which a horizontal structure 130 is substantially zero A second pillar 120 spaced apart from the first pillar 110 to support one end of the horizontal structure 130 and a second pillar 120 provided to the second pillar 120 A second support 122 for adjusting the height of the second column 120 in the vertical direction and a crane 100 including a base for supporting the first column 110 and the second column 120 do.

The second support base 122 is height-controlled so as to maintain the horizontal state of the horizontal structure 130 in response to the rolling motion of the base or the second support base 122 is controlled in the heaving motion of the base by the action of the control unit 140 The height of the trolley 138 can be controlled so that the vertical position of the trolley 138 is maintained.

The crane 100 may further include a first support 112 provided on the first pillar 110 to adjust the height of the first pillar 110 in the vertical direction. The first and second support members 112 and 122 are moved in the horizontal direction of the horizontal structure 130 and the vertical position of the trolley 138 in accordance with the rolling or heaving motion of the base Can be height-controlled to be maintained.

Here, the trolley 138 is transportable through a track (not shown) installed on the horizontal structure 130, and can load cargo. The first support 112 or the second support 122 may be configured to include a hydraulic cylinder. The second support 122 may be guided by a guide body 126, such as a linear guide or linkage structure. Although not shown, the first support 112 may also be guided by a linear guide or linkage structure. Furthermore, the first support 112 or the second support 122 may increase the stability of the structure by arranging a plurality of hydraulic cylinders in an oblique arrangement. Also, the structural rigidity of the crane 100 may be reinforced by the reinforcing beam 139, the reinforcing ropes 134 and 135, and the like. The horizontal structure 130 of the crane 100 may have a rope and a winch system which is attached to a hinge near the intermediate point and folds and rotates by 180 degrees so as to have a simple and stable shape when moving or not performing work. Here, the hinge may be the connection part 133 and the rotation direction may be the sky direction, but the rotation in the horizontal direction is also possible.

The crane 100 may further include a zero moment body 116 provided at a lower end of the first column 110 and supported at a position where the longitudinal moment becomes zero. The zero moment body 116 can be supported by the support joint 117 at a point where the longitudinal moment is zero and the support joint 117 can be tilted in the longitudinal or transverse direction , And may be supported by, for example, a universal joint or a spherical joint. In addition, the zero moment body 116 can be supported by a height adjustable auxiliary support 118 at one or both ends in the longitudinal direction. Stability can be increased if both ends are supported. Here, by the action of the control unit 140, the auxiliary support 118 can be height-controlled so that the zero moment body 116 is kept horizontal in correspondence to the pitching motion of the base.

 On the other hand, the first pillar 110 can be insulated from vibration, which is not subject to control, by installing a vibration isolator 119 having a spring-damper structure in series. The spring-damper structure mainly serves to isolate high-frequency vibration. In addition, the vibration isolation portion 119 of the spring-damper structure may be installed in parallel with the auxiliary support 118 to reduce the control force of the auxiliary support 118. [ The spring-damper structure can be provided using various materials and methods such as a rigid spring, air cushion, rubber, and the like.

The connecting portions 132 and 133 to which the first and second pillars 110 and 120 are connected to the horizontal structure 130 may be formed in a pivotable structure. A hydraulic cylinder (not shown) may be added to the connecting portions 132 and 133, which are freely rotatable so as to be capable of turning, so that the shape can be maintained without receiving large moments. Thus, even if there is relative movement between the first and second columns 110 and 120 and the horizontal structure 130, the first and second columns 110 and 120 can be tilted or turned without interfering with each other.

Further, the crane 100 may further include a conveyable balance 136 such that the lateral moment applied to the first pillar 110 is zero. When the weight applied to the horizontal structure 130 such as the conveyance of the trolleys 138 and the load of the horizontal structure 130 is changed, the balance 136 is conveyed or unattached in a direction compensating the balance so that the lateral moment becomes zero.

In addition, the base may include a first base 114 and a second base 124 that support the first column 110 and the second column 120, respectively. The first and second bases 114 and 124 may be provided with wheels 115 and 125 for movement. The first and second bases 114 and 124 may be installed close to each other and the wheels 115 and 125 may be installed close to each other below the first base 114.

Furthermore, when the base is integrated, the second column 120 and the second support 122 may be installed on the zero moment body 116, and the second column 120 and the first column 110 may be integrally formed It can also be produced. Also, the second support rods 122 are installed on both lateral ends of the zero moment body 116 to maintain the equilibrium of the crane three-dimensionally. That is, the first column 110 is supported on the two-dimensional or three-dimensional zero moment body 116. In this case, the support for supporting the zero moment body 116 together with the first pillar 110 may have the same structure as the body support 75 for controlling the upper body 70 of FIG. 3 or FIG.

The horizontal structure of the horizontal structure 130 and the vertical position of the trolley 138 are maintained in accordance with the swinging motion of the base according to the crane 100 according to the present invention, In particular, the equilibrium can be maintained without applying a large force to the hydraulic cylinder through the support by the zero moment point, so that accurate equilibrium holding control becomes possible.

6 is a configuration diagram showing the structure of a ship 150 equipped with a balancing crane 100 according to an embodiment of the present invention. Here, the longitudinal direction and the lateral direction of the ship 150 are both lateral directions of the ship 150.

A platform 152 on which the cargo can be loaded is provided on the upper part of the ship 150. The first and second bases 114 and 124 support the first pillar 110 and the second pillar 120 respectively and are installed on both lateral sides of the ship 150 to be movable in the longitudinal direction. Rails 154 are provided on both sides of the ship 150 so that the wheels 115 and 125 provided on the first and second bases 114 and 124 can move along the rails 154. It is a matter of course that the distance between the first base 114 and the second base 124 can be set smaller than the width of the ship 150. Moreover, it can be made extremely close to extreme. The driving unit 156 may be implemented in various ways, such as a motor (not shown) that provides power to move the crane 100 and a wire transport system (not shown) that uses ropes and winches. For additional safety, the wheels 115, 125 may be designed to have a structure such as a cart that is transported on the rails 154 or a sliding office desk drawer so that they can move on the rails 154 but not separate.

Meanwhile, the ship 150 according to an embodiment of the present invention adjusts the hydraulic cylinders of the first and second support rods 112 and 122 to reduce the height of the crane at the time of sailing to reduce the resistance at the time of sailing, . The horizontal structure 130 of the crane 100 may have a rope and a winch system which is attached to a hinge near the intermediate point and folds and rotates by 180 degrees so as to have a simple and stable shape when moving or not performing work. Here, the hinge may be the connection part 133 and the rotation direction may be the sky direction, but the rotation in the horizontal direction is also possible.

7 is a view showing a state in which a ship 150 performs an unloading operation with another container line S according to an embodiment of the present invention.

The side surface of the ship 150 and the side surface of the container line S are tilted and the crane 100 is extended in the direction of the container line S to perform the unloading operation of the cargo C. The trolley 138 moves along the horizontal structure 130 by loading the cargo C and the balance 136 maintains the moment applied to the first pillar 110 at zero.

At this time, the ship 150 rocks due to the influence of the wind, the waves, or the algae in the sea. Rolling, pitching, and the like are included in the rocking motion. In spite of such rocking motion, the horizontal state of the crane 100 or the absolute horizontal position of the trolley 138 must be maintained so that the unloading operation of the cargo C can be performed smoothly.

For example, even if there is pitching of the ship 150, the crane 100 desires to avoid pitching. The control unit 140 adjusts the angle between the first base 114 and the zero moment body 116 by sensing the pitch of the ship 150 and adjusting the hydraulic pressure of the hydraulic cylinder constituting the auxiliary support 118, The horizontal structure 130 can be kept horizontal. The second support platform 122 is controlled in height so as to maintain the horizontal structure 130 in a horizontal state in response to the rolling motion of the ship 150 or to cope with the heaving motion of the ship 150 So that the trolley 138 can be height-controlled to maintain its vertical position.

According to the ship equipped with the crane according to the present invention, the horizontal position and the vertical position of the crane are maintained in correspondence with the movement of the ship such as pitching, rolling or heaving, so that stable cargo unloading with other container lines is possible. The ship according to the present invention can efficiently handle cargo transportation of a container ship requiring deep water depth and can function as a moving port, thereby contributing to enhancement of competitiveness of the port system in the future.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it should be understood that the invention is not limited thereto and may be embodied in many different forms and forms without departing from the spirit and scope of the invention as defined by the appended claims. Should be interpreted. Skilled artisans may vary the material, size, etc. of each component depending on the application, and may combine or replace the disclosed embodiments to effect a pattern of a shape that has not been noted, but this is also within the scope of the present invention. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (36)

1. A horizontal structure in which a trolley is installed so as to be transported in the lateral direction,

   A first column supporting the horizontal structure at a point where a lateral moment becomes zero,

   A second column spaced apart from the first column and supporting one end of the horizontal structure,

   A second support provided on the second column to adjust a height of the second column in a vertical direction,

   And a base supporting the first column and the second column

   Included crane.
2. The method according to claim 1,

   And the second support is controlled in height so as to maintain the horizontal state of the horizontal structure in response to the rolling motion of the base.
3. The method according to claim 1,

   Wherein the second support is height-controlled so as to maintain the vertical position of the trolley in correspondence to the freezing motion of the base.
4. The method according to claim 1,

   And a first support provided on the first column to adjust a height of the first column in a vertical direction.
5. 5. The method of claim 4,

   Wherein the first support and the second support are height-controlled so as to maintain a horizontal state of the horizontal structure and a vertical position of the trolley in correspondence with the rolling or heaving motion of the base.
6. 6. The method according to any one of claims 1 to 5,

   And a zero moment body provided at a lower end of the first column and supported at a point where the longitudinal moment becomes zero.
7. The method according to claim 6,

   Wherein the zero moment body is supported by a universal joint or a spherical joint at a point where the longitudinal moment becomes zero.
8. The method according to claim 6,

   Wherein the zero moment body is supported at one or both ends in the longitudinal direction by a height adjustable auxiliary support.
9. 9. The method of claim 8,

   Wherein the auxiliary support is height-controlled to correspond to the pitching motion of the base such that the zero moment body is horizontal.
10. 9. The method of claim 8,

    And a vibration insulation unit having a spring-damper structure is installed on the zero moment body together with the auxiliary support.
11. 6. The method according to any one of claims 1 to 5,

    Wherein the first column is supported by a vibration isolation portion having a spring-damper structure.
12. 6. The method according to any one of claims 1 to 5,

    Further comprising a balance capable of being traversed such that a lateral moment applied to the first column is zero.
13. 6. The method according to any one of claims 1 to 5,

    Wherein the base includes first and second movable bases each supporting a first pillar and a second pillar.
14. 6. The method according to any one of claims 1 to 5,

    Said horizontal structure being foldable by providing a hinge in the middle thereof.
15. A horizontal structure in which a trolley is installed so as to be transported in the lateral direction,

    A first column supporting the horizontal structure,

    A zero moment body provided at a lower end of the first column and supported at a position where the lateral and longitudinal moments are zero,

    A plurality of supports for supporting one end or both ends in the transverse direction of the zero moment body so as to be adjustable in height,

    Wherein said zero moment body and said base supporting said plurality of supports

    Included crane.
16. 16. The method of claim 15,

    Wherein the plurality of supports is height-controlled so as to maintain a horizontal state of the horizontal structure or a vertical position of the trolley in correspondence with any one or more of movement of the base, i.e., heaving, rolling or pitching of the base.
17. 16. The method of claim 15,

    And a vibration isolation portion having a spring-damper structure is installed on the zero moment body together with the support.
18. 18. The method of claim 17,

    Wherein the first column is supported by a vibration isolation portion having a spring-damper structure.
19. 19. The method according to any one of claims 15 to 18,

    Wherein the zero moment body is supported by a universal joint or a spherical joint at a point where the longitudinal moment becomes zero.
20. 19. The method according to any one of claims 15 to 18,

    Further comprising a balance capable of being traversed such that a lateral moment applied to the first column is zero.
21. A horizontal structure in which a trolley is installed so as to be transported in the lateral direction,

    A first column supporting the horizontal structure at a point where a lateral moment becomes zero,

    A second column spaced apart from the first column and supporting one end of the horizontal structure,

    A second support provided on the second column to adjust a height of the second column in a vertical direction,

    And a base for supporting the first column and the second column,

    Wherein the first support is controlled in height such that the horizontal structure of the horizontal structure or the vertical position of the trolley is maintained in correspondence with the rolling or heaving motion of the ship.
22. 22. The method of claim 21,

    The crane further includes a first support provided on the first column to adjust a height of the first column in a vertical direction,

    Wherein the first support and the second support are height-controlled such that the horizontal structure of the horizontal structure and the vertical position of the trolley are maintained in correspondence with the rolling or heaving motion of the ship.
23. 23. The method of claim 21 or 22,

    Wherein the crane further comprises a zero moment body provided at a lower end of the first column and supported at a point where the longitudinal moment becomes zero,

    Wherein one end or both ends of the zero moment body are supported by a height adjustable auxiliary support,

    Wherein the auxiliary support is height-controlled such that the zero moment body is leveled to correspond to the pitching motion of the ship.
24. 23. The method of claim 21 or 22,

    Wherein the crane further comprises a balance capable of being conveyed such that the lateral moment applied to the first column is zero.
25. 23. The method of claim 21 or 22,

    Wherein the base comprises first and second bases supporting the first column and the second column respectively and provided on both lateral sides of the ship, the first and second bases being movable in the longitudinal direction.
26. 26. The method of claim 25,

    Wherein the first and second bases have wheels,

    Wherein the wheel is movable on a rail provided on both lateral sides of the ship but is not separated from the rail.
27. A horizontal structure in which a trolley is installed so as to be transported in the lateral direction,

    A first column supporting the horizontal structure,

    A zero moment body provided at a lower end of the first column and supported at a position where the lateral and longitudinal moments are zero,

    A plurality of supports for supporting one end or both ends in the transverse direction of the zero moment body so as to be adjustable in height,

    Wherein said zero moment body and said base supporting said plurality of supports

    A ship equipped with a crane.
28. 28. The method of claim 27,

    Wherein the plurality of supports are height-controlled so as to maintain a horizontal state of the horizontal structure or a vertical position of the trolley in correspondence with any one or more of the heaving, rolling or pitching of the base.
29. 29. The method of claim 27 or 28,

    Further comprising a balance capable of being conveyed so that the lateral moment applied to the first column becomes zero.
30. 29. The method of claim 27 or 28,

    The base includes a wheel,

    Wherein the wheel is movable on a rail provided in the lateral direction of the ship, but is not separated from the rail.
31. A swinging lower body,

    An upper body supported by the lower body at a point where the one-direction moment becomes zero,

    A body support for adjusting the vertical height of the upper body at one or both ends of the upper body;

    Including zero moment structure.
32. A swinging lower body,

    An upper body supported by the lower body at a point where the two direction moments become zero,

    A body support for adjusting the vertical height of the upper body at one or both ends of the upper body in two directions,

    Including zero moment structure.
33. 33. The method according to claim 31 or 32,

    Wherein the body support is height-controlled to maintain the horizontal state of the upper body corresponding to the swinging motion of the lower body.
34. 33. The method according to claim 31 or 32,

    Wherein the upper body is provided with a vibration insulation portion having a spring-damper structure together with the body support.
35. 35. The method of claim 34,

    Wherein the upper body is supported by a vibration isolation portion having a spring-damper structure.
36. 33. The method according to claim 31 or 32,

    Wherein the upper body is supported by a universal joint or a spherical joint at a moment where the moment becomes zero.

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