EP0521984A1 - Mooring system - Google Patents

Mooring system

Info

Publication number
EP0521984A1
EP0521984A1 EP19910906929 EP91906929A EP0521984A1 EP 0521984 A1 EP0521984 A1 EP 0521984A1 EP 19910906929 EP19910906929 EP 19910906929 EP 91906929 A EP91906929 A EP 91906929A EP 0521984 A1 EP0521984 A1 EP 0521984A1
Authority
EP
European Patent Office
Prior art keywords
mooring
coupling means
movable
ship
forces
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP19910906929
Other languages
German (de)
French (fr)
Inventor
Lennart Apelstrand
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
NORENT AB
Original Assignee
NORENT AB
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by NORENT AB filed Critical NORENT AB
Publication of EP0521984A1 publication Critical patent/EP0521984A1/en
Withdrawn legal-status Critical Current

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B63SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
    • B63BSHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING 
    • B63B21/00Tying-up; Shifting, towing, or pushing equipment; Anchoring
    • EFIXED CONSTRUCTIONS
    • E02HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
    • E02BHYDRAULIC ENGINEERING
    • E02B3/00Engineering works in connection with control or use of streams, rivers, coasts, or other marine sites; Sealings or joints for engineering works in general
    • E02B3/20Equipment for shipping on coasts, in harbours or on other fixed marine structures, e.g. bollards
    • E02B3/24Mooring posts

Definitions

  • the present invention refers to a mooring system between a movable unit, e.g. ship and a stationary unit, e.g. a quay, and which system comprises partly a mooring device consis ⁇ ting of a robot arm movable in the vertical direction which arm is provided with coupling means at one of the units and partly a mooring armature for receiving and fixation of the coupling means at the other unit.
  • the object of the present invention is to provide an active mooring device, which is structurally simple, which in principle consists of only one actuator, e.g. a hydraulic cylinder, which gives a possibility of a relatively long retracting distance. Further it has to be designed such that no bending moments are transmitted to the actuating device, on the ship side it should have a very small installation depth and there should be a possibility for mounting ex ⁇ ternally along the ship fender ledge. The device further should be designed such that it does not demand any greater precision at the landing and in passive position it should be protected inside the ship fender line of the quay.
  • a actuating device which is movable in the hori ⁇ zontal direction (z-direction), preferably actuable during the whole mooring phase, and that a device is connected to the coupling means, for absorbing of lateral forces acting on the extreme free end of the actuating device (lateral ship forces), so that substantially no bending moments are transmitted to the actuating device, and that said device is ' constituted by bendable means, provided to act on the coup- ling means and which are intended to transmit said forces to either of the units or to both of the units.
  • Fig.l shows in a diagrammatical view from the above of a ferry which has landed at a quay and is moored by means of the devices according to the present invention.
  • Fig. 2a-2g shows in seven lateral views maneuvering sequen ⁇ ces at mooring of a ship, whereby fig. 2a shows the mooring. device in a protected position inside the ship fender line, fig. 2b during adjustment of the vertical position relative ⁇ ly the ship, respectively the water surface, fig. 2c shows the device during pushing out of the mooring cylinder, fig. 2d pivoting out of the mooring cylinder, fig. 2e position finding of the mooring armature at the ship, fig. 2f hauling of the ship by means of the mooring cylinder and fig. 2g the ship in mooring position.
  • Fig. 3 shows in larger scale a first variant in a view from the front of a mooring device according to the invention.
  • Fig. 4 shows a section along the line IV-IV in fig. 3.
  • Fig. 5 shows a lateral view of the mooring device illustra ⁇ ted in fig. 3.
  • Fig. 6 is a section along the line VI-VI in fig. 4.
  • Fig. 7 shows the mooring armature illustrated in fig. 4 in a view from the front and partly in section.
  • Fig. 8 shows a section along the line VIII-VIII in fig. 7.
  • Fig. 9 shows in perspective view a second embodiment, of the mooring device according to the invention.
  • Fig. 10 shows the mooring device according to fig. 9 in a view from the front.
  • Fig. 11 is a section along the line XI-XI in fig. 10.
  • Fig. 12 is a section along the line XII-XII in fig. 10
  • Fig. 13 shows a section along the line XIII-XIII in fig. 12.
  • Fig. 14 shows a view from the above of the mooring armature and the coupling means illustrated in fig. 13.
  • fig. 1 is shown an embodiment of how the mooring device according to the invention can be used for mooring of two units 10,11, of which one can be a ship-, a ferry, a barge or some other floating object, while the other unit can be constituted by a quay, kevel head, an oil-rig or the like, that is a stationary plant.
  • a type of mooring device 12 at the bow which is exposed only to small angular deviations and a mooring device 13 with a spring function at the stern of the ship.
  • the ship - the railway ferry - is equipped with a movably mounted ferry flap 14 , which locks the ship at the quay in such a way, that it also absorbs longitudinal ship forces.
  • a movably mounted ferry flap 14 which locks the ship at the quay in such a way, that it also absorbs longitudinal ship forces.
  • only one mooring device 12 is required at the bow, which absorbes cross ship forces and smaller deviations from these, and a mooring device 13, which also can absorb longtudinal ship forces.
  • the embodiment shown in figures 3-6 consists of a mooring device 15 provided at the stationary unit, that is the quay
  • a robot arm 20 which in the embodiment shown is constituted by an actuator 21, e.g. a hydraulic cylinder, which is pivotably arranged on bearings such that it has at least two, at least three degrees of freedom, that is a large mobility in the vertical plane - the Y-axis .-, limited mobility in the vertical plane
  • the robot, slider 19 which supports the robot arm 20, is by way of a wire, cable or chain arrangement 22 and pulleys 23 counter balanced by means of weights 24.
  • a driving device 25, fig. 6 which acts on one of the pairs of pulleys 23, the elevation of the slider 19 can be changed.
  • the robot arm is pivotable about its horizontal axis 26 by means of a second actuator 27, which as well can be a hyd ⁇ raulic piston cylinder.
  • a coupling means 28 formed as a hook with a relatively large curved contact surface for a mooring armature 29 arranged at the second unit 10- the ship.
  • this is constituted by .
  • the connection means between the bendable means 30 and the tension springs 31 are formed with a guide 33, which coope ⁇ rates with a slot 34, which limits the extension length of the tension spring.
  • the bendable means 30 takes a straight position, protected by the ship fender line or.shell plating, so that the hook-formed coup ⁇ ling means 28 can grip behind the wire, such as is shown in fig. 4.
  • FIG. 2a shows the moo ⁇ ring device with the robot arm folded up to a protected position inside the outer edge of the quay, which normally is a fender arrangement not shown.
  • the mooring device 15 is manipulated by means of radio signals whereby as a first measure an adjustment is carried out of the elevation of the robot arm.
  • This eleva ⁇ tion adjustment can be performed either against one or several direction marks at the shell plate of the ship or with reference to the present water surface.
  • This sequence is shown in fig. 2b.
  • a second embodiment of the invention is shown in fig. 9, which in many parts are similar to the embodiment according to figures 3-8 and for those parts which are alike in both embodiments the same reference designations also have been used. What differs both embodiments is the mooring device according to fig. 9 being completed with a spring function and that the robot arm 20 is movable in the horizontal plane For this purpose are provided linear guides 35 at the sta ⁇ tionary unit 11, along which guides a slider 49 is displace- able.
  • the spring function of the mooring device is provided by stays 36 directed in opposite directions and articulatedly joined to the coupling means 28 of the robot arm 20, which stays at their opposite ends are connected each to a hydrau- lie power apparatus 37 by a pulley 38.
  • the cylinders of the robot arms are dimensioned to absorb the forces transverse of the centerline of the ship and the spring absorbs the longitudinal and the cross ship forces.
  • the mooring armature 29 on the movable unit 10 in fig. 9 is constituted by a kevel head 40 and the coupling means 28 of the robot arm 20 thus is formed as a ring 39, which kan be thread over the kevel head 40.
  • the hydraulic power apparatu ⁇ ses 37 can also be used to position the robot arm before a mooring, whereby the robot slider 19 is vertically displace- able along a guide 18 contained in a slider 49, which in turn is movable along guides 35 fixedly mounted at the quay 11 ,
  • the horizontal displacement of the slider 49 along the guides 35 is carried out by means of the power apparatuses 37, whereby between the stays 36 and the robot slider 19 are provided interconnection links 50, which transmit the tensi ⁇ le forces to the slider 49.
  • the unit 10 has been stated to be the movable unit, that is a ship, a ferry a barge or the like, while the stationary unit can be a quay, an oil-rig or the like, but of course it is possible to place the mooring device on the movable unit and the mooring armature on the stationary device.

Landscapes

  • Engineering & Computer Science (AREA)
  • Ocean & Marine Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Environmental & Geological Engineering (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Manipulator (AREA)
  • Jib Cranes (AREA)
  • Bridges Or Land Bridges (AREA)

Abstract

On décrit un système d'amarrage entre un objet mobile (10), par exemple un navire et un objet stationnaire (11), par exemple un quai, ledit système comportant partiellement un dispositif d'amarrage (15) composé d'un bras de robot (20) mobile dans au moins la direction verticale et pourvu de moyens d'accouplement (28) sur l'un des objets (11) et partiellement d'une armature d'amarrage (29) pour recevoir et fixer les moyens d'accouplement (28) à l'autre objet (10). Le bras de robot est constitué par un élément de commande (21) mobile dans le plan horizontal (direction Z), et peut être commandé de préférence pendant toute la phase d'amarrage. Les moyens d'accouplement (28) sont reliés à un dispositif pour absorber les forces latérales (forces transversales du navire) qui agissent sur l'extrémité distale libre de l'élément de commande (21) de sorte qu'essentiellement aucun moment de flexion ne soit transmis à l'élément de commande (21). Ledit dispositif est constitué de moyens souples, agencés pour agir sur les moyens d'accouplement (28) et destinés à transmettre lesdites forces à l'un ou l'autre des objets (10 ou 11) ou aux deux objets (10 ou 11).A mooring system is described between a mobile object (10), for example a ship and a stationary object (11), for example a quay, said system partially comprising a mooring device (15) composed of an arm of robot (20) movable in at least the vertical direction and provided with coupling means (28) on one of the objects (11) and partially with a mooring frame (29) for receiving and fixing the means of coupling (28) to the other object (10). The robot arm consists of a control element (21) movable in the horizontal plane (direction Z), and can preferably be controlled during the whole mooring phase. The coupling means (28) are connected to a device for absorbing the lateral forces (transverse forces of the vessel) which act on the free distal end of the control element (21) so that essentially no bending moment is not transmitted to the control element (21). Said device consists of flexible means, arranged to act on the coupling means (28) and intended to transmit said forces to one or the other of the objects (10 or 11) or to the two objects (10 or 11) .

Description

MOORING SYSTEM
The present invention refers to a mooring system between a movable unit, e.g. ship and a stationary unit, e.g. a quay, and which system comprises partly a mooring device consis¬ ting of a robot arm movable in the vertical direction which arm is provided with coupling means at one of the units and partly a mooring armature for receiving and fixation of the coupling means at the other unit.
Background of the invention
It is previously known to moore a ship at a quay by means of robot like mooring devices, whereby the maneuvering. of the mooring device most conveniently takes place from the ship. An example of such a device is shown in US 4 066 030 which refers to a mechanical connection device where a coupling bar with a coupling head at the robot is inserted in a guide formed retainer, which has a smaller slot than the width of the coupling head, and which head is turned to locking position inside the slot. The adaption to different water levels is carried out by displacing the coupling head of the robot along the slot.
If the ship moves in the lateral direction, parallel with the quay, bending moments occur in the mooring device, which it can not absorb, and which will lead to a breakdown.
Through US 4 008 678 is known a passive mooring device without active mooring force, where the ship is fixed to stationary, vertical pillars, along which the ship can move in the vertical direction. Any movement in the lateral direction is on the whole not allowed by the mooring device, why this "rigid" system is subjected to large stresses.
Through US 3 463 114 it is known to use sucking-discs for clamping of the ship relatively a quay installation and which sucking-discs are supported by an arm which is verti- cally and laterally movable. This device demands a very large diameter of the sucking-discs, even ship sides and a high grade vacuum, which three factors not always can be guaranteed, and therefor the system is very, unsafe.
Through the british patent 2.080.228 is known a so called "link span anchorage" and which is intended by means of arms kee a stationary pontoon along a quay independent of varia¬ tions in the water level. In a similar way as according to the publications stated above, the coupling device, which is firmly connected to the kevel head, is vertically movable by means of a slider, which is movable along vertical pillars. This device is not a temporary mooring device, but a perma¬ nent holding device. The pontoon is resiliently moored to the quay by means of wires, but these moorings cannot absorb the lateral forces which may occur at the free extreme ends of the arms.
Common to these prior mooring or retaining devices is that all technical problems have not been solved which are rela¬ ted to mooring devices of this type, despite for a long time existing need.
The object of the invention and most essential features
The object of the present invention is to provide an active mooring device, which is structurally simple, which in principle consists of only one actuator, e.g. a hydraulic cylinder, which gives a possibility of a relatively long retracting distance. Further it has to be designed such that no bending moments are transmitted to the actuating device, on the ship side it should have a very small installation depth and there should be a possibility for mounting ex¬ ternally along the ship fender ledge. The device further should be designed such that it does not demand any greater precision at the landing and in passive position it should be protected inside the ship fender line of the quay. These tasks have been solved by the robot arm being consti¬ tuted by a actuating device, which is movable in the hori¬ zontal direction (z-direction), preferably actuable during the whole mooring phase, and that a device is connected to the coupling means, for absorbing of lateral forces acting on the extreme free end of the actuating device (lateral ship forces), so that substantially no bending moments are transmitted to the actuating device, and that said device is' constituted by bendable means, provided to act on the coup- ling means and which are intended to transmit said forces to either of the units or to both of the units.
Description of the drawings
The invention will be described in closer detail below in some embodiments with reference to accompanying drawings.
Fig.l shows in a diagrammatical view from the above of a ferry which has landed at a quay and is moored by means of the devices according to the present invention.
Fig. 2a-2g shows in seven lateral views maneuvering sequen¬ ces at mooring of a ship, whereby fig. 2a shows the mooring. device in a protected position inside the ship fender line, fig. 2b during adjustment of the vertical position relative¬ ly the ship, respectively the water surface, fig. 2c shows the device during pushing out of the mooring cylinder, fig. 2d pivoting out of the mooring cylinder, fig. 2e position finding of the mooring armature at the ship, fig. 2f hauling of the ship by means of the mooring cylinder and fig. 2g the ship in mooring position.
Fig. 3 shows in larger scale a first variant in a view from the front of a mooring device according to the invention. Fig. 4 shows a section along the line IV-IV in fig. 3.
Fig. 5 shows a lateral view of the mooring device illustra¬ ted in fig. 3.
Fig. 6 is a section along the line VI-VI in fig. 4.
Fig. 7 shows the mooring armature illustrated in fig. 4 in a view from the front and partly in section.
Fig. 8 shows a section along the line VIII-VIII in fig. 7.
Fig. 9 shows in perspective view a second embodiment, of the mooring device according to the invention.
Fig. 10 shows the mooring device according to fig. 9 in a view from the front.
Fig. 11 is a section along the line XI-XI in fig. 10.
Fig. 12 is a section along the line XII-XII in fig. 10
Fig. 13 shows a section along the the line XIII-XIII in fig. 12. Fig. 14 shows a view from the above of the mooring armature and the coupling means illustrated in fig. 13.
Description of embodiments
In fig. 1 is shown an embodiment of how the mooring device according to the invention can be used for mooring of two units 10,11, of which one can be a ship-, a ferry, a barge or some other floating object, while the other unit can be constituted by a quay, kevel head, an oil-rig or the like, that is a stationary plant. In the example shown in fig. 1, which shows a railway ferry, has been used a type of mooring device 12 at the bow, which is exposed only to small angular deviations and a mooring device 13 with a spring function at the stern of the ship. The ship - the railway ferry - , is equipped with a movably mounted ferry flap 14 , which locks the ship at the quay in such a way, that it also absorbs longitudinal ship forces. In this case thus only one mooring device 12 is required at the bow, which absorbes cross ship forces and smaller deviations from these, and a mooring device 13, which also can absorb longtudinal ship forces.
The embodiment shown in figures 3-6 consists of a mooring device 15 provided at the stationary unit, that is the quay
11, and which comprises a fixed stand 16 in the form of a frame 17, the vertical frame sides of which form a guide 18 for a robot slider 19. This supports a robot arm 20, which in the embodiment shown is constituted by an actuator 21, e.g. a hydraulic cylinder, which is pivotably arranged on bearings such that it has at least two, at least three degrees of freedom, that is a large mobility in the vertical plane - the Y-axis .-, limited mobility in the vertical plane
-X-axis, and the movable part of the actuator- the piston rod- is movable in the Z -axis.
The robot, slider 19 which supports the robot arm 20, is by way of a wire, cable or chain arrangement 22 and pulleys 23 counter balanced by means of weights 24. By means of a driving device 25, fig. 6 which acts on one of the pairs of pulleys 23, the elevation of the slider 19 can be changed. The robot arm is pivotable about its horizontal axis 26 by means of a second actuator 27, which as well can be a hyd¬ raulic piston cylinder.
At the extreme free end of the robot arm 20 is provided a coupling means 28 formed as a hook with a relatively large curved contact surface for a mooring armature 29 arranged at the second unit 10- the ship. In this embodiment this is constituted by. a bendable means 30, e.g. a wire, which at its both ends is connected to at least one tension spring 31, the opposite end of which is connected to the unit 10. The connection means between the bendable means 30 and the tension springs 31 are formed with a guide 33, which coope¬ rates with a slot 34, which limits the extension length of the tension spring. In a non actuated position the bendable means 30 takes a straight position, protected by the ship fender line or.shell plating, so that the hook-formed coup¬ ling means 28 can grip behind the wire, such as is shown in fig. 4.
In the figures 2a to 2g is shown diagrammatically a maneuve¬ ring sequence of how a mooring with the device according to the invention may be carried out. Figure 2a shows the moo¬ ring device with the robot arm folded up to a protected position inside the outer edge of the quay, which normally is a fender arrangement not shown. When the ship approaches the quay 11 the mooring device 15 is manipulated by means of radio signals whereby as a first measure an adjustment is carried out of the elevation of the robot arm. This eleva¬ tion adjustment can be performed either against one or several direction marks at the shell plate of the ship or with reference to the present water surface. This sequence is shown in fig. 2b. Thereafter the piston bar of the robot arm 20 is pushed out, such as is shown in fig. 2c simultane¬ ously as the roboty arm is turned to stand by position, fig. 2d and 2e while awaiting the ship coming so close that an interconnection of the coupling means 28 of the robot arm and the mooring armature 29 of the ship can be carried out. When the interconnection is carried out, that is the hook formed coupling means has gripped behind the wire 30, the hauling in of the ship against the quay can be carried out such as shown in fig. 2f and 2g.
If another ship passes outside the moored ship, forces will occur, which tend to move the moored ship along the quay, and forces which will pull the ship from the quay". It is known that the forces increase if the speed of the ship increases. Therefor, the cylinders of the robot arms prefe- rably during the whole mooring phase have a constant holding pressure and resliently absorb the forces transverse of the centerline of the ship. Since the coupling means 28 can be moved somewhat along the wire 30, also small angular devia- tions in the horizontal plane can be allowed, that is, to a smaller extent the robot arm also can absorb longitudinal ship forces, which are transmitted by means of the springs 31 to the hull of the vessel.
A second embodiment of the invention is shown in fig. 9, which in many parts are similar to the embodiment according to figures 3-8 and for those parts which are alike in both embodiments the same reference designations also have been used. What differs both embodiments is the mooring device according to fig. 9 being completed with a spring function and that the robot arm 20 is movable in the horizontal plane For this purpose are provided linear guides 35 at the sta¬ tionary unit 11, along which guides a slider 49 is displace- able.
The spring function of the mooring device is provided by stays 36 directed in opposite directions and articulatedly joined to the coupling means 28 of the robot arm 20, which stays at their opposite ends are connected each to a hydrau- lie power apparatus 37 by a pulley 38. The cylinders of the robot arms are dimensioned to absorb the forces transverse of the centerline of the ship and the spring absorbs the longitudinal and the cross ship forces.
The mooring armature 29 on the movable unit 10 in fig. 9 is constituted by a kevel head 40 and the coupling means 28 of the robot arm 20 thus is formed as a ring 39, which kan be thread over the kevel head 40. The hydraulic power apparatu¬ ses 37 can also be used to position the robot arm before a mooring, whereby the robot slider 19 is vertically displace- able along a guide 18 contained in a slider 49, which in turn is movable along guides 35 fixedly mounted at the quay 11 ,
The horizontal displacement of the slider 49 along the guides 35 is carried out by means of the power apparatuses 37, whereby between the stays 36 and the robot slider 19 are provided interconnection links 50, which transmit the tensi¬ le forces to the slider 49.
The embodiment according to figures 10 - 14 in essential parts is similar to the embodiment shown in fig. 9. What distinguishes is primarily the design of the mooring armatu¬ re at the movable unit 10, which in principle is Y-formed and where the diverging shanks 42 form guide surfaces, to guide the head 43 of the coupling means 28 to correct moo- ring position. In this way the positioning of the ship relatively the robot arm has not to be so precise, as is the case with the ring shaped coupling means 28 according to fig. 9. In order to get the fixing point of the stays 36 to be positioned at the center of the head 43, the stays are fixed to angular arms 44, which have their common rotation center 45 at the center of the head 43.
What further distinguishes the embodiment according to figu¬ res 10 - 14 from the embodiment according to fig. 9 is that the guides 35, which guide the stand 16 at horizontal dis¬ placement, are contained in a stationary frame 46, whichis firmly connected to the quay 11. By way of an arrangement of wires 47 and pulleys 48 the movable stand 16 is guided in the lateral direction.
The invention is not limited to the embodiments shown and described but a number of variants are possible within the scope of the patent claims. In the embodiments described the unit 10 has been stated to be the movable unit, that is a ship, a ferry a barge or the like, while the stationary unit can be a quay, an oil-rig or the like, but of course it is possible to place the mooring device on the movable unit and the mooring armature on the stationary device.

Claims

1. Mooring system between a movable unit (10), e.g. a ship and a stationary unit (11), e.g. a quay, and which system comprises partly a mooring device (15) consisting of a robot arm (20) which is movable at least in the vertical direction (Y-direction) and provided with a coupling means (28) at one of the units (11) and partly a mooring armature (29) for receiving and fixation of the coupling means (28) at the other unit (10), c h a r a c t e r i z e d t h e r e i n, that the robot arm is constituted by an actuator (21) movable in the horizontal plane (Z-direction) which actuator can be activated during preferably the whole mooring phase, that the coupling means (28) is "connected to a device for absorbing lateral forces (transverse ship forces) acting on the free extreme end of the actuator (21), so that substan¬ tially no bending moments are transferred to the actuator (21), and that said device is constituted by flexible means, arranged to act on the coupling means (28) and which are intended to transmit said forces to either unit (10 o 11) or both units (10 and 11).
2. Mooring system according to patent claim 1, c h a r a c t e r i z e d t h e r e i n, that the flexible means (30,36) are provided between the coupling means (28) and the unit (11) at which the robot arm (20) is provided.
3. Mooring system according to patent claim 1, c h a r a c t e r i z e d t h e r e i n, that the mooring armature (29) is constituted by a flexible means, e.g. a wire (30) which is spring loaded at least at one end, and that the coupling means (28) is hook formed and provided with a curved contact surface for the wire (30), so that at laterally directed load the coupling means (28) is movable along the wire.
4. Mooring system according to fig. 3, c h a r a c t e r i z e d t h e r e i n, that the end of the wire (30) connected to the spring (31) respectively the ends is (are) forcibly guided in a groove (34).
5. Mooring system accoprding to fig. 1, c h a r a c t e r i z e d t h e r e i n, that the coupling means is pivotably mounted in opposite direction laterally directed stays (36), which are intended to absorb the spring forces of the movable unit.
6. Mooring system according to fig. 5, c h a r a c t e r i z e d t h e r e i n, that the ends of the stays (36) turned away from the coup- ling means (28) are connected each to a power apparatus (37). e.g. a hydraulic means and that the actuator is pro¬ vided in a slider (49), which is movable along a longitudi¬ nal guide (35) by means of said power apparatus.
7. Mooring system according to patent claim 1 or 6, c h a r a c t e r i z e d t h e r e i n, that the robot arm (20,21) by means of a driving device (25) is movable in the vertical direction along guides (35) in the slider (49) respectively a fixedly arranged stand (46) at one of the units (10,11).
8. Mooring system according to patent claim 5, c h a r a c t e r i z e d t h e r e i n, that the coupling means (28) at the free end of the actuator (21) is formed as a head (43) intended to cooperate with a mooring armature (27) developed with a complementary form, and that the laterally directed stays (36) are pivotally mounted to the head (43).
9. Mooring system according to patent claim 6, c h a r a c t e r i z e d t h e r e i n, that between respective stay (36) and the slider (49) is 12 provided an interconnection link (50), for transmission of traction forces at displacement of the slider (49) by means of respective power apparatus (37).
10. Mooring system according to any or some of previous patent claims, c h a r a c t e r i z e d t h e r e i n, that the actuator (21, 27) of the robot arm and/or the power apparatus (37) of the stays (36) are connected to a hydrau- lie system, which is active during the mooring phase and in which system is contained a control system, which is pro¬ vided to adapt the power in the apparatuses (21,27,37) to the present load to which these are exposed.
EP19910906929 1990-03-26 1991-03-26 Mooring system Withdrawn EP0521984A1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
SE9001079 1990-03-26
SE9001079A SE469790B (en) 1990-03-26 1990-03-26 Mooring system between a moving unit, eg a ship and a stationary unit, eg a berth

Publications (1)

Publication Number Publication Date
EP0521984A1 true EP0521984A1 (en) 1993-01-13

Family

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Family Applications (1)

Application Number Title Priority Date Filing Date
EP19910906929 Withdrawn EP0521984A1 (en) 1990-03-26 1991-03-26 Mooring system

Country Status (4)

Country Link
EP (1) EP0521984A1 (en)
FI (1) FI924291A0 (en)
SE (1) SE469790B (en)
WO (1) WO1991014615A1 (en)

Families Citing this family (11)

* Cited by examiner, † Cited by third party
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NL9302289A (en) * 1993-12-31 1995-07-17 Sven Olaf Aarts Method for manipulating a connecting element in shipping.
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Also Published As

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SE9001079D0 (en) 1990-03-26
SE9001079L (en) 1991-09-27
SE469790B (en) 1993-09-13
FI924291A (en) 1992-09-25
WO1991014615A1 (en) 1991-10-03
FI924291A0 (en) 1992-09-25

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