The present invention relates to a telescopic access bridge or gangway configured for providing access and egress to and from a unit, such as a work vessel, service and maintenance vessel, unit or vehicle, to or from a further unit, such as offshore structures or wind turbine foundations.
Conventional marine access bridges require constructions that need to be manoeuvred between a use position and a storage position. Considering the varying (marine) conditions and the substantial forces acting on the bridge a robust design is required. This requires a demand on the available space in a storage position that reduces freight volume, for example.
The objective of the present invention is to obviate or reduce the aforementioned problems and to provide easy and safe access.
The objective is achieved with the foldable marine access bridge according to the invention, the bridge comprising:
one end with a second hinged connection to the second end of the elevating unit, wherein the second hinged connection is configured to enable a horizontal side-by-side orientation or top-down orientation of the elevating unit and the bridge in a storage position of the telescopic access bridge.
By providing a telescopic access bridge, including so-called gangways, persons are enabled to transfer between a unit provided with a bridge and a further unit including a fixed platform, such as an oil platform, dock, vessel, wind turbine etc. The unit is part of a vessel or ship, for example. The telescopic parts enable adjustment of the distance between the base unit, and the landing zone of the further, receiving, unit. The first connection preferably comprises a height adjustment element, preferably a hydraulic cylinder, to enable height adjustment.
According to the invention the configuration of the elevating unit and the bridge is such that both parts can be stored in a side-by-side or top-down orientation/configuration in a storage position of the telescopic access bridge with the elevating unit and the bridge extending substantially parallel to each other in a horizontal or vertical plane. This significantly reduces the required space for the telescopic access bridge when not in use.
In a presently preferred embodiment of the invention the both parts can be stored in a side-by-side orientation/configuration. This allows that both parts are stored adjacently in a substantially horizontal plane or level.
In a preferred embodiment according to the invention the first and second hinged connections are configured to enable storing the access bridge in a folded position.
The folding of the at least two parts of the access bridge, i.e. the bridge and the elevating unit, is achieved with the hinged connections. This achieves a compact construction requiring a significantly reduced storage volume. This provides an access bridge that is effective in use and can be stored efficiently. For example, the access bridge is dimensioned to enable storing in and/or or as a 20 or 40 ft container, preferably a high cube container, for easy transport by road, rail and/or sea with low freight costs.
In a preferred embodiment according to the invention the unit comprises a slewing mechanism configured for rotating the bridge relative to the elevating unit.
Providing a slewing mechanism enables rotation of the bridge around a substantial vertical axis relative to the elevating unit. This improves the freedom to operate the access bridge. The slewing mechanism is capable of moving the bridge from a storing position to the landing zone. Preferably, the slewing mechanism is part of the second connection. Preferably, the slewing mechanism enables a rotation of at least 180°, more preferably at least 240°. Optionally the slewing mechanism enables a rotation of 360° endless turn. In a presently preferred embodiment the slewing mechanism is suitable for pedestal mounting and tilting frame mounting. This provides additional flexibility to the telescopic access bridge according to the present invention.
In a preferred embodiment according to the invention the telescopic bridge part comprises a bridge tip configured for connecting to another unit in a position of use.
Providing a bridge tip enables a correct and stable position of the bridge to the other unit and enables a flexible setup allowing for multiple landing zone configurations. This enables easy access and regress between a unit provided with the telescopic access bridge according to the present invention and a further unit, such as a work vessel, service and maintenance vessel, unit or vehicle, and other structures such as offshore structures and wind turbine foundations.
Preferably, the telescopic bridge part further comprising an inflatable bridge tip. The inflatable bridge tip enables flexible contact with a landing zone and compensates misalignments and small movements. The inflatable bridge tip may act as bumper element. Other tip executions are also possible due to the preferred modular design of the bridge according to the present invention.
In a preferred embodiment according to the invention wherein the access bridge further comprising an intermediate platform connecting the elevating unit and the bridge.
Providing an intermediate platform further improves the practical application of the access bridge.
In a preferred embodiment according to the invention there is provided a lifting mechanism configured for maintaining the intermediate platform and the base unit substantially level. The mechanism comprises a cylinder for raising and/or lowering the elevating unit comprising the stairs. Preferably, the mechanism comprises at least two cylinders. This provides additional stability to the system and further provides an additional safety measure in case of failure of one of the cylinders.
Alternatively, or in addition, the access bridge comprises one or more beams configured for maintaining the intermediate platform substantially level. Preferably, the beams are provided parallel to improve the stability of the access bridge, and extend substantially parallel to the elevating unit.
In a presently preferred embodiment the intermediate platform can be maintained in a substantially horizontal direction. In this preferred embodiment also the bridge is maintained in a substantially horizontal direction. This improves safe transfer across the bridge.
In a preferred embodiment according to the invention the access bridge further comprises a luffing mechanism.
Preferably, the luffing system comprises a set of cylinders for stability and a set to enable dynamic movement, while limiting the required power input. Providing a luffing mechanism enables rotation of the bridge around a substantial horizontal axis to adjust to the height of the further unit. The luffing mechanism is capable of compensating the heave of the vessel and adjustment to the height from base to landing zone of the further unit. Preferably, the luffing mechanism is part of the second connection. More preferably, the luffing and slewing mechanisms are integrated with the second connection.
In a preferred embodiment according to the invention the elevating unit comprises a stair with a number of steps and further comprises a compensating mechanism configured for adjusting the angle of the steps with the angle of the stairs, preferably mechanically.
Having a compensating mechanism to adjust the orientation of the steps in response to the angle of the elevating unit, i.e. the stairs relative to the ground surface of the bridge that is preferably defined by the base unit/ship's deck, and that preferably can be manipulated with the height adjustment element, such as one or more hydraulic cylinders provides additional safety when using the access bridge.
In a preferred embodiment according to the invention the access bridge further comprises a compensating controller configured for active and/or passive compensation.
Providing compensation with a controller enables compensation of the heave, for example. This increases the operation window for the access bridge according to the invention.
More specifically, the controller in this preferred embodiment is configured for controlling compensation movement. This enables an effective control of disturbances caused by waves. For example, wave disturbances when loading and/or unloading a vessel or ship is caused by wave motion involving a number of wave variables including heading, frequency and height. The disturbances act on the bridge and on the vessel provided with such bridge. For example, waves influence movement of the vessel including roll, pitch and yaw rotational movement and surge, sway and heave translational movements. The compensation controller automatically determines the correction actions that are required for the individual drives or compensators to provide disturbance compensation. This enlarges the window of safe operation with the bridge according to one or more of the preferred embodiments of the present invention.
In a presently preferred embodiment the compensation controller is provided with information about the position of the bridge, slewing angle and/or length of telescopic bridge such that this information can be taken into account when determining the required compensation control actions. The bridge in preferred embodiment of the invention is capable to operate in a safe mode under a wider range of weather conditions involving wave disturbances thereby reducing waiting times. This renders the transfer operation more cost effective. Also, the bridge prevents unsafe operations thereby reducing the number of injuries and accidents when working with the crane.
In an active mode of the compensation controller preferably the luffing, slewing and telescopic movements can be compensated. Therefore, the compensation is position controlled. This is specifically relevant when the free end of the bridge, i.e. bridge tip, is not in contact with a landing platform or other unit. In a passive mode of the compensation controller compensations are performed in response to pressure/forces. Therefore, the compensation is force controlled. This is specifically relevant when the bridge tip rests on a landing platform or other unit.
In one of the illustrated embodiments of the invention preferably two or more (compensation) cylinders are provided on opposite sides of the compensation joint and, therefore, opposite sides of the bridge. This makes an accurate compensation movement possible, enabling the use of relatively small actuators and minimal power requirements. It will be understood that the number and configuration of the compensation cylinders can be designed appropriately to provide a sufficient compensation and may involve the use of a different number of cylinders, for example 4 or 6 cylinders. The actual design may depend on the required forces that are expected for the compensation, for example.
In presently preferred embodiments the drives of the crane comprise hydraulic cylinders or other hydraulic elements. It will be understood that other drives could also be implied including electrical and pneumatic cylinders/drives.
Preferably, the compensation controller comprises an input for receiving information about measured and/or predicted disturbances. Providing the compensation controller with information about the disturbances that are measured and/or predicted enables the compensation controller to determine the optimal corrective action to provide a disturbance compensation for the (marine) bridge. For example, disturbances can be measured by the motion reference unit (MRU). It will be understood that also other systems can be used to provide disturbance information to the compensation controller. Furthermore, the compensation controller preferably receives information about the effective length of the bridge. This enables the compensation controller to take the varying dynamics of the bridge into account when determining the required compensation control actions and movements.
In a preferred embodiment according to the invention the unit is part of a ship, vessel or vehicle. Especially providing the base unit as part of the ship, vessel or vehicle provides an effective system.
Integrating the access bridge with a container, room or space on or at a ship, vessel or vehicle provides a modular system that can be easily installed and/or removed when necessary. This provides optimal flexibility to the access bridge according to the present invention.
The invention further relates to a vessel, ship or vehicle provided with the aforementioned telescopic access bridge.
The vessel or ship or vehicle provides the same effects and advantages as described for the bridge.
The invention further also relates to a method for providing access to another unit, the method comprising the steps of:
The method provides the same effects and advantages as described for the bridge, vessel, ship or vehicle.
Preferably, the method comprises the step of storing the telescopic access bridge. The method achieves an effective storage of the access bridge in a storage position, for example in a container. In a presently preferred embodiment the elevating unit and bridge are stored side-by-side, or in other words in a parallel position, preferably within dimensions that correspond with a 40 ft container. This enables transport of the telescopic access bridge on a trailer and/or in a container.
Preferably, the method comprises the step of storing the access bridge in a direction with a substantially vertical component. This significantly reduces the required storage volume.
Preferably, the method further comprises the step of actively and/or passively compensating movement of the base unit. Compensation of movement enlarges the window of operational conditions under which the bridge can be used.
Further advantages, features and details of the invention are elucidated on basis of preferred embodiments thereof, wherein reference is made to the accompanying drawings wherein:
Telescopic access bridge 2 (
Telescopic access bridge 102 (
In the illustrated embodiment telescopic bridge part 126 (
Intermediate platform 134 is provided between bridge 122 and stairs 120 (
Slewing mechanism 144 (
Bridge 102 (
In a folded or storage position the illustrated bridge 102 is configured to fit 40 feet high cube container dimensions (
When required, modular bridge 102 can be installed as a stand-alone unit on ship 104. When use is no longer required bridge 102 can be easily removed. When access to unit 106 is required lifting mechanism 136 raises intermediate platform 134 by extending cylinders 138. In the illustrated embodiment the joint operation of rod 140 and beams 142 stabilises platform 134. Telescopic bridge part 126 is moved relative to main bridge part 124 to extend bridge 122 and enable connecting to unit 106. To end the connection telescopic bridge part 126 is retracted and lifting mechanism 136 lowers bridge 102 to its rest position and/or storage position. In this position bridge 122 and elevating unit 118 extend substantially parallel to each other in a side-by-side or top-down orientation.
In another access bridge configuration, foldable marine access bridge 202 (
Bridge 224 comprises main bridge part 226 and foldable bridge part 228. Main bridge part 226 is connected with main rotating shaft 230 to unit 204. Foldable bridge part 228 and main bridge part 226 are connected with folding mechanism 232. Bridge 224 further comprises two-wire receiving system 234 for storage of bridge 224. Folding bridge part 228 comprises tip support 236 connectable to fixed platform 238 in a use position (illustrated with the substantially horizontal orientation). It will be understood that in a position of use, bridge 224 can be provided at an angle to the horizontal depending on the relative positions of fixed platform 238 and unit 204. In the illustrated embodiment the length of bridge 202 in a position of use is about 70 m. It will be understood that other lengths would also be possible in accordance with the invention.
When folding bridge 202, locking system 122 is activated (
It will be understood that elements of the folding bridge 102 and 202 can be applied to telescopic access bridge 2, and vice versa. This may further increase the efficiency of providing access and regress to and from a unit.
The present invention is by no means limited to the above described preferred embodiments thereof. The rights sought are defined by the following claims within the scope of which many modifications can be envisaged.
Number | Date | Country | Kind |
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2014725 | Apr 2015 | NL | national |
2014803 | May 2015 | NL | national |
2015438 | Sep 2015 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/NL2016/050301 | 4/28/2016 | WO | 00 |