The present disclosure relates to the general field of installation of structures on a seabed. In particular, the present disclosure relates to a method of controlling a position and/or an orientation of an elongated structure, such as a pile, in particular a pile to be placed into a water bottom formation, more in particular a monopile, connected via a gripper to a vessel. The present disclosure further relates to a system for controlling the position and/or orientation of such an elongated structure connected via a gripper to a vessel, and to a vessel comprising the system, as well as to a computer program product and a computer-readable medium. In particular, the present disclosure relates to a control system and method for floating installation of monopiles into a seabed.
Presently there is significant activity in installation of structures on a seabed, in particular for wind turbine generators offshore. Constructions of foundations for wind turbine generators offshore involves installation of large tubular structures, such as piles or monopiles on the seabed, from vessels.
For pile installations on the seabed, it is a primary scope to install the pile on a pre-known and accurately matched absolute position in Earth Coordinates (for instance expressed in terms of its position in latitude, longitude and up, its verticality, or in any known terrestrial geodetic system such as WGS-84, ITRF or others, for example) on the seabed (denoted by X-Y here for simplicity). Moreover, it is a goal to install the pile with a requirement on its verticality. In most cases, a pile, according to the state of the art today, should be installed with a verticality tolerance not exceeding an offset of maximum 0.2-0.25 degrees in any direction from verticality in Earth Coordinates.
Monopiles subject to this field can be considered extremely large tubular (hollow) structures with diameters ranging from 5 up to 11-12 meters and with lengths of up to around 110 meters. Such piles can weigh in the order of 2000 metric Tons (“T”) or more, like 1500-3500 T, and it is expected that piles will become larger in the future.
Pile installation may involve “floating” installation in which a monopile is lowered from a ship to a seabed. This is still rarely done in the industry. Presently, foundations such as monopiles are mainly installed by jack-up vessels, which are vessels fixed on the seabed, because floating installation is considered very difficult and potentially extremely dangerous. Jack-up based installations take much more time, which is why floating installations may still be preferable, provided that the present technical challenges can be overcome.
A falling pile on a vessel could cause catastrophic damage and easily lead to fatalities.
Considering floating installation, it is a further challenge that manipulation of a pile, due to the large inertias being involved, can have a significant impact on the operation of a vessel dynamic positioning system (“DP-system”).
A number of monopile gripper-frames have been proposed by the industry, to control a pile and enable the installation of monopiles with such requirements.
When installing a pile from a floating vessel, a motion compensated pile gripper frame is necessary. Such a pile gripper frame will have a control system that will generate forces and motions that will impact the pile, but will also cause an external effect on the control system and actuators of an existing DP-system. The coupling of systems (for instance vessel, DP-system, pile gripper, pile and seabed) can lead to undesirable situations, for instance if a pile is being inserted into the seabed and therefore experiences a certain high coupling stiffness with the seabed, while the DP-system may be for example in a high precision mode (characterized by the fact that the DP-system is configured to keep the vessel tightly at a specified location). Then, the combined coupling between vessel, motion compensated pile gripper, pile and seabed can lead to undesired instabilities (for instance control instabilities) in the coupled dynamic system. Such instabilities can cause large position drifts and deviations in station keeping performance by the DP-system or the Pile Gripper or both, that can then hinder the pile installation operation and can lead to potentially dangerous situations (for instance leading to a falling pile). Time lag in the DP-system, which may exist between sending a command to it and receiving a measurable response of the vessel, is generally too large to be able to effectively use active control inputs to the DP-system for stabilizing an unstable situation. One possible mitigation of this problem may be to ‘de-tune’ the DP-system, for instance to make it less precise at such moments, to avoid such instabilities; however, such de-tuning may result in a significant loss of installation accuracy, such as for instance in pile placement and pile verticality.
Therefore, a method and a system are desired to improve operational safety and installation accuracy, also under a large amount of possible failure conditions.
Further, since jack-up vessels are fixed to the seabed, active motion compensation is not necessary. Recently, some parties have started developing motion compensated pile-grippers and associated installation methods in order to be able to install monopiles from floating crane-vessels without the need for jacking-systems and/or mooring or anchoring the vessel on the sea-bed; e.g. WO 2019/172572 A2, NL 2020536 B1, WO 2019/125172 A2, NL 2022205 B1, NL 2018066 B1, EP 3517479 A1. These systems are based on “motion compensation” by means of positioning a movable pile-gripper on deck in mostly 2 degrees of freedom (X-Y). The vertical Z-axis is kept free in order to allow the pile to travel vertically through the gripper. Typically, rollers are used to guide a pile in Z-direction passively. Such rollers are arranged in a circular fashion around a gripper that firmly grasps the pile in a “roller-box”. The roller-box is then moved by the actuator system of the pile gripper in horizontal coordinates X, Y.
It is known to implement offshore motion compensation systems by a position control scheme in which a movable device is commanded based on a sensor signal stemming from a measurement of the vessel position and orientations. Such signals typically stem from inertial measurement systems (IMU's) and/or combinations of inertial with GPS measurements, sometimes called Motion Reference Units (MRU's) when combined. A variety of methods are known in the industry.
Some known concepts may make use of a separate pile measurement device, such as disclosed in e.g. AU 2012233801 A1, AU 2014281920 A1, EP 3382335 A1. WO 2019125172 A2 discloses the consideration that in general this could also be integrated with the control system, e.g. positioning of the pile-gripper in a horizontal plane with a possible input of vessel GPS data and pile measurement device.
In the context of the present disclosure, a pile installation sequence may contain the following elements, as will be discussed later in more detail:
In an aspect, a method of controlling a position and/or an orientation of an elongated structure is provided.
The method is a method of controlling a position and/or an orientation of an elongated structure connected via a gripper to a vessel. The method comprises the steps of:
The vessel may be, during at least part of the method, a floating vessel or a vessel fixed with respect to the water bottom formation such as being jacked-up. Also or alternatively the vessel may be floating with a limited degree of freedom such as being moored to the water bottom formation for example by anchors. The water bottom formation may be e.g. a seabed (including an ocean bottom), a lake-bottom or a river bed, etc.
The force data indicative of an interaction force between the structure and the gripper or between the gripper and the vessel may comprise force data from a force sensor configured to detect an interaction force between the structure and the gripper, and/or actuator operation data such as actuator current data, actuator torque data, e.g. actuator data from one or more sensors configured to detect one or more of actuator input current, torque, output force, output torque.
Herein, the orientation of the structure, e.g. a monopile, comprises an inclination of the structure. The inclination of the structure may preferably be determined absolute, i.e. relative to the Earth Coordinates and/or gravity. An inclination of the structure may be determined relative to the vessel and/or gripper orientation. Thus obtained relative inclination data of the structure may be merged with absolute position and/or orientation data of the vessel and/or of the gripper to determine the absolute inclination data of the structure. This applies likewise, mutatis mutandis, with respect to the orientation of the vessel and/or of the gripper, relative to the structure and/or absolute, i.e. relative to the Earth Coordinates and/or gravity.
Controlling the position and/or the orientation of the structure and the vessel on the basis of the force data, rather than position data as customary, allows greater sensitivity in the control, and brings an advantage in particular in terms of response time, and it allows a greater degree of freedom in specifying control parameters and allows to define the coupling stiffness and damping. This will be set out in detail below.
The step of controlling a position and/or an orientation of the structure and the vessel may comprise controlling an actuator between the vessel and the gripper based on the force data. In particular this may comprise controlling the actuator to control the position and/or the orientation of the structure and the vessel.
Accordingly, variation/adaptation of the stiffness (or the damping) of the coupling may depend, possibly among others, on a condition of the gripper. Additionally or alternatively, variation/adaptation of the stiffness (and/or the damping) may depend on an operational phase in the installation process (an operational phase of placement of the pile into the water bottom formation).
By controlling the actuator on the basis of force data rather than on the basis of position data (including position difference data) alone, allows for improving adjustment in the control to specifications and/or tolerances of the actuator and/or the gripper. This may prevent risks and/or damage. Controlling the actuator may suffice to control the position and/or the orientation of the structure and the vessel. However, also or alternatively, controlling the position and/or the orientation of the structure and the vessel may comprise employing a dynamic position control system and/or a mooring line tensioning system of the vessel.
The step of controlling the actuator may comprise controlling a force and/or a torque of a drive of the actuator and/or controlling a relative position and/or movement of movable parts of the actuator. The method may comprise controlling a force and/or a torque of a drive of several actuators and/or controlling a relative position and/or movement of movable parts of several actuators; this may be either parallel or in series. As an example, a rotary actuator may be controlled in torque by the drive by proportionally controlling the drive or motor current. The input to such torque control may come from a force measurement and a force controller. The input to such force controller may come from the control system such as to configure the rotary actuator in an Impedance control scheme, such as to accurately render different stiffness and damping. Alternatively, with a hydraulic drive train, the pressure may be used similarly to the current in the example above.
Controlling a force and/or a torque of a drive of the actuator may allow or simplify comparing control values (e.g. set values and/or achieved values) with the force data.
In any of the methods, adjusting a position of at least part of the gripper relative to the vessel may adjust part of the structure; this may adjust a position of the structure as a whole, or, in particular if the structure has a fixed point, e.g. a pile resting in or on a water bottom formation, may achieve adjustment of the orientation of the structure about the fixed point.
Executing at least one method may comprise employing a force controller and/or a structure orientation controller, this may comprise (performing) one or multiple feedback loops. E.g. a force controller may regulate a force or torque in an actuator based on a measured torque or force in such actuator, in order to achieve the desired force or torque at the output of the actuator. This may ensure that several, preferably all, nonlinearities of the actuator can be compensated for, such as friction. Such desired force or torque may in one configuration be provided by an output of a gripper position controller which may comprise an actuator controller, which may regulate a position and/or orientation of the structure based on a measurement of such position and/or orientation of the structure, in order to achieve a desired position and/or orientation of the structure. As such, the structure position controller, in combination with a force controller, may act as an impedance controller, regulating the stiffness and or damping of the coupling by adjusting a feedback factor (e.g., gain) to the structure position controller, e.g. using variable gains. The structure position controller may receive its desired position and/or orientation from the inclination controller, which regulates the structure orientation, in particular: inclination, based on a structure inclination measurement in order to achieve a desired inclination in absolute Earth Coordinates which inclination may preferably be set to zero.
The method may comprise the further step of:
The step of receiving structure data may comprise receiving structure data indicative of at least one of a position, an orientation and a movement of the structure relative to the gripper and/or to the vessel. However, it is preferred that the step of receiving structure data comprises receiving structure data of at least one of a position, an orientation and a movement of the structure relative to a water bottom formation onto and/or into which the structure is to be placed. Such water bottom formation may be represented in Earth absolute Coordinates. In the former case relative control (such as the vessel and the structure with respect to each other) may be improved which may e.g. simplify maintaining control within set boundaries of the actuator operating space and/or detection space of a sensor. In the latter case accuracy of control of the position and/or orientation of the structure may be improved, which may benefit meeting installation tolerances and, also or alternatively, may benefit meeting safety tolerances and/or detecting early warning signals of potentially critical and/or ill-conditioned situations.
Likewise, the method may comprise the further step of:
As explained for the structure/structure data, the step of receiving vessel data may comprise receiving vessel data indicative of at least one of a position, an orientation and a movement of the vessel and the gripper and/or the structure relative to each other; it is, however, preferred that the step of receiving vessel data may comprise receiving vessel data indicative of at least one of a position, an orientation and a movement of the vessel is relative to a water bottom formation onto (and hence an Earth Reference Coordinate system) and/or into which the structure is to be placed.
Receiving the structure data indicative of at least one of a position, an orientation and a movement of the structure may comprise receiving one or more of inertial measurement sensor (IMU) data, movement reference unit (MRU) data, global navigation satellite system (GNSS) data, global positioning system (GPS) data, laser range data, light detection and ranging (LIDAR) data, sound navigation and ranging (SONAR) data, camera data, depth gauge data, USBL data, todd-wire data and pile inclination controller data. Any such data may be acquired directly on the structure or indirectly with techniques involving remote sensing, such as for example by means of cameras, lidars or radar.
Receiving the vessel data indicative of at least one of a position, an orientation and a movement of the vessel may comprise receiving data from one or more of an inertial measurement sensor (IMU), global navigation satellite system (GNSS), global positioning system (GPS) sensor, laser range sensor, light detection and ranging (LIDAR) system, sound navigation and ranging (SONAR) system, camera, depth gauge, USBL data, todd-wire data and data from the dynamic positioning control system, vessel thruster controller, mooring line tension sensor, etc.
The method may make use of Sensor Fusion, by means of known sensor fusion algorithms, such as Kalman Filters, Particle Filters, Extended Kalman Filters or other statistics based method, in order to calculate robust estimates of the vessel and/or structure position and/or orientation and/or movement data. In such Sensor Fusion, various measurements of the same physical quantity may be used as an input, in parallel, and the most robust and accurate output measurement would be provided on the output for further usage inside the control system.
The method may further comprise the step of:
Then the step of controlling a position and/or an orientation of the structure and the vessel may also comprise controlling the position and/or the orientation of the structure and the vessel with respect to Earth Coordinates and/or with respect to the water bottom formation.
Thus, the method allows determination and/or controlling the structure and/or the vessel with respect to absolute coordinates and/or relative coordinates to an absolute position, which may comprise a position and/or an orientation of the structure and/or the vessel. This may benefit meeting installation tolerances and, also or alternatively, may benefit meeting safety tolerances and/or detecting early warning signals of potentially critical and/or ill-conditioned situations. Such situations could affect desired and/or achievable response characteristics of a system performing the method; in particular, see below, adjusting stiffness and/or damping of a coupling between the vessel and the structure may be desired on the basis of the vessel data. Such adjustment of the stiffness and/or damping of the coupling between the vessel and the structure may be provided by a monopile position controller in the form of an impedance controller which may be achieved by adjusting one or more gains in the controller.
The method may further comprise receiving load data, e.g. crane load data, from a load sensor configured to detect a load on a hoisting system, e.g. a crane, supporting the structure, then the step of controlling a position and/or an orientation of the structure and the vessel may also comprise controlling the position and/or the orientation of the structure and the vessel based on the load data. For example, the load data may be used to adjust the gains of a motion compensation controller during the pile lowering operational phase.
As such, variation/adaptation of the stiffness (or the damping) of the aforementioned coupling may depend, possibly among others, on conditions of the hoisting system. Additionally or alternatively, variation/adaptation of the stiffness (and/or the damping) may depend on an operational phase in the installation process (an operational phase of placement of the pile into the water bottom formation).
The hoisting system may comprise a crane and the load data may comprise crane load data.
This may improve controlling and/or stabilizing the structure supported from the crane, in particular at or during establishing contact between the structure and a water bottom formation onto and/or into which the structure is to be installed. At the establishment of the contact, the load on the hoisting system and/or dynamical behavior of the structure tend to vary significantly over a short period of time and/or over a small position change compared to the installation procedure and/or compared to one or more of time constants, time constraints, spatial constraints, movement characteristics etc.
Controlling the position and/or the orientation of the structure and the vessel based on both on the basis of the force data and the load data may improve control during a transition between different configurations and dynamic behaviors, in particular from a hoisted configuration wherein the structure is supported by (in particular: being suspended from) the hoisting system, to an off-loaded configuration wherein the structure is, at least predominantly, supported by another structure separate from the gripper, vessel and hoisting system, in particular standing on the water bottom formation.
The load data may comprise load data from a load sensor configured to detect a load on the hoisting system, a pressure sensor e.g. in a hydraulic system, and/or swell compensation data from a swell compensation system which may comprise one or more sensors to detect a hoisting driver load and/or -torque.
The method may further comprise receiving configuration data indicative of a relative position and/or movement of one or more movable parts of the actuator, and/or
Then, the step of controlling a position and/or an orientation of the structure and the vessel may also comprise controlling the position and/or the orientation of the structure and the vessel based on the configuration data and/or the vessel data. This may be done in particular in case the configuration data are indicative of the relative position and/or movement of movable parts of the actuator being outside of a predetermined space and/or velocity range, and/or in case the vessel data are indicative of the vessel being positioned and/or moving outside of a predetermined space and/or velocity range. In order to apply for instance a motion to the vessel, an external force input to the DP-system may be used. Alternatively, an external position or orientation correction to the DP-system inputs may be used.
The step of receiving configuration data indicative of a relative position and/or movement of one or more movable parts of the actuator may comprise receiving configuration data from a configuration sensor of the actuator configured to detect a relative position and/or movement of one or more movable parts of the actuator. The configuration data indicative of the movement may include data indicative of movement changes, such as starting a movement, stopping a movement, velocity, acceleration/deceleration (e.g. first time derivative of velocity), rate of acceleration/deceleration (e.g. second time derivative of velocity), etc.
In any method embodiment disclosed herein the position and/or orientation of the structure and/or of the vessel may be determined with respect to Earth Coordinates and/or relative to at least part of a water bottom formation onto and/or into which the structure is to be installed. Alternatively, the position and/or orientation of the structure may be determined relative to the Vessel position and/or orientation or alternatively relative to the gripper structure position and/or orientation (e.g., the position of the structure may be determined relative to the vessel position, and/or the orientation of the structure may be determined relative to the vessel orientation). The preferred embodiment is to for example re-compute all measurements to be represented with respect to absolute Earth Coordinates.
Any method herein may comprise the step of: determining a position on or in a water bottom formation wherein the structure is to be placed and the step of controlling the position and/or the orientation of the structure and the vessel symmetrically about the position, and/or
Thus, drift-off of the combined system of vessel and structure may be prevented. In such method, the vessel may be moved with respect to the structure rather than the structure being moved with respect to the vessel. It is noted that the center of inertia of the assembly may be determined to varying amounts by friction and/or stability of the structure as it is placed onto and/or into (in particular: driven into) a water bottom formation. Controlling the position and/or the orientation of the structure and the vessel symmetrically about the center of mass and/or a center or inertia may be performed by a Combined Vessel-to-Monopile controller (VMPC), also called ‘star controller’. Such VMPC may be arranged such that it can use the respective masses of the vessel and the structure to determine the center of mass and/or a center or inertia of the assembly to stabilize the combined dynamic system. Also or alternatively, the VMPC may be arranged such that it can use a given position on or in the water bottom formation to control the position and/or the orientation of the structure and the vessel symmetrically about the position. Also, or alternatively, the VMPC may be arranged such that it can use at least one of the shape, geometry orientation of the structure with respect to environmental aspects, such as one or more of wind, waves, currents, etc. on the vessel and the structure to control the position and/or the orientation of the structure and the vessel symmetrically about the give position. In other words, at least one of the position and orientation of the combined structure-vessel system may be controlled symmetrically about the given position based on at least one of the shape, geometry and orientation of the structure, and further based on environmental aspects, including for example wind, waves and/or currents.
In an aspect, which may be suitably combined with any other method embodiment disclosed herein, a method of controlling a position and/or an orientation of an elongated structure connected via a gripper to a vessel is provided which comprises the steps of: determining a coupling between the vessel and the structure and determining a stiffness and/or a damping of the coupling.
Then the method may further comprise the step of
E.g. adjusting the coupling from a comparably high stiffness and/or high damping to a comparably low stiffness and/or low damping and/or back. The stiffness and damping may be adjusted together or separately.
By adjustment of the stiffness and/or damping of the coupling, the coupling may be accommodated to different situations. E.g., situations where relatively large excursions or relatively small excursions of one or more of the data about a particular value are (to be) expected and/or can be allowed or cannot be tolerated.
This allows dynamic control over the step of controlling a position and/or an orientation of the structure and the vessel, also where that comprises controlling the position and/or the orientation of the structure and the vessel on the basis of the force data and/or one or more of the data identified herein as suitable for such controlling of the position and/or orientation of the structure and the vessel, either or not with respect to each other, e.g. force data, structure data, vessel data, load data, configuration data, insertion data, and possibly for any one of these data whether absolute or relative.
Adjusting the stiffness and/or the damping of the coupling may be based on one or more of the data identified herein, e.g. force data, structure data, vessel data, load data, insertion data.
Also or alternatively any step of a method disclosed herein may allow and/or require human input, e.g. allowing human intervention; in particular adjusting the stiffness and/or the damping of the coupling may involve human input such as for determining a time and/or an extent of adjustment.
Such method of determining a coupling and adjusting the stiffness and/or damping may in particular comprise the step of receiving at least one of
This allows adaptation of the control of the gripper, and any effect thereof, to variations in the configuration of the structure relative to the water bottom formation and/or the gripper and or the vessel. Examples of (receiving) load data have been indicated elsewhere herein. Insertion data may comprise e.g., one or more of length data and oscillation data of the structure such as resonance frequency data for longitudinal and/or transverse oscillations.
Any method herein may comprise the step of arranging the vessel in a body of water, comprising the further steps of supporting the structure from a hoisting system of the vessel, connecting the structure via the gripper to the vessel, in particular while the structure is supported by the hoisting system, placing the structure onto and/or or into a water bottom formation of the body of water and driving the structure into the water bottom formation, and disconnecting the structure from the gripper and/or from the vessel. The force data may be received from a force sensor during at least some of the time that the structure is connected via the gripper to the vessel.
This may further comprise the step of adjusting the stiffness and/or the damping of the coupling between the first setting and the second setting between one or more of these “further steps” and/or during execution of one or more of these “further steps”. An adjustment between the first setting and the second setting may comprise adjusting the stiffness and/or the damping of the coupling to one or more settings in between the first and second settings, at least part of which may be substantially stepwise or substantially continuously.
In an aspect, which may be suitably combined with any other method embodiment disclosed herein, a method of controlling a position and/or an orientation of an elongated structure connected via a gripper to a vessel is provided which comprises the steps of:
In an aspect, associated with at least the preceding, herein is provided a system for controlling the position and/or orientation of an elongated structure connected via a gripper to a vessel, the system comprising:
The system may further comprise a gripper mountable or mounted to a vessel for connecting with the vessel via the gripper an elongated structure, such as a pile, in particular a pile to be placed into a water bottom formation while gripped by the gripper.
The system may be configured to determine a coupling between the vessel and the structure, when the gripper is mounted to the vessel and connects the elongated structure to the vessel, and to determine a stiffness and/or a damping of the coupling, and the system may then be configured to adjust and/or allow adjustment of the stiffness and/or the damping of the coupling between a first setting of a comparably high stiffness and/or high damping to a second, different, setting of a comparably low stiffness and/or low damping, and preferably comprising adjusting the stiffness and/or the damping of the coupling to one or more settings in between the first and second settings.
The system may further comprise at least one of
In yet another aspect herewith is provided a vessel comprising the system described herein.
In yet another aspect herewith is provided a computer program product comprising instructions to cause the system described herein to execute the method steps of any one method embodiment described or indicated herein. In an associated aspect herewith is provided a computer-readable medium having stored thereon the computer program product.
The above-described aspects will hereafter be more explained with further details and benefits with reference to the drawings showing a number of embodiments by way of example.
In the Figures is shown:
The inset (in grey) shows a more detailed typical embodiment for the system indicated in grey, the exemplary “IMU, GPS and/or motor encoder measurements” block comprises multiple sub-systems as shown, i.e. at least one IMU (Inertial Measurement Unit), at least one GPS receiver (Global Positioning System receiver), the option of one or more external correction signals, such as e.g. the MarineStar, PPP or RTK corrections. However, other sub-systems and/or combinations (not shown) may be provided. For reference, one sensor fusion block is shown providing input to the motion compensation controller.
It is noted that the drawings are schematic, not necessarily to scale and that details that are not required for understanding the present invention may have been omitted. The terms “upward”, “downward”, “below”, “above”, and the like relate to the embodiments as oriented in the drawings, unless otherwise specified. Further, elements that are at least substantially identical or that perform an at least substantially identical function are denoted by the same numeral, where helpful individualized with alphabetic suffixes.
Further, unless otherwise specified, terms like “detachable” and “removably connected” are intended to mean that respective parts may be disconnected essentially without damage or destruction of either part, e.g. excluding structures in which the parts are integral (e.g. welded or molded as one piece), but including structures in which parts are attached by or as mated connectors, fasteners, releasable self-fastening features, etc.
In the following, embodiments and variants of the system disclosed herein are described.
An embodiment comprises a control system, also nicknamed herein an “X-Control Box” and a hardware suite comprising computers (computing devices) and sensors, which allows a retro-fit on existing motion compensated pile-grippers to allow safe and accurate pile installations. The X-Control Box is used in combination also with external sensors, such as MRU's and IMU's and GPS/GLASS systems and custom sensors for pose measurement of monopiles. The combination of X-Control Box with such external sensors is denoted X-Control Suite. The X-Control Box and X-Control Suite enable the safe and high-precision installation of monopiles (as non-limiting examples of structures, in particular elongated structures) to the seabed from floating crane vessels.
A gripper to which the X-Control Suite is fitted, may require at least one or at least two degrees of motion in X-Y direction and may require one or more force-sensors to provide input signals to the control system. Also or alternatively other input signals such as motor currents may be used.
The X-Control Box, or the control system in general, makes use of an inner force-loop as primary control system (central force control system), which aims that (a) the stiffness and/or damping of the vessel-to-monopile interface (coupling) can be varied, for example such that a control instability is prevented or even made impossible so that it cannot occur, e.g. by prevention of over- or underdefined situations, and that (b) one or more motions of the pile gripper for motion compensation of waves and wind induced motions can take place, and possibly may take place independently from the coupling stiffness between vessel and monopile. This may decouple the motions and reactions of the DP-system from the motions of the pile gripper. The variation of the stiffness and/or damping may depend on external forces and/or external conditions, for example.
In general, for example by means of the inner force-loop, the control system computes a suitable coupling stiffness and/or damping between monopile and vessel, as an option being based on (possibly instantaneous) crane-load data (e.g. to stabilize the pile when hanging in the crane) or based on the magnitude of forces being measured between the gripper and the monopile (in general, based on external forces and/or external conditions).
The control system computes, as a preferred option, a suitable coupling stiffness and/or damping between monopile and vessel based on (possibly instantaneous) insertion depth data of the monopile into the seabed (to decouple the pile when held stiffly by seabed and to avoid DP-system instability). The coupling stiffness and/or damping may also or alternatively be computed based on other factors and/or data, e.g. based on the magnitude of forces stemming from interactions between pile and waves, from magnitude measurements of waves, from wind strength measurements or from measurements of the motions of the monopile and/or vessel including from measurement of their relative motion.
The control system can, in some examples, compute motion responses to use the combined vessel-monopile system to stabilize the pile upright even under conditions when a Dynamic Positioning system (“DP-system”) of the vessel fails, drifts or is entirely absent.
Such system deviates from known systems in that the present-day focus of a pile gripper control system on only positioning tasks for motion compensation has a number of significant drawbacks that shall be explained here below. Moreover, the incapability of a vessel dynamic-positioning system to support pile-installation with a stiff precision setting while a pile is substantially inserted into the seabed has not been addressed before. Moreover, no present system makes use of force information during all operational steps and phases (e.g., the operation phases set out elsewhere in this disclosure) to constantly adjust the stiffness and damping parameters in the coupling between pile, gripper and vessel, which can lead to significant reductions in external forces on the pile gripper.
Various aspects of the disclosure are explained below. Some key problems with prior art and floating pile installations may be discerned:
Even with high-precision DP-systems, drifts can regularly occur and can be in the range of multiple meters. This is why a typical workspace of a gripper is also in the range of multiple meters, for instance ±3 or ±4 meters in X and Y directions.
While balancing the pile when not attached to a crane, any DP drift will cause a position-controlled gripper to move towards one of its end of stroke limits quickly (e.g. within tens of seconds or some few, say 1-3, minutes). If any of the end-of-stroke limits is actually reached, the pile can easily fall since it becomes uncontrollable;
It is therefore very hard to successfully balance a (mono)pile with mass and inertia close to the mass and inertia of a vessel for extended periods of time, especially under non-favorable weather conditions involving winds and waves that are significantly non-zero;
Once a pile driver is installed on a pile, the combined mass will be even increased and the center of mass may be shifted, compared to the pile without the pile driver, and a DP-system will need to be arranged such as to be very precise to ensure good positioning behavior for station keeping;
When driving the pile to the seabed, the increasing stiffness between pile and seabed can lead to the occurrence of DP-system instabilities (in particular control instabilities through the external constraint), which can cause large drift-offs and oscillations of the DP system. This then can create significant forces on the pile, pile gripper and/or vessel. Such situations can lead to a non-controllable case in which a pile can fall in any direction and potentially create significant damage. Such instability is most likely to occur when the pile-to-soil stiffness increases. As an alternative one could argue that the DP-system precision setting can be relaxed. If this adjustment is done too early, however, it may cause drifts and may rather incline the monopile, and/or lead to stroke-ends of the gripper, which may lead to installation outside the tolerances in the best case. If this adjustment is done too late, instability likely has already occurred and a drop of the pile cannot be avoided, at least in most cases.
In particular with reference to the Figures, the following is noted.
Embodiments of the invention described in more detail below address one or more of the above-mentioned problems by implementing a force-control based approach on at least some of the drives of a pile gripper as a central element of the control system of the motion compensated gripper. This allows to directly detect interface forces between a pile and a gripper/vessel system and hence react more quickly on a potentially ill-conditioned situation or on a situation that could lead to ill-conditioning of the pile. Moreover, the force control approach leads to the feasibility of implementing an Impedance or Admittance control which can modify the coupling stiffness and/or damping. Moreover, an inclination control may be used to ensure keeping pile inclination during operations preferably zero or within a predefined tolerance around zero.
Moreover, in an embodiment, the control system and possibly, the sensor suite make then use of an external position control loop around the central force control system, in order to perform a desired motion compensation to eliminate effects of marine- and wind-induced position drifts of the vessel onto the gripper and hence the pile inserted into it. It is here where also the Impedance control may be achieved: The motion compensation control loop computes a desired stiffness and/or damping and provides a desired force to achieve such stiffness/damping to the inner force control loop. In addition, the provided force also accounts for performing adequate responses for the motion compensation control.
In addition to such (possibly nested) motion-compensation control, which may be based on sensing the vessel absolute position and rotations in Earth coordinates e.g. via IMU and GPS systems, an embodiment also includes a dedicated pile inclination controller which ensures, or at least is configured to ensure, that the monopile can be installed within the required vertical installation tolerances.
Additionally, an embodiment of the control system disclosed here includes a mode in which the pile and the vessel are balanced together, to recover from situations when a DP-system fails or ill-behaves or when through other reasons nearing a stroke-end.
The proposed unique and new combination of force and position control allows to actively adjust the stiffness and/or damping of the interface between the vessel/gripper and pile. Through a combination of a force-control approach in the drives with an external position control loop an impedance control may be realized. Consequently, the pile and vessel can be coupled or de-coupled with varying degrees of stiffness and damping (impedance), depending on the task and on the operational step. Non-limiting examples for different stiffness and/or damping settings depending on operational steps may be as follows.
When the pile is fully self-supported (“pile balancing”), the control system may quickly detect any force deviations within its force control system, may use the sensor data from a number of position and/or orientation measurement sensors related to, e.g. expressed in, Earth absolute frame to compute an optimal motion compensation and preferably at the same time ensure that the pile-inclination is maintained. This allows adjusting, in particular: minimizing magnitude of forces in the system, preferably at all times. Pile inclination may be derived from a measurement and it may be fed on-line into the control system in real-time (e.g. associated with or even at sample-rate of the control system).
In a preferred embodiment, if an excessive DP-drift event occurs that the pile gripper controller cannot reject by these means, an optional dedicated “combined vessel-monopile controller” is enabled, for example by a supervisory-control system. The combined vessel-monopile controller (or control) may account for and/or use then the mass of the (mono)pile to influence the vessel position and help the DP system to recover. This optional controller can also be able to stabilize the pile/vessel system over extended periods of time under a situation where the DP system is partially or entirely non-functional or absent, for instance during pile balancing. In this way, the system can counter-act effectively DP drift-offs and offers a safe and robust solution that can prevent pile ill-conditioning. At the same time, under nominal operation, the system may ensure a highly accurate pile inclination, since the pile inclination is actively used in the control system and therefore may be achieved within the tolerances required by the industry.
In a later phase, when the pile is driven to the seabed (“pile driving”), sensor data from the insertion depth of the monopile may allow or may be used to change the stiffness and/or damping between the vessel/gripper and (mono)pile by changing a mechanical impedance of the gripper system. With progression of the pile into the seabed, the system can slowly and continuously lower the stiffness and/or damping to slowly de-couple the pile from the vessel with progressing insertion depth. This prevents the onset of DP-instability to occur even if a high-precision setting is chosen for station-keeping, which is preferable also for the entire operation. Adjustment of a mechanical coupling impedance allows to safely install piles at a large range of weather conditions.
In a last phase, when the pile is fully inserted to insertion depth (“Gripper retract”), and when the gripper needs to be opened, the vessel will be fully de-coupled from the pile. However, in order to prevent damage to the pile gripper (e.g. from excessive motions of the vessel due to waves) the priority can be transferred back in the present control-system to favor better motion compensation, with a stiffer actuator setting. This enables to then minimize relative motions between gripper and pile and enables or simplifies a safe and failure-free extraction of the gripper from the pile.
The monopile (P) needs to be installed on the exact X,Y location in Earth Coordinates and is installed by the Vessel (A1), Crane (A2) and Pile Gripper (G) simultaneously during a number of principal installation phases.
In a first phase, the monopile (P) is suspended on the crane prior to lowering it (P) on the seabed. This phase includes all transitions from a free-hanging pile that protrudes above water, to the pile protruding inside the water-line, to the pile entering the gripper and up to the pile being fully grasped by the gripper, which typically has some opening doors (not shown here for simplicity). Typically a pile would be inserted into a gripper by a slewing motion of a crane and by then closing and latching large circumferential doors with roller-boxes and/or other gripper portions. During this insertion, the pile position may be tracked actively by the pile gripper to maintain as little as possible relative motion between the pile gripper and the pile.
The gripper can then be moved in the horizontal direction, actively, by a corresponding actuator and drive-system in 1 or 2 degrees of freedom, denoted X and Y for simplicity;
The vertical direction Z is usually passive and the pile can freely and passively move along this axis along some rollers.
Note that here, a (mono)pile is used for explanatory purposes but the same phases and issues apply for (installation of) any other generally relatively long and thin (i.e., elongated) structure or may equally apply to the installation of other bottom fixed structures.
During Phase-I (
In Phase-II (
The pile (P) lowers into the seabed in Phase-I up to its self-weight penetration depth (SWP), which is the insertion depth until which the pile sinks due to its own weight and which depends on the ocean floor and mass and geometry of the pile.
In the third operational phase Phase-III (
The connection between the Hammer (H) and the Crane (A2) needs to be kept loose, in order to allow the hammer (H) to follow the pile passively (P) (in −Z direction) while driving the pile.
A major challenge of this operational Phase-III is the fact that a high-gain setting on a dynamic positioning system of the vessel (A1) can lead to control instability of the connected system of vessel (A1), gripper (G), pile (P) and Hammer (H) when the stiffness between pile (P) and seabed (S) reaches a certain value (resembling a moored vessel).
Installing a monopile (P) on the seabed (S) is challenging due to wave (W1) and wind (W2) disturbances acting on the vessel (A1) and the monopile during all phases. When the monopile is sitting on the seabed without crane support (or without sufficient penetration depth into the seabed) it is unstable and can fall.
When the vessel (A1) is not moored and not jacked up it can drift due to the forces of the monopile (P) acting on the vessel (A1). This can result in the monopile falling.
When the vessel (A1) makes use of a dynamic-positioning system (DP-system), then a coupling between the vessel (A1) and the seabed (S) through the pile (P) can cause instability in Phase-III of the operation, or else, when in Phases-I or Phase-II of the operation, can cause drifts of the vessel (A1), gripper (G) and pile (P) assembly which can cause to not install the pile on the accurate X,Y location, and/or can cause the pile to incline (possibly causing the pile to fall).
The mode of operation of a DP-system is considered known to a reader skilled in the art of offshore operations. A DP-system allows to position a vessel with adjustable thrusters to compensate for vessel position-drift to certain extent and to perform station keeping above a work-site. It acts mainly on low-frequency disturbances, such as currents and long-frequency changes in ocean and wind environment. However, each DP-system has a watch-circle within which it does drift around its set-point. Large drifts have been observed that can protrude outside a regular watch-circle involving deviations up to tens of meters in non-nominal cases.
This disclosure predominantly addresses a control system (C) and an associated sensor and measurement suite (S1-S5) (
The sensor and measurement suite in a preferred embodiment of the invention comprises the following sensors and measurement functions:
Further measurement functions may be used as well, e.g. absolute position measurement (X,Y coordinate) of at least part of the pile (not shown).
The shown sensor suite (S1-S5) hence finally processes and reads absolute position of the vessel (S1) and crane load (S4), the absolute inclination of the monopile (S3) the absolute insertion depth of the monopile (S5) and the relative positions and forces of several, preferably all movable axes of a mechanical gripper (S2). This information is passed to the controller (C1).
The controller acts on the position and force (Y1) of the mechanical gripper actuators.
A user interface (H1) allows changing the functionality of the control system.
During the monopile installation over all three phases, a preferred embodiment of the proposed control-system will fulfil a number of tasks related with the three main operational phases and will ensure a smooth transitioning between those phases, in particular,—during Phase-I the control system (C) ensures that energy in the pile is dissipated and that the pile can be safely inserted into the pile gripper (P),
All control functions of an overall pile-gripper system that are not shown here, possibly normally to be considered relevant if not essential for an overall control system, can be considered “standard practice”. Such functions and features include, but are not limited to, for instance, control system features to operate actuators, to prepare the gripper to receive data, to switch-on and switch-off the system, to log-data, etc. and would include the ‘standard’ SCADA system, Human-Machine Interfaces, Graphical User Interfaces and all other standard systems as considered applicable by a person skilled in the art of industrial control systems. All such features not described here would be required to fully operate a pile gripper and perform and coordinate all standard tasks such as logging data, moving parts, opening doors, activating safety systems, activating thermal monitoring and controls, pre-heating, etc. Those parts are not considered essential to this invention and take many various forms and are therefore not described in more detail in this disclosure.
The preferred overall control system (C) (C1) subject to this invention is a system, which is responsible for the successful operation of the pile gripper and which is responsible for performing the active motion compensation and the positioning of the pile to reach the required installation performances. The preferred control system is arranged such as shown in
Some or all control sub-systems can either receive independent inputs and provide independent outputs or can be cascaded, or grouped, or can be summarized into a single multiple-input multiple-output (MIMO) control system without the loss of generality, such as shown in
The primary sub-system, the force-control (FC) sub-system is arranged such that it receives a desired torque or force set-point as input and delivers a control signal as output to an actuator that is configured to process such output such as to create an equivalent torque or force mechanically to the gripper movable part.
In a preferred embodiment of the invention, a gripper position-control (PC) sub-system is nested around the force control sub-system that is arranged such as to follow a given reference position input and to generate an output towards the force-control sub-system. In particular:
In a preferred embodiment of the invention, the position-control sub-system is fed from the output of the inclination-control subsystem (IC), which can also be considered optional, but greatly improves the performance of the overall system.
In a preferred embodiment of the invention, moreover, a dedicated Combined Vessel-to-Monopile controller (VMPC) is implemented in parallel to the monopile position control and inclination control subsystems. This controller is arranged such as to cause gripper motions that stabilize the combined gripper-vessel system if needed. If the supervisory controller detects, for example, either a large deviation in pile-inclination, or for example a drift-off of the vessel via its INS-system, or for example a constant propagation of the gripper through its workspace and risking to reach the work-space end limits, or for example detects another anomaly in the system indicating a possible pile-fall, or a combination thereof, then this system can be activated to stabilize the vessel position by shifting the pile mass in such a way as to relocate the vessel with the pile mass. For this purpose, the controller can make use of measurement data of the system that is not shown in the figures above (e.g. end-switches, etc.) and can make use of any of the sensor inputs (S1-S5) or any processed result from such inputs. The combined vessel-to-monopile controller is preferably arranged to one or more of:
In a preferred embodiment of the invention, the activation of the combined vessel-to-monopile controller (VMPC) by the supervisory controller will be associated with or cause a de-activation of the position- and inclination control sub-systems;
Alternatively to, or in addition to, activating the VMPC, the supervisory controller may also then cause a correction signal to be sent to the vessel DP-system, such as to cause a gradual improvement of the given situation that causes the vessel drift to stop or to again move the gripper end-point in its center workspace by a support of the DP-system itself.
The control-system may change the activation and configuration of any of its sub-systems depending on the operational phase in which the installation is performed.
In the following, the preferred control system configuration will be shown for all of the three major phases which a monopile installation will undergo.
During operational Phase-I (
Thus,
As said,
During operational Phase-II (
An alternative control system configuration is shown in
During operational Phase-III (
For the avoidance of doubt, a monopile installation sequence will have more than just these three critical phases, however, the principles of operation of the controller during other involved operational sequences are similar to those principles described above, albeit with changes in parameters and relationships.
When retracting the vessel from the finally installed monopile, the gripper is opened, retracted and the vessel is free to clear from the site. Various stiffness and/or damping parameter and gain parameter changes may be performed by the supervisory controller, with or without human input, also during this step without changing the concept of the proposed invention.
It is understood that while a control system has been described above, any statements made throughout this disclosure with respect to the control system likewise apply to a corresponding control method (and vice versa).
Further, the disclosure is not restricted to the above described embodiments which can be varied in a number of ways within the scope of the claims.
Various embodiments may be implemented as a program product for use with a computer system, where the program(s) of the program product define functions of the embodiments (including the methods described herein). In one embodiment, the program(s) can be contained on a variety of non-transitory computer-readable storage media, where, as used herein, the expression “non-transitory computer readable storage media” comprises all computer-readable media, with the sole exception being a transitory, propagating signal. In another embodiment, the program(s) can be contained on a variety of transitory computer-readable storage media. Illustrative computer-readable storage media include, but are not limited to: (i) non-writable storage media (e.g., read-only memory devices within a computer such as CD-ROM disks readable by a CD-ROM drive, ROM chips or any type of solid-state non-volatile semiconductor memory) on which information is permanently stored; and (ii) writable storage media (e.g., flash memory, floppy disks within a diskette drive or hard-disk drive or any type of solid-state random-access semiconductor memory) on which alterable information is stored.
Elements and aspects discussed for or in relation with a particular embodiment may be suitably combined with elements and aspects of other embodiments, unless explicitly stated otherwise.
Number | Date | Country | Kind |
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2027739 | Mar 2021 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/056256 | 3/10/2022 | WO |