The disclosure relates to, a method and to a system for operating one or more tugboats, in particular remote-controlled tugboats, such as e.g. an unmanned remote-controlled and optionally partially autonomously operating tugboats.
Assist operations, for e.g. assisting a marine vessel, such as e.g. a cargo vessel into port, to berth, from berth and out of port are conventionally carried out by manned tugboats that are operated by a captain assisted by a number of other crew members such as able seamen between zero and eight. Marine vessels need this assistance since they can typically not maneuver by themselves in the constraints of a port environment. The one or more tugboats are used to tow the marine vessel using a towing line that connects a winch on the tugboat to a capstan or bollard on the marine vessel. The connection point on the marine vessel can be near the stern or near the bow, but also anywhere there between. The one or more tugboats can also be used to push the marine vessel when needed. Hereto, the bow of the tugboat engages a strong point (push point) on the hull of the marine vessel to be assisted (hereafter referred to as “assisted vessel”). The strong points on the hull are generally marked with large letters TUG in order to allow the crew of the tugboat to identify the position of the strong point.
In general, a tugboat is a boat that operates in water spaces, harbors, bays, navigable channels, lakes and rivers, and the purpose of a tugboat is to transfer mechanical energy from the tugboat to the marine vessel to be towed/assisted, through its engine and its propulsors. Tugboats are adapted to their task by the provision of powerful diesel electric or diesel drives and have an extremely high power to tonnage ratio in order to be able to provide a large pulling/pushing force (bollard pull).
A tugboat's power is typically stated by its engine's horsepower and its overall bollard pull. The largest commercial harbor tugboats in the 2000s-2010s, used for towing container ships or similar, had around 60-65 tons of bollard pull, which is considered as 15 tons above “normal” tugboats.
Tugboats are highly maneuverable, and various propulsion systems have been developed to increase maneuverability and safety. Most tugboats are propeller-driven. Kort nozzles have been added to increase thrust per kW/hp. Nozzle-rudders omit the need for a conventional rudder. Tugboats are typically provided with a so-called Z-drive or (azimuth thruster) which is a pod that can rotate 360° allowing for rapid changes in the thrust direction.
In addition or as an alternative tugboats have been provided with a Voith-Schneider propeller (VSP), also known as a cycloidal drive which is a specialized marine propulsion system. The VSP is highly maneuverable, being able to change the direction of its thrust almost instantaneously. It is widely used on tugboats. From a circular plate, rotating around a vertical axis, a circular array of vertical blades (in the shape of hydrofoils) protrude out of the bottom of the boat. Each blade can rotate itself around a vertical axis. The internal gear changes the angle of attack of the blades in sync with the rotation of the plate, so that each blade can provide thrust in any direction, very similar to the collective pitch control and cyclic in a helicopter.
Operational costs for tugboat operations i.e. vessel assist operations consist for a major part of expenses to crew. There is therefore a desire to reduce the expenses for operating tugboats.
It is an object of the invention to provide system that overcomes or at least reduces the problems indicated above.
The foregoing and other objects are achieved by the features of the independent claims. Further implementation forms are apparent from the dependent claims, the description and the figures.
According to a first aspect, there is provided a system for controlling at least one tugboat, the system comprising: a control center for wirelessly remote controlling the at least one tugboat for assisting a marine vessel to maneuver, at least one tugboat suitable for assisting a marine vessel to maneuver, and a mobile remote control unit configured to wirelessly control said tugboat once it has arrived at said particular position, said mobile remote control unit being configured to issue thrust commands to said tugboat and said tugboat being configured to carry out said thrust commands to said assisted marine vessel.
By providing a control center for controlling a at least one remote controlled tugboat the tugboat can be operated from a control center and the number of crew members needed on the tugboat can be reduced.
In a first possible implementation form of the first aspect the at least one tugboat is provided with an optical sensor arrangement or camera arrangement, preferably with a 360° field of vision in the horizontal plane of the area around at least one tugboat, a transmitter for wirelessly transmitting the signal of the optical sensor arrangement or camera arrangement to the control center and the control center being provided with a receiver for receiving the signal from the optical sensor and the control center being provided with display screens for displaying, preferably real-time, and even more preferably real-time and on a 360° circular array of display screens, the signal of the optical sensor arrangement or camera arrangement to a human operator.
In a second possible implementation form of the first aspect the at least one tugboat is provided with an acoustic sensor arrangement, preferably a directional acoustic sensor arrangement with a 360° field of hearing in the horizontal plane, a transmitter for wirelessly transmitting the signal of the acoustic sensor to the control center and the control center being provided with a receiver for receiving the signal from the acoustic sensor and the control center being provided with transducers for reproducing the signal of the optical sensor, preferably real-time, even more preferably real-time and spatially, in the control center.
In a third possible implementation form of the first aspect the at least one tugboat comprises a positioning system, preferably satellite-based positioning system, and the at least one tugboat being configured to transmit its position as determined by the positioning system wirelessly to the remotely located control center.
In a fourth possible implementation form of the first aspect the at least one tugboat comprises a navigation system configured to sail the tugboat, preferably autonomously, from its present position, such as for example a berth position, to a target position, such as for example a mobilization position, received from the control center.
In a fifth possible implementation form of the first aspect the at least one tugboat comprises a controller configured to berth the tugboat autonomously, the controller being configured to accurately react to the near environment of the at least one tugboat to avoid overloading of berth or hull of the at least one tugboat.
In a sixth possible implementation form of the first aspect the tugboat is provided with a crane or robot arm and a controller for controlling the crane or robot arm, the controller being configured to wirelessly receive instructions from the control center for operating the crane or robot arm.
In a seventh possible implementation form of the first aspect the at least one tugboat comprises a control and communication device configured to receive and execute instructions wirelessly received from the control center, and wherein the control center comprises a communication device configured to transmit instructions to the control and communication device on the at least one tugboat.
In an eighth possible implementation form of the first aspect the system further comprises a, portable, control unit for a pilot, the pilot preferably being located in the vicinity of at least one tugboat, the control unit being configured to allow the pilot to wirelessly send thrust instructions to the at least one tugboats.
In a ninth possible implementation form of the first aspect the at least one tugboat is configured to follow an assisted marine vessel at a substantially constant distance, preferably with a fixed relative position to the assisted marine vessel, upon receipt of instructions accordingly, received from the control unit or from the control center.
In a tenth possible implementation form of the first aspect the augmented reality is overlaid on the display screens, both for sound and preferably also for obstacles in the course of the tugboat.
In an eleventh possible implementation form of the first aspect the tugboat is unmanned, and preferably at least partially autonomously operating.
According to a second aspect, there is provided a method for controlling at least one tugboat that is suitable for assisting a marine vessel to maneuver, from a remotely located control center, the method comprising: providing at least one tugboat, providing a remotely located control center, sending instructions wirelessly from the remotely located control center to at least one of the at least one tugboat for said tugboat to sail to a particular position for assisting a marine vessel to maneuver, receiving the instructions wirelessly on the at least one tugboat, said at least one tugboat sailing to said particular position, providing a mobile remote control unit in the vicinity of said particular position, issuing thrust commands from said mobile control unit to said tugboat, and said tugboat being to carrying out said thrust commands to said assisted marine vessel.
In a first possible implementation form of the second aspect the method comprises a human pilot operating said mobile remote control unit, preferably whilst being located on said assisted vessel.
In a second possible implementation form of the second aspect control of said tugboat passes from said control center to said mobile remote control unit when said tugboat assists said marine vessel to maneuver.
In a third possible implementation form of the second aspect the method further comprises the at least one tugboat autonomously sailing from its present position to the particular position, preferably including the at least one tugboat navigating autonomously from its present position to the particular position.
In a fourth possible implementation form of the second aspect sending instructions wirelessly comprises sending instructions to the at least one tugboat to follow an assisted marine vessel at a constant distance, preferably an assisted marine vessel that is connected to the at least one tugboat by a towing line with no tension on the towing line.
In a fifth possible implementation form of the second aspect the method further comprises detecting optical and/or acoustical signals with sensors on the at least one tugboat, and sending the signal from the detected the goals and/or acoustical sensors wirelessly to the remotely located control unit.
In a sixth possible implementation form of the second aspect the method further comprises sending instructions from a remote control unit, for example a portable remote control unit on an assisted vessel operated by a pilot, to the at least one tugboat to deliver the free end of a towing line connected to the at least one tugboat to a recipient on a marine vessel to be assisted, particularly to a recipient on a particular position on a marine vessel to be assisted, and the at least one tugboat delivering the free end of the towing line to the recipient.
In a seventh possible implementation form of the second aspect the method further comprises sending instructions from a remote control unit, for example a portable remote control unit on an assisted vessel operated by a pilot, to the at least one tugboat to reel in a towing line, and the at least one tugboat reeling in the towing line.
In an eighth possible implementation form of the second aspect the method further comprises sending instructions from a remote control unit, for example a portable remote control unit on an assisted vessel operated by a pilot, for a thrust command with a given size and direction to the at least one tugboat for the at least one tugboat applying thrust of a size and direction to the assisted marine vessel in accordance with the instructions received from a remote position and the at least one tugboat applying thrust with a size and direction as instructed to the assisted marine vessel.
These and other aspects of the invention will be apparent from and the embodiment(s) described below.
In the following detailed portion of the present disclosure, the invention will be explained in more detail with reference to the example embodiments shown in the drawings, in which:
The marine vessel 1 is provided with bollards and capstans at several positions along the side of the vessel for attachment of a towing line 10. Typically, bollards and capstans are provided near the stern 6 and near the bow 7 and at regular intervals along the sides of the hull 3. The towing lines 10 are attached at a suitable position on the marine vessel 1 in accordance with the actual needs. Thus, one end of the towing line 10 is attached to the marine vessel 1 and the other end of the towing line 10 is attached to a tugboat 2.
In an assist operation a pilot is on board of the assisted marine vessel 1 and the pilot is in charge of controlling the thrust actions of the tugboats 2. In a conventional set up the pilot will issue thrust commands via wireless radio communication to the captains of the respective tugboats.
The present embodiment relates though to tugboats 2 that are preferably unmanned and preferably partly remote controlled and preferably partly autonomously operating. The tugboats 2 are preferably capable of operating partially autonomously in response to (wireless) received instructions and partially under direct (wireless) remote control.
The system controller 250 will e.g. be located in a control center 200 on shore and will normally not be in visual contact with the tugboats 2. The system controller 250 is in control of a fleet or plurality of tugboats 2. The system controller 250 decides which tugboats 2 are sent into action and instructs the navigation of the tugboats 2 from berthing position to mobilized position and vice versa. The system controller 250 is therefore used to instruct the tugboat 2 to navigate to a particular position, and in an embodiment the tugboat 2 will navigate to the particular position autonomously after having received instructions thereto. When the tugboat 2 has arrived at mobilization position, the control of the tugboat 2 will be taken over by a pilot using the remote control unit 150. The remote control unit 150 is used to control the tugboats 2 while assisting a marine vessel 1 to maneuver. The remote control unit 150 is operated by the pilot and the pilot will typically be in visual contact with the tugboats 2 used to assist the marine vessel 1 to maneuver. Alternatively or additionally the system land-based control center 200 controls the tugboats throughout the whole operation. In this way one or more tug boats is remotely controlled from the system controller 250 located on the shore. Advantageously by keeping the pilot in the land-based control center 200, the pilot can be kept out of danger if the environmental conditions are treacherous.
The camera on the crane with its signal broadcasted to the remote control center 200 or to the remote control unit 150 allows an operator in the remote control center 200 or the pilot via the remote control unit 150.
One or two propulsors in the form of one or two azimuth thrusters 28 (nozzle drives) are provided near the stern 26 (although other positions are possible) and provide thrust in any desired (horizontal) direction. The azimuth thrusters 28 are connected to internal combustion engines (diesel engine) or to diesel-electric drives or to electric drive motors for providing thrust, e.g. a bollard pull of at least 40 tons. Fuel tanks and/or electric batteries are also accommodated in the hull 23.
The tugboat 2 is provided with a superstructure 25 that houses a power winch 21; in this embodiment two power winches side-by-side on one shaft, and provides support for a radar mast 30 that is provided with a radar antenna 31 and other antennas for radio communication. The superstructure 25 also provides the support for a crane 22 and two LIDAR sensors 17.
The crane 22 is used to handle a towing line 10 that is at least partially reeled up to the power winch 21, i.e. to pick up the free end of the towing line 10 and to hand the towing line 10 to an able seaman or other crew member on the deck of the assisted vessel 1. Another task of the crane 22 is to handle a mooring rope and to handle the electrical connection to shore when the tugboat 2 is berthed.
One towing line 10 extends from the power winch 21 to and through an aperture in a bitt 11 that is located forward of the superstructure 25. The power winch 21 is preferably a double winch and another towing line 10 (
The bitts 11 and 12 guide the towing lines 10 and ensure that the towing lines 10 has the right angle relative to the power winch 21 for correct reeling in and reading out of the towing lines 10. The free end of the towing line 10 is held by a grasping tool at the free end of the crane 22. A so-called painter 13 is attached to the free end of the towing line 10. The painter 13 is a light line that can be handled by the crew and be passed through a fairlead in the assisted marine vessel 1 to a capstan on the assisted marine vessel 1. The heavy towing line 10 can then be pulled up to the deck of the marine vessel 1 through the fairlead by activation of the capstan.
The superstructure 25 carries the radar mast 30 on which the radar antenna 31 is provided. The radar mast 30 is also provided with other antennas for radio communication purposes.
The superstructure 25 also serves as the support for a crane 22. In this embodiment the crane 22 is a knuckle boom crane, but any other suitable type of crane or robot arm could also be used. In an embodiment the crane arm is provided with a fire monitor (not shown) or at least provided with means for securing a fire monitor to the crane arm.
The crane 22, the power winch 21 and other equipment on the tugboat 2 can be hydraulically powered. Hereto, the tugboat 2 is provided with a hydraulic pump or pump station that provides pressurized hydraulic fluid for these consumers under control from the electronic control unit 50.
The crane 22 is pivotally suspended from the superstructure 25 around a vertical axis of the tugboat 2 by a preferably annular base member 35. The proximal end of the inner section 32 of the crane arm is hinged to the base member 35 and the distal end of the inner section 32 is hinged to the outer section 33 of the crane arm by a hinge 34. The outer section 33 of the crane arm is telescopic for increasing the reach of the crane.
A first hydraulic cylinder 36 is at its proximate end hinged to base member 35 and at its distal end hinged to the outer section 33. The first hydraulic cylinder 36 can be used to lower end raise the crane arm. The crane arm is shown in a lowered, rest position in
A tool 42 is provided at the free distal end of the crane arm. In an embodiment the tool 42 is a grasping tool, but it is understood that the tool 42 is an exchangeable tool and can be exchanged for a tool for different purposes, in accordance with needs, such as e.g. a fire monitor or electrical connector, a hook, searchlight. Hereto, the tugboat 2 is provided with an assembly of tools that can be fitted to the free distal end of the crane arm. The assembly of tools is stored on the tugboat 2 in a position that can be reached by the free end of the crane 22 so that the tool at the end of the free end of the crane arm can be changed without the need of physical presence of a human operator.
The crane arm is provided with sensors (not shown) that indicate the position of the crane arm. The crane arm is in an embodiment provided with sensors (not shown) for determining the force/load acting on the crane arm.
The tugboat 2 is provided with a support 38 for the crane arm on which the crane arm can rest when it is not in action, i.e. for providing a part position for the crane arm. In an embodiment the support 38 is an integral part of the bitt 11 on the foredeck, and preferably has the form of a yoke. The tugboat can be provided with two supports, one support 38 on the foredeck and one support 39 on the aft deck, so that the crane arm can be part in a forward position or in a rearward position. The support 39 is preferably an integral part of the bitt 12 and shaped like a yoke. The support 38, 39 acts as a reference point for calibrating the position of the crane arm. In an embodiment the electronic control unit 50 is configured to recalibrate the crane arm at regular time intervals at support 38 or support 39.
The free, distal end of the towing line 10 is in an embodiment provided with a splice eye 14. The towing line 10 is preferably of a synthetic material that is both strong and light enough to float. Such type of towing line is commercially available. A bushing 15 is provided around the towing line 10 at a position close to the splice-eye 14. The details of the bushing 15 and its function will be described in greater detail further below.
In
In an embodiment the tugboat 2 is provided with an optical sensor arrangement or digital camera arrangement, preferably with a 360° field of vision in the horizontal plane to offer a full view of the area around the tugboat 2. The camera arrangement can operate in the visual part of the spectrum and/or outside the visual part of the spectrum. The electronic control unit 50 is in an embodiment configured to transmit the signal of the camera arrangement wirelessly to the control center 200 or to the remote control unit 150.
The electronic control unit 50 is provided with a navigation module, a collision avoidance module and an image recognition module, which will be described in greater detail further below.
The control center 200, illustrated in
In an embodiment augmented reality is overlaid on the display screens 277, both for e.g. information about sources of sound (distance and direction) and obstacles in the course of the tugboat 2.
The tugboat 2 is provided with an acoustic sensor, preferably a directional acoustic sensor arrangement with a 360° field of hearing in the horizontal plane. In an embodiment the electronic control unit 50 is configured to transmit the signal from the directional acoustic sensor arrangement to the control center 200 or to the remote control unit 150. The electronic control unit 250 in the control center 200 is configured to represent information on the direction and location of the source of the detected sound on instruments or on the display screens, e.g. by augmented reality.
The control center 200 is provided with transducers (loudspeakers) 274 for reproducing the signal of the optical sensor arrangement received via the wireless communication device 254, preferably real-time, even more preferably real-time and spatially, to a human operator in the control center 200. Thereby, the human operator gets an impression of the direction of the source of sound that has been detected.
The control center 200 is further provided with at least one control console 280 for allowing operators to enter instructions or commands for controlling the operation of the tugboats 2. The control console 280, the wireless communication device 254, the loudspeakers 274 and the display screens 272 are all connected to an electronic control unit 250. The electronic control unit 250 is configured to receive instructions and commands via the control console 280 from a human operator and to transmit these instructions/commands wirelessly to the tugboat 2 concerned. Electronic control unit 250 is also configured to reproduce information received from the tugboats on the display screens 272, via the loudspeakers 274 and on instruments and/or displays in the control console 280.
The positioning system on the tugboat 2 is in an embodiment a satellite-based positioning system (e.g. GPS) and the tugboat 2 is in an embodiment configured to transmit its geographical position as determined by the positioning system wirelessly to the control center 200 and/or the remote control unit 150.
In an embodiment the electronic control unit 50 is configured to berth the tugboat autonomously 2. Hereto, the electronic control unit 50 is configured to accurately react to the near environment of the at least one tugboat 2 to avoid overloading of berth or hull 23. The electronic control unit uses in particular the signal from the motion reference sensor, including acceleration information and jerk (change of acceleration, i.e. the derivative of acceleration with respect to time).
In an embodiment the method for controlling at least one tugboat 2 from the remotely located control center 200 comprises providing a tugboat 2, providing a remotely located control center 200, sending instructions wirelessly from the remotely located control center 200 to the at least one tugboat 2, receiving the instructions wirelessly on the tugboat 2, and carrying out the instructions with the tugboat 2.
In an embodiment sending instructions wirelessly comprises sending instructions for the tugboat 2 to sail to a particular position, the tugboat 2 receiving the instructions and the tugboat 2 sailing to the particular position. In an embodiment the method comprises the tugboat 2 autonomously sailing from its present position to the particular position, preferably including the tugboat 2 navigating autonomously from its present position to the particular position.
In an embodiment sending instructions wirelessly comprises sending instructions to the tugboat 2 to follow an assisted marine vessel 1 at a constant distance, preferably an assisted marine vessel that is connected to the tugboat 2 by a towing line 10 with no tension on the towing line 10.
In an embodiment the method comprises sending instructions from the remote control unit 150, to the at least one tugboat 2 to deliver the free end of a towing line 10 connected to the tugboat 2 to a recipient on a marine vessel to be assisted 1, particularly to a recipient on a particular position on the assisted marine vessel 1, and the tugboat 2 delivering the free end of the towing line 10 to the recipient using the crane 22 to deliver the free end of the towing line 10 to a crew member on the deck of the assisted marine vessel 1.
In an embodiment the method comprises sending instructions from a remote control unit, for example the portable remote control unit 150 on the assisted marine vessel 1 operated by a pilot, to the tugboat 2 to reel in or reel out the towing line 10, and the tugboat 10 reeling in for reeling out the towing line 10 by activation of the power winch 21.
In an embodiment the method comprises sending instructions from a remote control unit, for example the portable remote control unit 150 on the assisted vessel 1 operated by a pilot, for a thrust command with a given size and direction to the tugboat 2 for the tugboat 2 to apply thrust of a size and direction to the assisted marine vessel 1 and the tugboat 2 applying thrust with a size and direction as instructed to the assisted marine vessel 1.
In an embodiment the method comprises sending instructions from a remote control unit, for example the portable remote control unit 150 on the assisted vessel 1 operated by a pilot, for thrust position and optionally an optimum thrust angle, and the tugboat 2 moving to the indicated thrust position and optimum thrust angle.
A first RFID reader is associated with each of the bitts 11, 12 and the second RFID reader is associated with the free end of the crane 22. The communication device 54 allows the electronic control unit 50 to receive information and to send information.
The electronic control unit 50 is configured to control the operation of the power winch 21, the operation of the engine/drive motor (power) and the operation of the nozzle drive 28 (angle). The electronic control unit 50 is also configured to control the operation of the crane 22 and of the grasping tool (gripper) 42.
In an embodiment, the signals from the camera, RADAR and LIDAR, the positioning system and if available sonar are transmitted real time via the communication device 54 to the control unit 250 in the control center 200 or to the portable remote control unit 150 of the pilot.
The crane 22 is mounted centrally on the tugboat 2 so it is able to handle the towing rope 10 on the foredeck as well as on the aft deck. The central position will also allow the crane 22 to reach over the side in a berthing situation and when delivering the towing line 10 to an able seaman or other crew member on an assisted vessel 1.
The electronic control unit 50 is configured to control the operation of the crane in response to the position and motion sensors on the crane and/or the motion reference unit of the tugboat to and in response to the RFID reader on the crane.
In an embodiment the crane 22 is provided with a motion compensation unit. In an embodiment the motion compensation unit is provided with an element that can pivot about at least two orthogonal axes and wherein the motion compensation unit comprises actuators for pivoting the element controllably around the at least two orthogonal axes. In an embodiment the crane 22 is placed on a motion compensation platform, i.e. the motion compensation unit is formed by the motion compensation platform. The motion compensation platform may comprise three or more linear actuators that support the platform and around the control of the electronic control unit 50. In another embodiment the motion of the free end of the crane 22 is compensated by using the actuators of the crane, i.e. the motion compensation unit is formed by the actuators of the crane 22. In an embodiment yaw of the tugboat 2 is at least partially compensated by rotation of the crane 22 and surge heave are least partially compensated by raising or lowering and/or extending retracting movements of the crane arm.
The motion sensor (motion reference unit) informs the electronic control unit 50 of the motions of the tugboat 2, such as pitch, roll and yaw, more preferably including pitch, roll, yaw, heave, search and sway. The electronic control unit 50 is configured to compensate for the movement of the tugboat 2 in order to keep the free end of the crane arm substantially motion free relative to the global coordinate system. Alternatively, the electronic control unit 50 can be in receipt of a motion and/or position sensor on board of the assisted vessel 1 and keep the free end of the crane arm substantially motion free relative to the assisted marine vessel 1. In an embodiment the electronic control unit 50 is configured to ignore the actual sailing speed of the tugboat 2, i.e. the motion caused by the sailing speed of the tugboat is not taken into account when compensating. Thus, the free end of the crane arm can be stabilized while the tugboat 2 is following the assisted marine vessel 1. By compensating for the motion of the tugboat 2 or by keeping the free end of the crane arm motion free relative to the assisted vessel 1 it becomes much easier for a crew member on the deck of the assisted vessel 1 to grasp or catch the towing line 10 or the painter 13 attached thereto when the crane arm hands the towing line 10 to the crew member on the deck of the assisted vessel 1. The electronic control unit 50 is configured to compensate the motion of the free end of the crane arm when establishing an electrical connection to shore. Thus, the electronic control unit 50 is configured to minimize the motion of the free end of the crane caused by the motion of the tugboat in situations where this is useful. When the crane 22 is used for collecting the free end of the towing line 10 from its home (parked) position at the bitt 11 or 12, the electronic control unit 50 uses the coordinate system of the tugboat 2 itself as reference. The electronic control unit 50 is configured to use the rest position on the support 38 or 39 to recalibrate the position of the free end of the crane arm.
The electronic control unit 50 is provided with a navigation module allowing the electronic control unit 52 to navigate the tugboat 2 autonomously from a present position to a received instructed position, for example a position near a marine vessel 1 that needs assistance. The navigation module includes nautical charts required for safe navigation of the tugboat 2 and forms a navigation system for the tugboat 2. The navigational module allows the electronic control unit 50 to navigate the tugboat 2 from berth to a target position, e.g. a mobilization position, i.e. a position where the tugboat 2 is to be deployed for assisting a marine vessel 1 to maneuver. The navigation module also allows the electronic control unit to navigate the tugboat back to berth from mobilized position. Thus, upon receiving instruction via the wireless communication unit 54 the electronic control unit 50 sails the tugboat 2 autonomously from berth to a mobilization position and vice versa. Collision with obstacles in the way path of the tugboat 2 is avoided by the electronic control unit deploying the collision avoidance module that is explained in greater detail further below. With the assistance of the collision avoidance unit the electronic control unit 50 takes evasive action if needed in order to avoid a collision with an object, such as another marine vessel, land, a bridge pillar or shallow waters.
The navigation system is preferably an autonomous navigation system configured to maneuver the tugboat 2 to in all scenarios within the intentions of COLREG. COLREG compliant algorithms are be stored in the electronic control unit 50 so that electronic control unit 50 can make the necessary course corrections in order to safely navigate in all scenarios.
The collision avoidance module comprises regulatory information on preventing collisions, such as e.g. COLREGs (Convention on the International Regulations for Preventing Collisions at Sea, 1972) and takes evasive action in accordance with the rules. The collision avoidance module enables the electronic control unit 2 to determine when and which evasive action to take.
The electronic control unit 50 is also provided with an image recognition module allowing the electronic control unit 50 to recognize an image indicating a strong point on the side of the hull 3 and assisted marine vessel 1. In an embodiment the electronic control unit is with the help of the image recognition module capable of recognizing a crew member on deck: assisted marine vessel that is ready to receive a towing line 10.
Pivoting movement of the two parts 71 about the hinge pin 7 can be prevented by the action of an electromagnetically, pneumatically or hydraulically controlled locking pin 73. An electric, pneumatic or hydraulic actuator 74 controls the position of the locking pin 73 between a retracted position in which the locking pin 73 does not extend into a cylindrical recess 77 between the two parts 71 and an extended position (shown in
The hinge pin 78 extends from the grasping tool 42 into recesses in opposing arms of a yoke 84 that serves to suspend the grasping tool 42 from the free end of the crane. The grasping tool 42 according to the first embodiment can be suspended from the free end of the crane by a yoke in a similar way.
In an embodiment the power winch 21 is provided with a rotational position sensor (not shown) coupled to the electronic control unit 50, and through this rotational position sensor the electronic control unit 50 is roughly informed of the length of towing line 10 that is reeled out.
In an embodiment the power winch 21 is provided with a force or torque sensor, and the electronic control unit 50 is configured to limit the force applied to the towing line when reeling in using a signal from the force or torque sensor. The electronic control unit 50 preferably being configured to limit the force applied to the towing line 10 by the power winch 21 when towing in towards the end stop.
When the electronic control unit 50 instructs the power winch 21 to reel the towing line 10 a sudden increase in the signal from the force sensor on the power winch 21 informs the electronic control unit 50 to stop reeling in the towing line 10 since it is in its home (part) position.
In an embodiment the towing line 10 is provided with a first RFID tag 90 at or near the free end of the towing line 10. The first RFID tag is preferably a passive RFID tag 90. The tugboat 2 is in an embodiment provided with a first RFID reader, preferably an active RFID reader, the first RFID reader being placed such that the RFID reader detects the first RFID tag 90 when the free end of the towing line 10 is in close proximity of the bitt 11 or 12, i.e. in its home or part position. Preferably, there are provided two first RFID readers, one near each bitt 11, 12. The first RFID tag 90 is preferably a passive tag, and the first RFID reader is preferably an active RFID reader.
The first RFID tag 90 is in an embodiment provided in or at the hard splice eye 14. In another embodiment the first RFID tag 90 is provided at the end stop 15.
The first RFID reader is placed such that the RFID reader detects the first RFID tag 90 when the end stop 15 or the hard splice ring 14 is in close proximity of the bitt 11 or 12.
The electronic control unit 50 is coupled to the first RFID reader, and the electronic control unit 50 is configured to terminate the operation of the power winch 21 during a reeling in operation when the first RFID reader detects the presence of the first RFID tag 90 at bitt 11 or 12.
In an embodiment the crane 22 is provided with a second RFID reader, preferably an active RFID reader. The second RFID reader is being placed in close proximity to the gripping tool 42 so that the second RFID reader will detect the first RFID tag when the gripping tool is in a suitable position for gripping the towing line at or near the splice eye 14. The electronic control unit 50 will thus be informed when the gripping tool 42 is in the vicinity of the free end of the towing line 10.
The towing line 10 is in an embodiment provided with a plurality of RFID tags 90 spaced along the length of the towing line 10 at intervals, preferably regular distance intervals. The first RFID reader is placed such that it registers an RFID tag 90 of the plurality of RFID tags when such an RFID passes through the aperture 18 (
In another embodiment the towing line 10 is provided with a plurality of optical tags spaced along the length of the towing line 10 at intervals, preferably regular distance intervals, an optical reader connected to the electronic control unit 50 at the power winch 21, at the bitt 11, 12 or between the power winch 21 and the bitt 11, 12 detects the optical tags for determining the length of the towing line 10 that is reeled out.
The support 38 is preferably an integral part of the bitt 11, 12 and comprises a yoke shaped support formed by two wings 44 that provide two tapering guide services 43 for guiding the crane arm towards the center of the support 38. The support surface of the yoke is preferably inclined to match the angle of the crane arm resting thereon in its rest (parking) position.
In an embodiment the electronic control unit 50 is provided with instructions for moving the grasping tool 42 from any arbitrary position to a first reference position close to the bitt 11, 12, by manipulation of the crane arm. The electronic control unit 50 is provided with instructions to activate the grasping tool to grasp the towing line 10 when the grasping tool 52 has arrived at the first reference position. The electronic control unit 50 is also provided with instructions for moving the grasping tool 42 at the free end of the crane arm from the first reference position to an instructed position, the instructed position preferably being a position received wirelessly by the communication device 54 from a remote transmitter, such as e.g. the remote control unit 150 of the pilot. The electronic control unit 50 is also configured to reel out the towing line 10 simultaneously with the crane arm moving the free end of the towing line towards a desired position. Thus, a certain tension can be maintained on the towing line 10 while the crane 22 moves the free end of the towing line 10 from the parked position to a desired position.
The electronic control unit 50 is configured to deactivate/open the grasping tool 42 for releasing the towing line 10 when the grasping tool 42 has arrived at the instructed position and/or when the medication device 54 on the tugboat 2 has received a confirmation from a remote transmitter to deactivate/open the grasping tool i.e. when the crew member on the deck of the assisted vessel 1 has received the towing line 10. The remote control unit 150 of the pilot is provided with an input means to indicate that the towing line 10 has been delivered so that the grasping tool 42 can release the towing line. Alternatively, the crew member can be provided with his portable wirelessly capable unit for issuing the acknowledgment that the towing line 10 has been received.
In an embodiment the tugboat 2 is provided with a second reference point for calibrating the crane or robot arm in a coordinate system relative to the tugboat, the second reference point can be a fixed structure provided on the tugboat, such as the support 38 or 39. The electronic control unit 50 is configured to recalibrate the crane 22 at the second reference point at given time intervals.
The electronic control unit 50 is configured to reel in the towing line 10 by activation of the power winch 21 upon receipt of an instruction thereto via the communication unit 54, i.e. when the towing line 10 has been received released from the assisted marine vessel 1. The instruction to reel in the towing line 10 can originate from the remote control unit 150, e.g. when the pilot has decided that the assist operation is completed and a crew member on the system vessel 1 has detached the towing line 10 from the bollard or capstan on the system marine vessel 1. An additional remote control unit (not shown) can be carried by the crew member handling the towing line 10 on the deck of the assisted marine vessel 1 for enabling the crew member concerned to communicate wirelessly to the tugboat 2 that the towing line 10 has been released from the assisted marine vessel 1 and can be reeled in by the tugboat 2. This additional remote control unit for use by the crew member that handles the towline on deck is in an embodiment combined with the beacon X.
During the reeling in operation the electronic control unit 50 keeps track of the length of towline 10 that is reeled out using the signal from a rotational position sensor on the power winch 21 and if available, using the signal from the first RFID reader or the optical reader.
The electronic control unit 50 is configured to reel out the towing line 10 by activation of the power winch 21 upon the receipt of instructions thereto via the location device 54 so that the tugboat 2 can assume the optimal desired thrust position at an optimal distance from the assisted marine vessel 1. The instruction to reel out the towing line 10 can be issued by the remote control unit 150 of the pilot.
In an embodiment the crane arm is provided with a digital camera and the image recognition unit is configured to recognize a graphical marking on the hull of a marine vessel 1 to be assisted or to recognize a crew member on deck of the assisted marine vessel 1 or to recognize a fairlead on the assisted marine vessel 1 or to recognize a docking station or berthing location. In an embodiment the signal from the camera is wirelessly transmitted to a remotely located recipient, such as the control center 200, via the communication device 54.
In an embodiment the tugboat 2 is provided with a sensor (not shown) for detecting a position of a beacon X (
In an embodiment the electronic control unit 50 is configured to select an exchangeable tool from the assembly of tools in receipt of an instruction to select an exchangeable tool. The instruction to select an exchangeable tool comprising in an embodiment information for selecting a particular exchangeable tool in relation to a task to be carried out by the crane 22. The instruction to select a changeable tool can originate from the electronic control center 200 as part of an autonomous operation or from a remote sender, such as the remote control unit 150 of the pilot.
In an embodiment the remote control unit 150 is configured for wirelessly controlling the operation of at least one tugboat 2 from a position remote from the at least one tugboat 2, e.g. from the system marine vessel 1 by a pilot entering instructions into the remote control unit 150 via a user interface of the remote control unit 150. The remote control unit comprises a transmitter-receiver arrangement for transmitting and receiving information between the control center and the tugboat 2. Similarly, the tugboat 2 comprises a reciprocal transmitter-receiver arrangement for send and receiving information to and from the remote control unit 150. The remote control unit 150 is configured to send command instructions to the tugboat 1 to control movement thereof.
The remote control unit 150 is configured to transmit thrust commands wirelessly to the at least one tugboat 2. The electronic control unit 50 is configured to control the propulsors of the tugboat 2 for executing the thrust commands wirelessly received from the remote control unit 150. In an embodiment a thrust command comprises a vector indicating size and direction of the thrust to be applied.
Thrust commands are in an embodiment executed as vectors in relation to the hull 3 of the assisted marine vessel 1. The electronic control unit 50 is in an embodiment configured to block invalid commands, i.e. commands leading to collision between vessels involved.
In an embodiment the remote control unit 150 is configured to transmit follow the assisted marine vessel 1 instructions to the at least one tugboat 2. The electronic control unit 50 is configured to control the tugboat 2 to follow the assisted marine vessel 1 autonomously at a constant distance to the assisted marine vessel 1 for executing the received instruction. The follow the assisted marine vessel 1 instruction may include instructions on the tension required on the towing line 10 during the follow the assisted marine vessel 1 operation.
In escort (follow me mode) the desired position of the tugboat to is in an embodiment defined as either a relative vector from a reference point on the assisted marine vessel 1 or as an arbitrary point in the proximity of the assisted marine vessel 1.
The electronic control unit 50 is in an embodiment configured to transmit sensor data to the remote control unit 150, and the remote control unit 150 is in an embodiment configured to receive and present the received information to the pilot. Thus, the pilot can be informed of e.g. the exact position of the tugboat 2, the amount of thrust and direction of thrust applied and the tension on the towing line 10.
In an embodiment the remote control unit 150 is configured to transmit its (GPS) position to the tugboat 2 in order to allow the tugboat 2 to identify the position of the assisted marine vessel 1, i.e. in order to facilitate the tugboat 2 to reach the mobilized position in the vicinity of the assisted marine vessel 1.
The electronic control unit 155 is configured to display the location of the assisted marine vessel 1 in the form of an outline of the vessel on the display screen together with the tugboats 2 connected thereto (TUG1, TUG2, . . . TUGn) on a navigational chart, as shown in
By using the touchscreen 172 the pilot can indicate a new thrust size and direction, indicated in
When the communication unit 54 on the tugboat 2 receives the new thrust command from the remote control unit 150 the electronic control unit 50 controls the engines/motors and azimuth thrusters 28 accordingly in order to apply thrust of a size and direction to the assisted marine vessel 1.
The remote control unit 150 can also be used by the pilot to issue a follow assisted marine vessel command to the tugboat 2. In response to receiving follow the assisted marine vessel instructions by the wireless communication unit 54 the electronic control unit 50 operates the engines and azimuth thrusters (nozzle drive) 28 accordingly. Thus, the electronic control unit 50 causes the tugboat 2 to follow the marine vessel 1 at a constant distance and even more preferable the electronic control unit causes the tugboat 2 to follow the assisted marine vessel 1 at a constant distance and a constant relative position with respect to the assisted marine vessel 1.
The remote control unit 150 is in an embodiment provided with loudspeakers for reproducing sounds picked up by the microphone (arrangement) on the tugboat 2 or for reproducing other information that the pilot needs to receive from the tugboat 2.
In an embodiment the tugboat 2 is provided with an automatic mooring system that uses a spreader bar 111 (
As shown in
The process in
The electronic control unit 50 is configured to pick up the coil 95 using the grasping tool 42 and the grasping element 97 from the deck of the boat 2 and to move the coil 95 towards and over the pole 99 on shore. Thus, an inductive electrical connection is established with shore that can be used to transmit power and/or data.
The electronic control unit 50 is configured to maintain the electrical connection while the boat is moored, so that e.g. batteries on board of the boat 2 can be charged, and electrical equipment on board the boat 2 can be supplied with electric power. The electronic control unit 50 allows the crane 22 arm to move freely to accommodate movements of the boat 2 relative to shore while the connector 95 is connected to the connection point in the form of the coil 99.
The electronic control unit 50 is configured to disconnect the electrical connection when the boat 2 has to leave berth, e.g. go into action. Hereto, the electronic control unit 50 is configured to grasp the grasping element 97 using the grasping tool 42 and to lift the coil 95 from the pole 99 with the coil on quay and to move the coil 95 to and over the pole 91 on deck.
In an embodiment the cable reel 98 automatically reels the power cable 96 in and out keeping a predetermined amount of tension on the power cable 96, using resilient or other suitable means.
In an embodiment the tugboat 2 is configured to automatically prevent capsizing or sinking due to an excessive load on the towing line 10. Hereto, the tugboat 2 is provided with a sensor arrangement configured for sensing the size and direction of the pulling force that the towing line 10 exerts on the tugboat 2. This sensor arrangement can be a combination of a sensor on the power winch 21 that determines the torque applied thereto and the strain gauge or the like at the bitts 11, 12, which is particularly helpful for determining the direction of the force that the towing line exerts on the tugboat 2. The tugboat 2 is also provided with a sensor arrangement configured for sensing the orientation of the tugboat. The motion sensor (emotion reference unit) can be used for this purpose. The electronic control unit 50 is in receipt of the signal of the above-mentioned sensors, and the electronic control unit 50 is informed of the size and direction of thrust generated by the propulsors. The electronic control unit 50 determines if the tugboat 2 exceeds a safety threshold on the basis of the sensed size and direction of thrust, the sensed size and direction of the pulling force, and the sensed orientation of the tugboat. The safety threshold can include a maximum inclination of the tugboat 2 relative to the horizon.
In an embodiment the electronic control unit 50 reduces the size of the thrust and/or changes the direction of thrust when the electronic control unit 50 has determined that a safety threshold has been exceeded. Preferably, the electronic control unit will communicate this reduction in thrust size and or change in the direction of thrust wirelessly via the communication device 54 to the control center 200 or to the remote control unit 150.
In an embodiment tugboat 2 is provided with an arrangement for disconnecting the tugboat 2 from the towing line 10 in response to a command from the electronic control unit 50, the arrangement preferably comprising a device for severing the towing line 10. The arrangement for disconnecting the tugboat 2 from the towing line 10 by severing preferably includes a knife or ax or the like or an element to apply heat to the typically polymer-based towing line 10 for severing the towing line 10.
The electronic control unit 50 is preferably configured to sever the towing line 10 when the electronic control unit 50 has determined that the tugboat 2 has exceeded a second safety threshold that is higher than the first safety threshold. In an embodiment the first and second safety thresholds are a risk of the tugboat capsizing and/or the first and second safety thresholds are a risk of the tugboat sinking.
In an embodiment the electronic control unit 50 is configured to determine the risk of the tugboat 2 capsizing or sinking on the basis of a computer model that simulates the behavior of the tugboat 2. Hereto, the electronic control unit 50 can be provided with a mathematical model of the tugboat 2 that simulates the behavior of the tugboat 2 in response to thrust, towing line force and direction and optionally waves.
Thus, in an embodiment the electronic control unit 50 determines the size and direction of thrust created by the propulsors of the tugboat 2, determining the size and direction of a pulling force applied to the tugboat 1 by a towing line 10, determines the orientation of the tugboat 2, and determines if the combination of the size and direction of thrust and the size and direction of pulling force and the orientation of the tugboat 2 exceed a safety threshold. The electronic control unit 50 can further be configured to adjust the size and/or direction of the thrust in order to prevent the tugboat 2 from exceeding the safety threshold. The electronic control unit can further be configured to sever the towline 10 when a safety threshold is exceeded.
In an embodiment the boat or ship (could be any type of boat or ship and does not need to be a tugboat 2) is provided with a collision prevention system that can assist the crew to avoid collision with obstacles such as e.g. other boats or ships. In an embodiment the boat or ship is configured to issue a warning to the crew if a first risk level is exceeded, and in an embodiment the boat or ship is also configured to take evasive action if the crew does take evasive action when a second risk level that is higher than the first risk level is exceeded. The collision prevention system can also be used for an autonomously operating boat or ship, in which case the collision prevention system issues an alarm that is transmitted wirelessly to a remote recipient when a first risk level is exceeded, and the navigation prevention system takes evasive action when the second risk level is exceeded.
As shown in
The first collision zone 80 and the second collision zone 81 are larger in the direction of the heading of the boat or ship and will become larger at least in the direction of the heading with increasing speed of the boat or ship 2 and preferably also slightly larger in the direction traverse to the heading.
As shown in
The collision prevention system is configured to assign a category to each detected obstacle. Examples of categories are e.g. watercraft, fixed structures, shallow water, land and categories preferably including a plurality of categories of watercraft, including boats, ships, and said plurality of categories of boats yet even more preferably including fishing boats, tugboats, speedboats, yachts and sailing yachts and said categories of ships comprising cargo vessels, navy vessels, cruise ships and ferries. However, it is understood that this list merely provides examples and this list is not exhaustive.
Each category has associated information on e.g. the likeliness of the detected obstacle to change position, change course and/or change speed, preferably in relation to the navigation plan of the detected obstacle (if available) and using a mathematical model of the detected obstacle (if available). Each category may also have associated thereto information on the shape and size of the first collision zone and the second collision zone, preferably in relation to the detected speed and heading (if any) of the detected obstacle.
In an embodiment the navigation system is configured to track the course of a detected obstacle. In an embodiment the navigation system is configured to determine the likeliness of a detected obstacle to change course and/or speed, preferably on the basis of the category in which the obstacle has been placed.
Based on the determined category and on the speed of the detected obstacle, the navigation system determines a collision zone 83 around each detected obstacle.
In the example of
Simultaneously, the collision avoidance system broadcasts its change in route, preferably using VHF communication such as standardized Marine VHF communication (e.g. channel 16, which is used for urgent safety messages) and preferably in accordance with international standards, such as e.g. “IMO Standard Marine Navigational Vocabulary”. In the event where both vessels have the same collision avoidance system, a standardized communication protocol will be used for the data exchange.
In an embodiment the portable control unit 150 can be used to enhance the traditional VHF communication from the assisted vessel to a conventional tugboat. The system is configured so that the pilot can issue a command to control the whole system, including the tugboats 2 and the assisted marine vessel 1 in dynamic positioning mode. The interface on the formal control unit 150 can include additional sensors to support the DP operation and enhance the position data available to the captain (of the assisted marine vessel 1) and pilot.
In an embodiment the tugboat 2 is provided with an automatic anchoring system (not shown). The automatic anchoring system can be provided a safety feature and the electronic control unit 50 can in an embodiment be configured to trigger the automatic anchoring system as a safe fall back, e.g. the failure mode supports this action.
In embodiment the tugboat 2 is fully Unmanned Surface Vessel (USV), i.e. the tugboat 2 is automated to an extent where it can be operated without a crew onboard, possibly assisted by instructions from a remote control station such as the remote control sensor 200 or the remote control unit 150. The remote control station is equipped so it is possible for a single operator to safely maneuver or supervise the tugboat 2 in all work scenarios. The operator will have a 360° view of the operating area around the tugboat 2 from the control station, preferably accompanied by 360° sound.
The communication shall provide high reliability and bandwidth for fast effective communication. In an embodiment the communication system is redundant in itself by using topology that utilizes several different communication channels. As a secondary fallback option a satellite based communication system is be provided.
While the preferred embodiments of the boat, tugboat, ship and method have been described in reference to the environment in which they were developed, they are merely illustrative of the principles of the invention. The elements of the various embodiments may be incorporated into each of the other species to obtain the benefits of those elements in combination with such other species, and the various beneficial features may be employed in embodiments alone or in combination with each other. A single controller or control unit may be formed by a combination of controllers or control units. Other embodiments and configurations may be devised without departing from the spirit of the invention and the scope of the appended claims. In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
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PA201670186 | Mar 2016 | DK | national |
This application is a continuation under 35 U.S.C. § 120 of International Application No. PCT/EP2017/057556, filed Mar. 30, 2017 which claims priority to Danish Application No. PA201670186, filed Mar. 31, 2016, under 35 U.S.C. § 119(a). Each of the above-referenced patent applications is incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | PCT/EP2017/057556 | Mar 2017 | US |
Child | 16147289 | US |