In preferred embodiments, the present disclosure relates to methods for transportation of hazardous waste and/or waste classified under TSCA, and may comprise the acts of: translocating at least one intermodal trailer chassis from a primary terrestrial site to a first stationary barge, wherein said trailer chassis is carrying an intermodal shipping container containing the waste material, and wherein the first stationary barge is adapted to rise and fall with changes to the water level; moving the intermodal trailer chassis carrying the intermodal shipping container from the first stationary barge to a mobile barge adapted to traverse the body of water; traversing the body of water with the mobile barge; and offloading the at least one intermodal trailer chassis carrying the intermodal shipping container to a secondary terrestrial site via a second stationary barge.

A hoisting system, including: a hoisting crane including a hoisting cable, a craft, and a connector catch assembly for interconnecting the hoisting crane and the craft or a load/cargo on the craft. The connector catch assembly includes: a connector body, and a connector catch having a funnel-shaped trap-cage, whereby one of the connector body and the connector catch is attached to the hoisting cable and the other of the connector body and the connector catch is attached to the craft or the load on the craft. A wide side of the funnel shaped trap-cage is directed toward the connector body on approaching one another, whereas an opposite narrow side of the funnel shaped trap-cage has the connector catch mounted therein for releasably holding the connector body.

A hoisting system, including: a hoisting crane including a hoisting cable, a craft, and a connector catch assembly for interconnecting the hoisting crane and the craft or a load/cargo on the craft. The connector catch assembly includes: a connector body, and a connector catch having a funnel-shaped trap-cage, whereby one of the connector body and the connector catch is attached to the hoisting cable and the other of the connector body and the connector catch is attached to the craft or the load on the craft. A wide side of the funnel shaped trap-cage is directed toward the connector body on approaching one another, whereas an opposite narrow side of the funnel shaped trap-cage has the connector catch mounted therein for releasably holding the connector body.

A cargo transfer monitoring system at least comprises at least one vessel motion sensor, one pair of wireless modems, a central data processing unit with decision-making module, a rugged display panel as the operator station, and communication coupling. The cargo transfer operation will be carried out by a crane operator sitting in the crane cabin on the primary vessel. The transfer will take place either from target vessel to primary vessel or from primary vessel to target vessel. The sensor(s) collect the real-time motion of vessels, which is carried over to the central computer through data cable or wireless radio link. The decision-making module predicts the motion of the vessels for a subsequent time period. Based on the predicted value, the decision-making module projects the expected or predicted impact force on the payload if the operation is started at the particular time. If the predicted impact force on the payload is below a predetermined threshold, the system recommends the crane operator to resume the landing operation. The system can predict the motion and hence the rope tension for lifting operations and make similar recommendation to resume the lifting operation if the predicted rope tension falls below a predefined threshold.

A cargo transfer monitoring system at least comprises at least one vessel motion sensor, one pair of wireless modems, a central data processing unit with decision-making module, a rugged display panel as the operator station, and communication coupling. The cargo transfer operation will be carried out by a crane operator sitting in the crane cabin on the primary vessel. The transfer will take place either from target vessel to primary vessel or from primary vessel to target vessel. The sensor(s) collect the real-time motion of vessels, which is carried over to the central computer through data cable or wireless radio link. The decision-making module predicts the motion of the vessels for a subsequent time period. Based on the predicted value, the decision-making module projects the expected or predicted impact force on the payload if the operation is started at the particular time. If the predicted impact force on the payload is below a predetermined threshold, the system recommends the crane operator to resume the landing operation. The system can predict the motion and hence the rope tension for lifting operations and make similar recommendation to resume the lifting operation if the predicted rope tension falls below a predefined threshold.

The invention concerns a method for transferring a load between a target position on board a vessel (40) and an outboard position outboard said vessel. The invention further concerns a motion compensation device (1) applying the method. In the method the load is being transferred by a crane (30) carried by a motion compensation device arranged on board the vessel. The motion compensation device comprises a carrier frame (2), a base (3) and an actuator system (8, 9) for moving the carrier frame with respect to the base; the base being fixed to the vessel and the crane being carried by the carrier frame. During picking up a load from the vessel or placing a load on the vessel, the actuator system is being driven in an on board mode such that the carrier frame is being compensated for x-axis rotational movement and y-axis rotational movement of the vessel, and follows, viewed in the vertical direction, the vertical movement of the target location. During picking up a load from the outboard position or placing a load on the outboard position, the actuator system is being driven in an outboard mode such that the carrier frame is being compensated for x-axis rotational movement, y-axis rotational movement and z-axis translational movement of the vessel.

The invention concerns a method for transferring a load between a target position on board a vessel (40) and an outboard position outboard said vessel. The invention further concerns a motion compensation device (1) applying the method. In the method the load is being transferred by a crane (30) carried by a motion compensation device arranged on board the vessel. The motion compensation device comprises a carrier frame (2), a base (3) and an actuator system (8, 9) for moving the carrier frame with respect to the base; the base being fixed to the vessel and the crane being carried by the carrier frame. During picking up a load from the vessel or placing a load on the vessel, the actuator system is being driven in an on board mode such that the carrier frame is being compensated for x-axis rotational movement and y-axis rotational movement of the vessel, and follows, viewed in the vertical direction, the vertical movement of the target location. During picking up a load from the outboard position or placing a load on the outboard position, the actuator system is being driven in an outboard mode such that the carrier frame is being compensated for x-axis rotational movement, y-axis rotational movement and z-axis translational movement of the vessel.

A cargo transfer monitoring system at least comprises at least one vessel motion sensor, one pair of wireless modems, a central data processing unit with decision-making module, a rugged display panel as the operator station, and communication coupling. The cargo transfer operation will be carried out by a crane operator sitting in the crane cabin on the primary vessel. The transfer will take place either from target vessel to primary vessel or from primary vessel to target vessel. The sensor(s) collect the real-time motion of vessels, which is carried over to the central computer through data cable or wireless radio link. The decision-making module predicts the motion of the vessels for a subsequent time period. Based on the predicted value, the decision-making module projects the expected or predicted impact force on the payload if the operation is started at the particular time. If the predicted impact force on the payload is below a predetermined threshold, the system recommends the crane operator to resume the landing operation. The system can predict the motion and hence the rope tension for lifting operations and make similar recommendation to resume the lifting operation if the predicted rope tension falls below a predefined threshold.

A cargo transfer monitoring system at least comprises at least one vessel motion sensor, one pair of wireless modems, a central data processing unit with decision-making module, a rugged display panel as the operator station, and communication coupling. The cargo transfer operation will be carried out by a crane operator sitting in the crane cabin on the primary vessel. The transfer will take place either from target vessel to primary vessel or from primary vessel to target vessel. The sensor(s) collect the real-time motion of vessels, which is carried over to the central computer through data cable or wireless radio link. The decision-making module predicts the motion of the vessels for a subsequent time period. Based on the predicted value, the decision-making module projects the expected or predicted impact force on the payload if the operation is started at the particular time. If the predicted impact force on the payload is below a predetermined threshold, the system recommends the crane operator to resume the landing operation. The system can predict the motion and hence the rope tension for lifting operations and make similar recommendation to resume the lifting operation if the predicted rope tension falls below a predefined threshold.