A Machine Automation System (MAS) for a machine with an implement includes a plurality of Vehicle Electronic Control Modules (ECMs), a local transceiver, an Ethernet Local Area Network (LAN), a first Controller Area Network (CAN), an Autonomy Electronic Control Module (AECM), an environment monitoring system, and a Remote Shutdown Module (RSM). The AECM is configured to generate output control signals, and to transmit the output control signals to at least one ECM of the plurality of Vehicle ECMs, wherein the output control signals control an operation of the machine. The RSM is disposed on the machine and configured to receive a safety control signal from off-board the machine. The MAS is configured to operate advanced machine control features concurrently with execution of the input control signals received from off-board the machine.

A Machine Automation System (MAS) for a machine with an implement includes a plurality of Vehicle Electronic Control Modules (ECMs), a local transceiver, an Ethernet Local Area Network (LAN), a first Controller Area Network (CAN), an Autonomy Electronic Control Module (AECM), an environment monitoring system, and a Remote Shutdown Module (RSM). The AECM is configured to generate output control signals, and to transmit the output control signals to at least one ECM of the plurality of Vehicle ECMs, wherein the output control signals control an operation of the machine. The RSM is disposed on the machine and configured to receive a safety control signal from off-board the machine. The MAS is configured to operate advanced machine control features concurrently with execution of the input control signals received from off-board the machine.

The present invention relates to a system for collecting, lifting, and recovering seabed mineral resources, specifically, a device wherein hydrogen gas is evolved on the seabed, resources are lifted by the buoyancy of the gas to the sea surface, and the hydrogen gas which has become an excess buoyancy source during the lifting and recovering is absorbed into an organic substance including toluene, thereby yielding hydrogenated compounds including cyclomethylhexane to recover the energy required for hydrogen gas production.

A system and method of off shore mining for retrieval and extraction of heavy mineral concentrate from placer deposits or other suitable materials. The system comprises a dredge vessel and a barge, coupled in conjunction to the dredge vessel. The dredge vessel having thereon a dredging unit, at least one gravity separator and spiral separators for procurement of total heavy minerals from dredged sediment and debris. The barge is configured to acquire and process the total heavy minerals, wherein the barge has thereon at least one magnetic separator, electro-magnetic separators, and density separators for separation of desired minerals based on their physical properties. The system further comprises at least one discharge conduit for tailing of wastes, leftover after extraction and separation of desired minerals, back into water bodies.

An excavation data processing method includes: a first acquisition step of acquiring position data of a reference part of an excavating body, position data of a plurality of measuring parts with respect to the reference part in the excavating body, and data indicative of an excavation depth; a second acquisition step of acquiring inclination angle data of the plurality of measuring parts of the excavating body; a first deriving step of deriving a plurality of measurement positions as positions of the plurality of measuring parts from the reference part position data, the plurality of measuring part positions data and inclination angles data; a second deriving step of deriving an excavation bottom position by interpolation processing based on the plurality of measurement positions and the excavation depth; and an output step of outputting information of the excavation bottom position.

A collection tank for use in a vacuum operated earth reduction system, the collection tank comprising a closed first end, an open second end defining a tank sealing flange and a body extending between the closed first end and the open second end. An internal chamber defined by the body, the closed first end and the open second end has a door coupled to the open second end and is configured to releasably seal the open second end. An automated door closer is coupled to a center of the door, wherein the automated door closer provides a closing force at the center of the door so that the closing force is equally distributed about a periphery of the door to seal the door against the tank sealing flange.

A device for receiving and removing plastic, sludge-like materials deposited on beds of bodies of water. The device systematically senses the bottom of the body of water, suctions it off layer by layer, and independently moves along even if coarse obstacles are present. The device has at least one pump/compressor, at least one hydraulic unit and at least one electric power generator and is connected on one side to a disposal site or a settling basin or a transportable container on land and on the other side to the suction module by pipelines. The suction module moves along on the bottom independently by a special tracked chassis unit, is connected by a cable to an echo sounding emitter arranged floatingly above the suction module and/or to a GPS receiver, and has a pivoting arm, which independently adapts to the bed of the body of water and oscillates freely.

A shovel includes an attachment including a working assembly, a diesel engine provided with a supercharger, an oil hydraulic pump connected to the diesel engine provided with the supercharger, and a controller that executes a preload boost function, wherein the preload boost function is for increasing boost pressure of the supercharger prior to increasing a hydraulic pressure load on the oil hydraulic pump, wherein a range accessible by a predetermined part of the attachment includes a partial range at which, upon the working assembly being operated, the preload boost function is to be executed and a partial range at which, upon the working assembly being operated, the preload boost function is not to be executed.

An excavation system has a soil-agitation arrangement including an agitator operable to disturb soil to facilitate removal of disturbed soil from the ground. Also included is a vacuum arrangement operable to remove the disturbed soil from the ground, and a sensor arrangement including at least one sensor configured to detect a presence of at least one type of buried infrastructure in the ground. A shroud arrangement including a shroud disposed over at least a portion of the agitator and may be movable relative to the agitator to selectively cover and uncover at least a portion of the agitator.

A jetting system for an undersea trencher has jetting conduits extending aftward of its trench-cutting jetting swords. Jetting conduit nozzles direct liquid radially from their jetting conduits into the trench after the trench is excavated by the jetting sword cutting nozzles. The jetting conduits direct sufficient liquid into the trench to maintain the mix of trenched soil and water in the trench along the length of the conduits at not more than a super-critical density, extending the distance in which the product being laid in the trench is able to descend in the trench and increasing the likelihood that the product will be buried at the intended trench depth.