Aspects and embodiments of systems for fluid transportation using inductive heating are described. In one embodiment, the system includes a first transportation pipe having a first diameter and a second transportation pipe having a second diameter. The first diameter is greater than the second diameter. An augur that causes a fluid flow is within the first transportation pipe. A control circuit is electrically coupled to the first inductive element and the second inductive element, and to a power supply to inductively heat the first transportation pipe and the second transportation pipe.

An apparatus for filling sandbags includes a hollow housing tube, an auger, and a motor. The hollow housing tube includes an intake end, a curved central portion, and a discharge end. The hollow housing tube includes a discharge chute at the discharge end. The auger includes a shaft and flightings. The auger is at least partially disposed within the hollow housing tube. The auger includes a first end connected to a motor at the discharge end of hollow housing tube and a second end connected to a sand screw auger bit at the intake end of the housing tube. The auger includes a plurality of connected auger sections. A portion of the plurality of connected auger sections is disposed in the curved central portion of the hollow housing tube and is flexibly connected. The motor is operable to transmit rotational torque through an entire length of the auger.

An apparatus for filling sandbags includes a hollow housing tube, an auger, and a motor. The hollow housing tube includes an intake end, a curved central portion, and a discharge end. The hollow housing tube includes a discharge chute at the discharge end. The auger includes a shaft and flightings. The auger is at least partially disposed within the hollow housing tube. The auger includes a first end connected to a motor at the discharge end of hollow housing tube and a second end connected to a sand screw auger bit at the intake end of the housing tube. The auger includes a plurality of connected auger sections. A portion of the plurality of connected auger sections is disposed in the curved central portion of the hollow housing tube and is flexibly connected. The motor is operable to transmit rotational torque through an entire length of the auger.

An integrated granular-material scoop and near-vertical lifting feeder/conveyor includes special connections and skirts between a bullnose rotating scoop and an open-helical screw that provides the rotations and material lift and evacuation. A conical working-face of the bullnose rotating scoop has symmetrically distributed graters and vents to break loose and force-in granular material from natural deposits and cargo holds. The bullnose rotating scoop and the open-helical screw its attached to move the material into a continuous layer on the inside surface of an outer stationary sheathing. A motor drive attached to the open-helical screw above at the delivery end provides the lifting force necessary.

An integrated granular-material scoop and near-vertical lifting feeder/conveyor includes special connections and skirts between a bullnose rotating scoop and an open-helical screw that provides the rotations and material lift and evacuation. A conical working-face of the bullnose rotating scoop has symmetrically distributed graters and vents to break loose and force-in granular material from natural deposits and cargo holds. The bullnose rotating scoop and the open-helical screw its attached to move the material into a continuous layer on the inside surface of an outer stationary sheathing. A motor drive attached to the open-helical screw above at the delivery end provides the lifting force necessary.

A powered wheel assembly for an auger assembly is provided. The wheel assembly comprises a power source support structure configured for attachment to the auger assembly and a power source for providing a rotational force to a weight-load supporting wheel of the auger assembly. Actuating the power source causes the weight-load supporting wheel of the auger assembly to rotate and displace the auger assembly when the power source support structure is attached to the auger assembly.

A toilet system that includes a waste receptacle including an outlet configured to channel waste therethrough. The system also includes a conveyor assembly including a housing that includes an inlet and at least one outlet. The inlet is coupled in flow communication with the outlet of the waste receptacle. The conveyor assembly also includes a transport mechanism positioned within the housing, and the transport mechanism is operable to actively transport the waste from the inlet towards the at least one outlet of said housing.

A toilet system that includes a waste receptacle including an outlet configured to channel waste therethrough. The system also includes a conveyor assembly including a housing that includes an inlet and at least one outlet. The inlet is coupled in flow communication with the outlet of the waste receptacle. The conveyor assembly also includes a transport mechanism positioned within the housing, and the transport mechanism is operable to actively transport the waste from the inlet towards the at least one outlet of said housing.

The present disclosure is directed to underwater seismic exploration with a helical conveyor and skid structure. The system can include an underwater vehicle comprising a sensor to identify a case having a hydrodynamic shape, wherein the case stores one or more ocean bottom seismometer (“OBS”) units. The underwater vehicle includes an arm. The underwater vehicle includes an actuator to position the arm in an open state above a cap of the case, or to close the arm. The underwater vehicle can move the arm to a bottom portion of the case opposite the cap. An opening of the case can be aligned with the conveyor of the underwater vehicle. The conveyor can receive, via the opening of the case, a first OBS unit of the one or more OBS units. The conveyor can move the first OBS unit to the seabed to acquire seismic data from the seabed.

The present disclosure is directed to underwater seismic exploration with a helical conveyor and skid structure. The system can include an underwater vehicle comprising a sensor to identify a case having a hydrodynamic shape, wherein the case stores one or more ocean bottom seismometer (“OBS”) units. The underwater vehicle includes an arm. The underwater vehicle includes an actuator to position the arm in an open state above a cap of the case, or to close the arm. The underwater vehicle can move the arm to a bottom portion of the case opposite the cap. An opening of the case can be aligned with the conveyor of the underwater vehicle. The conveyor can receive, via the opening of the case, a first OBS unit of the one or more OBS units. The conveyor can move the first OBS unit to the seabed to acquire seismic data from the seabed.