Embodiments of the present disclosure provide for a self-pumping structure, methods of self-pumping, and the like.

A pumping apparatus for pumping a liquid from a source to a target including a motor and pump driven by the motor. The pumping apparatus further includes a support frame, a swivel platform pivotably mounted on the support frame and a drive assembly connected with the support frame and the swivel platform for pivoting the swivel platform with respect to the support frame, wherein pivoting of the swivel platform by the drive assembly changes an angle defined between a longitudinal axis of the motor and a longitudinal axis of the pump piston, and wherein a spacer is provided for limiting the range of the angle.

A pumping apparatus for pumping a liquid from a source to a target including a motor and pump driven by the motor. The pumping apparatus further includes a support frame, a swivel platform pivotably mounted on the support frame and a drive assembly connected with the support frame and the swivel platform for pivoting the swivel platform with respect to the support frame, wherein pivoting of the swivel platform by the drive assembly changes an angle defined between a longitudinal axis of the motor and a longitudinal axis of the pump piston, and wherein a spacer is provided for limiting the range of the angle.

A solid particulate pump includes a plurality of segments linked to each other in a serial, closed loop arrangement with gaps between neighboring pairs of the segments. A flexible seal extends across the gaps and seals an interior of the closed loop arrangement from an exterior of the closed loop arrangement.

A solid particulate pump includes a plurality of segments linked to each other in a serial, closed loop arrangement with gaps between neighboring pairs of the segments. A flexible seal extends across the gaps and seals an interior of the closed loop arrangement from an exterior of the closed loop arrangement.

A dispensing pump (10) for liquids, viscous materials, foams, gels, etc. includes a resilient plastic skirt spring (18) so that the entire pump can be more easily recycled. The dispensing pump (10) includes a base portion (12), an inlet valve (14), a piston valve (16), a polymer skirt spring (18), a spring guide structure (20) and a pump actuator (22). The skirt spring (18) comprises a plurality of concentric nesting rings (38) sequentially decreasing in diameter from a base ring (38A) to a top ring (38F) wherein adjacent rings are interconnected by spaced bridge segments (40) and the bridge segments are staggered at each sequential ring. The skirt spring (18) includes structures which interact with the piston valve (16) to open the outlet valve.

A dispensing pump (10) for liquids, viscous materials, foams, gels, etc. includes a resilient plastic skirt spring (18) so that the entire pump can be more easily recycled. The dispensing pump (10) includes a base portion (12), an inlet valve (14), a piston valve (16), a polymer skirt spring (18), a spring guide structure (20) and a pump actuator (22). The skirt spring (18) comprises a plurality of concentric nesting rings (38) sequentially decreasing in diameter from a base ring (38A) to a top ring (38F) wherein adjacent rings are interconnected by spaced bridge segments (40) and the bridge segments are staggered at each sequential ring. The skirt spring (18) includes structures which interact with the piston valve (16) to open the outlet valve.

According to the method and device for a membrane-based processing of ambient water-group species, the species are captured in a space environment by an ionic liquid disposed on a presenting face of a semipermeable membrane. To seamlessly process the captured species for in-situ resource utilization without need of moving parts, they are urged to pass through the membrane by a predetermined electric potential difference applied between opposite sides of the membrane via electrode contacts; an initial storage envelope is provided by an impermeable membrane attached to a back face of the semipermeable membrane. The device can be stowed in a manner of rolled plastic and deployed by unrolling. The device can also be configured as a scientific instrument to monitor a flux of ambient water-group species impinging in the space environment using electrical measurements.

A pump system includes a particulate consolidator pump that has a pump outlet. A duct is coupled to the pump outlet. The duct has a wall that is coupled with an oscillator. The oscillator is operable to oscillate the wall at a controlled frequency. The controlled frequency is selected with respect to breaking static bridging of particulate in the duct due, at least in part, to consolidation of the particulate from a downstream check valve.

A pump system includes a particulate consolidator pump that has a pump outlet. A duct is coupled to the pump outlet. The duct has a wall that is coupled with an oscillator. The oscillator is operable to oscillate the wall at a controlled frequency. The controlled frequency is selected with respect to breaking static bridging of particulate in the duct due, at least in part, to consolidation of the particulate from a downstream check valve.