Systems for a plastic pump/actuator capable of containing and pumping organic solvents and lubricants and having a more desirable lubricity within the system. The system has at least two cylinders, with plungers therein, oppositely disposed from each other and configured to operably connect to a pump.

Systems for a plastic pump/actuator capable of containing and pumping organic solvents and lubricants and having a more desirable lubricity within the system. The system has at least two cylinders, with plungers therein, oppositely disposed from each other and configured to operably connect to a pump.

A vehicle exhaust system includes a mixer having an inlet that receives engine exhaust gases and an outlet to direct swirling engine exhaust gas to a downstream exhaust component. The mixer has a plurality of internal surfaces that come into contact with the engine exhaust gases. At least one of the internal surfaces has a coating comprised of a low-coefficient of friction material.

A disperser includes an outer member and an inner member located radially inside the outer member. A flow path is formed between the outer member and the inner member, through which fluid flows from one side to the other side in the axial direction. The flow path includes a first region that extends spirally from the one side to the other side and a second region that extends continuously from the first region to the other side. The second region is defined by the tapered inner circumferential surface of the outer member and the tapered outer circumferential surface of the inner member. The tapered inner circumferential surface and the tapered outer circumferential surface are formed such that the angle of one with respect to the other in the axial cross section changes in the middle of the second region, and the second region of the flow path has portions each having a different clearance distance.

A disperser includes an outer member and an inner member located radially inside the outer member. A flow path is formed between the outer member and the inner member, through which fluid flows from one side to the other side in the axial direction. The flow path includes a first region that extends spirally from the one side to the other side and a second region that extends continuously from the first region to the other side. The second region is defined by the tapered inner circumferential surface of the outer member and the tapered outer circumferential surface of the inner member. The tapered inner circumferential surface and the tapered outer circumferential surface are formed such that the angle of one with respect to the other in the axial cross section changes in the middle of the second region, and the second region of the flow path has portions each having a different clearance distance.

A container for storing and transporting regolith includes an upper portion having a top end that includes an inlet opening. An inlet valve is attached to the inlet opening and is configured for moving between a closed inlet position and an open inlet position. The container also has a lower portion continuous with the upper portion. The lower portion has sidewalls that taper inwards and terminate in a bottom end having an outlet opening. An outlet valve is attached to the outlet opening and is configured for moving between a closed outlet position and an open outlet position. The container further includes a robotic arm interface configured for being gripped by a robot. An inner surface of the container may include a non-stick coating so that the regolith does not adhere thereto.

A container for storing and transporting regolith includes an upper portion having a top end that includes an inlet opening. An inlet valve is attached to the inlet opening and is configured for moving between a closed inlet position and an open inlet position. The container also has a lower portion continuous with the upper portion. The lower portion has sidewalls that taper inwards and terminate in a bottom end having an outlet opening. An outlet valve is attached to the outlet opening and is configured for moving between a closed outlet position and an open outlet position. The container further includes a robotic arm interface configured for being gripped by a robot. An inner surface of the container may include a non-stick coating so that the regolith does not adhere thereto.

A disperser includes an outer member having a tapered inner circumferential surface, an inner member having a tapered outer circumferential surface that faces the tapered inner circumferential surface, and a clearance adjustment part that allows a clearance distance between the tapered inner circumferential surface and the tapered outer circumferential surface to be adjusted by moving the outer member and the inner member relative to each other. A flow path is formed between the inner circumferential surface of the outer member and the outer circumferential surface of the inner member, through which fluid flows from one side to the other side. The flow path includes a dispersion region defined by the tapered inner circumferential surface and the tapered outer circumferential surface. The tapered inner circumferential surface and the tapered outer circumferential surface are formed such that the angle of one with respect to the other in the axial cross section changes in the middle of the dispersion region.

Systems and method for producing a small-scale mixer are provided. In some implementations, a method for includes obtaining dimensions of an at-scale mixer. The method also includes determining first dimensions of the small-scale mixer based on respective dimensions of the at-scale mixer. The method further includes determining second dimensions of the small-scale mixer independent of the dimensions of the at-scale mixer. Additionally, the method includes generating the small-scale mixer using the first dimensions and the second dimensions using a three-dimensional printer.

Systems and method for producing a small-scale mixer are provided. In some implementations, a method for includes obtaining dimensions of an at-scale mixer. The method also includes determining first dimensions of the small-scale mixer based on respective dimensions of the at-scale mixer. The method further includes determining second dimensions of the small-scale mixer independent of the dimensions of the at-scale mixer. Additionally, the method includes generating the small-scale mixer using the first dimensions and the second dimensions using a three-dimensional printer.