A dross abatement system for a printer is disclosed. The dross abatement system includes a print head ejector, a pump in communication with the print head ejector having an inner cavity, a first inlet coupled to the inner cavity, a supply of printing material external to the print head ejector, a heating element configured to heat the printing material in the ejector, and a supply of absorbent material external to the print head ejector. A method of abating dross in a metal jetting printer is also disclosed, which includes pausing an operation of the printer, advancing an absorbent material into a melt pool within a nozzle pump reservoir, wherein the melt pool may include a metal printing material, absorbing dross from the metal printing material, removing the absorbent material including the dross, and resuming operation of the metal jetting printer.

An apparatus includes a housing that defines a first zone, a second zone, a third zone, and a fourth zone. The apparatus includes an inlet, a first outlet, a second outlet, and a conveyor belt. The inlet is configured to receive a carbon dioxide-containing fluid in the first zone. The first outlet is configured to discharge a carbon dioxide-depleted fluid from the first zone. The second outlet is configured to discharge a carbon dioxide-rich fluid from the third zone. The conveyor belt passes through each of the zones. The conveyor belt includes a carbon dioxide sorbent. Within the first zone, the carbon dioxide sorbent is configured to adsorb carbon dioxide from the carbon dioxide-containing fluid to produce the carbon dioxide-depleted fluid. Within the third zone, the carbon dioxide sorbent is configured to desorb the captured carbon dioxide to produce the carbon dioxide-rich fluid.

An apparatus includes a housing that defines a first zone, a second zone, a third zone, and a fourth zone. The apparatus includes an inlet, a first outlet, a second outlet, and a conveyor belt. The inlet is configured to receive a carbon dioxide-containing fluid in the first zone. The first outlet is configured to discharge a carbon dioxide-depleted fluid from the first zone. The second outlet is configured to discharge a carbon dioxide-rich fluid from the third zone. The conveyor belt passes through each of the zones. The conveyor belt includes a carbon dioxide sorbent. Within the first zone, the carbon dioxide sorbent is configured to adsorb carbon dioxide from the carbon dioxide-containing fluid to produce the carbon dioxide-depleted fluid. Within the third zone, the carbon dioxide sorbent is configured to desorb the captured carbon dioxide to produce the carbon dioxide-rich fluid.

The invention features compact systems and methods for vacuum liquid purification and extraction of a liquid sample.

The invention features compact systems and methods for vacuum liquid purification and extraction of a liquid sample.

A whole blood treatment device includes a first conduit, a second conduit, and a rotating or reciprocating element having a channel. The first and second conduits are fluidly coupled to the rotating or reciprocating element such that the channel is fluidly continuous with the first conduit when the channel is fluidly discontinuous with the second conduit, and such that the channel is fluidly discontinuous with the first conduit when the channel is fluidly continuous with the second conduit. The first conduit is configured to receive whole blood, and the second conduit is configured to receive a regeneration fluid. The channel comprises a surface that is modified with an affinity agent at a concentration effective to allow removal of a target compound from whole blood.

A whole blood treatment device includes a first conduit, a second conduit, and a rotating or reciprocating element having a channel. The first and second conduits are fluidly coupled to the rotating or reciprocating element such that the channel is fluidly continuous with the first conduit when the channel is fluidly discontinuous with the second conduit, and such that the channel is fluidly discontinuous with the first conduit when the channel is fluidly continuous with the second conduit. The first conduit is configured to receive whole blood, and the second conduit is configured to receive a regeneration fluid. The channel comprises a surface that is modified with an affinity agent at a concentration effective to allow removal of a target compound from whole blood.

The invention features compact systems and methods for vacuum liquid purification and extraction of a liquid sample.

The invention features compact systems and methods for vacuum liquid purification and extraction of a liquid sample.