An apparatus for performing aspects of manufacturing carbon nanotubes includes a nozzle configured to receive a catalyst precursor solution and a carrier gas, the nozzle including an orifice configured to nebulize the catalyst precursor solution and produce a mist including a mixture of the nebulized catalyst precursor solution and the carrier gas, the nozzle configured to inject the mist directly into a high temperature reaction zone of a reactor. The apparatus also includes an elongated tubular body having a first conduit and a second conduit, and a cooling system configured to regulate a temperature of the catalyst precursor solution and the carrier gas along the length of the tubular body. The first conduit and the second conduit extend along a length of the tubular body, and the length of the tubular body is greater than or equal to a distance from an end of the reactor to the reaction zone.

A system for making and using a ground product that includes one or more of: a reactor operated to react a guar split with a reagent at a reaction temperature in a range of 120 F. to 180 F. to form a guar derivative, and a treatment and transfer section for optionally treating the guar derivative and transferring the guar derivative to a co-grinder. The co-grinder is operably associated with a heated vacuum system and is operated to co-grind an acid with the guar derivative to form a ground product.

Disclosed are a defoaming device and a method of defoaming. The defoaming device includes a container having a side wall, a liquid flowing platform that is placed inside the container wherein the liquid flowing platform has a substantial same shape of the side wall and the liquid flowing platform and the side wall has a gap in between, and a solution inflow part attached to the container wherein the solution inflow part is used for allowing a liquid solution to enter the container; and a lifting apparatus attached to the container, where the lifting apparatus attaches to the liquid flowing platform inside the container, and the lifting apparatus is capable of driving the liquid flowing platform to move along the side wall of the container for defoaming the liquid solution when the liquid solution passes through the gap between the liquid flowing platform and the side wall.

A method of manufacturing bulked continuous carpet filament from recycled polymer. In various embodiments, the method includes: (1) reducing recycled polymer material into polymer flakes; (2) cleansing the polymer flakes; (3) melting the flakes into a polymer melt; (4) removing water and contaminants from the polymer melt by dividing the polymer melt into a plurality of polymer streams and exposing those streams to pressures below 25 millibars or another predetermined pressure; (5) recombining the streams; and (6) using the resulting purified polymer to produce bulked continuous carpet filament.

A method for producing a catalyst for a fuel cell comprising: a) injecting carbon particles into a fluidized bed reactor; b) evacuating the fluidized bed reactor to form a base pressure; c) introducing a catalytic metal precursor together with a carrier gas into the fluidized bed reactor to contact the catalytic metal precursor with the carbon particles; d d) purging a purge gas into the fluidized bed reactor; e) introducing a reaction gas into the fluidized bed reactor to attach the catalytic metal precursor to the carbon particles; and f) purging a purge gas into the fluidized bed reactor, wherein, the catalytic metal is attached to the carbon particles in a form of nano-sized spot.

A low cost and versatile plate reactor is capable of producing exothermic reactions under a wide variety of conditions using a wide variety of materials. The reactor design can be used to test various combinations of materials and triggers for exothermic reactions quickly. The reactor design can be used for solid-state materials, wet-cells/electrolytic materials, plasmas, and gases. The design will work with nanoparticles, solid materials, materials plated to a reactor wall, heavy water, or other liquid materials, and gases.

A method of forming a ceramic-metal composite part is described herein. The method includes maintaining molten metal in an interior of a housing in a liquefied state, the interior including a first chamber, a second chamber, and a port defined therebetween. The method further includes sealing the port such that the molten metal in the first chamber is maintained at a first liquid level, suspending a part at a height within the first chamber above the first liquid level, forming a pressure differential between the first chamber and the second chamber, unsealing the port such that molten metal from the second chamber flows into the first chamber, and resealing the port when the molten metal in the first chamber reaches a second liquid level such that the ceramic part is submerged in the molten metal.

Methods for creating nanostructured surface features on polymers and polymer composites involve application of low pressure during curing of solid polymer material from a solvent solution. The resulting nanoscale surface features significantly decrease bacterial growth on the surface. Polymer materials having the nanoscale structuring can be used in implantable medical devices to inhibit bacterial growth and infection.

A method of manufacturing bulked continuous carpet filament from recycled polymer. In various embodiments, the method includes: (1) reducing recycled polymer material into polymer flakes; (2) cleansing the polymer flakes; (3) melting the flakes into a polymer melt; (4) removing water and contaminants from the polymer melt by dividing the polymer melt into a plurality of polymer streams and exposing those streams to pressures below 25 millibars or another predetermined pressure; (5) recombining the streams; and (6) using the resulting purified polymer to produce bulked continuous carpet filament.

A technique for bonding an organic group with the surface of fine particles such as nanoparticles through strong linkage is provided, whereas such fine particles are attracting attention as materials essential for development of high-tech products because of various unique excellent characteristics and functions thereof. Organically modified metal oxide fine particles can be obtained by adapting high-temperature, high-pressure water as a reaction field to bond an organic matter with the surface of metal oxide fine particles through strong linkage. The use of the same condition enables not only the formation of metal oxide fine particles but also the organic modification of the formed fine particles. The resulting organically modified metal oxide fine particles exhibit excellent properties, characteristics and functions.