Agglomerating nano-particles

A method of agglomerating nanoparticles to form larger agglomerates is shown. The nanoparticles are mixed with a resin to form a first mixture 803 of agglomerates, having sizes over a range that includes agglomerates considered to be too large, suspended in the resin. A bead milling cylinder 802 pro...

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Hauptverfasser:	Paul Jonathan Laughlin, Ian Carrick
Format:	Patent
Sprache:	eng
Schlagworte:	BASIC ELECTRIC ELEMENTS CALCULATING COMPUTING COUNTING ELECTRIC DIGITAL DATA PROCESSING ELECTRICITY MANUFACTURE OR TREATMENT OF NANOSTRUCTURES MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES NANOTECHNOLOGY PERFORMING OPERATIONS PHYSICS RESISTORS SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES TRANSPORTING
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creator	Paul Jonathan Laughlin Ian Carrick
description	A method of agglomerating nanoparticles to form larger agglomerates is shown. The nanoparticles are mixed with a resin to form a first mixture 803 of agglomerates, having sizes over a range that includes agglomerates considered to be too large, suspended in the resin. A bead milling cylinder 802 produces a second mixture 808 with fewer large agglomerates. A filter removes the remaining large agglomerates. The resulting mill-base may be cut with a solvent before deployment. The nano-particles may have a size less than 100nm and may be substantially spherical or acicular. The nanoparticles may be antimony-doped tin-oxide and the resin may be un-diluted lacquer. Agglomerates having a size greater than 10 micrometres may be considered too large. The mixing step may be performed by a speed mixer operating at a rotational speed of up to 1600 revolutions per minute. Bead milling may reduce the size of agglomerates to below 5 micrometres. The filtering step may deploy a filter with openings having a size of 10 micrometres.
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The nanoparticles are mixed with a resin to form a first mixture 803 of agglomerates, having sizes over a range that includes agglomerates considered to be too large, suspended in the resin. A bead milling cylinder 802 produces a second mixture 808 with fewer large agglomerates. A filter removes the remaining large agglomerates. The resulting mill-base may be cut with a solvent before deployment. The nano-particles may have a size less than 100nm and may be substantially spherical or acicular. The nanoparticles may be antimony-doped tin-oxide and the resin may be un-diluted lacquer. Agglomerates having a size greater than 10 micrometres may be considered too large. The mixing step may be performed by a speed mixer operating at a rotational speed of up to 1600 revolutions per minute. Bead milling may reduce the size of agglomerates to below 5 micrometres. 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subjects	BASIC ELECTRIC ELEMENTS CALCULATING COMPUTING COUNTING ELECTRIC DIGITAL DATA PROCESSING ELECTRICITY MANUFACTURE OR TREATMENT OF NANOSTRUCTURES MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES NANOTECHNOLOGY PERFORMING OPERATIONS PHYSICS RESISTORS SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES TRANSPORTING
title	Agglomerating nano-particles
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