Dust collection by using colloidal gas aphrons

Environmental Engineering Science

Volumn 25, Issue 8, 2008, Pages 1175-1180

  Jarudilokkul, Somnuk ^a   Sinthuphisut, Nantharat ^a   Boonamnuayvitaya, Virote ^a  

^a KING MONGKUT'S UNIVERSITY OF TECHNOLOGY THONBURI   (Thailand)

Author keywords

Colloidal gas aphrons; Dust collection; Fly ash; Surfactant

Indexed keywords

AIR; ANIONIC SURFACTANTS; CATIONIC SURFACTANTS; COAL ASH; CONCENTRATION (PROCESS); DIFFUSERS (OPTICAL); DUST COLLECTORS; DUST CONTROL; DYES; FLOW VELOCITY; FLY ASH; GAS DYNAMICS; GRAIN SIZE AND SHAPE; ISOMERS; NONIONIC SURFACTANTS; PARTICLE SIZE; POLYVINYL CHLORIDES; SEPARATION; SURFACE ACTIVE AGENTS; VELOCITY;

AIR FLOW VELOCITY; AIR FLOWS; COLLECTION EFFICIENCY; COLLOIDAL GAS APHRONS; DUST COLLECTION; DUST COLLECTION EFFICIENCY; DUST CONCENTRATIONS; DUST PARTICLES; DUST-REMOVAL; LARGE PARTICLES; NON-IONIC; SEPARATION COLUMNS; SMALL PARTICLE SIZE; SURFACTANT; TRITON X-100; WETTING ABILITY; WHEAT FLOURS;

DUST;

ANIONIC SURFACTANT; CATIONIC SURFACTANT; IONIC SURFACTANT; NONIONIC SURFACTANT; POLYVINYLCHLORIDE; SURFACTANT; TRITON X 100;

AIR POLLUTANT; AIR POLLUTION; AIRFLOW; ARTICLE; COLLOID; DUST; FLOUR; FLOW RATE; FLY ASH; GAS; PARTICLE SIZE; POWDER; SEPARATION TECHNIQUE; WETTABILITY; WHEAT;

TRITICUM AESTIVUM;

EID: 53549094136     PISSN: 10928758     EISSN: None     Source Type: Journal    
DOI: 10.1089/ees.2007.0126     Document Type: Article

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