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RECORD NUMBER: 2 OF 5

OLS Field Name OLS Field Data
Main Title Formation of Inorganic Particles during Suspension Heating of Simulated Wastes.
Author Mulholland, J. A. ; Sarofim, A. F. ; Yue, G. ;
CORP Author Massachusetts Inst. of Tech., Cambridge. Dept. of Chemical Engineering. ;Tsinghua Univ., Beijing (China).;Environmental Protection Agency, Research Triangle Park, NC. Air and Energy Engineering Research Lab.
Publisher c1991
Year Published 1991
Report Number EPA-68-02-4247; EPA/600/J-91/154;
Stock Number PB91-223354
Additional Subjects Aerosols ; Separation ; Particle size distribution ; Incinerators ; Simulation ; Condensates ; Air pollution control ; Stationary sources ; Nickel inorganic compounds ; Lead inorganic compounds ; Cadmium inorganic compounds ; Waste disposal ; Reprints ;
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NTIS  PB91-223354 Most EPA libraries have a fiche copy filed under the call number shown. Check with individual libraries about paper copy. 11/26/1991
Collation 8p
Abstract
The paper gives results of measurements of metal partitioning between the fine condensation aerosol and the larger particles produced during rapid heating of aqueous and organic solutions containing metal additives with widely varying volatilities in a laboratory-scale furnace operated over a range of temperatures (900-1500 K). A stream of monodisperse droplets (nominal diameter of 36 micrometers) was injected into an isothermal, laminar drop-tube reactor, quickly developing into a stream of droplets with heterogeneous size distribution due to droplet collision and coalescence. Gas was introduced to disperse the droplet stream, eliminating droplet interactions after 3 cm (2 ms) of flight. In the remaining 90% of reactor length, the droplets vaporized and burned, yielding inorganic particles of various sizes. Aqueous solutions containing nitrates of Cd, Pb, and Ni gave rise to particles with trimodal size distributions. Partitioning of the larger particles between residual and intermediate modes is suggestive of particle porosity variation. In addition, ultrafine particles, with submicron aerodynamic diameter, were formed, both by the anticipated vaporization pathway and by an unexpected explosive fragmentation mechanism. The fraction of submicron particles produced upon heating of a NiCl2 solution was higher than that formed by the heating of a Ni(NO3)2 solution.