Journal
JOURNAL OF POLYMER RESEARCH
Volume 18, Issue 6, Pages 1871-1877Publisher
SPRINGER
DOI: 10.1007/s10965-011-9594-6
Keywords
Poly(vinyl alcohol)(PVA); Nitrocellulose; Composite bead; Biofilter material; Biological application of polymer
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A new type of poly(vinyl alcohol)/nitrocellulose/granular activated carbon/KNO(3) composite bead was prepared and shown to be suitable for use as a filter material in the biofiltration process. This composite bead was a porous spherical particle with a diameter of 2.4-6.0 mm and a density of 1.125 g/cm(3). The amount of water-soluble nitrogen dissolved out of this composite bead was 145.5 mg N/g dry composite bead. The biochemical kinetic behaviors of n-butyl acetate in a spherical poly(vinyl alcohol) (PVA)/nitrocellulose (NC)/granular activated carbon (GAC)/KNO(3) composite bead biofilter (NC biofilter) and a spherical PVA/peat/GAC/KNO(3) composite bead biofilter (peat biofilter) were investigated. The values of the half-saturation constant K (s) for the NC biofilter and the peat biofilter were 33.55 and 35.54 ppm, respectively. The values of the maximum reaction rate V (m) for the NC biofilter and the peat biofilter were 23.83 and 22.46 ppm/s, respectively. Diffusion-limited zero-order kinetics were regarded as the most adequate biochemical reaction model for the two biofilters. The microbial growth rates and biochemical reaction rates for the two biofilters were inhibited at higher inlet concentrations. The biochemical kinetic behaviors of the two biofilters were similar. The maximum elimination capacities of the NC biofilter and the peat biofilter were 170.72 and 174.51 g C/h m(3) bed volume, respectively. The PVA/nitrocellulose/GAC/KNO(3) composite bead made it easier for the microbes to adjust to their new environment and secrete exocellular enzymes to break down the substrate.
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