TEMPERATURE SWING ADSORPTION COMPRESSION AND MEMBRANE SEPARATIONS

PDF Publication Title:

TEMPERATURE SWING ADSORPTION COMPRESSION AND MEMBRANE SEPARATIONS ( temperature-swing-adsorption-compression-and-membrane-separa )

Previous Page View | Next Page View | Return to Search List

Text from PDF Page: 067

and −dc∗􏱱􏱱c∗ ∂ζ+f(ξ)∂ζ+∂ζ+2c1 dc∗2􏱱􏱱c∗ ∂ζ=Perξ∂ξ ξ∂ξ +Pea∂ζ2 dn∗􏱱􏱱 ∂c∗ ∂c∗ ∂c∗ d2n∗􏱱􏱱 ∂c∗ 2 1 ∂ 􏱴 ∂c∗􏱵 2 ∂2c∗ 􏱱212∗􏱱122 00 (4.15) Following Taylor,10 we assume that the time necessary for appreciable effects to appear due to convective transport is long compared with that needed for the radial variations to be reduced to a fraction of their initial value due to molecular diffusion, i.e., axial derivatives are independent of radial position. After integrating the first order equation radially and applying both radial boundary conditions, we obtain A solution for c∗1 is assumed of the form dn∗􏱱􏱱􏱱 ∂c∗1 ∂c∗1 2 ∂2c∗1 −dc∗􏱱􏱱c∗ ∂ζ+∂ζ=Pea∂ζ2 0 (4.16) (4.17) (4.18) Per dc∗0 􏱹 ξ 􏰲ξ′ ξ′′f(ξ′′)dξ′′ c∗1=g(ζ)+ 0 dξ′ 2 dζ 0 ξ′ Substituting equation 4.17 into equation 4.14 we obtain dn∗􏱱􏱱∂g∂g 2∂2g −dc∗􏱱􏱱􏱱c∗ ∂ζ+∂ζ=Pea∂ζ2 0 Integrating equation 4.18 by parts gives  dn∗􏱱􏱱 2 dg 1−dc∗􏱱􏱱 g=Pedζ (4.19) After substituting equation 4.12 into equation 4.19 and integrating, we obtain the 􏱱c∗0 a solution for the axial contribution of the first order term, g (ζ), in the form  dn∗ 􏱱􏱱 dc∗ 􏱱0 􏱹 g(ζ)=B1exp 1− dc∗􏱱 􏰼 􏰽 (4.20) 􏱱c∗0 c∗0 − n∗|c∗0 􏰲′ 􏱹 dn∗􏱱􏱱 dc∗ Pedc∗􏱹ξ ξξ′′f(ξ′′)dξ′′ which when substituted in equation 4.17 yields ∗􏱱0r00′ c1 =B1exp 1− dc∗􏱱 􏰼 􏰽+ 2 dζ 0 ξ′ dξ (4.21) 􏱱c∗0 c∗0 − n∗|c∗0 The method for evaluating the second order term is the same as the one out- lined above for the first order term. The example demonstrates that the radial terms 55

PDF Image | TEMPERATURE SWING ADSORPTION COMPRESSION AND MEMBRANE SEPARATIONS

PDF Search Title:

TEMPERATURE SWING ADSORPTION COMPRESSION AND MEMBRANE SEPARATIONS

Original File Name Searched:

temp-swing-adsorption.pdf

DIY PDF Search: Google It | Yahoo | Bing

CO2 Organic Rankine Cycle Experimenter Platform The supercritical CO2 phase change system is both a heat pump and organic rankine cycle which can be used for those purposes and as a supercritical extractor for advanced subcritical and supercritical extraction technology. Uses include producing nanoparticles, precious metal CO2 extraction, lithium battery recycling, and other applications... More Info

Heat Pumps CO2 ORC Heat Pump System Platform More Info

CONTACT TEL: 608-238-6001 Email: greg@infinityturbine.com (Standard Web Page)