Consider the reactor shown in the figure. The flow rate through the reactor is Q m/h. The concentrations (in mg/L) of a compound in the influent and effluent are C, and C, respectively. The compound is degraded in the reactor following the first order reaction. The mixing condition of the reactor can be varied such that the reactor becomes either a completely mixed flow reactor (CMFR) or a plug-flow reactor (PFR). The length of the reactor can be adjusted in these two mixing conditions to LOMER and LpER while keeping the cross-section of the reactor constant. Assuming steady state and for C/C, = 0.8, the value of LoMER/LPER (round off to 2 decimal places) is. Q, C Q, Co
Consider the reactor shown in the figure. The flow rate through the reactor is Q m/h. The concentrations (in mg/L) of a compound in the influent and effluent are C, and C, respectively. The compound is degraded in the reactor following the first order reaction. The mixing condition of the reactor can be varied such that the reactor becomes either a completely mixed flow reactor (CMFR) or a plug-flow reactor (PFR). The length of the reactor can be adjusted in these two mixing conditions to LOMER and LpER while keeping the cross-section of the reactor constant. Assuming steady state and for C/C, = 0.8, the value of LoMER/LPER (round off to 2 decimal places) is. Q, C Q, Co
Chapter2: Loads On Structures
Section: Chapter Questions
Problem 1P
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
Transcribed Image Text:Consider the reactor shown in the figure. The flow rate through the reactor is Q m/h.
The concentrations (in mg/L) of a compound in the influent and effluent are C, and C,
respectively. The compound is degraded in the reactor following the first order reaction.
The mixing condition of the reactor can be varied such that the reactor becomes either
a completely mixed flow reactor (CMFR) or a plug-flow reactor (PFR). The length of the
reactor can be adjusted in these two mixing conditions to LCMFR and LPER while keeping
the cross-section of the reactor constant. Assuming steady state and for C/C, = 0.8,
the value of LoMER/LPER (round off to 2 decimal places) is_
Q, C
Co
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