CDP13-AC After showing that E(t) for two CSTRs in
series having different values is
you are asked to make a number of calculations. [2nd Ed. P13-11]
CDP13-BB Determine E(t) and from data taken, form
a pulse test in which the pulse is not perfect and the inlet concentration varies with
time. [2nd Ed. P13-15]
CDP13-CB Derive the E(t) curve for a Bingham
plastic flowing in a cylindrical tube. [2nd Ed. P13-16].
CDP13-DB The order of a CSTR and PFR in series is
investigated for a third-order reaction. [2nd Ed. P13-10]
CDP13-EB Review the Muphree pilot plant data when
a second-order reaction occurs in the reactor. [1st Ed. P13-15]
CDP13-FA Gasoline shortages in the United States
have produced long lines of motorists at service stations.
CDP13-GB Vary the parameters to learn their
effects on conversion. [2nd Ed. P13-2]
CDP13-HB The reactions described in Problem 6-27
are to be carried out in the reactor whose RTD is described in Example 13-7.
CDP13-IB Real RTD data from an industrial packed bed reactor operating under poor operation. [3rd Ed. P13-5]
CDP13-JB Real RTD data from distribution in a stirred tank. [3rd Ed. P13-7B]
CDP13-KB Triangle RTD with second-order reaction. [3rd Ed. P13-8B]
CDP13-LB Derive E(t) for a turbulent flow reactor with 1/7th power law. [3rd Ed. P13-11]
CDP13-MB Good problem. Must use numerical techniques. [3rd Ed. P13-12B]
CDP13-NB Internal age distribution for a catalyst. [3rd Ed. P13-13B]
CDP13-DQEA U of M, Doctoral Qualifying Exam (DQE), May, 2000
CDP13-DQEB U of M, Doctoral Qualifying Exam (DQE), April, 1999
CDP13-DQEC U of M, Doctoral Qualifying Exam (DQE), January, 1999
CDP13-DQED U of M, Doctoral Qualifying Exam (DQE), January, 1999
CDP13-DQEE U of M, Doctoral Qualifying Exam (DQE), January, 1998
CDP13-DQEF U of M, Doctoral Qualifying Exam (DQE), January, 1998
