there is Meteorological reaction, A -> 3B (volume increase reaction) k=0.4, CA0 =4mol/L v0 = 3L/min...

The conversion of ferrous ions to ferric ions by dissolved oxygen in the presence of bacteria...

The conversion of ferrous ions to ferric ions by dissolved oxygen in the presence of bacteria is a first order reaction with respect to ferrous ions in the concentration range of 0.1 – 0.6 mol L-1 . The rate of oxidation of 0.6 mol L-1 ferrous ions is 0.25 mol L-1 min-1 . Calculate the following: (a) First order rate constant for the oxidation reaction. (b) Time taken for 70% conversion of ferrous ions at an initial concentration of 0.6...

Consider a reaction of species A to form product B in a constant-density isothermal system. The...

Consider a reaction of species A to form product B in a constant-density isothermal system. The rate of disappearance of A is given by a second-order rate, that is, (-rA) = kCA2. A process plant carries out the reaction using a single PFR with 95% conversion of A. To increase production, a second reactor is added. The second reactor is to have the same volume as the first one, and the overall conversion from the system of two reactors is...

A perfectly mixed flow reactor is to be used to carry out the exothermic isomerisation reaction...

A perfectly mixed flow reactor is to be used to carry out the exothermic isomerisation reaction A -> R. The rate is given by: (-rA) = kCA (1st order) where k = 4 × 106e-8000/T s-1, where T is in K. The enthalpy of reaction ?HR = -167,480 kJ kmol-1 The molecular mass MA (=MR) = 100 kg kmol-1 CA0 initial concentration of A = 1 kmol m-3 For a temperature of 100°C and a production rate of R of...

Consider the CSTR with first order reaction and the process parameters and variables are given by:...

Consider the CSTR with first order reaction and the process parameters and variables are given by: The process parameters and variables are defined as: CA0 = feed concentration = 2.7 mol/L. Cp = heat capacity of the reactor feed and product (1000 cal/kg*K) = Cv. E/R = normalized activation energy (20,000 K). F = mass feed rate and product rate (10 kg/s). k0 = rate constant (1.97×10^24 1/s). Q = heat addition rate (initially 700,000 cal/s). T0 = feed temperature...

The elementary irreversible organic liquid-phase reaction, A + B → C, is carried out in a...

The elementary irreversible organic liquid-phase reaction, A + B → C, is carried out in a flow reactor. An equal molar feed in A and B enters at 27 oC, and the volumetric flow rate is 2 L/s. The feed concentration is CA0 = 0.1 mol/L. a) Calculate the PFR and CSTR volumes necessary to achieve 85% conversion when the reaction is carried out adiabatically. b) What is the maximum inlet temperature one could have so that the boiling point...

Part I The elementary gas phase reaction (CH3)3COOC(CH3)3 --> C2H6 + 2CH3COCH3 is carried out isothermally...

Part I The elementary gas phase reaction (CH3)3COOC(CH3)3 --> C2H6 + 2CH3COCH3 is carried out isothermally in a flow reactor. The reaction rate constant at 500C is 1x10-4 min-1 and the activation energy is 85 kJ/mol. Pure di-tert-butyl peroxide enters the reactor at 10 atm and 127oC and a molar flowrate of 2.5 mol/min. Calculate the reactor volume and space time to achieve 90% conversion in; a) PF reactor b) CSTR reactor c) Propose the diameter (Dt) and length (L)...

The elementary gas phase reaction A + B C is to be carried out isothermally in...

The elementary gas phase reaction A + B C is to be carried out isothermally in a continuous reactor. Reactants are entering with a stoichiometric proportions at 10 atm and 130°C molar flow rate of 20 mol/min. The exit conversion is 90%. The following data was collected from experimental work T, K kA (min-1) 360 5.38 368 8.35 376 12.73 385 16.34 395 21.23 410 28.61 425 33.81 Estimate the rate constant and the activation energy Calculate the required volume...

Question 2: a- Consider the elementary liquid-phase reaction: A ? B Taking place in A PFR....

Question 2: a- Consider the elementary liquid-phase reaction: A ? B Taking place in A PFR. Determine the space-time taken to reach 80% conversion of A. The value of k is 2.3 s -1 . b- The first-order reaction A? B is carried out in a batch reactor with k = 0.3 min-1 , what is the time (in min) required to consume 90% of A? c- Plot the conversion X against time for the reaction described in b by...

A first order, liquid-phase reaction A ?products, is conducted in a 2000 L CSTR. The feed...

A first order, liquid-phase reaction A ?products, is conducted in a 2000 L CSTR. The feed contains pure A, at a rate of 300 L min-1 , with an inlet concentration of 4.0 mol L-1 . The following additional data are available: cP = 3.5 J g-1 K-1; ? = 1.15 g cm-3 ; ?HRA = -50 kJ mol-1 (you can assume that these values are constants) kA = A e-EA/RT = 2.4 x 1015e-12,000/T min-1 , with T in...

The reversible first-order gas reaction ??? is to be carried out in a mixed flow reactor....

The reversible first-order gas reaction ??? is to be carried out in a mixed flow reactor. For operations at 300 K the volume of reactor required is 100 liters for 60% conversion of A. 4.1. What is the value of the reverse rate constant at 300K? 4.2. What is the equilibrium conversion at 300 K? 4.3. What is the equilibrium conversion at 400 K? 4.4. What should be the volume of the reactor for the same feed rate and conversion...