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Chemical Engineering - Chemical Reaction Engineering and Applied Chemical Kinetics

Full exam

CRE – 28.09.15 - Exam E (Solution) 1 096116 Chemical Reaction Engineering 28 September 2015 Exam E Family name _________________________________________________ First name _________________________________________________ ID number _________________________________________________ Signa ture _________________________________________________ 1. Second order reaction in a CSTR (25%) The following second-order liquid-phase reaction is taking place in a CSTR: ��+��→2��+�� A and B are fed to the reactor at rates of 4 mol/min and 2 mol/min respectively at a temperature of 300 K . The total volumetric flow rate is 10 l/min. Specific heats (in J/mol/K) of A, B, C and D are 125, 100, 130 and 135 respectively. The reactor is jacketed by water at a temperature of 40°C. The overall heat transfer coefficient has been estimated at 200 J/m2/s/K, while the heat transfer area is 0.5 m2. Mixing is ensured through an agitator, which contributes a work of 10 kW to the reactor. The heats of formation of A, B, C and D (at 298 K) are -45 kJ/mol, -30 kJ/mol, -50 kJ/mol and -60 kJ/mol respectively. The rate constant at 300 K is 0.1 l/mol/min and the activation energy is 30,000 J/mol. Find the steady-state temperature in the reactor for 90% consumption of the limiting reactant. Find the volume of the reactor to achieve this conversion. Solution Let us write the energy balance for a CSTR in non-isothermal conditions, according to what we studied for single reactions: ��̇ −��̇ �� 0 − ��∆�� =�� ̃�� ( ��−�� 0) ��( �� −��) −��̇ �� 0 − ��∆�� ( ��)+∆��̃ ��( ��−�� ) �=�� ̃�� ( ��−�� 0) We used B as the limiting species because of the stoichiometry and the initial number of moles. Thus, we can easily calculate the reactor temperature: CRE – 28.09.15 - Exam E (Solution) 2 ��= ��0��−∆��(��)+ ∆��̃��+ ��0∑��̃��0+ �� − ��̇ ��0∑��̃�� + 7# + (��0��∆��̃�� In order to estimate the size of the reactor, we have to apply the proper design equation: ��=�� 0�� =�� 0�� =�� 0�� 0 ( ��−��) �� 0 ( �� −��) =�� 0�� 0 2 ( ��−��) ( �� −��) Be careful: the kinetic constant �� in the expression above must be evaluated at the reactor temperature, which not necessarily is equal to the temperature at which �� is given in the main text. So: ��= ��300 �� 1300 −1�� 2. Consecutive reactions in a batch reactor (20%) The following liquid-phase consecutive reaction is taking place in a constant volume batch reactor. �� 1�� 2�� The first reaction is first order and the second reaction is zero order. a) Determine the concentrations of A, B and C as functions of time. b) If at time t=0 only A and B are present (with concentrations equal to 1 mol/l and 0.2 mol/l, respectively), what is the concentration of species C after 10 min? Assume that �� 1=1 �� −1 and �� 2= 1 �� 3 �� . Solution Part a. We have a constant volume batch reactor. Thus the governing equation for species A is: �� =−�� 1�� whose solution is: �� =�� 0��− �� 1 �� =�� 1��−�� 2=�� 1��0��− �� 1��−�� 2 whose solution: �� =�� 0+ �� 0− �� 0��− �� 1 Just use the given numbers in the expressions above. CRE – 28.09.15 - Exam E (Solution) 3 3. First-order reversible reaction in a CSTR (15%) A first-order reversible liquid phase reaction is carried out in a CSTR at 427°C, with the initial concentration of A being equal to 2 mol/l. ��↔�� Following parameters are given: ⎩ ⎪ ⎨ ⎪ ⎧ �� = 40 �� = 40 �� ∆�� 27°�� =−80 �� ( 27 °��) =2∙10 9 ��( 327°��) =1 ℎ�� −1 ��=30,000 ��/�� Determine the residence time in the reactor for 80% equilibrium conversion. Solution Let us apply the Van’t Hoff law to get the equilibrium constant �� at the reactor temperature ��: )=∆ �� (27 °��) �� 1 �� 27°�� −1 �� Same for the kinetic constant: )=− �� 1 �� 27°�� −1 �� We can easily calculate the equilibrium conversion: 1−�� =�� ⇒ �� =�� + 1 Now we can write the reaction rate: ��=�� −�� = �� 0 �1 −��−�� w here �� is the required conversion (i.e. a percentage of the equilibrium conversion �� ). From the design equation of CSTRs we have finally the residence time: ��= 1 ��1 �� − �� 4. First-order reaction in a packed bed reactor (30%) TA first-order, gas-phase reaction ��→�� is performed in a PBR at 400 K and 10 atm. Feed rate is 5 mol/s containing 20% A and the rest inerts. The PBR is packed with 8 mm-diameter spherical porous particles. The intrinsic reaction rate is ��′= G%�, where ��= 3.75 �� . Bulk density of the catalyst is 2.3 kg/l. The diffusivity is 0.1 cm2/s. The pressure drop parameter is found to be ��= 9.8∙10 −4 �� −1. CRE – 28.09.15 - Exam E (Solution) 4 a) What is the value of the internal effectiveness factor? What does it signify? b) How much catalyst (kg) is required to obtain a conversion of 75% in the reactor? c) Find the pressure at the exit of the reactor. Solution Let us calculate the Thiele modulus and the corresponding catalyst efficiency: ��=�� 2 �� Γ ��=3 �� 2�� ℎ�� −1� We can now write the governing equation for species A: �� 0 �� =�� =�� 0 1−�� 1+�� 0=�� 0 1−�� 1+�� √1 −�� =�� 0 ��0 1−�� 1+�� √1 −�� This differential equation can be easily solved by separation of variables: 1+�� 1−�� =�� 0 ��0 √1 −�� (1+��) ��1 1−�� −��=�� 0 ��0 2 3�� 1 −( 1−��) 3 /2 � The catalyst mass �� is obtained from the expression above (everything is known, �� is the only unknown). The outlet pressure is simply given by: �� = ��0√1− �� 5. PFR followed by a CSTR (20%) A reversible reaction ��↔�� is taking place in a PFR. The equilibrium constant (in terms of concentrations) is 4. The conversion which is obtained is 50% of equilibrium conversion . A CSTR of equal size is placed downstream of the PFR (PFR-CSTR) to increase conversion. What is the total conversion in the reactor sequence with this arrangement? Solution The equilibrium conversion can be easily calculated from the definition: �� = �� = ��0�� 0�1− ��= �� 1− �� CRE – 28.09.15 - Exam E (Solution) 5 Then, we can calculate the effective conversion at the exit of the PFR, �� , which is a certain percentage of the equilibrium conversion. From the data referring to the single reactor we can get the �� quantity (i.e. the residence time): ��=�� − �� Now, we can use the information calculated above to estimate the conversion at the exit of the CSTR, �� =�� −�� 1−�� −�� In the expression above, �� is the only unknown.