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Chemical Reaction Engineering 2 Semester 6 (TE Third Year) BE Chemical Engineering University of Mumbai Topics and Syllabus

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University of Mumbai Syllabus For Semester 6 (TE Third Year) Chemical Reaction Engineering 2: Knowing the Syllabus is very important for the students of Semester 6 (TE Third Year). Shaalaa has also provided a list of topics that every student needs to understand.

The University of Mumbai Semester 6 (TE Third Year) Chemical Reaction Engineering 2 syllabus for the academic year 2021-2022 is based on the Board's guidelines. Students should read the Semester 6 (TE Third Year) Chemical Reaction Engineering 2 Syllabus to learn about the subject's subjects and subtopics.

Students will discover the unit names, chapters under each unit, and subtopics under each chapter in the University of Mumbai Semester 6 (TE Third Year) Chemical Reaction Engineering 2 Syllabus pdf 2021-2022. They will also receive a complete practical syllabus for Semester 6 (TE Third Year) Chemical Reaction Engineering 2 in addition to this.

CBCGS [2018 - current]
CBGS [2014 - 2017]
Old [2000 - 2013]

University of Mumbai Semester 6 (TE Third Year) Chemical Reaction Engineering 2 Revised Syllabus

University of Mumbai Semester 6 (TE Third Year) Chemical Reaction Engineering 2 and their Unit wise marks distribution

University of Mumbai Semester 6 (TE Third Year) Chemical Reaction Engineering 2 Course Structure 2021-2022 With Marking Scheme

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Syllabus

C Catalytic Heterogeneous Reactions
101 Introduction
  • Kinetics and mechanism of various Heterogeneous reactions and design consideration of reactors used during different operating conditions.
102 Catalytic Heterogeneous Reactions
  • Properties of solid catalysts, Physical adsorption and Chemisorption, Surface area and pore size distribution, Langmuir-Hinshelwood model, General mechanism of solid catalysed fluid phase reactions.
  • Special cases when

(a) Film resistance controls.

(b) Surface phenomenon controls.

(c) Surface reaction controls

(d) Pore diffusion controls.

  • Intrinsic kinetics and various cases of adsorption and reaction stage controls.
  • Concept of effectiveness factor of catalyst and its dependence on catalyst properties and kinetic parameters.
CC Design of Solid Catalysed Fluid Phase Reactors
  • Phenomenon observed in operation of packed, fluid bed, slurry and such reactors.
  • Product distribution in multiple and complex reaction.
  • Thermal Effects, phenomena of stability, instability and run away and its analysis.
  • Strategies for stable operation of reactors.
  • Design consideration of fluid-solid catalytic reactors, including Fluid bed reactors.
CCC Non-catalytic Heterogeneous Reactions and Design of Reactors for Non-catalytic Reactors
301 Non-catalytic Heterogeneous Reactions
  • General mechanism of reaction.
  • Various models.
  • Specific cases with respect

(a) Film diffusion controlling.

(b) Ash diffusion controlling.

(c) Chemical reaction controlling.

302 Design of Reactors for Non-catalytic Reactors
  • Experimental reactors for heterogeneous Reactions, Non-Catalytic Fluid Solid Reactions in Flow Reactors, Application to design of continues solid flow reactors
  • Various design considerations, Application of fluid bed reactors and their design consideration, heat transfer effects.
CD Kinetics of Fluid-fluid Reactions and Applications to Design
401 Kinetics of Fluid-fluid Reactions

Reaction with mass transfer, The rate equation pertaining to fast to very slow reactions.

402 Applications to Design

Design of gas-liquid, liquid-liquid and gasliquid-solid reactors – Heterogeneous reactors, Bubble heterogeneous reactors, co-current and counter-current flow packed bed reactors.

D Non-ideal Flow Reactors
  • Concept of residence time distribution(RTD), Measurement and characteristics of RTD, RTD in Ideal batch reactors, Plug flow reactor and CSTR.
  • Zero Parameter Model – Segregation and Maximum mixedness model.
  • One parameter model – Tank in series model and Dispersion Model, Recycle Model.
  • Multi parameter models, Effect of dispersion on conversion for general irreversible reaction case, Diagnostic methods of analysis of flow patterns in reactors, Role of micro and macro mixing and segregation in ideal (MFR, PFR) and non ideal reaction cases.
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