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Paper Title

Cavitationally Driven Transformations: A Technique of Process Intensification

Authors

Aniruddha Bhalchandra Pandit
Aniruddha Bhalchandra Pandit
Dipak Vitthal Pinjari
Dipak Vitthal Pinjari
Chandrakant R. Holkar
Chandrakant R. Holkar
Ananda J. Jadhav
Ananda J. Jadhav

Keywords

  • Process Intensification
  • Cavitation
  • Cavitationally Driven Transformations
  • Energy Efficiency
  • Mass Transfer Enhancement
  • Heat Transfer Enhancement
  • Mixing Improvement
  • Reactor Design
  • Cost Savings
  • Safety Enhancement
  • Waste Reduction
  • Product Quality Improvement
  • Crystallization
  • Emulsification
  • Extraction
  • Wastewater Treatment
  • Depolymerization
  • Water Disinfection
  • Hydrodynamic Cavitation
  • Acoustic Cavitation
  • Ultrasonic Cavitation
  • Chemical Processing
  • Advanced Oxidation Processes
  • Reaction Kinetics
  • Sustainable Processing
  • Industrial Applications
  • Green Chemistry
  • Process Optimization
  • Fluid Dynamics
  • High Shear Processing
  • Sonochemistry

Article Type

Research Article

Journal

Industrial & Engineering Chemistry Research

Research Impact Tools

DOI

DOI Icon 10.1021/acs.iecr.8b04524

Issue

Volume : 58 | Issue : 15 | Page No : 5797-5819

Published On

March, 2019

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Abstract

The process intensification (PI) can significantly improve energy and process efficiency by enhancing mixing, mass, and heat transfer as well as driving forces. There are several benefits of such improvements, which include energy and cost savings, enhanced safety, smaller reactor size, less waste generation, and higher product quality. This review article focuses on the PI, discussion about its dimensions and structure, what it involves, and recent developments in PI which can be achieved using the technique of cavitation. Recommendations for optimum operating parameters needed for process intensification using cavitation phenomena which has been reported in the literature have been presented along with some of our own work in the area. Some experimental case studies have been presented which highlight the degree of intensification achieved when cavitation is used for different physicochemical transformations. These physicochemical transformations include crystallization, emulsification, extraction, wastewater treatment, depolymerization, and water disinfection.

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