Reactor Design

Because they represent the heart of a chemical plant — in which high-value products are produced through chemical transformation — reactors are a crucial component, and their high performance must be ensured. Reaction engineers are concerned with each reactor’s specific yield, selectivity, safety, environment, quality and purity — as well as the degree to which reactors support overall plant economic viability and optimal operational conditions.

Reactor Design

Contours of species mixing in a stirred tank reactor.

Engineering simulation for reactor design software solution and services from ANSYS are powerful, reliable suite of tools that complements conventional reactor engineering practices. By bringing comprehensive multiphysics capabilities to reaction engineering, ANSYS has created a simulation platform that encompasses fluid mechanics, structural mechanics, impact and safety analyses, customized mixing tools, pressure vessel analysis, electromagnetic and control systems, and heat and mass transfer analyses. ANSYS solutions can model a diverse range of reactions, including gaseous and liquid, single-phase and multiphase, and homogenous and heterogeneous.

ANSYS engineering simulation for reactor design including CFD for chemical reactor design, structural and thermal analysis and instrumentation and control software used for design and analysis of chemical reactors enable reaction engineers to answer what-if questions as they design and enhance reactors performance, energy usage, reactor yield and product uniformity. Users can optimize reactor performance by better understanding the effects and impacts of feed locations, vessel geometries and internals, vibrations, failures, dead spots, shear rates, resident time distributions, hot spots, and particle size distributions.

ANSYS engineering simulation for reactor design software tools help a wide range of customers to simulate and improve a wide variety of reactors and reaction types.

  • Stiff chemistry
  • Competing and parallel reactions
  • Catalytic reactions
  • Heterogeneous and homogeneous reactions
  • Surface and volumetric reactions
  • Laminar and turbulent flows
  • Single-phase and multiphase reactions
  • Fluidized bed reactions
  • Multi-tube reactors
  • Membrane reactors
  • Microreactors
  • Stirred tank reactors
  • Fixed reactors
  • Autoclave reactors
  • Emulsion
  • Hydrogenation
  • Chlorination
  • Polymerization
  • Hydrocracking
  • Crystallization and precipitation