Scale-up Your Process With MixIT


MixIT features

Bio-reactors mixing analysis

Fluid mixing analysis

Selection Of Mixing Equipment

tank dimensions

bottom shapes


dip tubes

Pharmaceuticals mixing analysis

Mixing Process Simulation

Heat transfer analysis

Stirred Tank Reactor Mixing Analysis

Chemical simulation software

chemical simulation

Selection Of Mixing Equipment

liquid Mixing

liquid blending

Chemical engineers

Chemical mixing industry

process flow simulation software

Mixing Process

Heat transfer

oil lab analysis

heat transfer process

dye mixing

tank mixing

resin mixing

chemical mixing

adhesive mixing

pigment mixing

paint mixing

liquid mixing ratio calculator

chemical simulation

chemical reactor

chemical mixing process

chemical process modeling



Mixing Optimization


Mixing Liquid Simulation

liquid mixing simulation

Mixing Process Simulation

Mixing Process Optimization

Mixing process

Scale up

Heating Cooling



Liquid Mixing

Liquid Solid Mixing

standard reactor

Mixing Equipment Design

Simulation of Heat Transfer

Selection of Mixing Equipment

mixing process Safety Control,

Mixing Production Design

Mass Transfer

Mechanical Calculation

Process Engineering

Mixing calculations

Reactor Design

Chemical Reaction

mixing pressure

mixing temperature

Biotechnology Process


MixIT Mixing analysis Features, process parameters, shaft speed, mixing pressure, industry standard reactor bottom shapes, reactor head shapes, conical, flat, Elliptical, tori-spherical, impeller, impellers,pitched blade turbine, rushton turbine, anchor agitators, import impellers ,Chemineer, Lightnin mixers, custom impellers, Standard Flat baffle, Fin baffle, Beavertail baffle, Flattened Pipe baffle, h-style baffle, baffle placement, baffle dimensions, Sparger, spargers, Ring Spargers, Coils, Dip Tubes, Multiple dip-tubes, unit system, Correlation Based mixing Analysis, mixing Performance Comparison, predictions of reactor performance, reactor performance predictions, empirical correlations,power per unit volume, blend time, gas hold-up, mass and heat transfer,impeller speed , solid suspensions, reactor scale performance, process scale-up performance, Customizable Correlations, reactor performance, Fully Automated 3D CFD Analysis, 3D, 3D CFD, CFD, CFD analysis, automated cfd analysis, automated cfd simulation, CFD models ,reactor velocity fields, reactor shear rate distribution, reactor flow patterns, vortex shape, vortex depth, top-mounted, centrally located impeller under fully un-baffled conditions,mixing profiles, power consumption, blend time, mixing intensity, mass transfer coefficients, reactor database, reactor types, reactor configurations, off-centered agitators, angled agitators, multi-shaft agitators, agitator rotation,Newtonian fluid rheology, non-Newtonian fluid rheology, fluid rheology, newtonian, non-newtonian, Power Law model, Cross Power Law model, Bird-Carreau model, Hersche-Bulkley model, lab scale, pilot scale, plant scale, shear stresses,blending, suspension, dissolution, emulsification, transfer, chemical reaction, micro-scale, high-shear treatment, viscous liquids production, polymers, paints, coatings, detergents, pastes, shampoos, food products.


Intuitive GUI

The intuitive GUI makes it easy to enter geometric details such as tank dimensions, bottom shapes, baffle details, internals such as dip tubes or coils, specify liquid, gas or solid properties, and process parameters such as shaft speed, temperature and pressure.


Industry Standard Bottom Shapes

User can quickly select from a list of standard bottom and head shapes such as conical, flat, Elliptical, tori-spherical used in the process industries.


Extensive Impeller Library

The built-in library includes standard impellers such as pitched blade turbine, rushton turbine, anchor agitators. The library is easily extended to import impellers from specific vendors like Chemineer, Lightnin mixers and others. Users can also create and import their own impellers.


Flexibility In Impeller Positioning

Top entering impellers can be inclined at any angle and placed anywhere in the tank by using the X-Offset and Y-Offset functionality. The horizontal impellers can now be positioned anywhere along the circumference of the tank and inclined at an angle. Allowing users to simulate tank geometries involving multiple side entering impellers and bottom mounted angled impellers.



MixIT users can select from a range of baffle types such as Standard Flat, Fin, Beavertail, Flattened Pipe, h-style etc. Users can easily change the number, dimensions and placement of baffles.


Custom Baffles

Users can now use a combination of different types of baffles and place them anywhere in the tank. MixIT also allows users to import their custom made baffles into MixIT for CFD analysis.


Spargers, Coils and Dip Tubes

Users can quickly create various internals like Ring Spargers, Coils, Dip Tubes and locate them appropriately in the reactor by entering various dimensions and parameters. Multiple dip-tubes can be specified simultaneously.


Spargers And Coils

MixIT 4.2 can now accommodate even more complex tank internals. MixIT allows users to simulate tanks with multiple helical coils for complex temperature sensitive processes. Heat transfer calculations in MixIT are now even more accurate as MixIT accounts for the side jacket as well as the bottom jacket. For large multiphase systems, MixIT allows users to specify multiple spargers.


Correlation Based Analysis & Performance Comparison

MixIT users can get preliminary predictions of reactor performance using empirical correlations with respect to various parameters such as power per unit volume, blend time, gas hold-up, mass and heat transfer characteristics, critical impeller speed for solids suspension and many more. Users can also quickly compare performance of reactors across scales for a given process.


Customizable Correlations

MixIT allows users to analyze the reactor performance using their own correlations. User can quickly create their own correlations using various input variables. User can share the correlations among themselves using import and export features.


Fully Automated 3D CFD Analysis

Perform fully automated 3D steady state, single phase flow analysis of stirred reactors. The CFD models can calculate performance parameters such as velocity fields, shear rate distribution, flow patterns in the reactor. The CFD models can also perform heat transfers and mixing analysis.


Runtime Monitor Plots

Turbulence Models - turbulence models in the CFD module cover a wide range of applications. Apart from the Laminar Flow model and the standard k-epsilon model for turbulent flow, MixIT offers k-ω and RSM turbulence models for better accuracy in operations that involve swirling flows. Simulation Monitoring - User can now monitor convergence by monitoring the residuals or the torque on the impeller and species concentration while the simulation is in progress.

Powerful Reports and Visualization tool

MixIT generates html reports with graphical and numeric data. Various graphical results such as contours and vector plots are generated from the CFD results along with animations to show the mixing profiles in the reactor. Various performance parameters such as, power and flow number, power consumption, blend time, mixing intensity, mass transfer coefficients are also calculated.


Tagging Reactor Types, Configurations and Processes

MixIT allows users to tag reactors a sitename and scale (lab/pilot/plant) along with its name. This makes it easy for the user’s to find the reactor quickly in the MixIT database.


Off-Centered, Angled and Multi-shaft Agitators

MixIT allows users to specify and do CFD analysis of the reactors with off-centered, angled and multi-shaft agitators. Along with this impeller speed and direction of rotation is specified for particular impeller.


Fluid Rheology

Users can specify both Newtonian and non-Newtonian fluid rheology. Various non-Newtonian models such as Power Law, Cross Power Law, Bird-Carreau, Hersche-Bulkley are available to select from.


Flexibility of Unit System

MixIT gives flexibility to the users to input quantities in various units. Users can also change the unit system as and when required.


Vortex Shape Predictions

MixIT predicts vortex shape and vortex depth for top-mounted, centrally located impeller under fully un-baffled conditions. The predicted vortex shape can then be used (instead of flat top surface) while performing CFD analysis.

Make Modern Mixing Decisions, Faster. See it in action.