Scale up confidently with Dynochem process modeling.
Green Solvent Swap Distillation

Webinar: Green Solvent Swap Distillation

Solvent swaps are common operations within a synthetic step to setup the following reaction, extract...

Development of Modeling Enhanced Work Streams to Optimize the Scale-up of Solvent Switches

Development of Modeling Enhanced Work Streams to Optimize the Scale-up of Solvent Switches

Dr. Roel Hoefnagels will talk about the overarching work streams are giving detailed guidance on all...

Scale-up of Batch Crystallization From Lab to Plant

Batch Crystallizer Scale-Up and Design

Scale-up of crystallization is notoriously complicated and companies are under pressure to develop s...

Lubrizol Process Development and Scale-up

Lubrizol's Efficient Scale-Up & Process Control

This webinar focuses on how to improve process development and scale-up by leveraging calorimetry an...

What does Dynochem do?

Dynochem software offers dynamic chemical process simulation and optimization by combining data with equipment characteristics and powerful predictive models. Calculating optimal process conditions and equipment utilization makes it possible to deliver better processes using fewer overall experiments.  

An extensive library of template models is available to all users. The application of models is supported by free training, expert guidance, and project support. Some of the most commonly used Dynochem applications include:

  • Solvent temperature-dependent properties and solvent interaction predictions
  • Mixing and Heat Transfer assessment and characterization tools for STRs and PFRs
  • Simulation of heating or cooling a reactor to quickly calculate the time required to bring a reactor to the recipe temperature for a reaction, crystallization, or other operation
  • Reaction models for homogeneous and heterogeneous reactions in batch and flow chemistry operations
  • Crystallization models to predict particle size distribution (PSD) 
  • Dynamic models of batch solvent swap operations in continuous and put-and-take modes to predict the amount of fresh solvent required on scale-up and the operation time
  • Tools to characterize key filtration process parameters and predict scale-up performance from lab to plant filtration equipment and between filtration and centrifugation operations

How can this help in process development?

With Dynochem, chemists and chemical engineers in process development and primary manufacturing can confidently scale up, troubleshoot, and optimize reaction, workup, and isolation stages. Common projects where Dynochem is used include:

  • Ensure adequate mixing and mixing equivalence on scale-up
  • Predict thermal process safety and effect of addition rates and heat transfer on Time to Maximum Rate (TMR) and Maximum Temperature of Synthesis Reaction (MTSR) 
  • Robust crystallization design from standard solubility experiments to optimize seeding strategy, cooling profile, and anti-solvent addition rate to promote crystal growth
  • De-bottleneck and optimize filtration and centrifugation equipment selection and operation
  • Design continuous manufacturing equipment and operating conditions to fit process chemistry needs

What is the difference between Dynochem and iC Safety?

The key difference is that Dynochem predictions are based on a kinetic model, which allows great flexibility in determining the behavior of your process in different equipment setups and thus allows the optimization of a safe process in silico. In comparison, iC Safety is based on determining standard metrics like MAT and DTad from RC1 data and using this to determine the Stoessel safety class. It won't directly allow you to predict, for example, what conditions would allow you to run the process safely when transferring to a large-scale vessel. The two approaches are complementary, however, and both are very robust!

What template models does Dynochem include?

Dynochem template models include:

  • Mixing and heat transfer in stirred tank reactors
  • Reactions in batch and semi-batch reactors
  • Binary and ternary phase equilibria
  • Batch distillation and solvent swap
  • Crystallization
  • Filtration and centrifugation
  • Drying

Common operations in continuous processing such as:

  • Mixing and heat transfer in PFRs
  • Reactions in CSTRs and PFRs
  • Crystallization in CSTRs
  • Counter-current extraction
  • Wiped-film evaporator