Veryst has deep expertise in fluidic mixing processes, which we leverage for our clients across industries. A fundamental aspect of mixing is the stretching and folding of the interface between initially separated substances. This occurs in many forms a
Fluid-structure interaction refers to the analyses involving simultaneous fluid flow and solid deformation. Veryst Engineering has worked on a wide range of FSI problems of different complexities.
Veryst offers a comprehensive approach to solving problems in microfluidic device development. We employ an array of modeling tools, such as scaling arguments, analytical formulas, computational simulations, and laboratory testing to inform the design and integration of common components.
Accurate simulation of many products now requires a multiphysics approach. Veryst Engineering specializes in multiphysics problems involving solids, fluids, heat transfer, mass transfer, acoustics, and electromagnetics. Our modeling and analysis expertise includes fluid-structure interaction, thermal-structure interaction, structural-acoustic vibrations, conjugate heat transfer, Joule heating, and microwave heating.
Modeling convective flow requires coupling fluid-flow with heat transfer. The coupled processes can be very complex, particularly if the fluid flow is turbulent, or if the heat transfer involves processes such as boiling, evaporation, or mixed fluids with varying thermal properties. F
Veryst provides expertise in many aspects of simulation and analysis for use in product design, manufacturing processes, and failure analysis. This includes modeling and analysis involving polymer materials, multiphysics modeling, finite element analysis, computational fluid dynamics, compu
Veryst offers clients consulting services in thermal modeling of both solid and fluid systems, including interactions between these systems. We employ state-of-the-art finite element analysis and computational fluid dynamics methods both to analyze and visualize the thermal profiles within client systems. Our simulation capabilities also include hard-to-solve coupled problems, including the interactions between thermal and structural effects and fluid movements resulting from thermal gradients.
Veryst is pleased to welcome a new member to its engineering team! Dr. Matthew Hancock, has an extensive background in fluid mechanics and model-based engineering, including microfluidics, wetting of textured surfaces, surface tension effects, heat/mass transfer, solid-fluid interaction, wave motion, and multiscale analysis.
Veryst is proud to announce that Dr. Matthew Hancock and Dr. Andrew Spann have been named Senior Consultants at 3D BioLabs--an early-stage R&D company in the field of tissue engineering and regenerative medicine.
Veryst is proud to have supported 3D BioLabs LLC with a study described in its recent publication titled “Rodent Model for Orthotopic Implantation of Engineered Liver Devices.” The publication presents a novel surgical technique to provide blood supply to implanted cellularized devices that augment or replace liver tissue function.
FluidicMEMS is an informal gathering of people from academia, medicine, industry, and business to meet and explore how microfluidic and BioMEMS technology will impact healthcare, research, and beyond.
Dr. Matthew Hancock presented "Simulations of Micropumps Based on Tilted Flexible Fibers" at the American Physical Society's 68th Annual Division of Fluid Dynamics (DFD) Meeting,
Dr. Nirmal Paudel presented a free, one-hour webinar titled "Electromagnetic Modeling and Design of an Actuator." He demonstrated a workflow for designing an electromagnetic actuator using the COMSOL Multiphysics simulation software and its parametric sweep and optimization tools in both static and transient simulations.