We have shown a solid reliability of the simulation in the description of our experiment: it can open the way to a basically unlimited number of applications, including those, for example, in which convective transport phenomena play a non-negligible role. Energy2D is a relatively new program Xie, and is not yet widely used as a building performance simulation tool. To gain more confidence in the predictions with Energy2D, an analytical validation study was therefore carried out first, inspired by the approach described in Hensen and Nakhi Loonen, Jan L.
It is also very nice to see that three platforms are supported and every single one is free to use. That is just awesome and I want to say thank you for all users. Description ProSim HEX software makes it possible to simulate in a detailed way a single exchanger or a network of connected heat exchangers in series, in parallel… with possible recycling between the heat exchangers to represent all the complexity of a real installation.
Powerful features for detailed design and analysis: sensitivity analysis, specifications, optimization… A rigorous and comprehensive thermodynamic library refer to Simulis Thermodynamics brochure ; An intuitive interface for the description of the equipment and the analysis of the results; An open software enabling the user to add their own know-how: user-defined unit operations, new compounds, Visual Basic scripts, addition of external unit operations or thermodynamic models using CAPE-OPEN technology… Hardware requirements Intel or equivalent based PC with: 2 GB RAM or more 4 GB recommended.
At least 2 GB free disk space after install for optimal desktop performance. Internet access to download the software and the license. Characteristics of CO-ProSim PHE : ProSim HEX can simulate most configurations of gasketed plate-type heat exchangers: Single-pass or multi-pass, for monophasic or diphasic exchanges liquid-vapor , in co-current or counter-current flow, for plates with chevron angle from 0 to 90 degrees.
Simple and fast use of results: all relevant information easily available: fluid temperature, plate temperature, fluid pressure, pressure drop, heat transfer coefficient, vaporization rate; summary tables with all the characteristics temperature, pressure, heat transfer coefficient, mass enthalpy, mass vaporization rate ; overall and localized results; Graphic visualization of the evolution of the temperature for each fluid on any specific part of the exchanger to quickly detect performance issues.
View All software. To learn more View more resources Access the Support Contact us. We use cookies to ensure you get the best experience on our website. You have control over which cookies you want to activate.
By clicking on Accept, you consent to the use of all cookies. Cookie policy Reject Personalize Accept. Edit my cookies. Close Edit my cookies We use third-party cookies which help us analyze and understand how you use this website. These cookies will only be stored in your browser with your consent. You also have the option of disabling these cookies, but disabling some of these cookies may affect your browsing experience. Apart from that, there is really no need to create an account to use this website.
Remember Me. Log in. Not registered yet? Create an account Forgot your username? Forgot your password? Heat Conduction multi-layered composite shell elements solid elements connectivity elements and thermal contact definitions temperature-dependent material properties anisotropic heat conduction internal heat generation phase-changes. Thermal Radiation models for solar radiation and all sorts of other sources of light and thermal radiation material properties depending on wavelength and angle of incidence intra-model surface-to-surface radiation considers absorption, reflection and transmission as well as refraction diffuse and specular reflection tool for generating representative solar and cloudiness environmental data for any place and time on earth.
Different types of thermal boundary conditions can be applied such as: heat exchange by convection at surfaces thermal radiation between surfaces and external solar loads direct spatial contact of surface areas various types of heat sources and sinks coupling of component part temperatures to adjacent air Most boundary conditions can be time-dependent or temperature-dependent.
The numerical solver itself allows for fixed and adaptive time stepping for efficient solution progress restarting a simulation based on previous results a wide range of expert solver options for fine-tuning of result precision and convergence behaviour.
Thermal analysis results on car driver. Simulate Thermal Conduction Results from heat transfer simulation on brake disc. For radiation in absorbing and scattering media, use the P1 approximation and DOM to, for example, model light diffusion in a nonemitting medium.
Lastly, you can model a radiative beam in absorbing media using the Beer—Lambert law, and couple the effect with other forms of heat transfer. For heat transfer in thin layers, the Heat Transfer Module provides individual layer models and layered material technology, to investigate heat transfer in layers that are geometrically much smaller than the rest of a model.
This functionality is available for thin layers, shells, thin films, and fractures. For individual layers, the thermally thin layer model is used for highly conductive materials with heat transfer tangential to the layer and negligible temperature difference on either side of the layer.
Conversely, the thermally thick layer model can represent poorly conducting materials that act as a thermal resistance in the shell's perpendicular direction; this model computes the temperature difference between the two layer sides. Finally, the general model provides a highly accurate and universal model, as it embeds the complete heat equations. You can visualize the results in thin, layered structures as if they were originally modeled as 3D solids.
By talking to one of our sales representatives, you will get personalized recommendations and fully documented examples to help you get the most out of your evaluation and guide you to choose the best license option to suit your needs. You will receive a response from a sales representative within one business day. You can fix this by pressing 'F12' on your keyboard, Selecting 'Document Mode' and choosing 'standards' or the latest version listed if standards is not an option.
Log Out Log In Contact. Modes of Heat Transfer All of the capabilities in the Heat Transfer Module are based on the three modes of heat transfer: conduction, convection, and radiation. What You Can Model with the Heat Transfer Module A multiphysics modeling approach for the many types of heat sources you may be interested in simulating. Joule Heating Model Joule heating also known as resistive heating in solids, fluids, shells, and layered shells.
Induction Heating 1 Model inline induction heaters and metal processing applications. Microwave Heating 2 Model microwave, or RF, heating in waveguides, tissue, and other bio-applications. Laser Heating 3 Use the Beer—Lambert Law to model laser heating and ablation in various manufacturing and biomedical processes. Thermal Stress 4 Understand the effects of thermal expansion and thermal stress for a variety of operating conditions. Thermal Contact Include the contact thermal conductance coefficient, which depends on the contact pressure from the solid mechanics model.
Thermoelectric Effects Account for the Peltier—Seebeck—Thomson effects, and include common materials, such as bismuth telluride and lead telluride.
0コメント