Downloads
CADAM3D is a user-friendly software based on the gravity method originally developed for one of the world biggest concrete dam owner, Hydro-Quebec, and for Dams and Hydrology of the Quebec Ministry of Environment (Quebec's legislator for dam safety). CADAM3D is fully functional and is intensively used by Hydro-Quebec since 2005. To our knowledge, no other software similar to CADAM3D is available at this time.
If you perform stability analyzes of concrete hydraulic structures, this software will allow you to perform them much faster and more efficiently. If you are interested in this type of software and would like to try CADAM3D for free, please click on the button "Contact us for a free trial of CADAM3D" to send us a message.
Parametric architecture refers to the use of algorithms and computational tools to design and optimize building structures. This approach allows architects to explore novel and complex geometries, while also optimizing building performance, sustainability, and functionality. Parametric design involves defining a set of parameters, such as building dimensions, materials, and site conditions, and then using algorithms to generate and manipulate the design.
Parametric architecture with Grasshopper offers a powerful toolset for architects, designers, and engineers to create innovative, optimized, and sustainable designs. By mastering Grasshopper's visual programming language and parametric design principles, you can unlock new design possibilities and take your projects to the next level. Whether you're a seasoned designer or just starting out, this comprehensive guide provides a solid foundation for exploring the exciting world of parametric architecture with Grasshopper. parametric architecture with grasshopper pdf
Grasshopper is a visual programming language developed by Robert McNeel & Associates, the same company behind Rhino. It's an intuitive and user-friendly tool that allows designers to create complex algorithms and parametric models without requiring extensive coding knowledge. Grasshopper integrates seamlessly with Rhino, enabling designers to use its powerful 3D modeling capabilities in conjunction with parametric design. Parametric architecture refers to the use of algorithms
Parametric architecture has revolutionized the way architects, designers, and engineers approach building design. By leveraging algorithms and computational tools, parametric design enables the creation of complex, innovative, and optimized structures that would be impossible to achieve through traditional design methods. One popular tool that has gained widespread acceptance in the industry is Grasshopper, a visual programming language for Rhino. In this article, we'll explore the world of parametric architecture with Grasshopper and provide a comprehensive guide to get you started. Grasshopper is a visual programming language developed by
RS-DAM is a computer program that was primarily designed to provide a computational tool to evaluate the transient response of a completely cracked concrete dam section subjected to seismic loads. RS-DAM is also used to support research and development on structural behavior and safety of concrete dams.
RS-DAM is based on rigid body dynamic equilibrium. It performs a transient rocking and/or sliding analysis of a cracked dam section subjected to either base accelerations or time varying forces. Several modelling options have been included to allow users to explore the influence of parameters (e.g. geometry, additional masses, variation of the uplift force upon rotation, hydrodynamic pressures in translation (Westergaard) and rotation, center of rotation moving with sliding, coefficient of restitution of impact, etc...). RS-DAM is developed in a university context and has no commercial aspect.
TADAM (Thermal Analysis of concrete DAMs) software employs a new frequency-domain solution technique to solve the 1D thermal transfer problem, allowing the calculation of temperature histories in a concrete dam section.
The direct solution calculates the evolution of the temperature distributions from the temperature histories of the upstream and downstream faces. The inverse solution uses temperature histories, measured inside the section, in order to calculate the temperature fields at the external faces, while taking into account the thermal wave attenuation effects and the phase angles along the section.
TADAM is developed in a university context and has no commercial aspect.
