The corresponding add-on modules can then be added to perform further analyses and designs according to various standards. RFEM calculates the deflections, internal forces, stresses, support forces, and soil contact stresses.
The program also allows you to create multi-material structures and to model solid and contact elements. RFEM is the main core program used to define structures, materials, and loads for planar and spatial structural systems consisting of plates, walls, shells and members.
Its versatile application and easy-to-use interface makes Dlubal RFEM the perfect solution for projects such as buildings, sports stadia, industrial plant, bridges, water treatment tanks, and for day to day use on simpler design projects. CADS can also provide consultancy services if required.ĭlubal RFEM is capable of designing civil and structural engineering projects of varying complexity in a wide range of construction materials. This thesis introduces and summarises research contributions that aim to help bridge this gap, through the development of robust model reduction approaches to control the cost associated with multiscale and physically detailed numerical simulations, with a particular emphasis on reliability assessment for composite materials and fracture.CADS are proud to be the Official Sales Partner for Dlubal for all their products in the UK, Ireland, India, UAE, Bahrain, Kuwait, Qatar and Saudi Arabia.Īs their Partner CADS will also provide clients with assistance in any sales enquiries, training and technical support. To unleash the full potential of high-fidelity computational mechanics, we need to develop a new generation of numerical tools that will bridge the gap between, on the one hand, heavy numerical solvers and, on the other hand, computationally demanding “online” engineering tasks. Models used for such applications require extreme robustness and swiftness of execution.
Emerging applications such as real-time control or interactive design require performing thousands of repeated analyses, with potentially limited computational facilities. Yet, such heavy numerical tasks are restricted to “one-shot” virtual experiments. Through advances in computer hardware and software, material failure can be reliably predicted using multiscale high-fidelity models coupled with appropriately designed discretisation strategies. High-fidelity modelling and simulation have profoundly transformed the area of material and structural design.
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