![]() ![]() Nine release-flexures are implemented to obtain an exact constraint design. We analyze the kinematics of the mechanism using three methods Grüblers criterion, opening the kinematic loops, and with a multibody singular value decomposition method. To ensure a deterministic behavior the assembled mechanism is made exactly constrained. To maximize unwanted vibration mode frequencies the mechanism is an assembly of optimized parts. By working with us, you canĮxploring possibilities for functionality beyond conventional products Standardize your design process by digitizing your design Shortening the design lead time.We present the exact constraint design of a two degrees of freedom cross-flexure-based stage that combines a large workspace to footprint ratio with high vibration mode frequencies. In order to extend the limits of such trade-offs, we have created an innovative information environment for the proper design of metamaterials, compliant mechanisms, and other structural design knowledge.īy operating these assets in-house and customizing them for each project, we are able to provide solutions to difficult design challenges, including trade-offs, that require a great deal of trial and error with conventional technologies. For example, there is generally a trade-off between reducing the weight and ensuring its support stiffness, where improving the performance of one will compromise the other. In addition to these, we can also realize highly challenging designs in which shape and physical function are closely related. ![]() Vibration control Vibration transmission.ĭeformation control by integral structure Heat exchange control. Using our proprietary design algorithm, Direct Functional Modeling™️, we provide various physical functions such as (*2: We mainly deal with shapes that are compatible with manufacturing methods suitable for mass production, such as press working and injection molding).ĭFM Design Solutions is the group of design solutions offered by Nature Architects. (*1: This includes structures that generate mechanical movement, such as moving parts, through elastic deformation (compliant mechanisms)). DFM applies to end products that explicitly deal with motion, such as robotics, automotive, and aerospace, as well as components such as levers, switches, fans, and springs.īy using DFM, Nature Architects can incorporate various physical functions such as deformation, flexibility, vibration absorption, and thermal conductivity into products, and develop new products with greatly increased added value in collaboration with clients. The design of these metamaterials is supported by our proprietary design technology, Direct Functional Modeling™️ (DFM), which enables the instantaneous generation of the appropriate metamaterial structure from the desired physical function and its incorporation into the product. In addition, metamaterials enable designs that go beyond conventional methods to balance multiple trade-offs in design requirements, such as weight reduction and rigidity. In this way, metamaterials can be used to incorporate new physical functions into products without increasing the number of assembled parts. In addition, metamaterials can be used to create precision movements and flexibility in a single structure without assembly, which has conventionally been achieved by assembling mechanical parts or combining different materials. Appropriate use of metamaterials will make it possible to achieve advanced physical functions that were previously thought impossible to achieve using conventional manufacturing methods such as injection molding and metal processing. Metamaterials *1 is a generic term for structures that realize functions beyond the physical functions of natural materials such as resins and metals through artificially designed geometric structures. Nature Architects provides shape design solutions for manufacturers to incorporate various physical functions such as vibration, heat conduction, deformation, and weight reduction into their products by utilizing metamaterials. ![]()
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