nTopology 4.1.3 Win x64
Free Download nTopology 4.1.3 | 1.5 Gb
The Team nTopology is pleased to announce the availability of nTopology 4.1.3. This is a lighter release with usage improvements and bug fixes to improve your nTop experience.
Product:nTopology
Version:4.1.3
Supported Architectures:x64
Website Home Page :
https://ntopology.com/
Languages Supported:english
System Requirements:Windows *
Size:1.5 Gb
nTop 4.1 - What's New
Type System Updates
With the release of nTop 4.1, we want to ensure that the nTop programming language can grow in a scalable manner to enable more powerful and robust computational design workflows in the future so that you can build the best parts. We fully maintained backward compatibility for this type update so any previous notebooks can be opened, viewed, run, and edited in nTop 4.1+ and future versions. In the new system, behaviors will be changed if you are working with:
- Lists
- Groups
- Abstract Types (e.g. Material, Spatial3D)
- Interface Functions (e.g. Translate Object, Rotate Object)
Usage Improvements
When automatically switching from an overloaded block that has an input containing an auto-populated default value, nTop will no longer prevent you from switching overloads and will discard the default value (shown below with Subdivisions input).
Note: If you delete the default value and type in any user-defined value, the overload will be prevented from switching until the value is cleared.
- The notebook description has been moved into the scrollable notebook body to allow you to view more of your workflow at a glance.
Block Updates
- We moved the Natural Frequency Response block for optimization to production version 1.0.0. You can find the block in the Optimization ribbon under the Responses section.
- We released new versions of the Sweep and Twisted Sweep blocks and deprecated versions 1.0.0. Version 1.1.0 of the Sweep and Twisted Sweep blocks include bug fixes, produces better fields with accurate gradients, and will run faster. We have also fixed the discontinuities in the interpolation of the twist angle in the Twisted Sweep block.
- We consolidated certain blocks into one block with multiple overloads. For the changes listed below, if you have been using the latest block versions, our backwards compatibility system will take care of this update for you. You do not need to make any manual changes to your notebook.
- The Collapse Mesh Vertices and Collapse Lattice Vertices blocks are now one block with multiple overloads, and we simplified the name to Collapse Vertices We also added another overload that accepts a Graph as an input.
- The Merge Meshes and Merge Lattices blocks are also consolidated into one block with multiple overloads, and there is a new overload for the Graph data type. Note that the merge operation does not collapse vertices. If needed, use Collapse Vertices prior to merging.
- We added an overload to the Trim Lattice block that accepts a Graph. This overload, as well as those mentioned above, gives you more control over your Graph when creating a custom Unit Cell for latticing.
- We separated version 1.0.0 of the Mesh from Implicit Body block from the versions 2.0-2.4 grouping, and renamed the block to Mesh from Implicit by DC. This block has a lower computational overhead than Mesh from Implicit Body, however the result may contain self-intersections and non-manifold edges or vertices.
https://avxhm.in/software/#collapse_78434
- We fixed an issue allowing you to import a file from the home screen but have the imported file hidden. You will no longer be able to import from the home screen. You can import once a file is created or opened.
- We fixed an issue that prevented warnings from displaying on the Merge Meshes block. The block warnings will correctly appear when the output has issues, such as self-intersecting elements.
- We fixed an issue in the Homogenize Unit Cell block to restore the speed of the material property calculation to its original performance
nTopologyintroduced the concept of implicit modeling for mechanical design, which is an innovative, modern, and scalable way define parts and products. It has many benefits to end-users and companies, such as the elimination of model failures, speed of changes or iterations, and scalability to name a few. But implicit modeling enables so much more. In this informational session, we'll explore a topic that is redefining product development - field-driven design. In short, field-driven design is a way for design, analysis, and manufacturing teams to overlay information into one engineering model. This approach enables orders of magnitude increase in design iteration speed and greatly improves collaboration between teams.
How Field-Driven Design Allows Engineers to Design for Additive Manufacturing
Watch this information session where we'll define field-driven design, show examples of how it enables better knowledge sharing, and show how it promotes the development of more sophisticated, highly engineered products. You'll also better understand how nTopology is addressing today's engineering problems through its nTop Platform product.
nTopologywas founded in 2015 to enable engineers and designers to create any geometry - no matter how complex - and meet the requirements of high-performance products.
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