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Superior fastening solution for securing rotating components to a shaft

Shaftloc^® fasteners offer distinct advantages over other fastening methods when securing rotating components to a shaft. The key to this compact, efficient design is its asymmetric thread geometry that produces a greater clamping force -- outperforming other fastening methods. Shaftloc is a patented fastening system manufactured by SDP/SI.
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Print 316L stainless steel on Markforged printers

316L Stainless Steel is now available for use with Markforged FX10 printers, allowing users to manufacture high-strength, accurate parts for demanding applications such as food and beverage processing, automotive, chemical and petrochemical processing, medical devices, and marine environments. This filament is safe and easy to handle. It makes machinable and polishable parts that have excellent corrosion resistance.
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10 best updates from the last 5 years: SOLIDWORKS

Follow along with the experts at TriMech Group as they chronicle the top feature updates in SOLIDWORKS. Are you still using SOLIDWORKS 2020 -- or an even older version? Find out what you are missing, such as: enhanced rendering and new technical drawing tools; improved file sharing, collaboration, and workflows; advanced customization and UI improvements; faster and more efficient assemblies and simulations; and more.
View the TriMech video.

Engineer's Toolbox: How to design the optimum hinge

Although many pin styles are available, Coiled Spring Pins are particularly well suited for use in both friction- and free-fit hinges. To achieve optimum long-term hinge performance, designers should observe these helpful design guidelines from SPIROL.
Read the full article.

Innovative new robo welding gun

Comau's newest N-WG welding gun is designed for high-speed spot welding for traditional, hybrid, and electric vehicles, in addition to general industry sectors. It features a patented, single-body architecture that enables rapid reconfiguration between welding types and forces, and it delivers consistent performance across a broad range of applications, including steel and (soon) aluminum welding. It supports both X and C standard gun configurations, has fast arm exchange, and universal mounting options. It is fully compatible with major robot brands and represents a significant advancement in spot welding performance and cost efficiency.
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What's a SLIC Pin^®? Pin and cotter all in one!

The SLIC Pin (Self-Locking Implanted Cotter Pin) from Pivot Point is a pin and cotter all in one. This one-piece locking clevis pin is cost saving, fast, and secure. It functions as a quick locking pin wherever you need a fast-lock function. It features a spring-loaded plunger that functions as an easy insertion ramp. This revolutionary fastening pin is very popular and used successfully in a wide range of applications.
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Engineering challenge: Which 3D-printed parts will fade?

How does prolonged exposure to intense UV light impact 3D-printed plastics? Will they fade? This is what Xometry's Director of Application Engineering, Greg Paulsen, set to find out. In this video, Paulsen performs comprehensive tests on samples manufactured using various additive processes, including FDM, SLS, SLA, PolyJet, DLS, and LSPc, to determine their UV resistance. Very informative. Some results may surprise you.
View the video.

Copper filament for 3D printing

Virtual Foundry, the company that brought us 3D-printable lunar regolith simulant, says its popular Copper Filamet™ (not a typo) is "back in stock and ready for your next project." This material is compatible with any open-architecture FDM/FFF 3D printer. After sintering, final parts are 100% pure copper. Also available as pellets. The company says this is one of the easiest materials to print and sinter. New Porcelain Filamet™ available too.
Learn more and get all the specs.

Copper foam -- so many advantages

Copper foam from Goodfellow combines the outstanding thermal conductivity of copper with the structural benefits of a metal foam. These features are of particular interest to design engineers working in the fields of medical products and devices, defense systems and manned flight, power generation, and the manufacture of semiconductor devices. This product has a true skeletal structure with no voids, inclusions, or entrapments. A perennial favorite of Designfax readers.
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Full-color 3D-printing Design Guide from Xometry

With Xometry's PolyJet 3D-printing service, you can order full-color 3D prints easily. Their no-cost design guide will help you learn about different aspects of 3D printing colorful parts, how to create and add color to your models, and best practices to keep in mind when printing in full color. Learn how to take full advantage of the 600,000 unique colors available in this flexible additive process.
Get the Xometry guide.

Tech Tip: How to create high-quality STL files for 3D prints

Have you ever 3D printed a part that had flat spots or faceted surfaces where smooth curves were supposed to be? You are not alone, and it's not your 3D printer's fault. According to Markforged, the culprit is likely a lack of resolution in the STL file used to create the part.
Read this detailed and informative Markforged blog.

Test your knowledge: High-temp adhesives

Put your knowledge to the test by trying to answer these key questions on how to choose the right high-temperature-resistant adhesive. The technical experts from Master Bond cover critical information necessary for the selection process, including questions on glass transition temperature and service temperature range. Some of the answers may surprise even the savviest of engineers.
Take the quiz.

Engineer's Toolbox: How to pin a shaft and hub assembly properly

One of the primary benefits of using a coiled spring pin to affix a hub or gear to a shaft is the coiled pin's ability to prevent hole damage. Another is the coiled pin absorbs wider hole tolerances than any other press-fit pin. This translates to lower total manufacturing costs of the assembly. However, there are a few design guidelines that must be adhered to in order to achieve the maximum strength of the pinned system and prevent damage to the assembly.
Read this very informative SPIROL article.

What's new in Creo Parametric 11.0?

Creo Parametric 11.0 is packed with productivity-enhancing updates, and sometimes the smallest changes make the biggest impact in your daily workflows. Mark Potrzebowski, Technical Training Engineer, Rand 3D, runs through the newest functionality -- from improved surface modeling tools to smarter file management and model tree navigation. Videos provide extra instruction.
Read the full article.

What's so special about wave springs?

Don't settle for ordinary springs. Opt for Rotor Clip wave springs. A wave spring is a type of flat wire compression spring characterized by its unique waveform-like structure. Unlike traditional coil springs, wave springs offer an innovative solution to complex engineering challenges, producing forces from bending, not torsion. Their standout feature lies in their ability to compress and expand efficiently while occupying up to 50% less axial space than traditional compression springs. Experience the difference Rotor Clip wave springs can make in your applications today!
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Why does static friction weaken at higher loads? Researchers have an explanation

Picture yourself at a busy pedestrian crossing. When the light is red, everyone waits -- until one person starts to cross. Soon, others follow, and, eventually, everyone follows the crowd and crosses. Physicists in Amsterdam have discovered that a very similar process happens at the microscopic level, when two touching surfaces start to slide. Their results were published in Physical Review Letters at the end of April.

In their experiment, Liang Peng, Thibault Roch, Daniel Bonn, and Bart Weber pressed a smooth silicon surface against a rough one. The researchers, from the University of Amsterdam and the Advanced Research Center for Nanolithography, then explored how the friction behaved when the strength with which the two surfaces are pressed together was varied. Does it get harder to slide the two surfaces along one another when one presses harder? If so or if not, why?

Understanding the why
It turned out that the amount of friction depends on a very interesting underlying process. At low applied force, only one tiny contact point -- a so-called "asperity" -- bears the load, and it needs to be pushed hard before it slips. However, as the force perpendicular to the interface increases, many asperities come into contact. The team discovered that in this situation, once a few asperities start slipping, others are triggered to follow -- just like the first bold pedestrians prompt a crowd to cross.

As a result, and perhaps counterintuitively, the surface starts sliding more easily, and the relative resistance to motion -- the so-called static friction coefficient -- decreases.

This sketch shows what the researchers see when they zoom in strongly on the interface between two materials. The rougher material (gray, on top) touches the smoother material (purple, bottom) in various asperities. [Credit: Image by Bart Weber/Courtesy of University of Amsterdam Institute of Physics]

Using a simple mathematical model to support their experiments, the researchers were able to show that the crowd-like behavior of the asperities explains why static friction weakens at higher loads.

From semiconductors to earthquakes
The results have applications at small and large scales. At small scales, in the semiconductor industry, the construction of electronic devices often requires clamping curved surfaces to a flat table. This results in an interface that is right at the boundary of slipping and not slipping. The new research explains how the onset of sliding is influenced by the scale of the contact, which is important to know when accurately constructing devices using all sorts of materials.

At larger scales, earthquakes are the result of the onset of sliding between sections of the Earth's crust. Understanding how this slip starts, and what effects become important when interfaces get bigger, can support our understanding of how earthquakes come about, and it may help predict them in the future.

Source: University of Amsterdam Institute of Physics

Published June 2025

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