November 02, 2021 | Volume 17 Issue 41 |
Manufacturing Center
Product Spotlight
Modern Applications News
Metalworking Ideas For
Today's Job Shops
Tooling and Production
Strategies for large
metalworking plants
JW Winco has expanded its magnet line to support more applications with new materials, shapes, systems, and even raw magnets. Learn about their latest offerings, including retaining magnets designed for corrosive environments (GN 50.8), encapsulated magnets designed for sensitive or painted surfaces (GN 51.8), handle magnets (GN 53.3), and powerful magnets designed to handle challenging environs (GN 52.6).
Learn more.
igus has developed a new polymer bearing material called iglide JPF that is free of both per- and polyfluoroalkyl substances (PFAS) and polytetrafluoroethylene (PTFE). This innovation marks an important step in the company's efforts to create sustainable alternatives to conventional plain bearings. JPF is a dry-running, wear-resistant polymer that offers comparable friction and wear performance to iglide J. It delivers high wear resistance and durability.
Learn more.
The all-new PSLA 270 projector-based polymer 3D-printing platform and associated new materials from 3D Systems enable faster production times for a wide range of applications. This machine's high throughput and accuracy make it ideal for industries like healthcare, aerospace, automotive, and manufacturing, where precise and durable components are critical. Complementary Wash and Cure systems streamline post-processing and ensure high-quality finished parts.
Learn more including materials and build sizes.
Southco has launched the E3 Compact MIM compression latch, bringing new ergonomic and safety features to its durable family of latches in a low-profile package. The E3 Compact MIM compression latch is metal injection molded and has a shorter head (4 mm vs. the normal 6.4 mm), 180-degree ergonomic actuation, and visual indicators machined into the latch and color coded to easily show when it is open or closed. Features a sleek, low-profile, polished look.
Learn more.
What is the right seal for my application? The Sealing & Shielding Team at Parker Hannifin is looking to help you out in this blog. Learn some basics and possible modifications, including application and manufacturing considerations, gland options, mating hardware, and more. They are always very helpful over there at Parker.
Read the Parker blog.
EXAIR's Adjustable Spot Cooler System offers a low-cost, reliable, and maintenance-free solution for industrial spot cooling needs. This tool offers precision control, versatility, and ease of use for a variety of applications including milling, machining, soldering, gas sampling, welding, and more. Utilizing cool and clean compressed air, the Spot Cooler allows users to precisely adjust temperatures from as low as -30°F (-34°C) to room temperature with the simple turn of a knob.
Learn more.
From the watch dial on your wrist to a wind turbine, no application is too small or too big for a Smalley retaining ring to secure. Light to heavy-duty loads? Carbon steel to exotic materials? No problem. See how retaining rings are used in slip clutches, bike locks, hip replacements, and even the Louvre Pyramid.
See the Smalley design applications.
Built on Formlabs' next-generation Low Force Display print engine, the new Form 4L SLA 3D printer delivers unmatched reliability with a 99% print success rate compared to other SLA 3D printers. These benefits, combined with a build volume nearly 5x the size of Form 4, allow Form 4L users to solve big problems and print smaller parts at high volume. Large-scale prints finished in under six hours.
Learn more.
The last couple of major releases of SOLIDWORKS each introduced significant new Assembly modeling features and workflows. Want to know what's new? Catch up on what you might have missed out on since your last upgrade -- and get a first look at highlights from the upcoming SOLIDWORKS 2025. Some very useful changes!
View the video.
3D-printing materials just keep getting better -- and now there are more choices than ever. Watch as Walter Voit, SVP Polymer Materials, Desktop Metal, describes the 3D printing of DuraChain Elastic ToughRubber photopolymers, which produce tough and resilient end-use parts while eliminating the need for a two-part resin. DuraChain photopolymers also demonstrate a long pot life of roughly one year, depending on environmental conditions, making them more suitable for volume production and reducing waste from spoiled, unused material. These materials are offered exclusively on the ETEC Xtreme 8K top-down DLP systems. ETEC is a wholly-owned subsidiary of Desktop Metal.
Learn about this exciting material.
Learn about the ETEC Xtreme 8K DLP systems -- and what makes them so much better.
THK has developed its best-performing, high-speed rotary bearing ever: the High-Speed, Double-Row Angular Contact Ring BWH. This rotary bearing has balls aligned inside a cage between the inner and outer rings and is part of the THK Rotary Series, along with the cross-roller ring. The main features of this product are its ability to receive loads in all directions as well as its high rigidity and rotational accuracy, which are equal to that of cross-roller rings. By adopting a new structure to change the rolling elements from rollers to balls, this product achieves the greatest high-speed performance ever offered by THK.
Learn more.
Ruland Manufacturing has expanded its jaw coupling line to meet the demands of high-torque applications, now offering bore sizes up to 1-3/4 in. or 45 mm and torque capacities of 2,655 in.-lb (300 Nm). Target uses are in precision systems with high deceleration and acceleration curves, such as semiconductor, solar, conveyor, and warehouse automation applications. Features include zero-backlash, industry-leading misalignment capabilities, and a balanced design that reduces vibration at speeds up to 8,000 rpm.
Learn more.
Can you get a design and functional edge with a wedge? In this animated video, Nord-Lock explains the principle behind their original wedge-locking technology, which secures bolted joints even when exposed to severe vibration and dynamic loads. The company says it is impossible for this washer type to loosen unintentionally, due to the wedge created underneath the bolt head and nut.
View the video.
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.
Learn more.
Rotor Clip has just launched its new, patented InterShim™ Wave Spring design, which has been engineered for high-acceleration electric motor applications. It features alternating turns between inactive (flat) and active (waved) turns to ensure reliable performance under torsional loads and precise rotational movement. The highly customizable wave spring's advanced design addresses physical challenges such as extreme forces and vibrations, making it a versatile solution for high-speed and high-stress applications across various industries.
Learn more.
Computational materials science experts at the U.S. Department of Energy's Ames Laboratory and their collaborators have identified the source of, and the way to tune the strength and ductility of, a class of materials called high-entropy alloys (HEAs). The discovery may help the power-generation and aviation industries develop more efficient engines, reducing fuel consumption and carbon emissions.
High-entropy alloys are composed from four or more different elements, and often have many desirable properties -- they are lightweight, strong, ductile, corrosion resistant, and ideal for energy-generation applications in extreme environments such as aviation. However, because the elements that make up an alloy can vary, as well as their relative proportions, experimentally testing the sheer number of possible combinations and their properties is difficult and time consuming.
The Ames Laboratory-led team used a quantum-mechanical modeling method to computationally discover and predict the atomic structure of a particularly promising HEA system, FexMn80-xCo10Cr10, and how transformations and defects in that structure result in a stronger, more ductile material.
"When we can pinpoint these transformations and the effect they have on a material's properties, we can predict the strength of it, and we can deliberately design strength and ductility into these very complex alloys," said Ames Laboratory scientist Duane Johnson. These predictions were then confirmed experimentally, studying single-crystal samples with advanced electron microscopy, including selective-area and electron-backscattered diffraction. Notably, the method is applicable to any multi-element complex alloy.
Theory-guided computational design, Johnson said, holds great promise for optimizing the performance of these materials, making them stronger, more ductile, and in many cases, less expensive. These performance improvements could have big implications for applications in extreme environments, like turbine engines for power-generation or aviation, which work more efficiently at higher temperatures.
"Using this predictive method, we've been able to speed up our alloy development timeline by more than 50%, and demonstrate 10 to 20% higher operational temperatures," said Johnson. In the case of aviation, he said, this could translate into hundreds of millions of dollars in cost savings, and a significant reduction in greenhouse emissions.
The research is further discussed in the paper, "Martensitic Transformation in FexMn80-xCo10Cr10 High-Entropy Alloy," authored by P. Singh, S. Picak, A. Sharma, Y. I. Chumlyakov, R. Arroyave, I. Karaman, and Duane D. Johnson; and published in Physical Review Letters.
Ames Laboratory is a U.S. Department of Energy Office of Science National Laboratory operated by Iowa State University.
Source: Ames Laboratory
Published November 2021