News

News

Scientists Use a Little Math to Print the Strongest Kind of Steel

Data: 2020-04-24
Views: 224

Industry News | Scientists Use a Little Math to Print the Strongest Kind of Steel


Scientists from Texas A&M University and the U.S. Air Force say they’ve developed a way to 3D print the strongest kind of steel, along with many other metals.


By using a steel powder melted into place by a laser, this process follows in the footsteps of technologies like powder welding. And by adding a mathematical model to gauge which laser settings will best reduce printing flaws, the researchers have made a process they say makes strong steel into strong 3D-printed steel items.


The mathematical model and its results are presented as an “optimization framework” that anchors the research team’s new paper.


“This framework utilizes the computationally inexpensive Eagar-Tsai model, calibrated with single track experiments, to predict the melt pool geometry,” the team writes. “Computationally inexpensive” means the mathematical model doesn’t require a lot of processing juice. Using this term usually indicates the new idea is an alternative that saves a ton of time compared to a traditionally iterating or permutating algorithm that can take, well, almost forever.


The results were striking right away. The team used its framework on a selective laser melting (SLM) additive sample made from an especially corrosion-resistant steel called AF9628. From the paper's abstract:


“Using this framework, fully dense samples were successfully fabricated over a wide range of process parameters, allowing the construction of an SLM processing map for AF9628. The as-printed samples displayed tensile strengths of up to 1.4 GPa, the highest reported to date for any 3D printed alloy.'


Why does introducing math make the steel so much stronger? The answer lies in some facts about steel itself and about 3D printing in general. The steel these researchers focus on, named martensite steel after the inventive 19th-century metallurgist Adolf Martens, is made in a process where extreme cooling traps carbon inside the structure of the steel. The overall category “carbon steel,” like a pan or car parts or the sharpest cutting implements, includes all martensite steels but is not exclusively martensite steels.


Carbon steels can already be quite brittle, and the techniques used in additive manufacturing—the technical term for 3D printing—can introduce flaws called porosities. “Porosities are tiny holes that can sharply reduce the strength of the final 3D-printed object, even if the raw material used for the 3D printing is very strong,” researcher Ibrahim Karaman explained.


And to minimize porosities, the researchers used the large existing body of research about powder and other kinds of welding, where metal powder is heated to form the bonding agent between two pieces of metal. By varying the number of laser pulses per second and the power of the laser itself, the researchers adapted a welding model to begin developing and fine-tuning their 3D printing model. In subsequent iterations, they continued to tune, until their final model could tell in advance if certain settings would work well or not.


This means steel manufacturers could save development time and wasted materials they might burn through while doing their own experiments with 3D printing—or, more likely, it could lure them into the realm of 3D printing at all. Adding ultrahard carbon steel to the 3D printing repertoire could be a huge boon for the industry, from the most established old companies to rocket-printing startups.


Via: https://www.popularmechanics.com/

Note: Content may be edited for style and length.





News / Recommended news More
2020 - 07 - 22
Material scientists from NUST MISIS and the University of Western Australia have presented an innovative bioresorbable alloy based on magnesium, gallium and zinc. The material can be used for the manufacture of temporary implants in the treatment of fractures and the restoration of surgically removed areas of the bone, as well as in the treatment of osteoporosis, multiple myeloma, Paget's dise...
2020 - 07 - 16
PM China & CCEC China & IACE China 2020 gathers nearly 500 exhibitors under one roof to showcase advanced technologies, equipments and high-quality products such as high-performance materials, advanced ceramics products, new molding and processing technology, manufacturing technology of high precision parts, intelligent manufacturing technology and 3D printing technology.Acquiring latest i...
2020 - 06 - 17
A new study by researchers at Cranfield University in the UK finds that switching from aluminum to zinc alloys in the production of automotive parts could greatly enhance their longevity and sustainability.The study, conducted by Cranfield’s Sustainable Manufacturing Systems Center, evaluated the performance of three different alloys (aluminum-A380, magnesium-AZ91D and zinc-ZA8) considering overal...
2020 - 05 - 14
MIM is currently the most scientific near net shape forming technology for metal parts formation. It can flexibly adjust to various performance indexes and has been successfully applied to popular areas such as auto parts, 3C digital, medical equipment and tool locks. Hence, traditional molding technologies such as CNC fine processing, to some extent, are being replaced. Although the future of MIM...
Share:
Uniris Exhibition Shanghai Co., Ltd.
Shanghai Branch
Tel:4000 778 909
E-mail:irisexpo@163.com
  
Guangzhou Branch
Tel:020-8327 6389
E-mail:pmchina@unifair.com

CCEC CHINA official website
犀牛云提供企业云服务
Scan the QR code to visit the official website by phone