繁体中文

Cambridge University researchers use lasers to "heat and strike" 3D printed steel

777
2023-11-03 15:05:19
查看翻譯

According to the University of Cambridge, researchers have developed a new method for 3D printing metal, which can help reduce costs and more effectively utilize resources. This method, developed by a research team led by the University of Cambridge, allows structural modifications to be "programmed" into metal alloys during 3D printing - fine-tuning their performance without the need for thousands of years of "heating and tapping" processes.

The new 3D printing method combines the best quality of two worlds: 3D printing makes complex shapes possible, and traditional methods allow for the engineering design capabilities of metal structures and performance. The research results are published in the journal Nature Communications.

3D printing has broad prospects, but it still has not been widely used in industry, mainly due to high production costs, "said Dr. Matteo Seita of the Engineering Department at the University of Cambridge, who led the research. One of the main drivers of these costs is the amount of adjustment required for materials after production.

Since the Bronze Age, metal parts have been made through the process of heating and beating. This method uses a hammer to harden the material and soften it through fire, allowing manufacturers to shape the metal into the desired shape while endowing it with physical properties such as flexibility or strength.

The reason why heating and beating are so effective is because they change the internal structure of the material, which can control its performance, "Seita said. That's why it's still in use thousands of years later.

One of the main drawbacks of current 3D printing technology is the inability to control the internal structure in the same way, which is why so many post production changes are needed. We are trying to come up with some methods to restore some structural engineering capabilities without the need for heating and tapping, which in turn will help reduce costs, "Seita said. If you can control the metal properties you want, you can take advantage of the green aspect of 3D printing.

Seita has collaborated with colleagues from Singapore, Switzerland, Finland, and Australia to develop a new 3D printed metal "formula" that can highly control the internal structure of materials when they are melted by laser.

By controlling the way the material solidifies after melting and the heat generated during the process, researchers can program the characteristics of the final material. Usually, metals are designed to be sturdy and tough, so they can be safely used for structural applications. 3D printed metal is inherently sturdy, but it is usually also very brittle.

The strategy developed by researchers triggers controlled reconfiguration of microstructure by placing 3D printed metal components in a furnace at relatively low temperatures, thereby fully controlling strength and toughness. Their method uses traditional laser based 3D printing technology, but has made some minor adjustments to the process.

We found that lasers can be used as' micro hammers' to harden metals during the 3D printing process, "Seita said. However, using the same laser to melt the metal a second time will relax the structure of the metal, allowing for structural reconfiguration when the parts are placed in the furnace.

Their 3D printed steel has undergone theoretical design and experimental verification, made of alternating regions of sturdy and tough materials, making its performance comparable to that of steel made by heating and beating.

We believe that this method can help reduce the cost of metal 3D printing, thereby improving the sustainability of the metal manufacturing industry, "Seita said. In the near future, we hope to bypass the low-temperature treatment in the furnace and further reduce the steps required before using 3D printed parts in engineering applications.

The team includes researchers from Nanyang University of Technology, the Science and Technology Research Bureau, the Paul Scherrer Institute, the VTT Technology Research Center in Finland, and the Australian Nuclear Science and Technology Organization. Matteo Seita is a researcher at St. John's College, Cambridge University.

Source: Laser Network

相關推薦
  • The Influence of Laser Beam Intensity Distribution on Lock Hole Geometry and Process Stability under Green Laser Radiation

    Researchers from the University of Aveiro in Portugal and the School of Engineering at Porto Institute of Technology (ISEP) in Portugal reported a study on the influence of laser beam intensity distribution on the geometric shape and process stability of lock holes under green laser radiation. The relevant paper titled "Influence of Laser Beam Intensity Distribution on Keyhole Geometry and Process...

    03-26
    查看翻譯
  • Shanghai University of Technology publishes the latest Nature paper

    With the increasing demand for human data, the requirements for data storage methods are also increasing. Optical Data Storage (ODS) is a light based storage method commonly used in DVDs, which is low-cost and very durable. But ODS usually stores data in a single layer, and the amount of data that can be stored is limited. Gu Min, academician of Shanghai University of Technology, Wen Jing, and Rua...

    2024-02-26
    查看翻譯
  • Internationalization Strategy Enters Stage 2.0 | HSG Hsglaser Thailand Manufacturing Base Holds Grand Opening

    At 9:00 am local time on June 26th, the opening ceremony of Hsglaser Thailand Manufacturing Base was grandly held in Bangkok Industrial Park, Thailand. This not only marks a significant expansion of Hsglaser's global strategic map, but also signifies that its international layout has officially entered a new 2.0 stage, and is another important milestone for Hsglaser to showcase its outstanding str...

    2024-06-27
    查看翻譯
  • Northeastern University of Japan: Breakthrough Laser Technology for Nanoscale Laser Processing

    In the fields of optics and micro/nano processing, precise manipulation of lasers to meet the growing demand for miniaturization is an important challenge in driving the development of modern electronic and biomedical equipment. Recently, researchers from Tohoku University in Japan successfully demonstrated the use of interference technology to enhance the longitudinal electric field of radially p...

    2024-04-12
    查看翻譯
  • The "white" laser device from startup Superlight Photonics will completely transform imaging

    Superlight Photonics, a start-up company headquartered in Enshurd, has developed a broadband laser chip that can replace the bulky and power consuming technology currently used in advanced imaging and metering equipment.This idea suddenly appeared in his mind, while moving his other belongings from Germany to his new home in Enschede. During his doctoral research at the Max Planck Institute of Mul...

    2023-10-28
    查看翻譯