Optical Fiber 1-color Pyrometer This classification includes one color infrared pyrometers which consist of lens, fiber optics and processing components. Fiber optic can bear high temperature up to 250℃ and do not need additional cooling. It has strong casing, use stainless steel lens(with air purge functions), die cast aluminum housing, protection grade is IP54. One color pyrometer determine the object temperature by receiving the sum of the narrow-band radiation energy, around(0.85~1.1)μm, emitted by the object. product detector nornally use si. Pyrometers can be widely used in metallurgical industry (wire rod, hot rolled plate,forging) and forging industry, heat treatment, induction heating, monocrystalline silicon and polycrystalline silicon,etc. SMART-F series is not only suitable for general industrial occasions of temperature measurement, but also suitable for installation in occasions with strong electromagnetic interference and high environmental temperature. Optical Fiber 1-Color Pyrometer,Optical Fiber Pyrometer,Fiber One Color Pyrometer,Infrared Pyrometer Calibration Changzhou Sijie Optoelectronics Technology Co.,Ltd. , https://www.sjinfrared.com
The LASIMM project, an ambitious endeavor in hybrid manufacturing, has recently come online and is set to revolutionize how large-scale components are produced across Europe. This project, spearheaded by ten organizations from six different countries, brings together a unique blend of expertise including robotics, software development, and advanced machinery engineering. Funded under the European Union's Horizon 2020 research and innovation program, LASIMM aims to enhance Europe's industrial competitiveness by reducing costs, improving efficiency, and offering greater production flexibility.
Based out of Loxin's facilities in Pamplona, Spain, LASIMM stands as one of the largest hybrid manufacturing machines in the world. It boasts exceptional capabilities in both additive and subtractive manufacturing, allowing it to create complex metal parts and structures up to 6 meters in length and 2 meters in diameter, with weights reaching up to 2000 kilograms. This machine represents a significant advancement in the field of hybrid manufacturing, promising to streamline the production of critical components for industries like aerospace, renewable energy, transportation, and construction.
Autodesk, alongside five other companies, two universities, and two research institutions, has played a pivotal role in developing LASIMM. Utilizing a scalable open architecture framework, the project integrates various manufacturing processes into a single system. This setup not only allows for parallel manufacturing but also supports the creation of intricate designs directly from CAD models. The machine is currently being tested on demonstrator parts such as large cantilever beams, airplane panels, and wind turbine components, each designed to push the machine's capabilities to their limits.
One of the standout features of LASIMM is its modular configuration, which combines industrial robot arms with specialized milling robots. These robots handle additive manufacturing tasks for aluminum and steel, followed by precision machining to achieve the desired finish. This approach opens new possibilities for industries seeking customized solutions over standardized components.
As the lead software partner, Autodesk has been instrumental in advancing multi-machine-multi-process CAM technology. Their innovative solutions enable the creation of toolpaths during the build process, significantly enhancing the machine's operational efficiency. The collaboration among the diverse team members, despite cultural differences, has been marked by camaraderie, fostering a spirit of unity and shared purpose.
The LASIMM project is expected to yield numerous benefits, including a projected 20% reduction in time and cost compared to traditional additive and subtractive processes, along with a 15% increase in productivity for high-volume additive manufacturing. Additional advantages include increased machine flexibility and robustness, reduced inventory needs, and shorter supply chains, all contributing to localized manufacturing environments.
Eurico Assunção, Deputy Director at the European Federation for Welding, Joining and Cutting and the LASIMM project coordinator, expressed excitement about the project's potential. He noted that while consumer-focused 3D printing has garnered much attention, it is within industrial applications that this technology holds the greatest transformative power. The successful completion of LASIMM marks a significant milestone in hybrid manufacturing, paving the way for future innovations in construction and beyond.
Looking ahead, the LASIMM project not only showcases the current state-of-the-art in hybrid manufacturing but also sets a foundation for future advancements. As industries increasingly adopt these technologies, they will benefit from enhanced capabilities, reduced costs, and improved sustainability. The collaborative effort behind LASIMM serves as a model for global partnerships in cutting-edge research and development, highlighting the power of combining diverse talents and resources to achieve groundbreaking results.