Optical Fiber 2-color Ratio Pyrometer
This classification includes two 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. SMART-F series two-color pyrometer determines the temperature of an object by measuring the ratio of energy at two different wavelengths. The advanced software and hardware design help pyrometers meet the application in harsh environment as moisture, dust, target size change, partial blockage and emissivity change, even if the detection signal attenuates 95%, the temperature measurement results will not be effected. SMART-F series two-color infrared pyrometer can meet the requirements of two color measuring in various industrial occasions. For example, medium-high temperature below 2000℃, such as: hot rolled plate, casting, cement kiln, heat treatment, induction heating, monocrystalline silicon and polycrystalline silicon, etc. It can also be used in ultra-high temperature below 3000℃ measuring with high stability, such as vacuum furnace, graphite furnace, high-temperature furnace 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 2-Color Ratio Pyrometer,Fiber Optical Pyrometer,Fiber Optical Infrared Pyrometer,Fiber Two Color Pyrometer Changzhou Sijie Optoelectronics Technology Co.,Ltd. , https://www.sjinfrared.com
The LASIMM project, an ambitious initiative funded by the European Union’s Horizon 2020 program, has finally reached the operational phase. This project brings together 10 organizations from six different countries, each contributing their expertise in robotics, software development, and advanced manufacturing. The result is the Large Additive Subtractive Integrated Modular Machine, or LASIMM, one of the world's largest hybrid manufacturing systems.
Based at Loxin's facilities in Pamplona, Spain, LASIMM stands out with its unique combination of additive and subtractive manufacturing capabilities. Designed to handle massive projects, the machine can fabricate metal parts and structures up to 6 meters by 2 meters in size and weighing up to 2,000 kilograms. This breakthrough technology aims to reduce costs, boost efficiency, and enhance production flexibility, giving Europe a competitive edge in the global industrial landscape.
Autodesk, alongside five other companies, two universities, and two research institutions, collaborated on this ambitious project. Their efforts focused on creating a scalable open architecture framework, allowing for full parallel manufacturing. The machine is equipped with modular configurations of industrial robots and specialized milling tools, capable of additive manufacturing for aluminum and steel, along with precision machining to achieve the desired finishes.
The LASIMM project represents a paradigm shift in how large-scale industrial components are manufactured. By integrating multiple processes into a single system, it offers significant advantages, including a projected 20% reduction in time and cost, and a 15% increase in productivity for high-volume additive manufacturing. These advancements not only promise to revolutionize industries like aerospace, renewable energy, and transportation but also contribute to the standardization and certification of new hybrid manufacturing techniques.
One of the standout features of LASIMM is its ability to move away from standardized components toward more personalized and bespoke solutions. This adaptability opens up possibilities for entire industries to rethink their manufacturing strategies, moving towards localized production environments and shorter supply chains. The project’s success is a testament to the power of collaboration across borders, with team members bonding over shared goals despite cultural differences.
Despite the challenges of working with such a diverse group, the LASIMM team has achieved remarkable progress. They’ve already begun testing the machine to produce demonstrator parts, including large cantilever beams, airplane panels, and wind turbine components. Designed by leading industrial end-users, these parts push the machine’s capabilities to the limit. The machine’s hybrid approach combines additive manufacturing, machining, cold-work, metrology, and inspection, delivering optimal solutions for large-scale engineering projects.
Looking ahead, the LASIMM project holds immense potential for reshaping the future of industrial manufacturing. As the lead software partner, Autodesk has played a crucial role in developing the necessary toolpaths for building complex parts. The integration of multiple processes into a single machine represents a significant leap forward in hybrid manufacturing, paving the way for even larger-scale applications in the future.
Eurico Assunção, Deputy Director at the European Federation for Welding, Joining and Cutting and the LASIMM project coordinator, expressed his excitement about the project’s achievements: “While consumer-focused 3D printing has gained much attention, it is in industrial manufacturing and construction where this technology could make its most profound impact. The completion of LASIMM marks a technological milestone that will enable the future of large-scale 3D-printed infrastructure.â€
The LASIMM project not only pushes the boundaries of what’s possible with hybrid manufacturing but also highlights the importance of collaborative efforts in advancing technology. With its projected benefits, including reduced costs, increased productivity, and improved flexibility, LASIMM is set to transform the global manufacturing landscape. The journey from concept to reality has been challenging yet rewarding, proving that innovation thrives when diverse talents unite under a common vision.