What Industries Use Sheet Tube Laser Cutting Machines?

Sheet Tube Laser Cutting Machines are a type of computer-controlled technology that uses a laser beam to cut metal sheets or tubes into accurate shapes. Its ability to cut through thick materials, intricately designed curves, and angles, has made it a popular choice for various industries. It is a versatile machine that can be used in various fields, including automotive, aerospace, electronics, construction, and many more.

What are the advantages of using Sheet Tube Laser Cutting Machines? Sheet Tube Laser Cutting Machines offer a highly precise and efficient cutting process. It can cut through a wide range of metals, from thin sheet metal to thick plates and tubes. It has a minimal heat-affected zone, which saves material and reduces the need for further finishing operations. The machine also has a high cutting speed, which results in reduced cycle times, increased productivity, and reduced production costs.

What industries use Sheet Tube Laser Cutting Machines? The automotive industry widely uses Sheet Tube Laser Cutting Machines for the production of car parts like stamped panels, brackets, and exhaust systems. Aerospace companies also use them to produce complex parts like aerodynamic parts and frames. Electronics manufacturers use Sheet Tube Laser Cutting Machines to produce metal parts for cell phones, computers, and other devices. Sheet Tube Laser Cutting Machines are also used in the construction industry to produce metal facades, railing, and stairs, along with many other industries.

What are the different types of Sheet Tube Laser Cutting Machines? There are two types of Sheet Tube Laser Cutting Machines: CO2 and fiber. CO2 machines are suitable for cutting thick metal sheets, while fiber machines are suitable for cutting thin sheets. Fiber machines are more efficient and can cut reflective materials like aluminum, copper, and brass.

Sheet Tube Laser Cutting Machines are an essential technology in various industries. Its high precision, efficiency, and versatility have made it a valuable asset in today's modern industry. As the technology continues to evolve, Sheet Tube Laser Cutting Machines will undoubtedly become even more widely used in the future.

Shenyang Huawei Laser Equipment Manufacturing Co., Ltd. is a leading manufacturer of Sheet Tube Laser Cutting Machines in China. With years of experience in laser technology, Huawei Laser is committed to providing quality products and excellent customer service. For more information about our products, please contact us at HuaWeiLaser2017@163.com.

References

1. Berthold, J.W. (2011). Fiber Lasers: The Future of Metalworking. Industrial Laser Solutions for Manufacturing, 26(3), 21-23.

2. Duflou, J.R., Debruyne, D., Verbert, J., & Boel, V. (2006). Laser cutting of thin tubes: a state-of-the-art review. Journal of Materials Processing Technology, 172(1), 88-96.

3. Li, L., Li, C., & Zhang, Y. (2016). Online monitoring system for laser cutting quality based on machine vision. International Journal of Advanced Manufacturing Technology, 87(1-4), 837-846.

4. Tanaka, H., Umezu, S., & Katayama, S. (2015). Determination of optimal cutting conditions in laser cutting of metal sheets. International Journal of Machine Tools and Manufacture, 92, 47-58.

5. Wang, Z., Li, X., & Li, B. (2016). Status and prospect of laser cutting technology based on big data analysis. Journal of Physics: Conference Series, 710(1), 01201.

6. Zhang, W., Wang, J., Huang, W., & Gao, Y. (2018). Study on laser cutting quality of metal sheets. International Journal of Advanced Manufacturing Technology, 96(9-12), 4063-4072.

7. Zhou, Y., Zhao, X., Guo, Y., & Huang, S. (2020). Investigation of material physical effects in pulsed laser cutting of thin titanium alloy sheets. CIRP Journal of Manufacturing Science and Technology, 27, 74-83.

8. Yin, J., Yang, J., Fu, Y., & Zhang, J. (2018). Study on optimal cutting parameters of stainless steel fiber laser cutting. Journal of Physics: Conference Series, 1069(1), 012130.

9. Hu, M., Zhang, S., Sun, D., & An, Q. (2017). A comparative investigation of cutting force models for fiber laser cutting stainless steels. Journal of Modern Manufacturing Engineering, 6(1), 29-36.

10. Zhao, Y., Zhu, G., Li, J., Lin, J., & Huang, H. (2016). Dynamic response and performance comparison of stiffness compensation methods for a laser cutting machine. IEEE/ASME Transactions on Mechatronics, 21(1), 542-551.