Robin Stuhler VIEWPOINTS INDUSTRY LEADER OPINION & ANALYSIS Laser Welding for Sheetmetal Fabricators v A


lthough laser welding is a well-established manufac- turing solution, many sheetmetal fabricators have been hesitant to implement the process at their shop. For many years they have missed out on the advantages laser welding has to offer and focused on improving other bottlenecks, for example, in laser cutting or bending. With these solutions in place and laser welding emerging as a more viable solution, many fabricators are beginning to rec- ognize the laser welding process as the next logical step in enhancing their production capabilities. Manufacturers benefi t from any process that reduces cost per part—and laser welding has many advantages in this regard. Due to the low heat input of this process, distortion and discoloration can be avoided to completely eliminate the need for refi nishing. As these postprocesses are ex- tremely time consuming and expensive, the costs per part are signifi cantly reduced. Furthermore, laser welding speeds are considerably higher than conventional processes, which often greatly reduces processing times. This leads to free capacity on the machine, allowing the manufacturer to serve more customers.


Laser welding is not only about reducing costs, but also


increasing functionality. A smooth surface with an extremely narrow welding geometry is benefi cial for kitchen, furniture and other industries where visible weld seams are common. Due to the low heat input, manufacturers can avoid discolor- ation and achieve highly aesthetic parts directly from the ma- chine. One can also achieve very strong seams for parts that require strength. The characteristic seam geometry of laser welding leads to full penetration of the parts while reducing the infl uence on the grain structure. Tensile strength tests show conventionally welded seams break in the welding seam, while laser welded parts break in the base material. After the welding program is implemented and the pa- rameters are set, a laser welding robot achieves consistent quality every time. It is also a very stable process and can


88 AdvancedManufacturing.org | April 2017


generate watertight seams to eliminate the need for leak tests. Laser welding also offers unique seam geometries en- abling the part designer to reduce weight, material and costs, such as replacing spot welds with overlap joints that are not only stronger, but also invisible from the other side. Despite all the benefi ts of laser welding, including cost


reduction in the long term, manufacturers are often discour- aged by the initial investment costs. The LaserNetwork can drastically reduce this cost while increasing the laser source utilization by using a single laser for up to four machines. This lowers the entry barrier of implementing laser welding into production. Once the company has enough orders and high machine utilization, a second laser source can be retrofi tted.


Laser welding speeds are considerably higher than conventional processes, which often greatly reduces processing times. This leads to free capacity on the machine, allowing the manufacturer to serve more customers.


One of the keys to a successful implementation of laser welding is the part and fi xture design. The part design must minimize gaps and avoid bending tolerances while the fi xture has many requirements that can make its design very important. Not only must the fi xture close gaps with force, it will consistently and precisely position the parts, be fast to load and unload, and enable good accessibility, while also functioning as a heat sink for the welding process. As a partner, Trumpf helps customers navigate these issues using its experience in lasers, sheetmetal design and welding pro- cesses. Laser welding is the next logical step and Trumpf has the know-how to support the implementation of this technol- ogy in your production process.


TruLaser Sales Engineer Trumpf


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