Lasers Lasercoil has seen fiber lasers improve so much in the past five years they are now offering laser blanking systems producing volumes of 50,000–70,000 parts per year economically. Laser Manufacturing Expands Its Reach Long known for versatility in material processing, lasers are moving out of prototype and specialty applications into mainstream production, including both older CO2 and newer solid-state lasers T here are at least two factors that are making lasers more attractive than ever for cutting, welding, and other material processing tasks. One is increasing power and the other is their improved ruggedness, according to Jim Rogowski, director of machine & power tool sales for Trumpf (Farmington, CT). Bruce Morey Contributing Editor More power means more productivity, cutting thicker materials or cutting the same materials faster. “Power will always continue to grow, especially in cutting applications,” he said. Just a couple of years ago customers were primarily cutting up to 1" (25.4-mm) thicknesses, but now he is seeing applications cutting up to 2" (50-mm) thicknesses of materials like stainless steel. November 2014 | ManufacturingEngineeringMedia.com 91 Lasers More reliability means these once delicate systems can live only practical choice for heavy-duty laser processing applica- in work-a-day shops and challenging environments. “Lasers tions like cutting and welding, these newer solid-state lasers that process plate metal and sheetmetal could be sitting offer advantages in power, efficiency, and materials they next to doors that open to winter weather and run automati- can cut. “Like the old Nd:YAG solid-state lasers, their light cally,” explained Rogowski. “This is enabled by reliability is roughly 1 µm in wavelength,” he said, as compared to the enhancements that have improved in just the last two years.” 10.6-m wavelength light of CO2 lasers. One-micron beams can Enhanced automation features are growing as well. He listed be delivered via fiber-optic cables, a convenient way to move options from Trumpf that automatically center beams of CO2 and mount laser energy compared to the optics and mirrors lasers using sonic waves, nozzle changers that automatically required of the far infrared CO2. The 1-µm wavelength is also change nozzles, and single cutting heads for all sheet ranges absorbed better by more materials, especially nonferrous met- in different applications. als like copper and brass, expanding utility. While he believes CO2 lasers will remain in the market, “the big advancement in just the last few years is the introduction of solid-state lasers,” said Rogowski. Rise of Solid State Tom Kugler, fiber systems manager for Laser Mechanisms (Novi, MI) agrees about the importance of the rise of solidstate disk and fiber lasers. While CO2 lasers were once the Solid-state lasers delivered through optical fibers are cutting in 3D and in nonferrous metals. He also notes that these newer solid-state lasers boast efficiencies of 30% or more. While this helps with electricity costs, there are other practical advantages. “For lasers up to 500 watts, you can buy air-cooled lasers, which simplifies their use and lowers their cost. There are a lot of processes done in that 100–500-watt range,” he said. What applications could benefit the most from these newer solid-state lasers? He reports seeing more instances of lasers performing 3D cutting, equipped on multiaxis robots and CNCguided machine tools. “[Solid-state lasers] are also definitely making their mark in the flat sheetmetal market,” he added. “These used to be all mounted with CO2 lasers. In the last three–four years, solid-state 1-µm lasers are showing they are faster in thin metal, up to three times faster in 1–2-mm-thick metal sheets, especially in aluminum or polished stainless.” 92 ManufacturingEngineeringMedia.com | November 2014 Lasers Short-pulse lasers are ideal for precise, small holes such as those needed for today’s gasoline direct-injectors that measure a few hundred microns in width. An example is shown in magnification here. He also observes that CO2 lasers still dominate cutting thicker materials, about 3/8" thick or thicker (>9.5 mm). This is because of the complicated physics of how materials absorb different wavelengths, with better absorption from a 10.6-m beam at the low angle the laser strikes the cut front, according to Kugler. Automation Keeps Up with High Mix and Low Volume Jason Hillenbrand, product manager for Ama3054-4088-ME_1114-4.56x4.88-2C.eps 1 9/29/2014 7:14:14 AM da America (Schaumburg, IL) notes that lasers have another fundamental advantage to offer—versatility. “Lasers material processing is always adopted by addressing the most common problem in manufacturing—the high-mix/low-volume scenario,” he said. He sees the entire spectrum of manufacturing and fabrication adopting more laser material processing because of this. “Our customers need to address quick turnover in rush jobs, which is why C programmable laser equipment is so M important to them,” he said. “They cannot wait a week to get parts to potential cus- Y tomers, they will lose the business.” CM There is also the continuing push to MY reduce inventory and work-in-progress, CY just as important to large OEMs as to small job shops. “OEMs also assemble CMY parts into kits [for later assembly]. They K need to put together an entire assembly that contains mixed materials and thicknesses.” A single laser system programmed for all the parts of a kit, suitable for all of its materials, is ideal. That's because it requires no special tooling, just some new programming— as long as the material is suitable. 94 ManufacturingEngineeringMedia.com | November 2014 He also notes that as lasers are getting more rugged and process, that are typically produced in mechanical shearing,” cutting faster, the integrated, automatic systems they live in Finn said. This is especially important as the automotive indus- must improve as well. “It puts a major strain on automation try begins using more high-strength steels (HSS) and advanced because the new lasers, especially fiber lasers, are so much high-strength steels (AHSS) to reduce weight and improve fuel faster. As a result, the downstream process has really been challenged,” he said. “We have increased speeds and new features on our material handling automation to address the faster process time of lasers.” Laser Moves to Automotive Production High-speed laser blanking from LaserCoil (Toledo, OH) is a case in point where laser is encroaching into a field dominated by a traditional process, in this case die blanking. “Originally we were looking at using a 1–2-kW laser to cut sheets that were 0.5–2.5-mm thick,” explained Jay Finn, applications engineer for LaserCoil. “Cutting speeds then were 20–30 meters per minute.” This was suitable for a system that could perform limited special service or prototype work. However, their plans were overtaken by developments. Over the past five • Servo Cutoff Lathes • CNC Cutoff Lathes • Laser/Plasma Cutoff Lathes years, costs have gone down and cutting speeds have grown exponentially. They could purchase a 4-kW laser today for the price of a 2-kW fiber laser five years ago. Their vision to create a device for a coil-fed, laser-blanking system quickly changed. “We are looking at production today,” said Finn, “with a system producing significant volumes of 50,000–70,000 parts per year economically.” It is not just speed or cut quality where laser offers an advantage, though Since 1916 Modern Machine Tool has been a pioneer in the evolution of cutoff lathes. From the early days of manually operated lathes to the sophisticated CNC controlled lathes of today, Modern Machine Tool has a solution to fit your production needs. Call us with your special request and put our 100 years of engineering experience to work for you. both matter. “For the material that we cut, lasers certainly offer better quality ... Since you are not mechanically shearing the edge, there are none of the microfractures produced in the laser-cutting November 2014 | ManufacturingEngineeringMedia.com 95 Here’s a great idea for: High-speed reaming DIHART REAMAX TS Modular precision reaming system ® ® The idea: Incorporating micro-adjustable reaming heads and holders into a Plug’n Ream tool system. Why it’s great: •Expandableheadcompensates for wear. •Builtinrun-outadjustmentwith DAH Zero arbor. •Headcanbechangedwithin the machine in seconds. •Plug’nReamsystemwithDAH, ABS® or straight shank holders. Lasers economy. Laser die-blanking is solving the problem of micro-fractures often seen in these harder materials when cut with die-blanking presses. “These micro-fractures increase the likelihood of a split during the subsequent draw process and this potential for defect is simply not present with laser cutting,” he explained. Aluminum is another material automakers are looking at adopting that a 1-µm fiber laser can easily cut. The TruLaser 5030 fiber, a 2D laser cutting machine with a 5-kW solid-state laser, uses the new BrightLine fiber function to cut stainless steel up to 1” thick, along with other materials as shown in this test piece. While Finn is pleased with the current speed and capabilities, he sees future improvement. He anticipates the day when laser power will be even more economical. “Our laser gantry system is designed for the integration of a 10-kW laser. We are serious about someday building a laser-cutting system that will go faster than a mechanical press,” said Finn. Expanding Power, Precision, and Speed Learn more about this and other great ideas. Go to www.komet.com/greatideas or scan this QR code. Companies like Amada are still improving the 1-µm fiber laser. Its ENSIS fiber technology, for example, not only processes thin materials very fast—which has been the strength of fiber lasers—but it also processes thick plate with the same speed and quality that higher wattage CO2 machines can do. Hillenbrand from Amada believes this is revolutionary. “We are now cutting plates as thick as 1" mild steel with a 2-kW fiber laser with quality comparable to a 4-kW CO2 laser,” he said. The first installation in the ENSIS-3015AJ system adjusts the beam configuration automatically to cut different types and thicknesses. Trumpf is also improving the capabilities of its solid-state lasers. The company is now offering its TruLaser 5030 fiber with its new BrightLine fiber function that www.komet.com 800-656-6381 96 ManufacturingEngineeringMedia.com | November 2014 cuts stainless steel up to 1" thick. The BrightLine fiber also The other trend to watch is the short and extremely short- enables the laser to produce small holes and tight contours pulsed lasers. These are in contrast to continuous-wave lasers in thick sheet metal with better exceptional cut quality in that they concentrate high power in very short bursts of Grinder General M.E._Layout 1 10/1/14 11:57 PM Page and productivity in mild steel in the ½–1" (12.7–25.4 mm)Island Ad energy, which has many advantages. ME 1 thickness range, according to Trumpf. For the future, there are two developments in lasers that bear watching, according to Rogowski from Trumpf: direct-diodes and short-pulse lasers. “We use 0.96µm diode lasers to pump resonator material in our disk and fiber lasers, which produce beams more useful Feature Machines of the Month You Deserve a Clausing Heavy-duty Surface Grinder for cutting and other applications,” he explained. Skipping the resonator device and using the diode directly would be an even more efficient laser beam, greater than 50%, with an even smaller footprint. Currently, beam quality of direct diodes is 8–10 times worse than that from solid-state lasers, which limits their utility in cutting. But each year brings improvements and they have produced excellent quality and speed for applications in welding and cladding operations. Want More Information? Amada America Ph: 877-262-3287 Web site: www.amada.com LaserCoil Ph: 419-592-0050 Web site: www.lasercoil.com Laser Mechanisms Ph: 248-474-9480 Web site: www.lasermech.com/ Raydiance Ph: 707-559-2100 Web site: www.raydiance.com Trumpf Ph: 860-255-6000 Web site: www.us.trumpf.com/ Model CSG3A818 shown with optional dresser and coolant/dust system Model CSG1640ASDlll shown with optional paper/coolant system A New Generation of Automatic Surface Grinders, The Precision ASDlll Series with the All New PLC Digital Control Panel Clausing Precision ASDlll Automatic Surface Grinders Feature... • Delta PLC Digital Control features a 7.2" color touch screen and is equipped with the exclusive EQUIPTOP picture mode working system, easy to learn and operate • On ASDlll models, you can set the vertical zero point, start point, finish grinding volume, target point and the grinding wheel vertical position point • Vertical positioning is displayed on the screen showing present spindle and setting the start point, rough grinding volume, finish grinding volume, downfeed volume for finish grinding, target point, vertical position point, intermittent spark-out • Cross transverse travel powered by brushless DC servo motor, allows step feed and continuous infeed grinding • The speed of wheel dressing can be adjusted on the control panel and much more Clausing Offers A Full Range of Precision, Low-cost, High Performance Surface Grinders... • Precision Manual Surface Grinders: 6" x 18" and 8" x 18" • Precision Hydraulic Surface Grinders: 6" x 18" thru 16" x 40" • Precision ASDlll Automatic Surface Grinders: 8" x 18" thru 20" x 40" • Large Capacity ASDlll Automatic Surface Grinders: 24" x 48" thru 32" x 120" Call 800-323-0972 or visit www.clausing-industrial.com Celebrating A Century in the Machine Tool Business November 2014 | ManufacturingEngineeringMedia.com 97
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