Materials Processing - Diode lasers test their mettle in surface treatment

Most everyone has heard the old adage, “If it ain’t broke, don’t fix it.” But history has repeatedly demonstrated that technology advances can often improve a process or outcome we didn’t even realize needed fixing. (Then it’s just a matter of waiting until it becomes affordable.)

Advances in high-power diode lasers are a case in point, especially when it comes to materials processing. During the past 20 years, multimode diode-laser bars and individual single-emitter diode devices have achieved increasingly higher output powers and better power-conversion efficiencies, allowing semiconductor lasers to evolve from the scientific arena into true industrial tools. In fact, interest in direct-diode materials processing has been a key factor in the development of high-power diode lasers. While diode lasers are still a few years away from being practical ablation or cutting tools for heavy metals, they are gaining traction in materials-processing applications in which beam quality and brightness are not critical to the outcome, such as surface treatment.

Surface treatment is one of the most efficient uses of laser energy and one of the most controllable heating processes when working with metal components. Laser-based techniques such as heat treating, cladding, alloying, and welding have become well-established in the automotive, aerospace, energy, defense, and machine-tool industries for applications ranging from increasing wear resistance of turbine blades to improving corrosion resistance and performance in car engines. Historically, these applications have been served by Nd:YAG and CO₂ lasers, both of which are well-accepted materials-processing tools. Displacing these lasers would require a solution that brings not only operational but financial advantages.

This is where high-power diode lasers come in. While engineers continue to work out a few remaining kinks-such as how to offset the thermal issues that arise in a compact package as it churns out 3 to 4 kW of power in a single shot-the diode laser offers a number of advantages for industrial surface-treatment applications as compared to the Nd:YAG or CO₂ laser. In particular, the shorter wavelength of the diode laser enables much better absorption of the laser energy, leading to an overall lower power requirement for surface treatment applications. A diode-laser cladding system can typically perform cladding with half as much laser power as a CO₂ laser (see table). The diode laser typically has 25% to 30% wall-plug efficiency, compared to about 10% for the CO₂ and the Nd:YAG laser. In addition, the diode laser can be fiber-delivered, which makes it more attractive for automated applications. Also, there is no need to precoat the metal to increase absorption-a necessity with the CO₂.

Electrical energy costs
	CO2	Nd:YAG (diode pumped)	Diode
Required laser power	5 kW	3 kW	3 kW
Average wall-plug efficiency	10%	10%	30%
Approximate electrical power consumption of the lasers	50 kW	30 kW	10 kW
Electrical power cost per hour @0.09$/kWh	4.50 $/h	2.70 $/h	0.90 $/h
Source: Fraunhofer

“Most laser-cladding operations use the CO₂ laser, but there are inherent disadvantages compared to the diode laser or other lasers with the same wavelength as the diode,” said Eric Stiles, laser-division manager at the Fraunhofer Center for Coatings and Laser Applications (Plymouth, MI). “But the diode laser is interesting for applications like cladding because of the low cost for kilowatt power. A 3 to 4 kW diode-laser system can do the same work as a 6 to 8 kW CO₂-laser system because a lot of the energy of the CO₂ is lost. With the diode you get much better absorption with a lot of materials, especially at lower power intensities where CO₂ absorption is poor.”

Pros and cons

Despite these advantages, however, diode lasers still need further refinement in terms of being reliable enough for intensive industrial applications like laser cladding, a process in which laser energy is used to melt or weld a metallic or ceramic powder onto a substrate to create a wear- or corrosion-resistant layer on a metal component (see Fig. 1). While the current generation of high-power diode lasers has resolved many of the reliability issues that plagued earlier generations, random failures remain a problem when a diode-laser system is used in high-volume production applications, particularly when pulsing is required. Thus, while the overall cost of an industrial diode-laser system should be lower, the need to replace the diodes more frequently disrupts production cycles and increases overall cost of ownership.

“The main specificity of this market [materials processing] is the operating regime,” Franck Leibreich, director of marketing at Newport’s Spectra-Physics Lasers Division (Mountain View, CA). “Long micropulses-one second on, one second off-is the most difficult operating regime for the diode because it stresses the diode very much, which leads to random failures. So we and others are working to make the lasers more robust by focusing on the interaction between the soldering material and the heat sink in order to compensate for the coefficient of expansions. The goal is to optimize the thermal exchange between the materials.”

Brightness is another factor. According to Leibreich, the need to transform inherently low-brightness, highly asymmetric diode lasers have led to the development of several important beam-shaping and beam-combining technologies (see www.laserfocusworld.com/articles/250394). As a result, diode-laser devices that produce 4 kW from a 600-µm-diameter-core fiber are now being used in applications such as cladding and annealing.

“As diode lasers continue to evolve, we can predict that there are two areas where this technology will grow in attraction for industrial applications,” said Phillip Anthony, manager, macro business unit at Rofin-Sinar (Plymouth, MI). “The life of the diodes and diode bars will get longer, and as this happens the long-term cost of ownership becomes less of an issue. Second, a lot of time and energy is being spent on improving the beam quality, which should lead to becoming more realistic for fiber delivery. In the end this will be driven by the cost of ownership and the predictable life of the diode that can be measured in tens of thousands of hours.”

The real world

While efforts are under way to improve the reliability and lifetimes of diode lasers, some companies and organizations are already demonstrating the efficacy of this technology for surface treatment. At Fraunhofer, for example, Stiles and his colleagues have developed a new cladding process that utilizes a 3 kW Rofin-Sinar direct diode laser and a coaxial powder-feeding nozzle. It was initially tested in the oil industry, in which new wear-protective hard coatings were developed, tested, and applied to a number of down-hole drilling tools.

On the commercial front, Nuvonyx (Bridgeton, MO) and Laserline (Mülheim-Kärlich, Germany) have both had some success with their diode-laser cladding systems (see Fig. 2). Nuvonyx, founded in 1998 by former employees from the McDonnell/Douglas Laser Systems Division, has been a pioneer in the commercial introduction of high-power direct-diode and fiber-coupled laser systems for industrial applications in aerospace and defense. In 2005 Nuvonyx was acquired by ICx Technologies, which then acquired Thales Laser Diode (Orsay, France), which has since become Nuvonyx Europe. The company’s newest product, introduced in June 2006, is a fiber-coupled diode-laser system with an optical power density of more than 1 MW/cm², which the company says is an order of magnitude higher than any other commercially available system operating at a single wavelength.

Laserline’s expertise is also in fiber-delivered high-power diode lasers up to 6 kW. According to Klaus Kleine, vice president of U.S. operations, Laserline is beginning to see diode-laser cladding systems replacing CO₂ and Nd:YAG lasers in industrial applications, particularly in the United States. While the aerospace and power-plant industries continue to account for the bulk of laser-cladding applications, Kleine says there is a big push under way in other industries and that the compactness, efficiency, and affordability of the diode-laser systems should begin to attract more customers.

“The automotive applications are much more prevalent in Europe, which is also at the forefront of installed diode-laser systems for surface treatment,” he said. “A lot of these advances are being pushed by diesel-engine technology; the goal (in Europe) is to make diesel engines cleaner and much more fuel efficient via surface treatment.”

Slow Industrial Acceptance of Laser Cladding

Laser cladding appears to require a dedication to the specialty to make it successful

Laser cladding is one of several ways in which a wear- or corrosion-resistant surface layer can be applied to repair or extend the life of components. Because industrial lasers are a controllable heat source, the laser cladding process is characterized by good control of the heat input to the workpiece. This results in lesser dilution of the coating layer (mixing of the coating with the substrate) and lesser distortion of the workpiece. Other methods, such as submerged arc welding or shielded gas metal arc welding, require significantly higher heat input to the part, greater dilution, the potential of greater distortion of the part, and a rougher surface that requires grinding if a smooth surface is required. Non-welding methods, flame spraying and plasma spraying, produce coatings that are mechanically rather than metallurgically bonded to the surface. Generally speaking, coatings produced by these methods are thinner than coatings produced by laser or arc welding processes.

By the early 1980s, laser cladding was identified as a process with a significant edge over the various competing processes for depositing wear- and corrosion-resistant coatings. The three main suppliers of high-power industrial lasers (Spectra Physics Industrial Lasers, Avco Everett Metalworking Lasers and the United Technologies Research Center, later United Technologies Industrial Lasers), none of whom currently exist, had developed an in-house expertise at laser cladding and were willing to address the needs of customers. A patent, #3,952,180 issued to Avco, said to be the dominant patent in this technology, was made available to all, on a non-royalty basis, to advance the technology. Still, the applications by-and-large did not become popular. Lists of locations where laser cladding was being used in the mid-1980s are not very different from current lists prepared today. Of the more than 150,000 industrial laser systems sold since lasers were invented, less than 100 are performing laser cladding operations.

Why has laser cladding seen so little market penetration? Here we consider only laser cladding for surface modification and not the extension of this process (called direct metal deposition or laser engineered net shaping (LENS) by different manufacturers) to building up solid objects by laser powder consolidation. This article is also limited to the installed base of lasers in North America, which are most familiar to the author; however, it is believed that laser surface modification practices in general have seen much wider applications on other continents.

Laser cladding is a production application in cladding of steam turbine blades, for manufacture of gas turbine blades on both sides of the Atlantic, for repair of gas turbine blades, for hard facing of oil field valves, hard-banding of drill rods, and surfacing of automotive and diesel valves. Water walls for power plants, paper mill components, and components of earth-moving equipment are being laser clad. Military components currently being laser clad include catapult launchers and drive shafts.

In the automotive industry, the valves of a non-commercial vehicle will be subject to 300 to 500 million thermal and mechanical cycles in an automobile's lifetime, and an exhaust valve in particular is subject to a stream of hot gas that may contain soot particles and corrosive constituents. In the early days of laser technology, numerous research facilities showed pictures of laser-clad valves in their publications and literature. How many of these laser systems for cladding automotive valves were put into production? To the best of this author's knowledge, only two, and these are not in North America. The chief reason for this lack of market penetration is the availability of somewhat less expensive equipment for coating valves using plasma transferred arc (PTA) welding, which produces deposits with the low levels of dilution. Deposits produced by laser welding do not have a demonstrated advantage over those produced by PTA, so it is difficult for manufacturers to justify the extra expense.

This is an example in which high technology has been applied to a process typically considered low technology. Because lasers are relatively expensive, it is easy to justify using robotic control and computer-controlled manipulators to make the best use of the controllable heat source. Manufacturers are reluctant to apply the same degree of controlled manipulation to inexpensive heat sources. But a highly controlled motion system applied to the plasma arc welding process has allowed repeated, high-quality deposits to be put onto valves, so little advantage is seen to using the laser process.

Numerous suppliers and repair shops in the airborne gas turbine industry around the world use lasers for reinforcement of the shroud interlocks and repair of blade tips. Competing processes for these applications include gas tungsten arc welding (GTAW) for the shroud interlocks and both GTAW and plasma arc welding for the blade tips. Many manufacturers and blade repair installations have laser equipment installed. Reasons why the laser process is finding increasing success in these applications include the fine control of the heat input in the laser process, which leads to accurate powder deposition at locations where it is needed.

In this successful application there is still considerable room for market growth, even though it is perceived as one of the more sophisticated of the industrial laser applications, requiring special skills. There are a limited number of people in North America who have developed these skills, and a limited number of equipment suppliers. One vendor of laser cladding equipment has sold a system into a shop where it was the first piece of equipment with computer-controlled (CNC) manipulators.

The laser cladding process equipment is usually applied to high-value products, consequently potential users require samples to be produced before they will commit a considerable amount of money to equipment purchase. But demand for the equipment is low, and equipment vendors cannot afford to have a laser cladding machine in their application laboratories or showrooms for occasional sales. The vendor must also have machine tool operators skilled in the laser cladding process as well as tooling to process a variety of part shapes in order to produce parts for potential customers. Some suppliers have provided one or two machines each, while only a few major vendors that specialize in this area have provided the largest amount of cladding equipment currently in use.

Successful laser cladding requires an accurate and controllable method of applying filler metal at the leading edge of the weld pool created by the laser beam. Use of an uncontrolled or poor method of adding filler metals results in poor utilization of the often expensive filler metal. This lack of control can be tolerated in high-heat-input arc welding processes or cladding with a multi-kilowatt laser because the filler metal inevitably gets absorbed into the larger weld pool. Laser cladding for repair of detail in components such as turbine blades requires more control in the powder deposition, which has lead to the development of highly controlled methods of adding the filler metal.

Sandia National Laboratories has developed a computer-controlled wire feeder that allows controlled deposition of wire into a weld pool; this design of wire feeder has been commercialized by Alabama Laser Systems (Munford, GA). Several suppliers of powders have developed powder feeders with a higher degree of control than possible with powder feeders used for other applications.

Several different styles of nozzles have been developed for applying the beam and the powder together at the workpiece. Accurate deposition of the powder inevitably means the powder nozzles must be close to the weld pool and, hence, must be water cooled. Nozzles have been developed at Imperial College in the United Kingdom, Sulzer Innotec in Switzerland, Fiat Automotive in Turin, IREPA laser in France, the Laser Institute in Canada, Battelle Columbus Laboratories, Huffman Corporation, and General Electric Aircraft Engines in the US. The proprietary nature of these designs and lack of information available to small users has been another factor in slowing the acceptance of the laser cladding process. Many users of the laser cladding process have developed their own nozzle design, but there is little technical information available to assist in this process.

Not all powders of nominally identical composition are suitable for the laser cladding process. Some powders prepared by gas atomization contain a fine porosity. Because the laser process is a low-heat-input, high-cooling-rate welding process, there is insufficient time available for the porosity to escape from the weld pool. A ground surface prepared with such a powder is found to contain fine porosity, which may frustrate attempts to introduce the laser cladding process. This is avoided by careful evaluation of powder suppliers.

A final reason for the slow acceptance of the laser cladding process is the perception that laser cladding is a process requiring more sophistication than other laser applications. Laser cladding has been economically profitable for companies in which there has been a champion who will sponsor the adoption of the technologies. Other more established processes such as laser cutting don't need a champion because the economics of these technologies will speak for themselves, and companies generally have the necessary expertise in-house to adopt the new process. Laser cladding requires the company to have three sets of skills, the CNC skills, the welding skills and the laser skills. The laser skills can be provided by the equipment vendor in a short course, as in the case of cladding, but the other skills must be provided in-house or by hiring outside technical people.

Laser cladding knowledge has been developed by a relatively scarce supply of "champions." For example, personnel from Westinghouse R&D assisted in the founding of a job shop, which is now a successful Praxair operation. A graduate from Imperial College established the laser cladding technology at Quantum Laser Systems, which is now a part of the Honeywell-Allied Signal organization. Personnel from IREPA laser in France established the Gremada Industries laser operation. By contrast, a number of smaller shops have attempted to add laser cladding to their operations. But unless they have a full-time champion to provide the expertise and bring in a lot of business, the attempts to provide all services for all customers appear to be less successful than that seen in the shops such as Gremada and Praxair that specialize in the laser cladding operation. In general, laser cladding appears to require a dedication to the specialty to make it successful, and companies, either processing shops or equipment vendors that attempt to add laser cladding to their diverse capabilities do it much less successfully than companies that specialize in it.