The Laser Institute of America LasersToday.com Weekly Wrap-Up aggregates industry news, conference updates, and LIA happenings. Here is the latest:
Industry News
Valuable Resources in Laser Manufacturing
When discussing resources to increase your laser manufacturing knowledge, blogs may not be the first thing that comes to mind! There are plenty of credible, informative laser manufacturing blogs online. This week, on Lasers Today we highlighted some of our favorites, suitable for every level of laser professional. Check it out here.
With the new year quickly approaching, be sure to take a closer look at the new reporting guidelines from OSHA. The new guidelines require all incidents to be reported online, where they can be viewed by the public. The decision has divided affected industries, with some celebrating the increased transparency, and others citing privacy concerns and the potential for bad press as negatives for the decision. Find the details here.
In case you missed it last week, Lasers Today shared a guest post on The Magic of Nonlinear Laser Processing: Shaping Multi-Functional Lab-in-Fiber. Learn how the manipulation of femtosecond laser light inside transparent media can be used for dense memory storage, 3D circuits, and more. Find the in-depth look at the process here.
LIA Happenings
Are you a medical professional who works with or around lasers? Be sure to check out An Overview of Medical Laser Safety Courses to determine which medical laser safety course is right for your needs. A large portion of laser applications take place within the medical field, and the diverse course offerings reflect this, making it easy for you to stay on top of your laser safety education. Included in the blog post is a link to our free e-book Tackling Laser Safety in the Classroom. Find it all here.
Conference Updates
Industrial Lasers featured an ICALEO® wrap-up this week, giving an excellent first-hand experience from inside the conference. Check out the post from the Chief Editor of the publication here.
Don’t miss a single laser industry update! Sign up today to receive the latest in lasers delivered straight to your inbox. Be sure to follow LIA on Facebook and Twitter for even more laser news.
The Laser Institute of America (LIA) is the international society for laser applications and safety. Our mission is to foster lasers, laser applications, and laser safety worldwide. Find us at www.lia.org
Additive Manufacturing processes like selective laser melting (SLM) and powder metallurgy are on the rise – and they continue to disrupt traditional manufacturing as we know it.
While the public eye continues to focus almost solely on 3D printing, these other laser additive manufacturing methods are quite literally shaping our manufacturing future.
In the weeks that follow LIA’s 35th International Congress on Applications of Lasers and Electro-Optics (ICALEO®), Lasers Today shifts its focus to innovative and critical additive manufacturing processes in preparation for our Laser Additive Manufacturing Workshop (LAM®). Our next LAM, which takes place February 21-22, in Houston, Texas, will cover all facets of additive manufacturing, including 3D printing, selective laser melting (SLM), powder metallurgy, and more.
A recent Fortune article, which discusses the urgency of 3D metal printing and additive manufacturing processes and the challenges faced by the rise of these methods, echoes the importance of laser applications in these areas succinctly. While 3D printing is a big part of the present and future of additive manufacturing, it is equally important to acknowledge other applications that are disrupting the marketplace and defining its future.
SLM and Powder Metallurgy Are Making Waves in the Industry
In its September issue, EuroPhotonicspublished an article discussing the changing landscape of Laser Materials Processing. Illustrating a shift from a handful of manufacturing operations to the rapid increase of additive methods, the change is happening worldwide. The piece discusses several additive processes outside of 3D printing. The use of selective laser melting (SLM) in rapid prototyping, for example, allows early versions or low volume creations to be created without the use of complicated, often time-consuming tooling.
This feature is just one of the many additive manufacturing processes described. Find the full article here.
The use of powder metallurgy to create high-quality parts only continues to rise. LPW Technology shared a blog post discussing the quality control process of determining if unexpected results are the doing of a machine, or the powders themselves. As manufacturing experts know, a machine’s output can be disrupted by even the slightest error or change. This power metallurgy article provides a unique, first-hand perspective on some of the challenges, and the subsequent solutions associated with additive manufacturing practices.
Interested in learning about these laser applications and more at LAM in February? Review the Lasers Today LAM 2016recap and visit www.lia.org/conferences/lamto register today.
Whether you are an expert in the field of laser manufacturing, an ambitious student, or are just beginning your career, discovering new information about laser manufacturing applications is always a valuable endeavor.
3D Laser Cutting – Trumpf Inc.
With that in mind, the LIA team compiled a list of the top laser welding and manufacturing-related online publications for you to explore. These resources are packed full of information, tips, stories, and real-life applications for all laser manufacturing levels.
Tulsa Welding School has served as a training school for welders for over 60 years. With three locations nationwide, Tulsa Welding School is focused on the education and careers of its students. Beyond classroom and hands-on instruction, the institution regularly updates The Welding School Blog and covers the most breaking information in laser welding, like this article on how new technology, including lasers, is revolutionizing the welding industry.
Other posts focus on potential students and individuals interested in the field, or aim content toward current professionals, discussing competitions, career advice, and networking opportunities for welders. In all, the Welding School Blog manages to share intriguing stories, history, and background on the history and impact of welding applications.
Read more from The Welding School Blog on laser technologies in welding here.
Industrial Laser Solutions for Manufacturing is an online magazine packed full of relevant content for laser manufacturing professionals. Although the magazine itself is released every other month, the Industrial Laser Solutions for Manufacturing web page is frequently updated with the latest news, developments, and information— including laser engraving and welding.
Featuring industry news, relevant videos, popular products, financial reports, and links to other online resources, this publication is bookmark-worthy for anyone professionally involved with laser manufacturing. Be sure to check out the Editor’s picks for exclusive pieces not found in the magazine.
Like the previous entry, Industrial Photonics Magazine is also an online industry magazine. This magazine does an excellent job of aggregating the best news, features, webcasts, videos, and more in relation to laser applications. While you will find a whole lot more than pieces on laser manufacturing, Industrial Photonics Magazine stays on top of the latest industrial headlines, making it a valuable resource for those looking to expand their laser knowledge even outside of their own profession. Read on and subscribe by clicking here.
Laser Institute of America is committed to providing the latest and most valuable laser manufacturing information to our members and the laser manufacturing community at large. For breaking industry news and updates in one convenient location, visit our website LasersToday.com here. You can even sign up to receive updates directly to your inbox, so you never miss articles on Laser Weld Process Monitoring and Laser Welding Publications, for example.
LIA Today is a full-color newsletter that is published six times per year. It includes articles on the latest industry news to keep members and other laser professionals current on important issues that impact the laser community. To read the September/October issue of LIA today, Science and Research, and to subscribe, click here.
Be sure to support the blogs listed above by clicking through the links – and feel free to comment below and let us know what your favorite laser manufacturing publications and resources are, too.
Become part of the LIA experience and stay on top of your laser manufacturing career. Explore how to become an LIA member today by clicking here.
The Laser Institute of America Weekly Lasers Wrap-Up is an aggregation of all that you may have missed this week in the world of lasers. From Industry news to Conference updates and LIA happenings, here’s what happened during ICALEO Week 2016:
ICALEO 2016 wrapped up yesterday – explore photos on our Twitter profile @LaserInstitute and on LasersToday.com.
LIA Happenings & Updates
This week brought us the 35th ICALEO® in San Diego, California. The LIA Twitter page is filled with updates, photos, and featured tweets from the event. Follow @laserinstitute on Twitter to see what you may have missed at this year’s event.
Be sure to download our latest trend report The Future of Laser Technology Manufacturing. As an increasing number of industries harness laser technology as part of their protocol, what impact could this have on the future of laser applications? Learn about alternatives to traditional manufacturing applications, as well as emerging developments in laser technology, in new industries here.
Are your laser safety precautions up to date? The Laser Accident Series reveals what may happen if proper procedures are not met in the workplace. Featuring real-life OSHA accident reports, the Laser Accident Series paints an unsettling picture of the potential of accident or injury, when working with lasers. Read the LIA Blog post here.
Laser Industry News
Lasers Today featured two guest posts of interest to laser enthusiasts this week. The first, The Magic of Non-Linear Laser Processing: Shaping Multi-functional Lab-in-Fiber, discusses “the manipulation of femtosecond laser light inside transparent media” and how it can be directed to “open new directions in creating dense memory space, 3D optical circuits, 3D microfluidic networks, and high speed scribing tracks.” Take an in-depth look at the potential capabilities of this exciting form of laser processing here.
Figure 2. (a) Schematic of a temperature-compensated 3D fiber shape sensor, coupled to single-mode fiber (SMF), and laser-written in coreless fused silica fiber
Also featured was Laser Weld Process Monitoring: Seeing the Unseeable. This guest post gives an interesting perspective on the current state of laser weld processes. Discussing the before, during, and after processes of laser welding checks as well as top measuring methods, the importance of record keeping, and more. Find it here.
ICI can be used to monitor multiple aspects of the laser weld process at the same time
A scientist at University of Central Florida has created the “most efficient” quantum cascade laser ever. According to Space Coast Daily, Professor Arkadiy Lyakh and team have simplified the traditional process in developing quantum cascade lasers, with the intention of seeing them used in a greater number of processes. Read the original article here.
Lasers may soon be responsible for a more accurate atomic clock. Science Daily reports that a group of physicists have designed a laser that is “based on synchronized emissions of light, from the same atoms used in advanced atomic clocks.” Find the official news release here.
Want the latest information on laser industry conferences, like ICALEO®? Interested in the latest in laser news? Sign up to receive Lasers Today updates, straight to your inbox, here. The Laser Institute of America (LIA) is the international society for laser applications and safety. Our mission is to foster lasers, laser applications, and laser safety worldwide. Visit us at www.lia.org.
The economic case for using lasers in industrial welding applications is no longer in question. Industrial lasers provide massive leverage in the form of an unmatched combination of speed, precision, robustness and—increasingly—accessibility. In serial production they can provide time and cost savings, and enable more efficient product designs. The price per kilowatt of laser power has dropped steeply in recent years, and in combination with a growing market and increasing number of players supplying laser solutions, this has led to increasing commoditization of laser sources and systems. In the quest to gain an edge over the competition, many system integrators and manufacturers are shifting their focus to increasingly sophisticated sensing techniques in order to wring more performance and higher quality out of their laser processes.
Controls and checks are of course an integral part of any production chain. The cost of out-of-spec parts reaching the hands of end users can be incalculable, and may be more than monetary where safety-critical components are involved. Many excellent quality assurance measures applicable to laser welding have existed for decades. The gamut of checks that can be applied to ensure a weld result is good reaches upstream to production of the feedstock and downstream to a point where the weld may be part of a complex and expensive sub-assembly. What checks give the best return on investment for a manufacturer? This is a tough question to answer generally, but recent weld process monitoring advances have recently opened new opportunities for automated quality assurance and active control—improving laser weld quality and increasing certainty in the results.
Laser welding checks can be loosely sorted into three subsets: pre-process, in-process and post-process. For now, we’ll use ‘in-process’ checks to refer to any automated measures deployed during the welding process (while the laser is on) but not necessarily measuring the process itself (where the laser hits the metal).
Pre-process checks include steps taken at any stage prior to welding to ensure welds turn out in-spec. Tight control of feedstock and supplier processes are employed to enforce adherence to material standards, but such approaches classically have rapidly diminishing returns on investment and may be outside of a given organization’s power to control. The output of the laser system itself may be monitored with power meters and beam profilers to ensure correct delivery of power to the workpiece. Some sophisticated laser systems tightly integrate laser power delivery with robot motion to further reduce potential process errors.
It’s a generally sound philosophy to try to predict and design out problems rather than react to them, but pre-process checks can’t stand alone. No pre-process measurement can capture all the variables that may influence results, so verification of the results of the process is essential.
Tried-and-true post-process inspection methods such as manual visual surface inspection and destructive testing are still favorites of many laser users who favor their intuitiveness and robustness. Challenges arise due to time, cost and expense, however. Visual inspection provides limited information, and the best measurements from destructive testing can only be practically obtained from a small fraction of finished welds; sometimes at an enormous cost in labor, scrap and lost production.
Automated post-process non-destructive testing exists in the form of x-ray CT, ultrasound and magnetic flux leakage. X-ray builds up highly detailed three-dimensional images of finished welds, including subsurface features, but is too expensive and time-consuming for all but the most specialized applications. EMAT ultrasound uses electromagnetic coupling to both produce and detect an ultrasound source inside ferrous materials. Magnetic flux leakage detects subsurface defects by measuring regions in which magnetic field lines “leak” out of the part as they skirt around voids in the material.
With downstream post-process checks, the most complete information (from sectioning and CT) is also the most difficult to obtain. Destructive testing can only be used on a small fraction of parts, none of which are serviceable after the fact. As an added complication, the further downstream the check is performed, the higher the value of the scrapped parts when defects are found.
A good balance of time and cost savings is found by concentrating checks in-process, using automated sensing equipment. In-process checks can also be sorted into pre- in- and post-weld groupings. In this case the leading (pre) and trailing (post) measurements happen close to the welding process, typically while the welding beam is on. Some in-weld measurements look directly at the point of contact between the welding beam and the material in order to directly sense process dynamics as they unfold.
Sensors that lead the process during welding carry an advantage over earlier pre-process checks in that they are placed at a confluence of weld quality pre-determinants. These sensors can catch errors caused by stock tolerances and fit-up, fixturing and motion control, often with the same measurement. Examples of this kind of sensor include laser triangulation and camera-based systems for seam following. The position of the seam is used in a feedback loop to correct the weld path on the fly.
Trailing sensors allow the finished weld to be assessed before any further value is added to the part, avoiding expensive scrap further downstream. Both ultrasound and magnetic flux leakage are good candidates for immediate, on-line inspection. Laser triangulation is also a popular choice to measure surface topography of the finished weld bead.
For measurement of the process itself, relatively few sensing options exist. The weld process produces intense light across a wide region of the spectrum, blinding traditional cameras without specialized filters. Photodiode sensors make use of these emissions by measuring different bands of optical radiation from the process zone; backscattered light from the welding laser, radiation from the weld plume, or blackbody emissions from the melt region can all be used to assess the weld process. The challenge when implementing these indirect measurements lies in determining which signals correspond to an in-spec weld. The teach-in process for such sensors typically involves lengthy comparisons with destructive testing, and once this stage is complete, the process conditions must remain stable for the sensor to function properly. The relationship between the light coming from process and the shape of the finished weld is complicated.
Thermography is another in-process sensing method that maps the distribution of heat on the surface of the melt pool and weld seam, in order to draw conclusions about subsurface features (e.g., fusion in a lap joint).
Indirect measurements are a useful litmus test for determining whether a process is behaving consistently, but they have their limits. The data often doesn’t provide enough to detail to point to a specific failure mode, or to control process parameters in response to measurements.
Inline coherent imaging (ICI), an emerging in-process measurement technology patented by Laser Depth Dynamics, measures weld penetration directly at the point where the process laser interacts with the workpiece. This technology is natively compatible with select modern welding heads (e.g., Laser Mechanisms FiberWELD), and retrofits are possible with most common fixed-optic and some scanning-optic heads. ICI makes a time-of-flight measurement with a secondary low-power laser beam, which is immune to blinding by the intense light radiating from the process. This beam is delivered through the same optics as the welding laser, allowing ICI to make direct measurements of the bottom surface of the vapor channel opened by the process laser. This translates into a direct weld penetration measurement. The information produced is similar to the outputs from destructive analysis. Since the measurement occurs during the weld, ICI can be used for automated pass/fail, or even to control the laser power in real time to reach a target depth.
A sectional weld micrograph with ICI penetration depth measurements
ICI also functions as a leading and trailing in-process measurement. Using a small pair of scanners on the head, the ICI beam can be moved to other regions of the workpiece. This allows collection of seam position and workpiece height data ahead of the welding beam, and imaging of the finished seam surface immediately behind the melt pool. All of these measurements are taken through the head optics, within a few millimeters of the process beam. This suite of quality checks can be performed by a single instrument, by rapidly switching between measurement positions during the weld. The end result is automated pass/fail on any combination of seam position, material height, keyhole depth and finished weld surface, as well as the option to run closed-loop control of laser power and robot motion using the former three measurements. ICI technology provides the most complete automated laser weld monitoring solution to date.
Significant time and cost savings can be realized with advanced in-process sensing. The latest generation of monitoring technology eliminates the need for some downstream tests. The quality assurance for a given weld can often be worked into the existing cycle time. Scrap rates can be cut down through dramatic reduction of destructive tests. Inspection of 100 percent of production welds means entire batches don’t have to fail when defects are discovered, and the direct nature of latest-generation process measurements lowers the theoretical likelihood of false positives when compared with indirect approaches.
ICI can be used to monitor multiple aspects of the laser weld process at the same time
The ability to keep a complete, accurate record of production parts is allowing manufacturers to change how they approach quality assurance. It’s now possible to think weld-by-weld instead of batch-by-batch, with unprecedented confidence in the quality of the finished product.
Chris Galbraith is the Applications Specialist and Paul Webster is CTO at Laser Depth Dynamics Inc.20
![Figure 2. (a) Schematic of a temperature-compensated 3D fiber shape sensor, coupled to single-mode fiber (SMF), and laser-written in coreless fused silica fiber[8]. The λ1 to λ9 wavelengths represent nine different Bragg resonances for waveguide gratings distributed along three laser-written and parallel waveguide tracks. Micrographs of the fiber cross section (125 μm diameter) at the (b) coupling and (c) sensor regions show the arrangement of the internal laser-written waveguides. The figure is reproduced, with permission, from Fig. 1 of Lee et al.[8] © 2013 OSA [http://dx.doi.org/10.1364/OE.21.024076].](https://www.laserstoday.com/wp-content/uploads/2016/10/Fig_2_Lee-300x246.png)
