Category Archives: Laser Additive Manufacturing

Welcome back to the Industrial Laser Conference!

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ILC 2022

Welcome back to the Industrial Laser Conference!

Don’t miss out on early bird savings by registering before AUGUST 12!

The Industrial Laser Conference is a one-day conference taking place on Wednesday, September 14, 2022 as a part of IMTS in Chicago, IL.

Don’t be left behind! This conference will teach you how to incorporate lasers into your manufacturing processes to stay competitive in the current high-tech market. We will cover industrial applications of lasers, such as: Additive Manufacturing, Cutting, Welding, Marking and more. Most importantly, we will show you how to apply lasers to increase your profits and efficiency.

Early Bird Registration – $315 (until August 12, 2022)
Standard Registration – $395 (after August 12, 2022)

Register Today!

 

Your Registration includes:

  • Full access to the Industrial Laser Conference
  • Full access to the IMTS Exhibit Hall September 12-17.
  • Includes lunch and snacks on the event day.
  • Access to 2022 Conference Guide with presentation and speaker information.

 

View the 2022 ILC Agenda

 Sponsorships Available!

Email marketing@lia.org if you are interested in sponsoring!

 

 

 

 

 

 

 

 

 

Laser Additive Manufacturing’s Journey to Commercialization

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By Andrew Albritton

As seen in LIA TODAY

LASER ADDITIVE MANUFACTURING CHALLENGES

Laser Additive Manufacturing (LAM), as it pertains to powder based manufacturing, is a technique that utilizes the interaction of lasers and base materials to construct a product, rather than removing material from a pre-constructed block of material. LAM is quickly approaching the critical point of being more than a method to produce prototypes and small runs of one-off parts – it is poised to turn everything we know about mass production on its head. Professor Dr. Minlin Zhong, President-Elect of LIA and Director of the Laser Materials Processing Research Center at Tsinghua University, believes it surpasses all available alternative methods.  Prof. Dr. Zhong  says “LAM shows obvious advantages on freeform manufacturing, including free geometry, free structures, free strengthening mechanism, free microstructures, free performance and even free scale (from macro, to meso, to micro, to nano),”. Manufacturers who use LAM are able to reduce the waste of materials commonly associated with traditional subtractive manufacturing methods; decrease the weight of parts by cutting out filler materials; and have more control over material properties resulting in stronger, more complex, lighter, and more efficient parts. With such exceptional technology currently at our disposal, why hasn’t LAM been more widely adopted?

IT’S EXPENSIVE

One of the most commonly cited reasons is that the costs to produce parts through LAM are prohibitive. The key driver of these high costs is that the supply chain for metal powders is not yet optimized for LAM technology. Materials are expensive, custom made, or not readily available. The Metal Powder Industries Federation (MPIF) states in its 2017 PM Industry Roadmap that, “A better understanding of the precursor materials impact on the metal AM process is required. Traditionally, precursor materials have been existing thermal spray powders that have not been refined/tuned to the AM process limiting optimization.” LAM parts producers are often using metal powders that have not been designed for use in LAM processes, which frequently results in suboptimal products.

According to MPIF, as of 2017, there are approximately 12 suppliers of metals for Additive Manufacturing (AM) for the international market, most produce stainless steel, cobalt-chrome, and titanium, with a few supplying aluminum alloys, copper, super alloys, platinum, Inconel, tungsten, molybdenum, and tool steels. With so few suppliers and a sparse number of common material types, there is a bottleneck for providing quality affordable metal powders to the LAM industry. With companies expanding the selection of materials that can be laser processed, it is vital that the problem of material availability be resolved. For example, Nuburu has produced a “blue” laser which operates at the 450 nm wavelength, and is capable of processing gold, aluminum, brass, and copper.

SUPPLY AND DEMAND

What can be done to improve the supply chain and reduce the cost of LAM part production? The metal powder industry does not supply enough quality powder to support widespread adoption of LAM, while early adopters of LAM applications do not create enough demand to drive competition into the metal powder market to reduce prices. A first step to get these industries operating in unison will be the creation and mass adoption of standards, specifications, and best practices in regards to metal powders. By standardizing metal powder properties for best final product properties, metal powder suppliers would be able to build up an inventory without relying on custom special orders. Specifications on how surplus powder from a project can be reused could also help introduce addition cost savings to manufacturers.

STANDARDS FOR QUALITY CONTROL

Another hurdle for LAM is microstructural quality, uniformity, and repeatability. To become a replacement for more legacy manufacturing methods, LAM needs to produce parts consistently and continuously that are to specifications. With traditional subtractive manufacturing methods, there are several quality control points where product is inspected and defects are addressed prior to the next step, resulting in no wasted effort past the point of failure. With LAM, the part in question is created from the ground up; this determines the final product’s quality, microstructure, and mechanical properties simultaneously. The process is completed with either a perfect or defective final product. Paul Denney, Director of Advanced Process Development with IPG Photonics, states, “Unlike machining where you start with a “block” of material with known quality and properties, additive production of parts requires a combination of motion with the prediction of the microstructures, mechanical properties, and stresses. Because the properties are closely connected to how the material is deposited, this greatly complicates the development of processing procedures and parameters.”

What methods can be implemented into a given LAM process to help ensure quality of the final product? The first quality control concerns are addressed long before the process begins. Starting materials must be certified as appropriate for the application, the order of operations of the production device should be scrutinized to ensure that the final product will be to spec with minimal waste, and the machine itself must be operating at peak parameters. As the production of a LAM product can take an extended amount of time, any loss of power to the point of interaction can have detrimental effects to the end product and even the products in queue. Loss of power can be caused by an actual power failure, a dirty or damaged optic, or other origins. With the structural integrity of a LAM part resting critically on the success of every step of the process, it is imperative that the process is stringently optimized and the machine is operating at peak performance. Here is what Paul Denney has to say about the subject:

“Because of the additive manufacturing approach in bed based systems, even if defects can be detected and possibly ‘corrected’, any changes may not be possible. An example of this may be what is done if a ‘defect’ is flagged in a single part in a batch of parts being produced. One approach would be to stop the processing and ‘correct’ the defect. However, if this is done then the thermal history for all of the parts may be altered and all parts may now be out of the desired properties. Another approach would be to stop processing on the part with the defect, but this again would alter the heat load on the complete batch or the time between other parts being produced which may again alter the properties. So any monitoring system will need to detect changes prior to the formation of any defects while at the same time any corrections must be made within the acceptable parameter range.”

There is a thin line between success and failure: one small interruption can ruin an entire batch of product. What can be done to prevent this?

As Paul explained, this is not a single issue, LAM processes need both a method to detect defects and the ability to immediately respond to them. A starting point is to ensure that redundancies are incorporated into the build process so that if a common defect occurs at a certain stage, there are defined responses the system can take automatically to correct them. In the case of a laser lens issue, it may be beneficial to incorporate additional laser delivery systems to the process as a redundancy to pick up where a suboptimal device has failed in real time.

EVALUATING THE FINAL PRODUCT

In addition to inline defect detection, the industry as a whole will require a standardized best practice for evaluating finalized parts. For traditional manufacturing methods, a sample of the produced part pool is selected for evaluation via destructive and non-destructive tests to certify whether a set of parts are built to specifications. As many LAM-produced parts are complex and costly to produce, it seems wasteful to destroy a set of them to certify them. In the paper “Evaluation of 3d-Printed Parts by Means of High-Performance Computer Tomography” presented at ICALEO 2017, authors Lopez, Felgueiras, Grunert, Brückner, Riede, Seidel, Marquardt, Leyens, and Beyer reviewed the viability of X-ray Computer Tomography (CT) and 3d scanning as methods to detect inferior AM parts. The paper concludes that the CT method best fits the needs of the AM industry. According to Lopez et. al, “Computer tomography can quantify all complex structures in scope of the proposed demonstrator and delivered deviation values of the measured structure, providing a good base for comparison across demonstrators made by different methods, materials and dimensions. Porosity or defects down to 3 µm can be determined by the used CT system.” Currently, CT scanning a LAM part is a time consuming process, but with additional focus on improvement it could become an essential quality non-destructive control method for finalized parts to evaluate complex internal structures.

TOO MANY ALTERNATIVES

A third barrier to the spread of LAM is the multitude of alternative methods in the industry. As stated by Prof. Dr. Zhong, “Some conventional metal deposition technologies such as arc building-up welding, plasma building-up welding and electronic building-up welding can also fabricate metallic components in near shape. Their deposition rate and productivity may be high and the costs may be lower, but normally they are limited in fabricating complex geometry and accuracy.” Freeform manufacturing is where LAM excels, but despite its many advantages over alternative methods, it has an Achilles heel.

One advantage of alternative manufacturing methods is the speed at which a product can be produced. However, according to Paul Denney, this speed gap is closing faster every day.

“While higher laser powers allow for higher deposition rates but at the expense of lower resolution, some researchers are looking to maintain the resolution by combining multiple lasers into an additive deposition system. Research groups and equipment builders are investigating how best to handle multiple lasers in the same processing area. There are other areas that may be investigated including power distribution to improve the interaction between the power and laser beam to improve efficiency of the process and to minimize defects. This could improve the deposition rates while at the same time maintaining quality.”

Prof. Dr. Zhong hopes that soon LAM researchers will, “improve the materials diversity, increase the dimension (to square meters), increase the deposition rate and decrease costs. A hybrid approach to combine LAM with the conventional additive manufacturing methods may be a solution to achieve the above targets.” The concept of a hybrid production system that can combine multiple lasers with fast alternative methods where complexity is not a requirement could lend itself to faster build times.

THE LATE ADOPTERS

Earlier in the article, we touched on the final barrier to the wide spread success of LAM: industry standards. Current standard offerings from ASTM and ISO cover Design, Materials and Processes, Terminology, and Test Methods. Additionally, new processes are created frequently and new standards are being developed every year in an attempt to keep up. It is unclear how much of the industry has adopted these existing specifications. Until the entire market accepts a set of standards for all steps of the Additive Manufacturing process and supply chain, the evaluation of AM parts will remain a costly endeavor that will limit AM’s potential. MPIF expresses a bleak outlook on metal AM in its State of the PM Industry in North America – 2017 document: “Despite all the fanfare, true commercial long-run production still revolves around only three product classes: titanium medical implants, cobalt-chrome dental copings, and cobalt-chrome aircraft nozzles.” The truth of the matter remains that without a set of clearly defined standards, the LAM industry will continue to remain confined to early adopters like the Aerospace and Medical fields. With the benefits in intricacy and weight saving advantages LAM should have obvious opportunities in the automotive and electronics industries.

Markets are watching LAM for innovative uses before taking the plunge and embracing the technology. Currently, LAM may appear to have a bad Return on Investment (ROI) if producers only hope to replicate their existing products through LAM rather than innovating their parts to capitalize on its strengths. In the words of Paul Denney, “If AM is supposed to make big impact, companies are going to have to rethink their parts; determine how AM allows for changes in the design and possibly improve the performance. The benefits can come in many forms which could be a weight savings, a production savings, and/or a performance savings.” The industry needs to challenge its way of thinking about production to allow the benefits inherent to LAM to propel their production and parts to new levels of performance. Paul Denney provided the following illustration: “With the formation of properties ‘locally’ instead of in ‘bulk,’ it is possible to produce ‘gradient’ materials. The ‘gradient’ can come by changes to the properties of a given chemistry of material or by using materials with different chemistries. As an example: a bracket could be produced for a jet engine that has high temperature properties near the engine but as the bracket extends to an attachment point, the properties/chemistry can be altered to improve the fatigue properties.”

LAM has a bright future and many engineers and scientists are working to unlock its full potential. Once the barriers of the supply chain, dynamic quality control, speed of production, and process standardization have been resolved, it is highly likely the LAM will be a manufacturing method of choice.

 

ACKNOWLEDGEMENTS

Paul Denney, Director of Advanced Process Development with IPG Photonics and LIA’s Past President

Prof. Dr. Minlin Zhong, Director of Laser Materials Processing Research Center at Tsinghua University

and LIA’s President-Elect

 

References:

Lopez, E., Felgueiras, T., Grunert, C., Brückner, F., Riede, M., Seidel, A., Marquardt, A., Leyens, C., Beyer, E. (2018). Evaluation of 3D-printed parts by means of high-performance computer tomography. Journal of Laser Applications 30, 032307; https://doi.org/10.2351/1.5040644

Explore Laser Manufacturing Technology at the Lasers for Manufacturing Event

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ORLANDO, FL (March 19, 2018) – The Laser Institute of America is excited to announce that the 2018 Lasers for Manufacturing Event® (LME®) will be held at the Schaumburg Convention Center in Schaumburg, Illinois March 28-29. This year will be the first time the event will be co-located with the Laser Additive Manufacturing (LAM®) Conference, which takes place March 27-28.

LME offers an opportunity for anyone interested in using lasers in manufacturing to learn more about commercial applications and interact with companies that offer laser manufacturing solutions.

The event will feature about 60 exhibitors, including Amplitude, Ekspla, Light Conversion, Lumentum, SPI, Alabama Lasers, GF Machining Solutions, Hass Laser technologies, Lasea, Kentek, LPW Technology, and Powder Alloy Corporation.

LME is made possible by generous sponsors Han’s Laser, IPG Photonics, Laser Mechanisms and Trumpf. All four companies will have exhibit booths attendees can visit to learn more about the laser manufacturing solutions they provide.

On day one, keynote speaker Ron D. Schaeffer, a technical consultant for PhotoMachining, will give an overview on the industrial laser market, and host a tutorial on current trends in laser micromachining.

On the second day, Dr. Geoff Shannon from Amada Miyachi America will give his keynote address on lasers used for medical device manufacturing, and David Havrilla of Trumpf will present a tutorial on Laser Welding Techniques and Applications.

Throughout both days of the event, industry experts will host an ongoing series of laser introductory courses on the exhibit floor that will cover topics such as laser sources, beam delivery systems, laser safety, laser marking, laser cleaning, laser cutting, laser welding, laser cladding and optics.

An “Ask the Experts” booth will also be open both days on the exhibit floor. Organized by Directed Light Inc. President Neil Ball, this booth will have laser industry experts ready to help supply attendees with all the information they need to increase profits and efficiency and expand their businesses.

After gaining a world-class laser education from the exhibitors and experts, attendees can enjoy live laser demonstrations, tour the TRUMPF smart factory, and relax and mingle during the complimentary ice cream social and drink reception. All LME attendees will also be entered in a giveaway.

For more information, and to register for the event, visit www.laserevent.org.

 

About LIA

The Laser Institute of America (LIA) is the professional society for laser applications and safety serving the industrial, educational, medical, research and government communities throughout the world since 1968. www.lia.org, 13501 Ingenuity Drive, Suite 128, Orlando, FL 32826, +1.407.380.1553.

Design Guidelines For Laser Metal Deposition of Lightweight Structures

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Design Guidelines for Laser Metal Deposition of Lightweight Structures

By Ake Ewald and Josef Schlattmann

Introduction

Weight critical applications, like parts in the aerospace industry, are driven by lightweight design. Titanium alloys have great potential in lightweight design of structural parts due to their excellent specific mechanical properties. Today, structural parts are manufactured in conventional milling processes. Titanium parts are characterized by poor milling behaviour as well as high material waste rates up to 95 % [1]. The Laser Metal Deposition (LMD) is a layer-wise manufacturing process for the production of three-dimensional complex parts [2].

LMD builds parts based on a nozzle-fed powder, which is solidified by a laser. The process can be used for surface cladding, repair and build-up of parts. For an effective industrial application, it is necessary to identify all advantages and disadvantages. A lowering of the introduction barrier can be achieved by design guidelines helping the engineer early in the product development. With LMD like Selective Laser Melting (SLM), existing manufacturing guidelines cannot be simply adopted. Due to the complex process constraints, a design guideline for LMD has been established.

Complex parts often share simple geometries as a basis. These shapes were identified and used to evaluate the applicability and effectiveness of LMD. Following established lightweight design guidelines, the presented guideline focuses on fine structures. In addition to the manufacturability, the building accuracy and the surface roughness have been investigated, since both have a significant influence on the product quality and the necessity of post processing towards the final shape of a part.

Investigation of process constraints

The investigations are performed with a Trumpf TruDisk 6001 multi-mode continuous wave disk laser with a laser power of 6 kW at a wavelength of 1.03 µm. A three nozzle processing head is used with a rotational table feeder (Fig. 1). The used Ti-6Al-4V powder is spherical and sieved to a fraction less than 80 µm.

Figure 1 Robot cell (TruLaserRobot).

Three different building strategies have been identified in a preliminary design guideline by Möller et al., 2016 [3]. Figure 2 shows the different building strategies. In S1 an inclination is achieved by a stepwise offset (a) between the layers (α = β = 0°). S2 rotates the platform to reach the inclination. The structure is manufactured vertically without an offset between the layers. S3 rotates the machine head to the inclination angle of the structure. The structure can be manufactured without an offset. Besides the three single building strategies, combinations of these are possible, which are not considered at this point. The preliminary guideline published by Möller et al. (2016) showed a high potential in the degree of freedom of building strategy S2 and S3 [3]. For this reason, these strategies were further investigated.

Figure 2 S1: horizontal offset between layer, S2: rotation of platform, S3: rotation of machine head

The mentioned fine structures have been classified as thin walls, curved walls, congregating and aggregating structures. The width of the manufactured structures has been set to a single layer width. The length has been set to 50 mm.

Thin Walls

The build-up of inclined thin walls has been made to investigate

  • the connection towards the platform,
  • the influence of the gravitation,
  • the building accuracy and
  • the influence on the wall surface.

Both strategies produce a constant and comparable wall thickness under (see Fig.3). It varies due to the surface roughness of about 150 µm. The variation of the measured angle is less than 1°.

Figure 3 Measured wall thickness of the inclined walls manufactured with S2 and S3.

The surface quality of a part has an influence on the appearance, the buy to fly ratio in case of a post processing, and the fatigue strength. The mean values of the surface roughness remain constant with rising inclination angles. The surface roughness of S3 is about 15 µm higher than with S2.

 

Curved Walls

Curved walls can vary in radius and angle. Curved walls can be divided into curves with their rotational axis parallel, and perpendicular to the building direction (z-axis, Fig. 4). The vertical built up of the curved walls with different radii can be seen in fig. 5.

Figure 4 Sketch of curved elements perpendicular (a) to the building direction and (b) parallel to the building direction.

 

Figure 5 Set of manufactured parallel curved elements with radius of 0 mm (left) to 30 mm (right).

The radii of the built walls are 0.15 mm to 0.4 mm smaller than expected. An intended vertical edge (radius of 0 mm) produces an outer radius of 3.58 mm. Without post processing, edges should be designed to allow a radius up to the layer width. The radius independent deviation allows the manufacturing in reproducible tolerance fields.

Congregating and Dividing Structures

The separation in congregating and dividing structures is based on the necessity of different manufacturing strategies and constraints in LMD (Fig. 6).

Figure 6 Sketch of the three defined congregating and dividing structures with building direction in z: (a) Y-branch, (b) overhang and (c) reversed Y-branch.

The manufacturing of regular and reversed Y-branches was realised by using S3. To achieve good results, binding on alternating branch sides is recommended (Fig. 7).

 

Figure 7 Sketch of the Y-branch (above), manufactured Y-branches with the angles β1 = β2 = 30° and β1 = β2 = 45° (below).

 

 

Additionally, overhangs were built on the manufactured vertical wall (Fig. 8) to evaluate

  • the connection between a thin rough wall and a manufactured wall,
  • the building accuracy, and
  • the boundary constraints.

The measured angles of the overhangs have an angle deviation of less than 1° up to a manufacturing angle square to the gravity (Tab. 1). This is comparable to the inclined walls. Overhangs show that overhangs with the same or smaller width can be manufactured on thin walls.

Figure 8 Manufactured overhangs with inclination angles from 30° to 90°.

 

Table 1 Measured inclination angles of the manufactured overhangs. The guidelines derived from the experimental investigation have been collected in a design catalogue according to the VDI 2222 in extracts shown in the figure 9.

 

Figure 9 Detail from the established design catalogue

Conclusion and Outlook

LMD offers a high degree of freedom in the design of parts. Lightweight parts can benefit from this flexibility. An industrial application can be achieved by design guidelines helping engineers to take the advantages and disadvantages of the LMD process into account during the design process.

The experimental investigation points out that structures based on the basic shapes are producible with constant geometric and surface tolerances, which allows reliable final machining. This is the basis for a successful design process. The building strategy S2 and S3 can be applied. The comparable results of S2 and S3 allow to choose the better fitting strategy for a specific use case.

By focusing on lightweight application, the following aspects have been achieved:

  • Investigation and manufacturing of basic shapes
  • Determination of process constraints
  • Draft of a design guideline.

The developed design catalogue builds a first step towards a comprehensive design guideline for LMD.

 

M.Sc. Ake Ewald has been a research assistant in the workgroup System Technologies and Engineering Design Methodology at the Hamburg University of Technology since 2013. He works in the methodical product development where he researches the methodical design of hybrid manufactured structural parts using LMD.

Josef Schlattmann is Univ.-Professor at the Hamburg University of Technology. He leads the workgroup System Technologies and Engineering Design Methodology.

 

References

[1] Allen, J. (2006) An Investigation into the Comparative Costs of Additive Manufacture vs. Machine from Solid for Aero Engine Parts, Rolls-Royce PLC Derby, UK.

[2] Ravi, G.A., Hao, X.J., Wain, N., Wu, X., Attallah, M.M. (2013) Direct laser fabrication of three dimensional components using SC420 stainless steel, Materials & Design, Vol. 47, 731-736.

[3] Möller, M., Baramsky, N., Ewald, A., Emmelmann, C., Schlattmann, J., (2016) Evolutionary-based Design and Control of Geometry Aims for AMD-manufacturing of Ti-6Al-4V Parts, Laser Assisted Net Shape Engineering 9 International Conference on Photonic Technologies Proceedings of the LANE 2016, S. 733–742, DOI: 10.1016/j.phpro.2016.08.075.

LIA Invites You to The 2018 Laser Additive Manufacturing Conference

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By Ron D. Schaeffer, Ph.D.

 Laser Additive Manufacturing (LAM) is one of the most exciting potential growth areas for the laser industry. The market has been watched for a few years and every year there are gains in the revenue generated by this market segment, but so far the revenue curve has not started rising dramatically. This can be viewed as both good news and bad news. The “bad” news is that the market has not exploded…yet! According to Alan Nogee from Strategies Unlimited, the industry can be broken down as follows:

• Stereolithography – Reasonable growth but the industry depends on more non-laser solutions.

• Laser Sintering (DMLS/SLS) – This area is growing strongly. There are two main application areas – plastics and metals. Plastics suffer from the availability of a variety of materials and usually use CO2 and Diode lasers, usually with under 300W of output power.

• High Speed Sintering (HSS) – This is a newer technology and is used primarily for plastics. This technique is 10 – 100 times faster than SLS and can manufacture many tens of thousands of units per day. At the time of this writing, metals are not yet there, but time may change that. 

The good news is that the LAM market is set to really ramp up and could spike in the next couple of years. Therefore, it is a great time to investigate LAM (and thereby the LAM® Conference) to get in on the “ground floor” of the technology. While this conference has been around for 10 years, this year the venue has moved to Schaumburg, IL, for the first time and is co-located with the Lasers in Manufacturing Event® (LME®) with overlap on Wednesday, March 28th. The conference takes place at the Schaumburg Convention Center on March 27–28, 2018.

Why attend LAM?

•Interact with laser industry experts – the Program chairs in particular are a very recognizable and highly
respected group.

• Find out if Laser Additive Manufacturing can help with your manufacturing problems.

• Network not only with the exhibitors but other attendees as well.

• As part of the registration fee for LAM, entry to the LME show is also included! Take advantage of both events and all of the associated benefits.

• Find a job in the photonics industry – or find laser experts to bring onto your team if you are thinking about ramping up laser processing.

• Increase the bottom line by increasing profits! In a manufacturing world this is what it is all about.

 

Program/Agenda

The LAM chairs will return to build on its successful program from last year. Milan Brandt of RMIT University will continue as the General Chair, with John Hunter of LPW Technology, Inc. and Minlin Zhong of Tsinghua University serving as Conference Co-chairs.

 

Day One

A representative from America Makes will give the first keynote address of the conference, titled “Smart Collaboration: A Public-Private Approach to Advancing the Additive Manufacturing Industry.” America Makes strives in additive manufacturing (AM) and 3D printing (3DP) technology research, discovery, creation, and innovation to increase global manufacturing competitiveness.

Other presentations range in topics from laser cladding to laser welding. Prabu Balu of Coherent, Inc. will discuss recent advances in laser cladding. Balu is the senior application engineer at Coherent. His talk will provide a set of guidelines to successfully deposit highly reflective materials using powder-based laser cladding (LC), high deposition rate (up to 10 kg/hr) with minimal dilution (as low as 1%) using hot-wire based LC and thin coating thicknesses (varying from 25 µm to 500 µm) using ultra-high-speed LC process.

Paree Allu of Flow Science will give a presentation on “Computational Fluid Dynamics (CFD) Modelling for Additive Manufacturing and Laser Welding.” Allu is a computational fluid dynamics engineer at Flow Science. Allu will explain how CFD modelling can help with the widespread use of AM technologies by providing a framework to better understand AM processes from the particle and melt pool scales.

Day One will wrap up with presentations on Process Monitoring, featuring John Lehman from the National Institute of Standards and Technology (NIST) and his talk on Laser-based Manufacturing; Novel Developments in Process Monitoring at NIST. Lehman is the leader of the Sources and Detectors research group at NIST and a fellow of the Alexander von Humboldt Foundation of Germany. The research group provides laser power and energy meter calibrations to the U.S. and much of the world.

Day Two

Keynote speaker Ehsan Toyserkani from the University of Waterloo will kick off Day Two with an overview of Canada’s additive manufacturing initiatives. Toyserkani is the founder of and research director for the MSAM lab at the University of Waterloo, the university research chair for additive manufacturing, and a professor in the Department of Mechanical and Mechatronics Engineering. His presentation will cover the challenges and opportunities related to a research program on novel in- and off-line quality monitoring of selective laser melting along with assurance protocols.  

The following session will feature Warwick Downing of Rapid Advanced Manufacturing Limited and his thoughts on how to grow the metal additive manufacturing industry. Downing is the chief executive of Rapid Advanced Manufacturing. He established Rapid Advanced Manufacturing Ltd (RAM3D) in 2013 with a group of like-minded shareholders to grow the commercial opportunities created by the growth of the metal 3D printing sector.

In the final session of the conference, Mohsen Seifi from the American Society for Testing and Materials (ASTM) International will discuss the standardization of additive manufacturing. Seifi is the director of Global Additive Manufacturing programs at ASTM International. Previously, he was a doctoral researcher in the Department of Materials Science and Engineering at Case Western Reserve University.

 After the final session, there will be a reception on the show floor in conjunction with LME starting at 4 pm. Since LAM attendees are welcome to fully participate in LME, there are also many more talks, tutorials and classes available. Please see the information on LME for details. LIA will provide attendees with an enhanced experience by co-locating LAM and LME.

 

Sponsors

The premier LAM conference sponsor is Alabama Laser. Alabama Laser has been involved in laser materials processing for many years and is one of the pioneers of LAM in the U.S. Alabama Laser provides a range of advanced laser services, such as cladding, welding and heat treating, as well as process development, laser research, and custom laser systems. Working in conjunction with their affiliate company, Alabama Laser Technologies, they are also able to offer customers additional services such as laser cutting, punching, forming, welding, and precision machining services.

 The other generous sponsors of LAM are Trumpf, LPW and Laserline. Trumpf is a German manufacturing company with not only a large laser division, but an even larger traditional machine tool presence, and they are making a big push for LAM as part of their strategic future planning. LPW Technology Inc. is a metal powder manufacturer that aims to improve additive manufacturing. Its quality powders are compatible with all additive manufacturing systems. The company also offers a PowderLife lifecycle management program for quality assurance. Safe-handling, storage, measurement, and testing solutions are available to ensure proper powder usage. Laserline is a company delivering high power diode lasers. Laserline is a longtime LIA supporter and has been in the LAM industry for many years. Laserline offers industry-appropriate laser solutions for laser materials processing – from beam generation to the work piece. 

 In addition to their sponsorship, all of the above companies are also exhibitors and will have experts at both LAM and LME ready to answer any technical or budget-related questions that may arise. 

 Registration is now open! For more information and to register, visit www.lia.org/lam

Ron D. Schaeffer is a technical consultant to PhotoMachining.