13 minute read
QUALITY & INSPECTION
from AMT AUG/SEPT 2020
by AMTIL
Metrology is becoming a critical area of focus in additive manufacturing as it moves towards becoming a serious production technology. The nature of the process and the surface characteristics it produces create challenges for many metrology tools. By Eric Felkel of ZYGO Corporation.
Undoubtedly there are many benefits associated with the use of additive manufacturing (AM) as a production technology. Across industries, manufacturers exploit the fact that with AM they can not only build complex parts in one piece that were previously impossible, but they can also build stronger, lighter-weight parts, reduce material consumption, and benefit from assembly component consolidation across a range of applications. These advantages have been well documented over the last 10- 20 years, as AM has emerged as atruly disruptive technology for not just prototyping but also production. They are invariably seen as being enabled by the additive hardware that builds the parts. In reality, this is a partial picture, particularly for serial production applications of AM. The hardware systems are just one part – albeit a vital one – of an extensive ecosystem of technologies that enable AM, both pre- and post-build. Of unique importance today is the role of post-process metrology to validate the integrity of AM builds. One specific reason for this importance is that many parts produced by AM today end up in safety-critical applications where end-use functionality is of vital importance. The nature and relative roughness of AM surfaces, whether analysing individual layers within a build, or the surface of a finished part render conventional metrology solutions somewhat impotent. Recent developments from ZYGO are allowing hitherto unattainable metrology results that are being used to enhance the use of AM as a production technology by making validation protocols more efficient. Metrology and additive manufacturing Richard Leach, Professor in Metrology at the University of Nottingham in the UK, has been working with ZYGO on a number of projects related to the use of metrology in AM. Leach believes the issue of metrology is crucial to the success of AM as it begins to establish itself as a true production technology. “There is absolutely no doubt that inadequate metrology solutions are a huge obstacle to overcome if AM is to be used as a viable production technology across industry,” says Leach. “Basically, as we stand today, there is a lack of clarity as to the precise nature of defects that you get when undertaking an AM build, and you also have little idea how they may cause problems in terms of part functionality. We don’t have a detailed enough map of how the topography of the defects and the anomalies that you get during the AM process propagate through to the part in an end-use scenario. Leach offers the example of a turbine blade being made in an AM layering process, and where a blip occurs in the topography in layer four. “This layer will in-time be covered up, so its characteristics will be fundamentally different by the time the finished part is complete,” he explains. “And it is at this moment impossible to know – without the clarity that good metrology provides – whether the blip is in fact still there when the build is complete, and if so, if it was actually significant in the first place. Essentially, we are working on, but still haven’t completely solved, the problem of understanding what issues you get on the surface and under the surface when using AM, and how these relate to product functionality. “Therefore, it is difficult to predict the mechanical properties, the thermal processes, the fatigue properties, etc … from the types
A sample part made at Nottingham University from Ti6Al4V using selective laser melting (SLM) measured by a ZYGO Nexview CSI microscope.
of structures we are seeing post-process. Defect-function analysis may allow us to move towards controlled AM by just stopping the process when things go wrong, as right now we spend hours building a part that may in fact have a problem in layer one.” Despite these challenges, many companies are already using advanced AM successfully for the production of critical parts and components, often in aerospace applications where part failure is not an option. To ensure that these AM-produced parts conform fully with design intent, part suppliers undertake far more mechanical testing and metrology verification than they would normally employ for conventional manufacturing processes. Manufacturers are forced out of necessity to focus on process development and throw all the validation resources they can to ‘prove’ the integrity of the finished AM part. This latter is effectively a belt-and-braces approach, relying on Gage R&R reproducibility and repeatability as a stand-in for a more rigorous measurement uncertainty approach when evaluating the integrity and functional characteristics of AM parts. The current solution is what could be termed ‘extreme-testing’. “Everyone blames the confusion on a lack of standards for measuring AM parts, but this is not where attention should be focussed,” Leach comments. “You cannot develop standards if you don’t have the correct measurement technology in place to start with. Standards being developed without the technology solution ready to use are actually worse than no standards at all. “That is why the emphasis with ZYGO and other metrology instrument suppliers is on adapting metrology solutions to make them better aligned with the unique characteristics of the AM process and AM end-use parts. In the respect of standards, our focus today is on producing a Good Practice Guide showing OEMs what metrology
A true colour 3D image of the AM Ti6Al4V part produced using the ZYGO Nexview CSI microscope.
solutions are in place today, and how to get the best results from these when applied to AM surfaces, and setting the instrument up in the best way to understand the data.” ZYGO – Coherence scanning interferometry for AM A key focus in the area of metrology for AM is to reduce the time and cost inefficiencies inherent today of relying on a vast range of duplicated and often inadequate metrology steps to validate that an end-use part is fit for purpose. As Leach works on this vital area, he is involved with a number of metrology instrument suppliers using a variety of measurement technologies. ZYGO is perceived to be a trusted supplier with nearly 50 years of history in the ultra-precise metrology regime. “For post-process metrology, a number of alternatives exist including confocal and focus variation, and ZYGO’s coherence scanning interferometry (CSI),” says Leach. “Initially it was thought that CSI was not suitable to the vagaries of post-process AM parts (with their unusual surface roughness). But ZYGO enhanced its CSI instruments by introducing new ways of playing with the optical light source, illumination conditions, and detection conditions, which led to the attainment of high-quality results with extremely rough and complex AM surfaces. I have to admit that before looking in depth at the ZYGO CSI solutions, even I thought that they probably wouldn’t be able to be applied to AM parts, but it actually works extremely well.” Leach’s initial work with CSI, which informed his early view of the inappropriateness of the technology for AM super-rough surface metrology, was based on CSI from an alternative supplier other than ZYGO. The CSI instrument his work was initially focussed on was a CSI instrument in terms of its basic measurement principle, but it differed from the ZYGO system in terms of hardware, firmware and data analysis. Using data from the alternative CSI solution provider, Leach and his team at Nottingham concluded that interferometry was fundamentally not suitable for AM metrology, because the example instrument failed to capture most of the highly irregular topographic features. However, by then ZYGO had already solved this problem with the introduction of its Nexview instrument in 2014. It is the Nexview technology that Leach and ZYGO work on together today, and which is now accepted to be a strong and viable AM metrology tool. The Nexview instrument and its sister product the NewView include a package of innovative hardware and software upgrades referred to at ZYGO as ‘MoreData’ technology, which have made the instrument much better suited to AM parts. “We installed a NewView 8300 instrument at Nottingham in October 2016,” Leach recounts. “Measurements made at Nottingham as well as at ZYGO’s headquarters in the US on AM surfaces conclusively demonstrated that ZYGO’s CSI implementation was well suited to the task. The ZYGO system is arguably a reference standard today for AM metrology, and other research groups have confirmed its superior capabilities. Today, we work with ZYGO’s Nexview optical surface profiler.” The ‘MoreData’ capability has been part of ZYGO’s complete product line (including ZeGage and NewView optical profilers, and the Nexview system) for several years now and has been shown to be one of the most successful technology developments for the product line. ‘MoreData’ significantly improves the baseline sensitivity of CSI and enables high-dynamic range (HDR) operation, making it valuable for a wide range of parts, from steeply sloped smooth parts to exceptionally rough textures with poor reflectivity. Additionally, HDR is able to measure parts with a wide range of reflectance, often a struggle for other CSI instruments. HDR is unique to ZYGO, meaning that an alternative implementation of CSI may not be able to achieve the performance on AM parts that ZYGO can provide. Today, the focus is on using the ZYGO HDR CSI technology to undertake surface texture analysis and to attempt to better understand its links with the AM production process. Leach concludes: “My work with ZYGO is centred around understanding precisely how the CSI instrument works, and accurately modelling it for AM applications. At the moment, the issue is that AM surfaces are so different from what we are used to in terms of the raw surface and the post-processed surface that there is no standardised way of measuring and characterising these surfaces. We are working with ZYGO to ensure that we continue to optimise metrology solutions for the increasingly important area of AM for production scenarios.”
Eric Felkel is a Product Manager for Optical Profilers at Zygo Corporation. www.zygo.com
VALE
IAN SMITH
– M.T.I. QUALOS
e Management and Sta of M.T.I. Qualos sadly advise to the many friends and colleagues around Australia, the passing of our Managing Director and Chairman, Ian Smith.
Ian began work with M.T.I. Qualos in 1974 as a Sales Representative essentially to promote the Japanese brand Mitutoyo to the Australian engineering sector. In 1989 Ian was appointed Managing Director and expanded the market share of the Mitutoyo brand throughout the country until his retirement in 2007, where he took on an overseeing role as Chairman. Ian was a long-standing supporter of the Australian Manufacturing Industry, and as such M.T.I. Qualos was a founding member of AMTIL back in 1999. We thank Ian for his involvement in the industry and pass on our condolences to his family and friends at M.T.I. Qualos.
Quantum physicist, defence scientist take top awards on World Metrology Day
With the theme ‘Measurements for global trade’, World Metrology Day took place on 25 May, recognising the importance of the science of measurement in helping Australian industry to access and compete in global markets.
To mark the day, Australia’s National Measurement Institute (NMI) Chief Executive Officer and Chief Metrologist Dr Bruce Warrington announced the recipients of the Barry Inglis Medal and NMI Prize. The awards are held annually and recognise significant contributions to measurement science, research and leadership. This year’s recipients highlighted the broad range of organisations undertaking and applying measurement research in Australia. “I would like to congratulate Professor Warwick Bowen as the 2020 Barry Inglis Medal recipient, for his role in the development of quantum technologies and innovative practical solutions to the benefit of measurement science,” Dr Warrington said. The Barry Inglis Medal recognised Professor Bowen’s work at the University of Queensland developing ground-breaking sensors, enabling the study of individual molecules, medical imaging, and mineral exploration. He has partnered with Australian industry to commercialise these technologies, and made an outstanding contribution to health, industry, and fundamental research outcomes. In short, reverse engineering is the reproduction of a product or part that cannot be obtained by other means. It involves measuring an object and reconstructing it as a 3D model, then manufacturing the part. The process is primarily used for machinery parts, rather than the production of parts for mass assembly line manufacturing. “Reverse engineering is the only option when OEM parts are no longer available, particularly for an aged piece of equipment,” says Leussink’s Managing Director Jason Leussink. “However, there is no reason why reverse engineering processes cannot be used for newer components. The process can be applied in many industries and applications.” Reverse engineering can be undertaken using a variety of tools and technologies. Generally, the complexity of the part being reverse engineered will dictate the type of equipment and software used. “The simplest reverse engineering process is manual measurement and data collection of a physical model’s dimensions,” says Jason. “In this process, hand tools such as micrometers, Vernier calipers, and gauges are used to capture the critical dimensions needed to generate a part drawing. “A more sophisticated approach is to use a coordinate measuring machine (CMM) like the Tomelleri Space Arm distributed by Leussink in Australia & New Zealand. The CMM measures the geometry of physical objects by sensing discrete points on the surface of the object with a probe.” The part or product is measured and the dimensions immediately digitised and transferred to a CAD Dr Renée Webster was the recipient of the 2020 NMI Prize in recognition for her work as part of the Department of Defence Science and Technology Group. Dr Webster’s efforts included the development of new analytical approaches to improve our understanding of the complex chemistry of fuels at high temperatures and trace impurities produced prior to combustion. “This work is particularly important for high performance military aircraft and contributes to the safe and effective operations of the Australian Defence Force,” Dr Warrington said. As Australia’s peak measurement body, NMI plays a vital role in supporting manufacturing to innovate, as well as giving regulators, industry and consumers confidence in the safety and quality of products and services. World Metrology Day is held annually on 20 May to celebrate the international Metre Convention, signed in 1875 to establish a global measurement system for trade and innovation.
Reverse engineering in the spotlight with worldwide parts shortages
The COVID-19 pandemic has had a huge impact on industry right around the world, and the knock-on effects will continue to be felt for many months and even years. Illawarra-based engineering firm, Leussink, believes reverse engineering of scarce parts can play a role in helping with the shortfall.
www.worldmetrologyday.org.au
system, where surfaces are developed and drawings are finalised. Besides reducing the risk of measurement errors, processing data electronically significantly reduces the time required for the overall reverse engineering effort. “Reverse engineering is particularly applicable where there are machines that can run 24/7 for months on end, repeating the same process over and over again,” Jason explains. “This type of high use means parts and accessories are going to need to be replaced regularly, and in some cases major components as well. Given the potential life span of some machinery, by the time a major part is required, it may no longer be in production or may be too expensive to replace, or in the case of our current times may not be available to order in a reasonable time frame. The data gathering of the reverse engineering process can also take place on-site, which is a huge advantage for large equipment that cannot be moved easily. Leussink’s team delivers reverse-engineered components through the use of scanning and datapoint collection metrology equipment. The data is imported directly into CAD software, where a Finite Element Analysis (FEA) can be conducted for optimal performance and lifecycle. Once Leussink has the FEA, engineers can make adjustments to the design to increase efficiency and add value to the project, before putting the component into production. “Reverse engineering was not possible a few decades ago,” says Jason. “But with technological advancements, it has become feasible and economical.” www.leussink.com.au
