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Renishaw

Metrology

Advanced Ballbar Training for Better Machine Tool Accuracy

‘Super-tune’ machines to better-than-factory accuracy

Published: Tuesday, June 24, 2014 - 14:45

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dvanced ballbar training enables a shop to achieve better-than-new machine tool accuracy and extend machine life for unconventional silicon processing. Semiconductor industry suppliers now understand their machine tool’s performance better than OEM service technicians.

Ballbar testing is nothing new to those who use fleets of machine tools, including people like Wayne Ross and Jacob Hibbeler of Silfex Inc. based in Eaton, Ohio. Both have used ballbar analysis to maintain and enhance the accuracy of the plant’s 50-plus machines for more than a decade. But, it turns out that experienced ballbar users can still learn a few new tricks that can be transformational to a business. After upgrading to a QC20-W wireless ballbar and taking the Renishaw Advanced Ballbar course, total productive maintenance (TPM) manager Ross and machine operator Hibbeler now use captured ballbar data to evaluate machines, “super tune” them to better-than-factory accuracy, and get longer life out of machine components. They have also changed the way Silfex proves out machines, schedules maintenance, and evaluates the need for new machines.

“We’ve done ballbar testing for years, but until we took the advanced ballbar course, we weren’t making full use of the results,” says Ross. “Now we’re using the ballbar to qualify metrology, time our maintenance decisions, implement TPM and SPC, and even forecast machine life. It’s helping us make operational and capital equipment decisions in ways we never thought possible.”

Unconventional processing with conventional equipment

Silfex’s machining application is like a military proving ground for machine tools, so machine diagnostics are a way of life. Its lathes and vertical machining centers—primarily Haas and Mazak—use diamond tooling to grind and polish silicon and quartz for the semiconductor industry, resulting in glass-like debris and diamond particles forming an abrasive compound that wears out components in months. The 290-employee company is a rapidly growing division of Lam Research Corp. and has built a reputation as a single-source supplier of electrodes and silicon fixturing for Lam plasma etching chambers. These consumable parts support the etching process in the manufacture of computer chips, and part values can be as high as $30,000.

“We are one of the few companies in the world that can grow defect-free, single-crystal silicon to a diameter of 460 mm,” Ross explains. “We do start-to-finish manufacturing under one roof, which is important because the semiconductor industry requires 100-percent traceability on everything, from the material source to the machined parts, and we have all of that under direct control. For our customers’ requirements, this is a purchasing manager’s dream.”

The plant is environmentally controlled and equipped with multiple clean rooms from class 10,000 to 100. “One speck of contamination can wipe out a lot of computer chips,” Ross explains. Processing the silicon includes wire sawing, waterjet cutting, milling, drilling, grinding, and lap polishing before inspection in metrology rooms with coordinate measuring machines (CMM) and video CMM equipment. Parts then go to an on-site clean room for packaging. Production runs range from five to 100 pieces per setup, and the required tolerances are typically ±0.001 in., with some requiring ±0.0005 in.

Grinding silicon creates an extremely harsh machining environment. “We’re using conventional machines to do unconventional processing, and using ballbar diagnostics to stay on top of our machine capability in a high-wear application,” says Ross. “We use the ballbar to diagnose ballscrew wear every six months, but usually get called to test machines before that. The advanced ballbar training showed us how to determine if we can make machine adjustments, or if it’s time to replace the ballscrews. This allows us to control downtime scheduling and maintain our accuracy as machine components wear out, rather than judging machine capability from the quality of finished parts. We run these machines hard—three shifts, five days a week—with quite a few long runs, and the grinding environment is tough on the equipment. I’m amazed at how accurate we can make these machines considering how rapidly the machining environment changes. Our VMCs are hitting accuracies comparable to much higher-end machines. And, while high-end machines are faster, we can only grind so fast. So, we don’t need ‘faster,’ just accurate.”

Advanced ballbar training raises the bar for company’s machining capability

Ross and Hibbeler came away from Renishaw advanced training with a much better understanding of their ballbar data and how to use it. Conducted at Renishaw in Hoffman Estates, Illinois, the hands-on course lets participants practice setting up and running ballbar analysis on a variety of different machine tools in a learning lab. “I’ve been working with ballbars for 13 years and thought I knew my stuff,” says Hibbeler. “But after 10 minutes, I was learning new tricks. Among other things, we learned how to troubleshoot scale mismatch, which has helped us super-tune our circular interpolation and extend the useful life of the mechanical parts of our machines. We also look at lateral play to gauge the condition of our linear guides.”

“After the advanced class, we concentrated on interpreting our numbers to see if there were more details we could control,” Ross says. “Jacob has gotten really good at adjusting the backlash and reversal spikes, so we can get more life out of the ballscrews, which is our edge until we can get a service technician in. Sometimes we can do two or three adjustments, and that buys us a lot of productive time to schedule when to take the machine offline for repair.”

Accuracy now starts at ground level

Silfex uses ballbar diagnostics to determine a machine’s squareness, which is the prerequisite for analyzing backlash and reversal spikes. “Many machine shops overlook the effects of the floor, as we were, on machine level,” says Ross. “We are lucky our concrete is substantial enough to support all the weight we put on it, and we check and adjust the machine level upon installation. Once we set the level, we can diagnose reversal spikes, backlash, and scaling mismatch, which we didn’t know how to do before the class.”

Ross and Hibbeler now handle machine leveling, largely because they can hit specs that some technicians have trouble achieving. “The two-tenths bubble servicemen can meet our requirements, but the five-tenths bubble guys can’t,” says Hibbeler. “Our leveling is so precise today that we often wish the leveling screws had a finer pitch on them.”

After the training Ross and Hibbeler used their new knowledge to push the boundaries of machine accuracy. “Our goal on squareness was 0.000050 in./in., and I decided we would try for 0.000025 in./in.,” says Ross. “When I told Jacob he expressed doubt, but I showed him data that proved he had already achieved it three times prior.”

Based on their success with the ballbar, Ross and Hibbeler are expanding their machine diagnostics. “The ballbar tells us about the foundation: the linear guides, the ballscrews and the truss bearings—the bottom end of the machine—that’s where mechanical tolerances are established, and it also confirms our metrology,” says Ross. “We’ve also started using some vibration analysis, and that tells us about the top-end of the machine, which dictates finish. So, between the two, we are analyzing all the factors that affect our size and finish. We’d like to get into volumetric compensation testing with the ballbar. We currently test X and Y on VMCs, and X and Z on the lathes, and have done full Y-Z testing in the past on a few machines, but with volumetric testing we’ll also hit X-Z, and I think we’ll be able to get what we need in the 220-degree sweep the ballbar is capable of performing.”

No wire, no worry

Upgrading to the wireless ballbar simplified data collection, and made it safer, Hibbeler explains. “With the wired ballbar, I spent a lot of time babysitting a machine under test,” he says. “I had to feed wire in through the back of the machine, and if I walked away for a few minutes, I often came back to a twisted wire. I always had a nagging thought that any little tug on a wire during a test might skew the results. We don’t have those issues with wireless operation. I can set it up and go do something else until the test is complete. It’s also safer now that we’ve eliminated open-door testing.”

Ballbar data opens doors for new programs

Silfex is now using ballbar data to establish thresholds in relation to its various processes and determine process capability. “We now have diagnostics to back up what we think is happening with our machines,” says Ross. “These data are being used for our TPM program, implementation of SPC, and our future OEE [overall equipment effectiveness] monitoring. Full SPC will allow us to move away from 100-percent inspection. We are also working to determine what will be the useful life of a machine based on capability, maintenance costs and consistent quality.”

Even machine tool technicians are impressed with the expertise demonstrated at Silfex. “Some of them will say, ‘Well, this machine is now as good as new,’ and we tell them we need it better,” says Hibbeler. “Their response is, ‘Well, then tell us what to do,’ and when we show them, they ask how we did it. The advanced training provided us with knowledge that is tech-level and in some cases beyond, so we have data to back up our thinking.”

The data generated through ballbar analysis have even found their way to the company’s C-suite. “The executives at corporate now want to see a ballbar report every time a machine is qualified,” says Hibbeler. “This is filed with the machine documentation as part of our regular procedures between here and headquarters. Manufacturing keeps raising the bar, and ballbar analysis helps us reach higher.” Ross adds, “The world revolves around numbers, and ballbar analysis is our magnifying glass to help make good business decisions.”

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Renishaw

Renishaw is a global company with core skills in precision measurement, motion control, healthcare, spectroscopy, and manufacturing. The company supplies products and services used in applications as diverse as jet engine and wind turbine manufacturing to dentistry and brain surgery. Also a world leader in additive manufacturing, Renishaw designs and makes industrial 3D printers. Between 13 and 18-percent of annual sales are invested in R&D and engineering. The Renishaw Group has more than 80 offices in 36 countries, with 5,000+ employees.