Vibration is a byproduct of the rotating tools common in milling. But excessive vibration leads to chatter, which causes wear on tools and machines—and worse can result in poor-quality parts and excessive cycle times. Here’s an overview of the elements involved in vibration analysis to eliminate chatter.
If you work in manufacturing, you know about vibration—mainly that excessive vibration is not good for the milling machines on the shop floor or the parts being produced. In fact, machinists spend a lot of time attempting to eliminate chatter caused by vibration.
“Chatter may cause fast wear of tools and poor surface quality of the workpieces at high cutting speed, and it will happen on different process parameters,” notes research published in The International Journal of Advanced Manufacturing Technology.
Typically, machinists turn to trial-and-error tactics, spending anywhere from half to an entire work shift to determine the ideal setup for a job on a CNC milling machine.
To achieve the optimal setup and eliminate chatter—that increasingly louder screech that indicates an unsmooth cut—machinists might reduce speed, adjust feed rates, try varying axial and radial depths of cut, and even replace tools.
Why? To determine how to produce a part at the optimal operating level because that not only extends tool life, it ultimately lets a business produce more high-quality parts more quickly.
When the tool setup on a CNC machine is running in a stable manner, it’s akin to running a hot knife through butter: swift, quiet and clean.
In limited instances right now, machining teams try to measure and analyze the frequency of vibration between the workpiece and the cutting tool, and to track the data across setups and machines. The time savings can be significant, but unlike the use of vibration analysis for planning preventive and predictive maintenance of industrial machinery, it’s fairly uncommon in machining and, most specifically, milling.
Read more: Good Vibrations: How to Optimize Your Machine Setups to Minimize Chatter
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Have vibration analysis tools and software advanced to the point that they can be used by setup and production personnel in a machine-shop environment? How do we get this information boiled down to actionable items like "reduce tool runnout" or "increase RPM by 10%". Do we still need dedicated technicians with specialized training in both machining and vibratory analysis to make these recommendations? Trial and error may be slow, but not many shops are going to have a PhD sitting around waiting for chatter to pop up either.
158This technology has been used for 30 years in industry, and software the past 20 years by machinists, electricians, CAM operators. The new MillMax software was designed to be very straightforward. If your employee can use a smart phone, turn on a computer, or operate CAM software, then they can use this. The goal is not to wait for chatter to pop-up, but optimize a tool to start and program with the best parameters that increase MRR often times 100-500% faster. You do not need a Vibration Expert, but an open minded staff willing to learn a better way to choose RPM and DOC then guessing or using a table. Programming in CAM takes weeks of training and years to perfect, and every shop all have these people. This technology takes hours to learn and implement. I have fixed problems in 10 minutes that companies have spent weeks and months trying to fix by testing tool after tool and speed after speed. People are shocked at what it can do!
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