1/26/2017 | 2 MINUTE READ

Real-World Precision Is an Active Pursuit

Facebook Share Icon LinkedIn Share Icon Twitter Share Icon Share by EMail icon Print Icon

As with any choice of technologies, choosing between active and passive CMM scanning requires thinking beyond specification sheets and staying abreast of what’s on the market.

Share

Facebook Share Icon LinkedIn Share Icon Twitter Share Icon Share by EMail icon Print Icon

Connect at

ZEISS Industrial Quality Solutions will be exhibiting new technology at IMTS 2020 in Chicago this September.

Plan to meet up with their team or get registered here!

Two different CMM scanning heads from the same manufacturer have the same level of measurement uncertainty, but only one offers the ability to articulate on its own. The other requires stylus extensions—sometimes lengthy, complex extensions that take time and effort to properly configure—in order to ensure the probe tip approaches the work at a normal (perpendicular) vector. If purchasing decisions could be based solely on capability, why would anyone choose the non-articulating head, even if the application doesn’t involve exceptionally complex geometry or multiple approach angles? 

Because the quality lab isn’t the real world, whatever the quoted level of uncertainty, and because there’s good reason why some scanners are designed to leave stylus positioning mostly to the CMM’s own axes. So says Kevin Donovan, senior technical sales engineer with Carl Zeiss. Known as active scanning systems, these models’ complex internals prevent the head itself from articulating like their passive cousins, which rely on a static system of springs and displacement sensors to gather part data. Active scanning, he explains, adds finesse to the proceedings in a different way:  by maintaining an even, user-specified level of force on the workpiece surface throughout the scanning routine, even absent a nominal. Given this capability, active scanners rely less on compensating software algorithms.

That was a key consideration for Tube Hollows, the subject of our December-issue cover story and a specialist in tubular components near Portland, Maine. With new customers demanding more robust data that can be interpreted in more ways, active scanning was deemed the best option, says Andrew March, technical sales engineer. Another key consideration in purchasing Zeiss’s Vast XT Gold was the ability to compensate for the force of gravity on the stylus extensions required to measure complex features deep inside of long tubes. 

Yet, as is the case with so much manufacturing technology, active and passive scanning defy simplistic, black-and-white comparisons. After all, Zeiss offers a model that slightly blurs the lines: the XTR Gold. “Slightly” because this is most certainly an active scanning head, but it does feature an integrated swivel joint that enables turning the stylus mount in 15-degree increments. That’s limited compared to the range of motion of a typical passive head, and it wouldn’t help much with Tube Hollows’ long bores (although, if it offered capability to articulate in Z, “That would be a different story,” Mr. March says). That said, the advantages for other kinds of work are obvious: additional flexibility on complex, multi-featured geometry without sacrificing the advantages of active scanning.

In examining this technology and writing this story, it occurred to me that regardless of the end game and regardless of the technology involved, the pursuit of any manufacturing goal should be an active one. That is, one characterized by close attention to what’s available on the market and a willingness to look beyond specifications when evaluating capabilities. 

RELATED CONTENT

  • Going Lean in Order to Grow

    This shop has a plan for dramatically expanding its contract machining business in high-value markets.

  • Gaging Countersunk And Chamfered Holes

    While countersunk and chamfered holes are similar in appearance, functionally they are quite different. Consequently, different gages exist to serve these different functional requirements.

  • 3D Scanning: Reproducing One-Of-A-Kind Prototypes

    A laser scanning system helps this shop capture the free-form surfaces on a hand-sculpted original. The resulting digitized models are the basis for CAM applications such as programming a CNC machining center. 

Resources