Kaiser Manufacturing’s Tool Caddy Safely Stores Cutting Tools

One of the first clues that Precision Plus is different from other machine shops was a gentle clicking noise. The sound emanates from more than a dozen mechanically driven Swiss-type lathes at the center of the shop floor. Lined up in neat rows and serviced by obviously newer barfeeders, these machines cut uncovered, without the noise-damping enclosures that characterize the shop’s CNC machines. A closer look reveals a half-dozen or so tools simultaneously plunging in and out of the workpiece as the cams rotate.

Some of these machines had already been producing parts for years by the time the company moved to its current location in Elkhorn, Wisconsin in 2000. Under the leadership of company president Mike J. Reader, the company has since added various newer CNC equipment, including Miyano ABX and BNX two-spindle lathes as well as multiple Star and Tsugami Swiss-type CNC lathes. And yet, Precision Plus still relies heavily on equipment that operates in much the same way as it did when Reader’s father, Phil, first purchased the company in 1988 – that is, by using physical cams rather than CNCs to space out the timing and depth of cuts. Why?

This was my first question to Michael P. Reader, VP of Engineering (and Mike Reader’s son). His answer was simple: “The cam-driven machines, when they can be used, are cheaper to operate,” he says.

“For small cylindrical parts with higher annual volumes, the Swiss cam machines are very economical,” says Reader. The fleet of mechanically driven Swiss-type lathes from Tornos have lower electrical costs, and crucially can often cut parts significantly faster.

That last factor might be surprising to some, as a computer-operated machine tool seems like it should have no problem competing with a machine that has absolutely no computing power whatsoever. However, the cam-driven machines can utilize multiple cutting tools at once, with very little travel. “All the tools are at rest less than two inches from the part,” Reader says, gesturing to a semicircle of cutting tools frantically cutting a firing pin out of a thin bar. “This makes it much faster than a CNC.”

How much faster could it be? “We have one part that would take eight seconds per piece on a Swiss CNC,” Reader says. “On the cam machine, it takes three seconds.” More than doubling production speed is a major difference, especially when dealing with high volumes. “If we had to use a CNC on that part,” he says, “we wouldn’t even break even.”

But when are the CNC machines preferable?

“It really depends on the needs of the part,” Reader says. “Some parts need increased precision, which a Swiss CNC provides.” Take the example of a dental component the facility produces. At one end, the diameter is only 0.01 inches thick, and its length-to-diameter ratio is quite high, so it requires additional support to eliminate chatter and prevent breaking the component off in the machine. These features of the part make the CNC necessary, as it is capable of higher precision and greater rigidity. Additionally, surface roughness must be nearly flawless, as a slight imperfection can be catastrophic. “We need to make sure we hit the tolerance exactly,” Reader says. “If this dental component had any surface imperfections, it could lead to crack propagation and failure during use.”

I think anyone who has sat in a dentist’s chair is grateful for the increased precision of the CNC machine.

Factors other than tolerance can play into the choice to use the CNC machines. For starters, they can handle larger parts – 12, 20 or 32 millimeters, depending on the machine. Additionally, parts like the dental component require high-pressure coolant, which is not possible in the cam-driven Swiss lathes. Coolant can also be a major factor for materials that generate stringy or sticky chips, as well as valve components with O-ring’s grooves that require high pressure to remove chips.

Finally, the headstock lathes find work with larger and more complex parts up to 2.5 inches in diameter. “Generally, when we have lots of material removal or a higher degree of complexity, we’re going to utilize our Miyano platform,” Reader says. The Miyano ABX is used for aggressive and precise machining – in part due to the hydraulically operated chucks and the robust machine design the platform offers. One part used in semiconductor production involves a great deal of ID material removal, off-center drilling, threading and OD turning on high-tensile, high-yield stainless steel. On a two-spindle lathe with three turrets, the component can be machined complete in one operation at a highly competitive rate.

The other lathe – the Miyano BNX – is primarily there for its efficiency. “The BNX offers faster production rates surface milling cutters than the ABX while also allowing for fifth-decimal offsets,” Reader says. Precision Plus machines components plus-or-minus 1 ten-thousandth of an inch on OD turning, and a total of 3 ten-thousandths on ID bores. When it does not need to be quite so precise, it is capable of machining simultaneously on the main and sub spindle with the single turret, which increases throughput on many parts. Both platforms are equipped with quick-change chucking systems from Hainbuch to improve setup time and part concentricity from spindle to spindle.

As with many things in machining, it really comes down to the part. “In general, the larger and more complex the part, the more likely it is to go on the fixed headstock lathes,” Reader says. “Smaller cylindrical parts with extremely tight tolerances or that need tube process inserts high-pressure coolant go on the Swiss CNC machines. But if we can make it on the Swiss CAM machines, it will likely be faster, and just as precise, to be produced there.”

The Carbide Inserts Website: https://www.aliexpress.com/item/1005005874938885.html