Keeping cool grinding stainless

Author Jeffrey A. Badger, Ph.D.
Published
February 01, 2013 - 10:30am

The Doc Replies: Stainless is more difficult to grind than hardened steel primarily for two reasons: lower thermal conductivity and a nasty chemical reaction. First, stainless steel, such as 304 or 316, has about half the thermal conductivity of, say, 52100 steel. That means 52100 sucks away the heat generated during grinding more quickly, reducing surface temperatures. Based on the Jaeger heat-source model, having half the thermal conductivity results in grinding surface temperatures that are about 40 percent higher.

Second, the high chrome content—at least 10.5 percent—in stainless steel causes a thin passivation layer of chromium oxide (Cr2O3). The chemical formula for aluminum-oxide wheel grits is Al2O3. Those two molecules are mutually soluble, meaning they dissolve in one another, and that spells trouble. If you perform X-ray spectroscopy on a ground stainless steel workpiece, you’ll find aluminum is present. This means the stainless steel workpiece dissolved a little Al2O3 from the wheel. The result is loading at the wheel surface and excessive wheel wear.

What’s the solution? In terms of the reduced conductivity, you must reduce the feed rate by around 30 percent to achieve the same grinding surface temperature. There’s no getting around it.

In terms of minimizing the chemical reaction, improved cooling is the best approach. If you can get a thin layer of coolant between the grit and the workpiece, you’ll retard that chemical reaction. You can achieve this with a coolant velocity that’s close to the wheel surface velocity and by aiming the coolant directly at the wheel/workpiece interface.

 

Dear Doc: When creep-feed grinding tungsten-carbide endmills, some of our operators push the feed rate hard and others not at all. Can you provide some guidelines?

The Doc Replies: I don’t think in terms of feed rate because it’s just not very useful. Instead of feed rate, a better parameter is the specific material-removal rate, or the “Q-prime” value.

The formula is:

Q-prime (mm2/sec.) = DOC (mm) × feed rate (mm/sec.)

Or, if you’re an imperial guy:

Q-prime (mm2/sec.) = 10.8 × DOC (in.) × feed rate (ipm).

Over a few days, take a survey of the Q-prime values everybody is using. You’ll find they’re all over the place. Joe is grinding at a Q-prime of 3.2 mm2/sec., Frank is at 1.8 mm2/sec., José is at 7.2 mm2/sec. and Barney is at 8.4 mm2/sec. Pick a value—5.0 mm2/sec. is a respectable number when creep-feed grinding carbide—and bring everybody in line with that value. You’ll find your grinding to be more consistent. Once you do that, slowly start increasing the Q-prime value to reduce cycle times.

The next step is to find the optimal grit penetration depth and then keep that constant as you increase Q-prime values. This is a little more complicated, but something I teach at my Carbide Master-Grinder Clinic. CTE

About the Author: Dr. Jeffrey Badger is an independent grinding consultant. His Web site is www.TheGrindingDoc.com. He’ll be giving his High Intensity Grinding Course March 6-8 in Columbus, Ohio, and his Carbide Master-Grinder Clinic April 9-11 in Mundelein, Ill.

Related Glossary Terms

  • coolant

    coolant

    Fluid that reduces temperature buildup at the tool/workpiece interface during machining. Normally takes the form of a liquid such as soluble or chemical mixtures (semisynthetic, synthetic) but can be pressurized air or other gas. Because of water’s ability to absorb great quantities of heat, it is widely used as a coolant and vehicle for various cutting compounds, with the water-to-compound ratio varying with the machining task. See cutting fluid; semisynthetic cutting fluid; soluble-oil cutting fluid; synthetic cutting fluid.

  • creep-feed grinding

    creep-feed grinding

    Grinding operation in which the grinding wheel is slowly fed into the workpiece at sufficient depth of cut to accomplish in one pass what otherwise would require repeated passes. See grinding.

  • feed

    feed

    Rate of change of position of the tool as a whole, relative to the workpiece while cutting.

  • grinding

    grinding

    Machining operation in which material is removed from the workpiece by a powered abrasive wheel, stone, belt, paste, sheet, compound, slurry, etc. Takes various forms: surface grinding (creates flat and/or squared surfaces); cylindrical grinding (for external cylindrical and tapered shapes, fillets, undercuts, etc.); centerless grinding; chamfering; thread and form grinding; tool and cutter grinding; offhand grinding; lapping and polishing (grinding with extremely fine grits to create ultrasmooth surfaces); honing; and disc grinding.

  • web

    web

    On a rotating tool, the portion of the tool body that joins the lands. Web is thicker at the shank end, relative to the point end, providing maximum torsional strength.