Dear Doc: I use resin- and metal-bond diamond wheels and used to manually stick them. Now our machine does it automatically and I don’t have the “feel” to determine if the wheel is being stuck hard enough. Is there a way to know how fast I should stick?
The Doc Replies: For some reason, companies that were sticking aggressively suddenly stick timidly when they switch to auto-sticking. Here’s a ballpark equation to calculate how fast to stick:
Sticking aggressiveness = 76,000 × sticking velocity (ipm) ÷ wheel speed (sfm)
Aim for a sticking-aggressiveness value around 250.
Finding an effective grit-penetration depth is critical to successful plunge grinding. If it’s too large, you’ll rip the wheel apart; if it’s too small, you’ll burn the workpiece. Illustration courtesy J. Badger.
Let’s say you’re sticking at 1.0 ipm on a wheel running at 3,000 sfm. That gives a sticking aggressiveness of 25.3 (76,000 × 1.0 ÷ 3,000). That’s a timid stick. To get in the ballpark of 250, increase sticking velocity to 9.0 ipm. This gives a sticking aggressiveness of 228—an aggressive stick.
Finally, an effective way to see if you’re sticking correctly is to monitor grinding power. If the power doubles because of wheel loading, a good stick should drop the power close to its original value. On the other hand, a timid stick will only drop it 10 percent.
Dear Doc: I cylindrical plunge grind ODs in tungsten carbide, but every time I increase the feed rate, something bad happens. What can I do?
The Doc Replies: You want to focus on the grit-penetration depth. The equation for grit-penetration depth is complicated, but for a given wheel diameter and workpiece diameter, keep the grit-penetration-depth parameter (GPDP) constant.
GPDP = √plunge feed velocity × √workpiece rpm ÷ wheel speed
Use whatever units you want, as long as you’re consistent, and pay close attention to the two—not three—square-root signs.
Let’s say you’re plunging into a workpiece at 0.040 ipm, with a workpiece speed of 200 rpm and a wheel speed of 5,000 sfm. That gives a GPDP of 0.000566 (√0.040 × √200 ÷ 5,000). If you double the feed rate, to 0.080 ipm, then decrease the workpiece rpm to 145 and increase wheel speed to 6,000 sfm. That will give you a GPDP of 0.000568. That’s close enough, and the wheel will behave more or less the same.
Try it. You’ll be amazed at how high you can crank things up. Just remember, though, there are limitations to how high you can go. I’ve pushed my luck a few times and blown up wheels. But then I back off a little and successfully plunge grind at a much higher feed rate. CTE
About the Author: Dr. Jeffrey Badger is an independent grinding consultant. His Web site is www.TheGrindingDoc.com. He’ll be giving a course focused on effectively grinding tungsten carbide Nov. 6-8 at Rollomatic’s facility in Mundelein, Ill.
Related Glossary Terms
- 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.
- inches per minute ( ipm)
inches per minute ( ipm)
Value that refers to how far the workpiece or cutter advances linearly in 1 minute, defined as: ipm = ipt 5 number of effective teeth 5 rpm. Also known as the table feed or machine feed.
- tungsten carbide ( WC)
tungsten carbide ( WC)
Intermetallic compound consisting of equal parts, by atomic weight, of tungsten and carbon. Sometimes tungsten carbide is used in reference to the cemented tungsten carbide material with cobalt added and/or with titanium carbide or tantalum carbide added. Thus, the tungsten carbide may be used to refer to pure tungsten carbide as well as co-bonded tungsten carbide, which may or may not contain added titanium carbide and/or tantalum carbide.
- 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.