MRR & Cutting Power — Copper C110

Material removal rate and spindle power for milling Copper C110 using its specific cutting force kc.

Axial depth ap (mm)Radial width ae (mm)Table feed vf (mm/min)Specific cutting force kc (N/mm²)Handbook value for this material — tune with insert geometrySpindle efficiency0.8–0.9 typical for belt/direct drives

Removal rate (cm³/min)

Power at cutter (kW)

Motor power needed (kW)

Pure copper's kc (~1,300 N/mm²) overstates how 'easy' it is: the power is modest but the material smears, so finish quality depends far more on edge sharpness than on the wattage you throw at it.

Formula

Q = ap·ae·vf / 1000 · Pc = Q·kc / 60,000

References: Sandvik Coromant — Milling formulas & definitions; Kalpakjian & Schmid, Manufacturing Engineering and Technology, 7th ed., ch. 21

Note: Catalog starting values only — always confirm against your tool maker's data sheet and cut a test part. Machine rigidity, coolant and workholding shift real-world numbers.

Disclaimer: This tool is for general informational and estimation purposes only and is not professional financial, tax, accounting or legal advice. All figures are estimates — verify with a qualified professional before making decisions. Read the full disclaimer.

Material removal rate and spindle power for milling Copper C110 using its specific cutting force kc. A free cnc machining: speeds, feeds & tool wear tool — no sign-up, no upload, instant results in your browser.

About MRR & Cutting Power — Copper C110

MRR & Cutting Power — Copper C110 computes the governing relationship Q = ap·ae·vf / 1000 · Pc = Q·kc / 60,000 live as you type. Pure copper's kc (~1,300 N/mm²) overstates how 'easy' it is: the power is modest but the material smears, so finish quality depends far more on edge sharpness than on the wattage you throw at it. Defaults are pre-filled with realistic values for this exact scenario, and the worked example substitutes your numbers step by step so the math is never a black box.

How to use MRR & Cutting Power — Copper C110

1Enter your values — Axial depth ap, Radial width ae, Table feed vf, Specific cutting force kc and more (sensible defaults are pre-filled).
2Read the live results: Removal rate, Power at cutter, Motor power needed.
3Check the "with your numbers" line to see Q = ap·ae·vf / 1000 · Pc = Q·kc / 60,000 substituted step by step.
4Adjust inputs until the scenario matches yours, then copy or share the result.

Why use MRR & Cutting Power — Copper C110?

✓Instant, free and private — every calculation runs client-side in your browser; nothing is uploaded
✓Built on the stated formula Q = ap·ae·vf / 1000 · Pc = Q·kc / 60,000 with authoritative sources cited on the page (Sandvik Coromant — Milling formulas & definitions; Kalpakjian & Schmid, Manufacturing Engineering and Technology, 7th ed., ch. 21)
✓Pure copper's kc (~1,300 N/mm²) overstates how 'easy' it is: the power is modest but the material smears, so finish quality depends far more on edge sharpness than on the wattage you throw at it.
✓SI ⇄ Imperial toggle converts your inputs in place, so you can work in the units your drawings use

Frequently asked questions

What formula does the mrr & cutting power — copper c110 use?+

It evaluates Q = ap·ae·vf / 1000 · Pc = Q·kc / 60,000, exactly as published. Sources: Sandvik Coromant — Milling formulas & definitions; Kalpakjian & Schmid, Manufacturing Engineering and Technology, 7th ed., ch. 21. The substituted worked example on the page lets you verify every step against the textbook.

How should I read the result — and how far can I trust it?+

Pure copper's kc (~1,300 N/mm²) overstates how 'easy' it is: the power is modest but the material smears, so finish quality depends far more on edge sharpness than on the wattage you throw at it. Catalog starting values only — always confirm against your tool maker's data sheet and cut a test part. Machine rigidity, coolant and workholding shift real-world numbers.

When is this calculator the right tool for the job?+

Material removal rate and spindle power for milling Copper C110 using its specific cutting force kc. A free cnc machining: speeds, feeds & tool wear tool. Pure copper's kc (~1,300 N/mm²) overstates how 'easy' it is: the power is modest but the material smears, so finish quality depends far more on edge sharpness than on the wattage you throw at it. For neighbouring scenarios, the related tools below cover the same engine with different presets.

Does it support both metric and imperial units?+

Yes — the SI ⇄ Imperial toggle converts the values already in the fields, preserving the physical quantity, so you can flip mid-calculation without re-entering anything.

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