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ISO 2768 General Tolerances Calculator

Instantly compute tolerance bands, verify measured parts, and assess DfM cost impact.

Dimension Type

Lengths, diameters, steps - the most common drawing dimension.

Tolerance Class
Medium - Recommended Default

Standard CNC milling & turning. Best balance of precision and manufacturing cost. The correct default for the vast majority of machined features.

Value (mm)

Enter nominal drawing dimension in mm.

Enable measured value check

Compare an actual measured dimension against the computed limits.

Downloadable General Tolerance Sheets
ISO 2768 General Tolerances Quick Reference Chart
ISO 2768 QA Inspection Reference Card
ISO 2768 vs ISO 286 — When to Use Each Standard
ISO 2768 Bilateral Tolerance

±0.30 mm

mm - nominal 50 mm, class m

Upper Limit (Max)

50.300

Lower Limit (Min)

49.700

Tolerance Zone Preview

50 ±0.3 mm ±0.3 ±0.3 50 mm nominal - symmetric deviation 50 ±0.3 mm ±0.3 ±0.3 50 mm nominal - symmetric deviation
ISO 2768-1 Reference Matrix Active range highlighted
Nominal Range (mm) f - Fine m - Medium c - Coarse v - V. Coarse
0.5 – 3 ±0.05 ±0.1 ±0.2
>3 – 6 ±0.05 ±0.1 ±0.3 ±0.5
>6 – 30 ±0.1 ±0.2 ±0.5 ±1
>30 – 120 ±0.15 ±0.3 ±0.8 ±1.5
>120 – 400 ±0.2 ±0.5 ±1.2 ±2.5
>400 – 1000 ±0.3 ±0.8 ±2 ±4
>1000 – 2000 ±0.5 ±1.2 ±3 ±6
>2000 – 4000 ±2 ±4 ±8

What is ISO 2768 and When Do You Need It?

ISO 2768 defines general tolerances for linear dimensions, external radii, chamfer heights, and angular dimensions on engineering drawings — specifically for features where no individual tolerance is explicitly stated. It simplifies drawings by letting a single title-block notation (e.g. ISO 2768-m cover every non-critical dimension, eliminating the need to annotate every feature individually.

Part 1: Dimensions

Part 1: Dimensions

Controls linear lengths, diameters, radii, and angles. Four classes: f, m, c, v. No datum references required.

Part 2: Geometry

Part 2: Geometry

Controls form tolerances — flatness, straightness, circularity, run-out. Three classes: H, K, L. Separate from Part 1.

When to Override

When to Override

Critical interfaces — bearing seats, press fits, sealing surfaces — must have explicit tolerances stated directly on the drawing face.

Frequently Asked Questions

What is the difference between ISO 2768-1 and ISO 2768-2?

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ISO 2768-1 covers general tolerances for linear and angular dimensions on features where no explicit tolerance is shown: lengths, radii, chamfer heights, and angles. It defines four accuracy classes (f, m, c, v) and requires no datum references.

ISO 2768-2 is a separate standard governing geometric form tolerances — straightness, flatness, circularity, cylindricity, and run-out — using three classes (H, K, L). Both are commonly referenced together in a drawing title block, for example ISO 2768-mK, to provide full coverage for both dimensions and form. The two parts control completely different error types and are independently specified.

Standard Controls Classes Datum Required
ISO 2768-1 Linear dims, radii, chamfers, angles f, m, c, v No
ISO 2768-2 Flatness, straightness, circularity, run-out H, K, L Yes (for position)

Which tolerance class should I specify for a standard CNC machined feature?

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Class m (Medium) is the correct default for the vast majority of CNC milling and turning features. It reflects the natural accuracy envelope of modern 3-axis machine tools under standard production conditions, without requiring special fixturing, temperature control, or inspection routines.

Class Name Suitable Process Cost vs. Class m Default for
f Fine Precision CNC +30–60% Critical mating surfaces only
m Medium Standard CNC milling/turning Baseline General machined features
c Coarse Sheet metal, basic fabrication -20–40% Non-critical holes, flanges, bends
v Very Coarse Sand casting, forging, flame cut -40–60% Cast and forged structural profiles

Specifying class f for non-critical features adds cycle time, tooling qualification overhead, and inspection cost without functional benefit. For cost-sensitive parts, cross-reference tolerance selection against the DfM ebook on Xometry Pro before finalising the drawing.

Why do angular tolerances tighten as the leg length decreases?

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This follows from basic trigonometry. The linear positional error at the end of an angle leg equals the leg length multiplied by the sine of the angular deviation. A short leg amplifies angular error into a large linear consequence at the measured surface. A long leg geometrically dilutes the same angular error.

ISO 2768-1 compensates by assigning tighter degree tolerances to shorter legs, keeping the maximum linear consequence of any angular variation within a consistent practical band.

Shortest Leg (mm) Class m Angular Tolerance Equivalent Linear Error at Leg End (class m)
Up to 10 ±1° ±0.17 mm at 10 mm
>10 to 50 ±0°30′ ±0.44 mm at 50 mm
>50 to 120 ±0°20′ ±0.70 mm at 120 mm
>120 to 400 ±0°10′ ±1.16 mm at 400 mm
>400 ±0°5′ Same order at large scale

This design produces roughly consistent linear consequence regardless of leg length, which is the practical intent of the standard.

What should I do when ISO 2768 tolerances are too loose for a critical feature?

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Declare an explicit tolerance directly on the drawing for that specific feature. ISO 2768 is a catch-all baseline — it is overridden entirely by any feature-level annotation. Three main tools apply depending on the requirement:

Requirement Tolerancing Approach Example Notation
Precision bore/shaft fit (clearance, transition, interference) ISO 286 limits and fits H7/g6, K7, p6
Dimensional coordinate tolerance Bilateral explicit ±0.010 mm
Positional or form accuracy GD&T with datum ⌀0.02 (M) A B
Surface interface (seal groove, bearing seat) ISO 286 + surface finish N7, Ra 0.8

How does ISO 2768 relate to GD&T (Geometric Dimensioning and Tolerancing)?

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ISO 2768-1 controls size and angular dimensions. GD&T (per ISO 1101 or ASME Y14.5) controls form, orientation, location, and run-out — the geometric relationship between features. They are complementary, not competing.

ISO 2768-2 provides a simplified substitute for GD&T form tolerances when the full datum reference framework of ISO 1101 is not warranted. Most industrial parts use a combination: ISO 2768-m(K) in the title block as the general baseline, with GD&T callouts added only on features where geometric accuracy is functionally critical.

The key rule: any explicit ISO 1101 / GD&T callout on a feature overrides the ISO 2768-2 general form tolerance for that feature, just as an explicit size tolerance overrides ISO 2768-1.

Can I use ISO 2768 tolerances to verify a part on the shop floor?

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Yes. The QA Inspection mode in this calculator automates the check. Enter the nominal dimension, select the drawing class, enable QA mode, and enter the measured value. The tool returns PASS or FAIL with the deviation from the nearest limit.

Manual calculation procedure if checking without the tool:

  1. Identify nominal dimension and ISO 2768 class from the drawing title block
  2. Determine dimension type (linear, radius, angular)
  3. Read ± tolerance from the standard table for the correct nominal range
  4. Upper limit = nominal + tolerance, Lower limit = nominal – tolerance
  5. Part passes if measured value falls between the two limits

What is the difference between ISO 2768 and ISO 286?

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Both are dimensional tolerancing standards but they apply at different levels of the same drawing and control different things.

Property ISO 2768-1 ISO 286-1
Applied via Title block callout Feature annotation (e.g., 25H7)
Controls All unspecified dimensions Specific bore/shaft fit precision
Tolerance type Bilateral ±band Unilateral upper + lower deviations
Datum required No No (size); Yes (when position GD&T added)
Overrides the other Never — is the baseline Yes, always overrides ISO 2768 on that feature
Typical use General milled features Bearing seats, press fits, sliding clearances

Use ISO 2768 as the drawing baseline. Apply ISO 286 notation on any feature where fit precision directly affects assembly performance.

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