Load Moment Check — Loader Crane (t·m Rating)

Working load moment vs the loader crane (t·m rating) rating — the number the whole chart hangs on.

Gross load (t)Working radius (m)Rated load moment (t·m)

Working moment (t·m)

Moment utilization (%)

Knuckle-boom ratings ARE moment ratings — 24 t·m delivers 3 t at 8 m or 1.2 t at 20 m with extensions. Every hydraulic extension adds dead boom weight that subtracts from net moment; the practical chart of a fully-extended loader is thinner than the brochure's headline suggests.

Formula

M = W × r vs rated t·m

References: EN 13001 / EN 14439 — Crane design & tower crane standards; ASME B30.5/B30.9/B30.20 — Cranes, slings and below-the-hook devices

Note: Rigging and crane decisions are life-safety critical. This calculator is a planning aid — the load chart, sling tags, site lift plan and a qualified lift director govern every real lift.

Working load moment vs the loader crane (t·m rating) rating — the number the whole chart hangs on. A free crane load, wind & rigging safety tool — no sign-up, no upload, instant results in your browser.

About Load Moment Check — Loader Crane (t·m Rating)

Load Moment Check — Loader Crane (t·m Rating) computes the governing relationship M = W × r vs rated t·m live as you type. Knuckle-boom ratings ARE moment ratings — 24 t·m delivers 3 t at 8 m or 1.2 t at 20 m with extensions. Every hydraulic extension adds dead boom weight that subtracts from net moment; the practical chart of a fully-extended loader is thinner than the brochure's headline suggests. 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 Load Moment Check — Loader Crane (t·m Rating)

1Enter your values — Gross load, Working radius, Rated load moment (sensible defaults are pre-filled).
2Read the live results: Working moment, Moment utilization.
3Check the "with your numbers" line to see M = W × r vs rated t·m substituted step by step.
4Adjust inputs until the scenario matches yours, then copy or share the result.

Why use Load Moment Check — Loader Crane (t·m Rating)?

✓Instant, free and private — every calculation runs client-side in your browser; nothing is uploaded
✓Built on the stated formula M = W × r vs rated t·m with authoritative sources cited on the page (EN 13001 / EN 14439 — Crane design & tower crane standards; ASME B30.5/B30.9/B30.20 — Cranes, slings and below-the-hook devices)
✓Knuckle-boom ratings ARE moment ratings — 24 t·m delivers 3 t at 8 m or 1.2 t at 20 m with extensions.
✓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 load moment check — loader crane (t·m rating) use?+

It evaluates M = W × r vs rated t·m, exactly as published. Sources: EN 13001 / EN 14439 — Crane design & tower crane standards; ASME B30.5/B30.9/B30.20 — Cranes, slings and below-the-hook devices. 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?+

Knuckle-boom ratings ARE moment ratings — 24 t·m delivers 3 t at 8 m or 1.2 t at 20 m with extensions. Rigging and crane decisions are life-safety critical. This calculator is a planning aid — the load chart, sling tags, site lift plan and a qualified lift director govern every real lift.

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

Working load moment vs the loader crane (t·m rating) rating. Every hydraulic extension adds dead boom weight that subtracts from net moment; the practical chart of a fully-extended loader is thinner than the brochure's headline suggests. 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.

Related tools

Related Manufacturing tools

⚙️

Spindle Speed Calculator — Aluminum 6061

Carbide starting RPM for milling Aluminum 6061: n = 1000·Vc/(π·D) with a handbook cutting speed preset.

● Live

⚙️

Spindle Speed Calculator — Mild Steel 1018

Carbide starting RPM for milling Mild Steel 1018: n = 1000·Vc/(π·D) with a handbook cutting speed preset.

● Live

⚙️

Spindle Speed Calculator — Stainless 304

Carbide starting RPM for milling Stainless 304: n = 1000·Vc/(π·D) with a handbook cutting speed preset.

● Live