Thrust & Torque — 9 m Rail TBM

Cutterhead thrust and torque estimate for a 9 m rail tbm.

Disc cuttersForce per cutter (kN)17-in ≈ 250 kN · 19-in ≈ 267–311 kNDiameter (m)Shield friction & drag share (%)Torque coefficient αT = α·D³ rule-of-thumb band 0.5–0.9 (soft higher)

Total thrust required (MN)

Breakout torque (MN·m)

Single-track rail bores carry the classic 19-inch/267 kN cutter spec. Torque grows with the cube-ish of diameter while thrust grows with the square — by this size, the cutterhead drive becomes the engineering showpiece.

Formula

thrust = (n·F) × (1+friction) · T ≈ α·D³

References: Maidl et al., Mechanised Shield Tunnelling, 2nd ed.; Colorado School of Mines TBM performance model

Note: Planning-level tunnelling estimate — actual TBM performance is set by detailed geotechnical baseline data, machine design and the contractor's means & methods. Use for feasibility framing only.

Cutterhead thrust and torque estimate for a 9 m rail tbm. A free tbm performance & tunnelling tool — no sign-up, no upload, instant results in your browser.

About Thrust & Torque — 9 m Rail TBM

Thrust & Torque — 9 m Rail TBM computes the governing relationship thrust = (n·F) × (1+friction) · T ≈ α·D³ live as you type. Single-track rail bores carry the classic 19-inch/267 kN cutter spec. Torque grows with the cube-ish of diameter while thrust grows with the square — by this size, the cutterhead drive becomes the engineering showpiece. 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 Thrust & Torque — 9 m Rail TBM

1Enter your values — Disc cutters, Force per cutter, Diameter, Shield friction & drag share and more (sensible defaults are pre-filled).
2Read the live results: Total thrust required, Breakout torque.
3Check the "with your numbers" line to see thrust = (n·F) × (1+friction) · T ≈ α·D³ substituted step by step.
4Adjust inputs until the scenario matches yours, then copy or share the result.

Why use Thrust & Torque — 9 m Rail TBM?

✓Instant, free and private — every calculation runs client-side in your browser; nothing is uploaded
✓Built on the stated formula thrust = (n·F) × (1+friction) · T ≈ α·D³ with authoritative sources cited on the page (Maidl et al., Mechanised Shield Tunnelling, 2nd ed.; Colorado School of Mines TBM performance model)
✓Single-track rail bores carry the classic 19-inch/267 kN cutter spec.
✓Niche-specific defaults give a meaningful worked answer the moment the page loads

Frequently asked questions

What formula does the thrust & torque — 9 m rail tbm use?+

It evaluates thrust = (n·F) × (1+friction) · T ≈ α·D³, exactly as published. Sources: Maidl et al., Mechanised Shield Tunnelling, 2nd ed.; Colorado School of Mines TBM performance model. 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?+

Single-track rail bores carry the classic 19-inch/267 kN cutter spec. Planning-level tunnelling estimate — actual TBM performance is set by detailed geotechnical baseline data, machine design and the contractor's means & methods. Use for feasibility framing only.

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

Cutterhead thrust and torque estimate for a 9 m rail tbm. A free tbm performance & tunnelling tool. Torque grows with the cube-ish of diameter while thrust grows with the square — by this size, the cutterhead drive becomes the engineering showpiece. For neighbouring scenarios, the related tools below cover the same engine with different presets.

Do I need to install anything or create an account?+

No. The tool is pure client-side JavaScript: open the page and it works, offline once loaded, with no account, no quota and no data leaving your device.

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