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Let-Go vs Walk-Back Anchoring

2 February 2026 4 min read Latest Articles, On Deck
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Brake control, runaway chain, and why anchoring accidents happen in seconds

Estimated read time: 55–65 minutes
Skill level: Cadet → AB → Junior Officer → Chief Mate

Contents

  1. Introduction – Anchoring Is Not “Dropping Weight”
  2. The Windlass–Brake–Cable System
  3. Let-Go Anchoring: What Actually Happens
  4. Walk-Back Anchoring: Why It Exists
  5. Brake Physics: Holding, Slipping, Burning
  6. Runaway Chain Events (Real Failure Sequences)
  7. Human Positioning During Let-Go & Walk-Back
  8. Weather, Way On, and Load Shock
  9. Decision Rules: Which Method, When
  10. Key Takeaways

1. Introduction – Anchoring Is Not “Dropping Weight”

Anchoring looks simple from the outside.

On deck, it is one of the most violent energy transitions on the ship:

  • a moving vessel
  • a massive chain
  • friction-based braking
  • seabed engagement
  • human proximity

Most anchoring injuries and near-fatalities occur before the anchor ever touches bottom.

The problem is not the anchor.
It is loss of control during energy release.

2. The Windlass–Brake–Cable System

Anchoring is a system, not a piece of equipment.

It consists of:

  • windlass motor & gearbox
  • band brake (or disc brake)
  • cable lifter / wildcat
  • chain
  • anchor
  • seabed

The brake is the only thing preventing gravity and ship momentum from winning instantly.

A brake does not “stop” a chain.
It converts kinetic energy into heat.

This matters — because heat destroys brakes quietly.

3. Let-Go Anchoring: What Actually Happens

In a let-go:

  • brake is eased
  • anchor and chain run under gravity
  • speed is controlled manually
  • ship’s way must be minimal

What goes wrong in reality

A common real-world sequence:

  1. Ship still has slight way on
  2. Brake eased “a bit more”
  3. Chain accelerates
  4. Brake overheats within seconds
  5. Brake glaze forms
  6. Operator loses friction
  7. Chain runs uncontrollably

At this point:

  • the chain is a moving weapon
  • nobody can stop it
  • people panic and step where they shouldn’t

This is how fingers, limbs, and lives are lost.

4. Walk-Back Anchoring: Why It Exists

Walk-back anchoring uses the windlass motor to:

  • control chain speed
  • limit acceleration
  • protect the brake
  • manage energy gradually

It is not “slow anchoring”.
It is controlled anchoring.

Walk-back is safer when:

  • water is deep
  • weather is marginal
  • ship handling is complex
  • brake condition is uncertain

How walk-back still fails

Failures occur when:

  • motor is overloaded
  • operator fights the brake
  • communication breaks down
  • crew assume “motor will handle it”

Motors stall.
Brakes still matter.

5. Brake Physics: Holding, Slipping, Burning

A windlass brake works by:

  • friction
  • surface area
  • pressure

Under rapid chain movement:

  • friction generates heat
  • heat reduces friction
  • friction loss accelerates runaway

A burned brake often:

  • looks intact
  • smells “hot”
  • fails next time — not immediately

This is why many runaway incidents happen on the second anchoring, not the first.

6. Runaway Chain Events (Real Failure Sequences)

Typical real-world pattern:

  • anchoring went “a bit fast” last time
  • brake adjusted tighter to compensate
  • next anchoring loads brake harder
  • brake fails catastrophically
  • chain runs to bitter end
  • securing arrangement fails
  • structure damaged / people injured

Runaway chain events escalate too fast for reaction.

The only defence is preventing them entirely.

7. Human Positioning During Let-Go & Walk-Back

During anchoring:

  • nobody stands in line with the cable
  • nobody steps over the chain
  • nobody reaches across the wildcat
  • nobody “just clears something quickly”

Most serious injuries happen when:

“It was nearly finished.”

The danger peaks at:

  • brake adjustments
  • final scope
  • stopping the run

8. Weather, Way On, and Load Shock

Anchoring with way on multiplies load instantly.

Wind, swell, or current can:

  • snatch the cable
  • lift chain off seabed
  • reintroduce shock loads
  • overwhelm brake friction

Anchoring is not static — it is dynamic until the ship is settled.

9. Decision Rules: Which Method, When

Let-go is acceptable when:

  • way on is minimal
  • conditions are calm
  • brake is proven
  • crew are clear and disciplined

Walk-back is preferred when:

  • depth is significant
  • conditions are variable
  • traffic is heavy
  • brake condition is uncertain

Choosing the wrong method is a judgement failure, not bad luck.

10. Key Takeaways

  • Anchoring is energy release, not weight drop
  • Brakes fail through heat, not neglect
  • Let-go failures escalate instantly
  • Walk-back controls acceleration, not risk
  • Human positioning decides injury outcomes