SVP Technology & Market Development
VP LTM Business Development Region
Manager Local Technical Marketing
Boilers are designed to operate under stable condition. But in today’s industrial reality – where plants face unplanned outages, reduced loads, and frequent cycling – boilers are increasingly operating outside their comfort zone.
What many operators underestimate is that the most severe damage to a boiler often does not occur during operation, but during shutdown, preservation, and restart. This was the central message of Kurita’s recent webinar “Boilers Under Stress: Safe Shutdown, Preservation & Restart“.
Here’s what every plant manager, reliability engineer, and boiler operator should know.
Shutdown: The Most Overlooked High-Risk Phase
In day-to-day operation, boiler systems benefit from:
- Controlled temperatures and pressures
- Continuous circulation
- Carefully managed water chemistry
During shutdown, these safeguards are weakened or disappear altogether.
Shutdowns are risky for two main reasons:
- They are not routine. Operators are well trained for steady operation and upset conditions, but shutdown and preservation procedures are often less standarised or inconsistently applied.
- The financial impact of getting it wrong is massive. Corrosion damage initiated during shutdown typically becomes visible only after restart – when pressure, temperature, and flow return. At that point, consequences can include forced outages, tube failures, multi-day downtime, and permanent efficiency losses.
In many real cases, a €50,000 investment in proper preservation prevents millions in repair and production losses.
What Really Happens Inside a Boiler During Shutdown
Several corrosion mechanisms are triggered when boilers stop or operate at low road. Worse, many occur simultaneously.
Oxygen Pitting: Small Traces, Big Consequences
Even very small amounts of oxygen entering a boiler during shutdown can lead to deep pitting corrosion. These pits act as a crack initiation points and often evolve into stress corrosion cracking during restart.
Under-Deposit Corrosion: Hidden but Aggresive
When circulation slows, suspended solids settle on metal surfaces. Under these deposits:
- Oxygen concentrates
- Local pH drops
- Chlorides accumulate
Bulk water analysis, may look fine, while sever local corrosion is already progressing.
Flow-Accelerated Corrosion After Restart
Magnetite layers formed during normal operation soften during shutdown. When flow returns, especially in elbows, economisers, and high-velocity zones, metal loss can accelerate rapidly.
The Silent Problem: You Don't See It Until It's Too Late
A critical takeaway from the webinar is this:
Most shutdown-related corrosion remains invisible until restart.
Water chemistry may appear acceptable. Visual inspection may show nothing unusual. Damage only becomes clear once the system is back under thermal and mechanical stress.
Why Traditional Preservation Often Falls Short
Conventional preservation methods – high oxygen scavenger dosing, phosphate programs, nitrogen blanketing – focus mainly on wet areas of the boiler.
Their limitations:
- Vapour spaces, steam lines, and condensate systems remain vulnerable
- Nitrogen protection ends the moment blanketing stops
- High inorganic loading increases conductivity and blowdown
- Startups are slow, with high iron levels and delayed steam purity
These weaknesses become critical and cyclic operation or standby boilers, now increasingly common in power and industrial plants.
Cetamine® Technology: A Different Approach
What Makes It Different?
A major focus of the webinar was the use of Cetamine® Technology as a modern solution for shutdown, preservation, startup, and continuous operation.
- Forms a hydrophobic protective film directly on metal surfaces
- Film exists in both water and vapour phases
- Volatile components protect steam and condensate systems
- Same product can be used for operation, preservation, and restart
What Operators See in Practice
Plants using this approach report:
- Dramatically lower iron transport
- Reduced blowdown and faster startups
- Immediate steam quality suitable for turbines
- Lower energy and water consumption
- Protection during wet, dry, or stagnant conditions
In one real example shared during the webinar:
- Startup time dropped from ~29 hours to ~5 hours
- Iron levels fell from ~90 ppb to ~2 ppb
- Blowdown was reduced by around 40%
- Cycles of concentration increased significantly
Faster, Safer Restarts
With traditional preservation, restart often means:
- Draining and dilution
- Long blowdown periods
- Delayed turbine admission
With Cetamine® Technology:
- No draining required
- Iron levels remain low
- Steam quality is achieved much faster
- Assets experience less thermal and mechanical stress
This is especially valuable in plants facing frequent shutdown-restart cycles.
Monitoring During Preservation
Preservation strategies must be adapted to each site, but typical monitoring includes:
- pH
- Iron levels
- Residual film-forming amine
- Visual inspections or corrosion coupons where applicable
The goal is simple: confirm the protective is present and stable, even when circulation is limited or absent.
The Takeaway: Shutdown Is Not a Passive State
One message from the webinar stands out clearly:
Shutdown is not neutral condition - it is one of the highest-risk phases in a boiler's lifecycle.
Corrosion during shutdown is:
- Fast
- Often hidden
- Extremely costly if unmanaged
With proper planning, defined procedures, and modern protection strategies, operators can:
- Avoid unexpected failures
- Restart faster and safer
- Extend asset lifetime
- Reduce water, energy, and chemical consumption
Turn Shutdown Risk into Reliability
In a world of increasing operational volatility, shutdown readiness is no longer optional - it is a core element of boiler reliability and business continuity.
Watch the Webinar