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Acid Dew-Point Corrosion

Time: Jul 6 2026 Views: 1

INTRODUCTION

 

Acid dew-point corrosion is one of the most critical limiting factors in low-temperature flue gas heat recovery systems.

 

It occurs when flue gas cools to a temperature where acidic vapors condense on heat transfer surfaces, leading to rapid material degradation and system failure if not properly controlled.

 

Understanding this phenomenon is essential for designing reliable and efficient heat recovery systems.

 

 

WHAT IS ACID DEW-POINT CORROSION?

 

Phase Transition of Corrosive Compounds

 

During combustion processes, flue gas contains sulfur compounds such as:

 

sulfur dioxide (SO)

sulfur trioxide (SO)

 

As the gas cools, these compounds react with moisture to form sulfuric acid vapor.

 

When the temperature drops below the **acid dew point**, this vapor condenses into liquid acid on metal surfaces.

 

This process is known as acid dew-point corrosion.

 

 

HOW IT OCCURS

 

Corrosion Formation Process

 

Step 1 Combustion Gas Formation

 

Fuel combustion produces high-temperature flue gas containing sulfur compounds.

 

 

Step 2 Cooling of Flue Gas

 

As heat is recovered, flue gas temperature decreases.

 

 

Step 3 Acid Formation

 

SOreacts with water vapor to form sulfuric acid (HSO).

 

 

Step 4 Condensation on Surfaces

 

When temperature falls below the acid dew point, acid condenses on heat exchanger surfaces.

 

 

Step 5 Material Corrosion

 

Acidic liquid aggressively attacks metallic surfaces, causing corrosion and material loss.

 

 

WHY IT IS CRITICAL IN HEAT RECOVERY SYSTEMS

 

The Efficiency vs Corrosion Trade-Off

 

Heat recovery systems aim to reduce flue gas temperature to improve energy efficiency.

 

However:

 

> Lower temperature increases heat recovery

> but also increases corrosion risk

 

This creates a fundamental engineering constraint in system design.

 

 

IMPACT ON INDUSTRIAL SYSTEMS

 

Consequences of Acid Dew-Point Corrosion

 

1. Equipment Degradation

 

Metal surfaces are progressively damaged by acidic attack.

 

 

2. Reduced Heat Transfer Efficiency

 

Corrosion and fouling reduce thermal performance over time.

 

 

3. Increased Maintenance Costs

 

Frequent inspection, repair, and replacement are required.

 

 

4. Operational Instability

 

Severe corrosion can lead to unplanned shutdowns.

 

 

5. Limited Heat Recovery Depth

 

Systems are forced to operate at higher exhaust temperatures to avoid corrosion.

 

 

KEY ENGINEERING CHALLENGE

 

Safe Heat Recovery Below the Acid Dew Point

 

The central engineering problem is:

 

> How to recover more heat without triggering corrosion failure.

 

Traditional metallic systems are limited by this boundary condition.

 

 

ENGINEERING SOLUTION APPROACH

 

Corrosion-Resistant Heat Transfer Surfaces

 

Modern solutions use advanced material systems such as:

 

Fluoroplastic-Steel Composite Structures

 

Fluoroplastic outer layer prevents acid contact

Steel core provides mechanical strength

Enables operation in corrosive low-temperature zones

 

This allows deeper heat recovery while maintaining long-term reliability.

 

 

KEY INSIGHT

 

Acid Dew Point Defines System Limits

 

The acid dew point is not just a temperature value.

 

It is a **design boundary** that determines:

 

maximum achievable heat recovery

material selection

system configuration

lifecycle performance

 

 

APPLICATION AREAS

 

Where Acid Dew-Point Corrosion Is Critical

 

Power generation flue gas systems

Chemical processing exhaust systems

Metallurgy and smelting plants

Sulfuric acid production systems

Waste acid recovery facilities

Environmental treatment systems

 

 

CONCLUSION

 

Acid dew-point corrosion is one of the most important engineering challenges in low-temperature heat recovery systems.

 

It directly determines:

 

how much energy can be recovered

how long equipment can operate

what materials must be used

 

Effective system design must address corrosion at the structural level, not as an afterthought.

 

 

CTA

 

Want to design a heat recovery system that operates safely below the acid dew point?

 

Discuss your flue gas conditions with our engineering team to identify the optimal solution.

 

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