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Valve Seat Leakage Classes and Acceptance Criteria

Valve seat leakage class determines the allowable leakage past a closed valve. Selecting the correct class ensures process integrity and prevents product loss or safety hazards.

Standard Leakage Classes

ANSI/FCI 70-2 defines six control valve leakage classes from Class I through Class VI. Each class specifies maximum allowable leakage as a percentage of rated valve capacity.

  • Class I: No test required; manufacturer's standard

  • Class II: 0.5% of rated capacity at maximum differential pressure

  • Class III: 0.1% of rated capacity

  • Class IV: 0.01% of rated capacity (metal seat standard)

  • Class V: 0.0005 mL/min per inch of port diameter per psi differential

  • Class VI: Bubble-tight; soft seat valves tested with air or nitrogen

On/Off Valve Leakage Standards

For isolation valves, API 598 governs seat leakage testing. It specifies shell, back seat, and closure tests with acceptance criteria based on valve size and pressure class.

  • No visible leakage: Required for metal-seated valves in many services

  • Allowable drops or bubbles: Defined by valve size (NPS) in API 598 tables

  • Soft-seated valves: Zero leakage expected at rated pressure

  • Test medium: Water for shell test; air or water for seat test

Factors Affecting Seat Leakage Performance

Surface finish, contact stress, and material hardness all influence leakage performance. Proper lapping and grinding of metal seats reduces leakage to acceptable levels.

  • Surface finish: 16–32 Ra microinch typical for metal seats

  • Contact stress: Higher actuator force reduces leakage but increases wear

  • Temperature effects: Differential thermal expansion can open or close seats

  • Erosion and corrosion: Damage seating surfaces over time, increasing leakage

Specifying Leakage Class in Procurement

Specify leakage class in valve datasheets based on process requirements. Tight shutoff valves cost more and require more precise manufacturing. Match the class to actual service needs.

  • Critical isolation: Class V or Class VI for hazardous or high-value fluids

  • Throttling service: Class IV typically acceptable for control valves

  • Low-criticality: Class II or III reduces cost without compromising function

  • Review with operations: Higher class means more maintenance over lifecycle

 
 
 

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