RERATING.pdf

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N. Al-Khirdaji, AZTech Sr. Consultant 1 4.1 Rerating Piping and Pressure Vessels • Overview • Guidelines Minimum Required Thickness Determination Regulatory Requirements Major Piping Inspection Codes API 570 Piping Inspection Code Underlying Corrosion Underlying Design Standards New Construction Corrosion Mitigation Standards Quality Safety Other Inspection Codes / Documents ASMEB16.34 Valves - Flanged Threaded and Welding ends API 651 Cathodic Protection of Aboveground Storage Tanks NACE RP0169 Control of External Corrosion on Underground or Submerged Metallic Piping Systems ASME BPVC Sec IX, "Welding and Brazing Qualifications" API RP 750 Management of Process Hazards Of Materials API 510 Pressure Vessel Inspection Code ASME BPVC Sec VIII, Division 1 & 2 Pressure Vessels R:0170 Protection of Austenitic Stainless Steels from Polythionic Acid Stress Corrosion Cracking During NACE RP0274 High-Voltage Electrical Inspection of Pipeline Coatings Prior to CP-189 Standard for Qualification and Certification of Nondestructive Testing Personnel NFPA 704 Identification of the Fire Hazards of Materials API RP 574 Inspection of Piping System Components Shutdown of Refinery Equipment Coatings Prior to Installation ASME B31.3 Process Piping Application of Organic Coatings to the External Surface of Steel Pipe for Underground Piping SNT-TC-1A API 598 Valve Inspection and Testing Notes: 1. The source of this data is from API Standard 570 "Piping Inspection Code", Second Edition October 1998, Section2 "References"; 2. API 570 references directly all of the standards shown on this diagram and they are applicable and mandatory under the appropriate conditions as indicated in API 570. 3. API Standards are revised, reaffirmed, or withdrawn at least every 5 years. 4. API Standards, revision or addenda are effective 6 months after the date of issuance

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Piping and Pressure Vessels

Transcript of RERATING.pdf

N. Al-Khirdaji, AZTech Sr. Consultant 1

4.1 Rerating Piping and Pressure Vessels

• Overview• Guidelines• Minimum Required Thickness Determination• Regulatory Requirements

Major Piping Inspection CodesAPI 570

Piping Inspection Code

Underlying CorrosionUnderlyingDesign StandardsNew Construction

CorrosionMitigation Standards

Quality Safety Other InspectionCodes / Documents

ASMEB16.34Valves - Flanged

Threaded andWelding ends

API 651Cathodic Protection ofAboveground Storage

Tanks

NACE RP0169Control of External

Corrosion onUnderground or

Submerged MetallicPiping Systems

ASME BPVC Sec IX,"Welding and Brazing

Qualifications"

API RP 750Management ofProcess Hazards

Of Materials

API 510Pressure VesselInspection Code

ASME BPVC Sec VIII,Division 1 & 2

Pressure Vessels

R:0170Protection of

Austenitic Stainless Steels from Polythionic Acid Stress Corrosion

Cracking DuringSh d f

NACE RP0274High-Voltage ElectricalInspection of Pipeline

Coatings Prior to

CP-189Standard for Qualification

and Certification ofNondestructive Testing

Personnel

NFPA 704Identification ofthe Fire Hazards

of Materials

API RP 574Inspection of Piping

SystemComponents

Shutdown ofRefinery Equipment

Coatings Prior toInstallation

ASME B31.3Process Piping

Application of OrganicCoatings to the

External Surface ofSteel Pipe for

Underground Piping

SNT-TC-1A API 598Valve Inspection

and Testing

Notes:1. The source of this data is from API Standard 570 "Piping Inspection Code", Second

Edition October 1998, Section2 "References";2. API 570 references directly all of the standards shown on this diagram and they are

applicable and mandatory under the appropriate conditions as indicated in API 570.3. API Standards are revised, reaffirmed, or withdrawn at least every 5 years.4. API Standards, revision or addenda are effective 6 months after the date of issuance

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Piping System Management CyclePrioritizePipes ForAnalysisMonitoring

Techniques

InspectionTechniques

RepairRehabilitate

Replace

InspectionAnd dataGathering

C t f

Data GatheringMethods

ProbabilityOf Failure

DecisionMaking

ConditionAssessment

ConsequencesOf Failure

AvailableFunds

Cost ofRenewal

DeteriorationRates

FailureMechanisms

Rerating• Rerate. A change in either or both the

d i t t th idesign temperature or the maximum allowable working pressure.

• Existing piping systems or pressure equipment might require rerating to accommodate new operational needs (or toaccommodate new operational needs (or to accommodate deterioration that cannot or will not be repaired).

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Rerating - 2

• Frequently when debottlenecking process plant i t th ibilit f i i thequipment, the possibility of increasing the

equipment's design temperature, design pressure, or both comes up. This process of re-evaluating the equipment for more severe design conditions is usually referred to as uprating.

Rerating - 3

• In other cases, after a piece of equipment or i i t h b i i f bpiping system has been in-service for a number

of years and corrosion has taken its toll, it may be necessary to re-evaluate whether the equipment has sufficient corrosion allowance until the next inspection or whether the equipment should be retired from service.

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Rerating - 4

• Rather than assuming that the piece of equipment must be replaced when its corrosion allowance ismust be replaced when its corrosion allowance is used up, it may be worthwhile to investigate deratingthe equipment to allow its continued use although at somewhat less severe design conditions.

• In some cases the term rerating of the equipment may also be used to cover changing the throughput oralso be used to cover changing the throughput or service of the equipment.

Rerating of Piping Systems• API 570 Piping inspection code: Inspection, repair,

alteration and rerating of in-service piping systemsalteration, and rerating of in service piping systems covers the inspection, repair, alteration and re-rating procedures for in-service metallic piping systems.

• The code establishes the requirements and guidelines that allow the owners and users of piping systems to maintain the safety and mechanical integrity of systems after they have been placed into servicesystems after they have been placed into service

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Rerating Definition

• Section 3 of API 570 - “Definitions” states the definitions that apply to this code They include thedefinitions that apply to this code. They include the following definitions that pertain to rerating:

“Rerating [3.39]: A change in either or both the design temperature or the maximum allowable working pressure of a piping system. A rerating may consist of an increase a decreaseA rerating may consist of an increase, a decrease, or a combination of both. Derating below original design conditions is a means to provide increased corrosion allowance”.

MAWP Determination - 1• Maximum Allowable Working Pressure: (MAWP)

[3 21]: The maximum internal pressure permitted in[3.21]: The maximum internal pressure permitted in the piping system for continued operation at the most severe condition of coincident internal or external pressure and temperature (minimum or maximum) expected during service.

• It is the same as the design pressure, as defined in ASME B31 3 and other code sections and is subjectASME B31.3 and other code sections, and is subject to the same rules relating to allowances for variations of pressure or temperature or both

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MAWP Determination - 2

• MAWP for the continued use of piping systems shall b bli h d i h li bl dbe established using the applicable code.

• Computations may be made for known materials if all the following essential details are known to comply with the principles of the applicable code:a. Upper and/or lower temperature limits for specific materials.b. Quality of materials and workmanship.Q y pc. Inspection requirements.d. Reinforcement of openings.e. Any cyclical service requirements.

MAWP Determination - 3• For unknown materials, computations may be made

assuming the lowest grade material and jointassuming the lowest grade material and joint efficiency in the applicable code. – When the MAWP is recalculated, the wall thickness used

in these computations shall be the actual thickness as determined by inspection (see 5.6 for definition) minus twice the estimated corrosion loss before the date of the next inspection (see 6.3).

• Allowance shall be made for the other loadings in accordance with the applicable code.– The applicable code allowances for pressure and

temperature variations from the MAWP are permitted provided all of the associated code criteria are satisfied.

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Retirement Thickness Determination - 1

• The minimum required pipe wall retirement q p pthickness shall be equal to or greater than the minimum required thickness, or retirement thickness, and shall be based on pressure, mechanical, and structural considerations using the appropriate design formulae and

d ll blcode allowable stress. • Consideration of both general and localized

corrosion shall be included

Retirement Thickness Determination - 2

• For services with high potential consequences if failure were to occur, the piping engineer should consider increasing the required minimum thicknessabove the calculated minimum thickness to provide for unanticipated or unknown loadings, undiscovered metal loss, or resistance to normal abuse.

• In this case, the retirement thickness shall be used in ,lieu of the minimum required thickness in 7.1.1 for remaining life calculations

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Rerating RequirementsAPI 570 - Sub-Section 8.3

• Rerating piping systems by changing the temperature rating or the MAWP may be donetemperature rating or the MAWP may be done only after all of the following requirements have been met:a. Calculations are performed by the piping engineer or

the inspector.b. All reratings shall be established in accordance with the

requirements of the code to which the piping system q p p g ywas built or by computation using the appropriate methods in the latest edition of the applicable code.

c. Current inspection records verify that the piping system is satisfactory for the proposed service conditions and that the appropriate corrosion allowance is provided.

Rerating RequirementsAPI 570 - Sub-Section 8.3

d. Rerated piping systems shall be leak tested in d i h h d hi h h i iaccordance with the code to which the piping system

was built or the latest edition of the applicable code for the new service conditions, unless documented records indicate a previous leak test was performed at greater than or equal to the test pressure for the new condition. An increase in the rating temperature that does not affect allowable tensile stress does not require a leak testallowable tensile stress does not require a leak test.

e. The piping system is checked to affirm that the required pressure relieving devices are present, are set at the appropriate pressure, and have the appropriate capacity at set pressure.

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Rerating RequirementsAPI 570 - Sub-Section 8.3

f. The piping system rerating is acceptable to the inspector or piping engineer.p p g g

g. All piping components in the system (such as valves, flanges, bolts, gaskets, packing, and expansion joints) are adequate for the new combination of pressure and temperature.

h. Piping flexibility is adequate for design temperature changes.

i A i i i d d di. Appropriate engineering records are updated.j. A decrease in minimum operating temperature is

justified by impact test results, if required by the applicable code.

Use of API 579 Procedure For Rerating

• For rerating pressure vessels and piping, the following expressions apply:following expressions apply:MAWPr = MAWP (RSF/RSFa) for RSF < RSFa MAWPr = MAWP for RSF ≥ RSFa

• RSF is the remaining strength factor , which is defined as: RSF = LDC/LUC• LDC is the limit or plastic collapse load of the damaged p p g

component, and • LUC is the limit or plastic collapse load of the undamaged

component.

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Use of API 579 Procedure For Rerating

• MAWPr is the reduced maximum allowable working pressure,

• MAWP the original maximum allowable working pressure, and

• RSFa is the allowable remaining strength factor (typically 0 9)factor (typically 0.9).

Evaluation of Inspection DataMAWP Calculations Using Corrosion Half-life Concept

Example 1:Design Pressure: 500 psigg p gDesign Temperature: 400°FPipe Material A 106 Gr. BPipe Size: NPS 16Allowable Stress: 20,000 psi (from B31.3)Longitudinal Weld Efficiency: 1.0 (A 106 Gr. B is

seamless pipe)Thickness Measured During Inspection: 0.32 in.Observed Corrosion Rate: 0.01 in./yearNext Planned Inspection: 5 years

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Evaluation of Inspection DataMAWP Calculations Using Corrosion Half-life Concept

Estimated thinning until next inspection = 5 x 0.01 = 0.05in.(5 x 0.254 = 1.27mm)

MAWP = 2SEt/D (From ASME B31.3)= 2 x 20,000 x 1 x (0.32 – 2 x 0.05) /16= 550 psig (3747 kPa )

Since the MAWP > 500 (system design pressure), the system may remain in service at the design pressure without repairs, replacements, or rerating.

= 550 psig (3747 kPa )

Evaluation of Inspection DataMAWP Calculations Using Corrosion Half-life ConceptExample 2:Next planned inspection 7 yrs. Ne t p a ed spect o 7 y s.Estimated corrosion loss by date

of next inspection = 7 X 0.01 = 0.07 in.(7 x 0.254 = 1.78mm)

MAWP = 2SEt/D= (2 x 20,000 x 1 x (0.32 – 2 x 0.07) /16)

MAWP 450 i (3104 kP )MAWP = 450 psig (3104 kPa)

Conclusion: Must reduce inspection interval or determine that normal operating pressure will not exceed this new MAWP during the 7th year, or renew the piping before the 7th year.

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Rerating a Piping System• Operators may reduce the maximum allowable

operating pressure of defective pipe to a safe level instead of permanently repairing the pipe This isinstead of permanently repairing the pipe. This is conditional on demonstrating that a safe operating pressure can be calculated under accepted engineering guidelines based on the remaining strength of the corroded pipe (e.g., ASME B31.G)

• Rerating can be used both to increase design d d l dpressure and temperature, and also to decrease

design pressure and temperature to increase the available wall thickness for corrosion/erosion allowance.

Rerating a Piping System - 2• Inspection, repair, alteration, and rerating of in-

service piping systems are normal activities that p p g ymust be dealt with in process plants.

• Requirements and procedures are necessary in carrying out these activities to ensure that piping system integrity is maintained.

• API 570 is the industry standard that is used to 7 s e dus y s d d s used oform the basis for more detailed procedures that must be developed by process plant owners.

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Rerating a Piping System

• Rerating an existing piping system is ti ll d i i th t fessentially redesigning the system for new

design/service conditions.• The new design and service conditions must be

specified.• The anticipated new corrosion rate must be• The anticipated new corrosion rate must be

determined.

Fluid Properties and CharacteristicsThe following information must be specified:

• Chemical composition, material safety data sheet(MSDS) chemical formula(MSDS), chemical formula.

• Chemical reaction. If the fluid involves a reaction,note whether the reaction is exothermic orendothermic.

• Moisture content in the fluid. Design value andnormal range.g

• Characteristics of the feed. Viscosity, cohesion, flowability, reactivity, change in composition, toxicity, flammability.

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Service and Design Conditions

Design pressure - As defined in ASME 31.3 para. 301 2: The design pressure of each component in a301.2: The design pressure of each component in a piping system shall be not less than the pressure at the most severe condition of coincident internal or external pressure and temperature (minimum or maximum) expected during service, except as provided in ASME B31.3 para. 302.2.4. See also p pASME B31.3 para. 301.2.1 and para. 301.2.2.

Service and Design Conditions - 2• Design temperature - As defined in ASME B31.3 para.

301.3: The design temperature of each component in a piping system is the temperature at which, under the p p g y p ,coincident pressure, the greatest thickness or highest component rating is required in accordance with para. 301.2. (To satisfy the requirements of para. 301.2 different components in the same piping system may have different design temperatures.).

• In establishing design temperatures, consider at least the fluid temperatures ambient temperatures heating orfluid temperatures, ambient temperatures, heating or cooling medium temperatures, and the applicable provisions of ASME B31.3 paras. 301.3.2, 301.3.3 and 301.3.4. See also ASME B31.3 para. 301.3.1.

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Use of API 579 Procedure For Rerating

• For rerating pressure vessels and piping, the following expressions apply:following expressions apply:MAWPr = MAWP (RSF/RSFa) for RSF < RSFa MAWPr = MAWP for RSF ≥ RSFa

• RSF is the remaining strength factor , which is defined as: RSF = LDC/LUC• LDC is the limit or plastic collapse load of the damaged p p g

component, and • LUC is the limit or plastic collapse load of the undamaged

component.

Use of API 579 Procedure For Rerating

• MAWPr is the reduced maximum allowable working pressure,

• MAWP the original maximum allowable working pressure, and

• RSFa is the allowable remaining strength factor (typically 0 9)factor (typically 0.9).

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Piping Stress Analysis• Performing a piping stress analysis is not normally

a part of inspection and maintenance. However, t l i id ti t till b k t istress analysis considerations must still be kept in

mind.– The pipe must be adequately supported to carry its

weight. Locations where supports have become damaged or are otherwise ineffective should be identified for further evaluation or repair.

– Adequate flexibility to accommodate thermal displacements must be provided. Identify situations where thermal expansion might be restricted (e.g., due to interference by adjacent items).

Piping Stress Analysis - 2

– The pipe must not vibrate excessively, since this could cause leakage at flanged joints and threadedcould cause leakage at flanged joints and threaded connections, or cause a fatigue failure.

– A new stress analysis may be required if the design conditions are changed (e.g., due to equipment rerate) or if the system is modified (e.g., adding a new equipment item with associated piping to thenew equipment item with associated piping to the system).

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Pressure Testing• Except where local jurisdictions require it,

pressure tests are not normally done as part of a routine inspection. When pressure tests are done (e.g., after alterations) they should be based on the following:– Must meet (e.g. ASME B31.3) requirements.– Test fluid must be water unless this would have adverse

consequences (e g freezing process contaminationconsequences (e.g., freezing, process contamination, water disposal problem).

– Stainless steel piping requires special attention (e.g., potable water and blown dry).

Requirements for Rerating• The following requirements must be met to

permit rerating a piping system to a newpermit rerating a piping system to a new design temperature or MAWP:– Design evaluations must be done by the piping

engineer or inspector to verify the system for the new conditions.Th ti t t th i t f– The rerating must meet the requirements of either the original construction code or the latest edition of that code.

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Requirements for Rerating - 2

– Current inspection data must verify that the system is adequate for the proposed conditions and hasis adequate for the proposed conditions and has sufficient remaining corrosion allowance.

– The system must be pressure tested for the new conditions, unless records indicate that a previous test was done at a pressure that was greater than or equal to that required for the new conditionsequal to that required for the new conditions.

Requirements for Rerating - 3

– The safety valves must be reset for the new design pressure and confirmed to have adequate relievingpressure and confirmed to have adequate relieving capacity.

– The rerating must be acceptable to the inspector or piping engineer.

– All components in the system (e.g., valves, flanges bolts gaskets etc ) must be checked andflanges, bolts, gaskets, etc.) must be checked and found to be acceptable for the new design conditions.

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Requirements for Rerating - 4

– Piping flexibility is adequate for the new design temperature New calculations may be required totemperature. New calculations may be required to confirm this.

– The engineering records for the system must be updated.

– A decrease in the minimum operating temperature is justified by impact test results (or exemptions) ifis justified by impact test results (or exemptions) if required by the code.

Temperature Uprating Considerations

• The flange pressure-ratings may decrease too• The flange pressure-ratings may decrease too much as the temperature increases.

• The higher temperature may cause problems with:– thermal expansion of the piping and related stresses.– Corrosion rates may also go up as the temperature is

increased. – In some cases temperature limits on various types of

construction should also be considered, such as temperature limits for slip-on flanges, gasket type, bolting, painting, and insulation.

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Rerating Documentation

• The old and new design conditions • The Code used for the rerate • The allowable stresses and joint efficiencies • The minimum required thicknesses vs. the

existing thicknesses for each component ff t d b th taffected by the rerate

Rerating Documentation - 2

• The remaining life of each component • The required inspection interval determined • Any physical modifications required • Any requirements for pressure testing, such as

test pressure and temperature

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TSSA Guidelines for Registration of Piping

• Anyone, or any company, intending to design, fabricate and/or install a piping assembly infabricate, and/or install a piping assembly in Ontario should first refer to the Ontario Regulations made under the Technical Standards and Safety Act, 2000, which govern such actions. The Act and Regulations require compliance with the applicable CSA Standards, ASME and ANSI Codes and reference should also be made to theseCodes and reference should also be made to these standards.

• Modification or alteration (rerating) to an existing system that include a change in design pressure and temperature requires re-registration.

TSSA Guidelines for Registration of Piping - 2

• Submissions:• Drawings (flow diagrams, piping and

installation drawings) shall be submitted in triplicate, together with one copy of the system specifications and a letter of application requesting registration.application requesting registration.

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TSSA Guidelines for Registration of Piping - 3

• General Inromation:• Construction Code Information latest Edition andConstruction Code Information latest Edition and

Addenda (i.e. ANSI B31.1, B31.3 or B31.5) (excludes B31.9 Building Services Piping);

• Design Pressure;• Design Temperature;• Test Pressure and Type of Test;yp ;• Service Fluid Information (e.g. Air, Water, Steam

or specific Gas or Liquid);• Safety/Relief Valve Setting and Location; or• Statement regarding overpressure protection

TSSA Guidelines for Registration of Piping - 4

• Specifications:• Pipe specification shall indicate, as a minimum, the

following:• Pipe line identification;• Pipe size and schedule;• Pipe material (in accordance with ASME or ASTM p (

material specification);

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TSSA Guidelines for Registration of Piping- 5

• Fitting(s) classification, identification and rating (for details see TSSA’s Guidelines for the Registration of Non-Nuclear gFittings in the Province of Ontario, also note Appendix “E” of this Guideline, for the requirements for flexible hose assemblies);

• Statement attesting that only registered fittings are used;• Pipe joining methods and details (welding, brazing, or others);• Non-destructive examination (NDE);• Statement describing maximum support spacing and type, and

anchor location.