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Asset Integrity Management
Citation preview
Philip A. Henry, P.E. RBI Technical Advisor and Principal Engineer
The Equity Engineering Group, Inc. Shaker Heights, OH USA
Tuesday 6 March 2012 API Singapore 2012
Singapore Marina Bay Sands Resort
Asset Integrity Management Overview
Life-Cycle Management of Pressurized Fixed Equipment
2
Presentation Overview
Introduction Life-Cycle Management (LCM)
Regulatory Viewpoints
Refining & Petrochemical Industry Goals
Owner-User Goals
Cooperative Achievement of Goals
The Life-Cycle Management Process
LCM Case Study
Benefits of the LCM Process
Conclusions
3
Introduction Life-Cycle Management Many process plants continue to operate pressurized
equipment well beyond its intended design life
Owner-users of pressurized fixed equipment, including pressure vessels, piping, and tankage, are becoming increasingly interested in Life-Cycle Management (LCM) of equipment to enhance reliability and availability
LCM is the process of managing the entire life-cycle of fixed pressurized equipment from initial design, through construction and in-service use, and to retirement
Questions How do you get a LCM process started? How do you incorporate codes and standards that are not
developed by ASME or API? Is there a process that can be used as a model?
4
Regulatory Viewpoints
A US Regulators View
Safety and production are inextricably linked.good safety performance makes good business sense.stable production means reduced risks.if integrity management is sacrificed for production, production will eventually suffer and lives may be lost.
Actively manage your operations to achieve safety and environmental objectives.participate in standards development.conduct research and develop technology.share important safety information.
UK Health and Safety Commission
asset integrity will continue to be one of the main priorities .. it is for the industry itself to show leadership and face up to its responsibility.
5
Refining & Petrochemical Industry Goals
Public and workforce safety; good safety performance is a key element of good business practice
Global acceptance of industry codes and standards
Ensure safety and reduce losses through the sharing of technology and best practices that are promoted to a code or standard status
Maximize efficiency through standardization; promoting the use of industry standards wherever possible to replace in-house corporate standards
Regulatory Acceptance
6
Owner-User Goals
Industry and Owner-User goals are in alignment
Additionally, want to achieve Optimized LCM costs, a balance between construction and in-service maintenance costs
7
Cooperative Achievement of Goals
The proposal:
A LCM process can be instituted that promotes public and workforce safety and utilizes international industry codes and standards while permitting optimization of life-cycle costs for fixed pressurized equipment
The proposed LCM process Utilizes existing codes, standards and recommended
practices; international documents may be substituted based on regulatory requirements
Emphasizes proper use of these codes, standards, and recommended practices through industry committee participation and/or training
Risk management techniques may be used
8
The Life-Cycle Management Process Life-Cycle Management
(LCM) for Pressurized Fixed Equipment: Key Elements Damage Mechanism
Identification Construction Codes &
Standards In-Service Inspection Codes FFS Standard Post Construction & Repair
Guidelines
Important Aspects Standards development
including input from industry experts, owner-users and group sponsored JIPs
Proper use of standards to address safety & reliability
User training
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
9
The Life-Cycle Management Process Calibration to Industry Segments
The LCM process shown on the previous slide is calibrated to the down-stream segment in refining and petrochemical in North America Calibration of the LCM Process starts with Damage
Mechanism Identification; API 571 and WRC 489 were specifically written to address damage mechanisms affecting fixed equipment in the refining industry
ASME Construction codes are used in the down-stream segment for pressure vessels and piping and API Design and Construction codes are used for tankage and fired heater tubes
In-service inspection standards are API and NBIC Fitness-For-Service (FFS) is API/ASME Post Construction & Repair Guidelines are ASME Note that the calibration also includes location, i.e. North
America, to address regulatory requirements
10
The Life-Cycle Management Process Damage Mechanism Identification
Damage mechanisms identification is an important part of the Life-Cycle Management Process Required during the design phase, influences materials
selection Required for inspection planning Required for FFS if un-anticipated damage occurs (i.e.
damage found during inspection was not accounted for in design phase)
Understanding of damage mechanisms is also important for developing models with associated material properties for life assessment determination
These models form the basis of FFS and RBI, but can also be used in construction codes with an appropriate design margin
11
The Life-Cycle Management Process Damage Mechanism Identification
Documents covering damage mechanism identification WRC Bulletin 488 Damage Mechanisms Affecting Fixed
Equipment in The Pulp And Paper Industry
WRC Bulletin 489 & API 571 Damage Mechanisms Affecting Fixed Equipment in The Refining Industry
WRC Bulletin 490 Damage Mechanisms Affecting Fixed Equipment in Fossil Electric Power Industry
ASME PCC-3 Inspection Planning Using Risk-Based Methods (Appendices B & C)
12
The Life-Cycle Management Process Construction Codes & Standards
API Codes, Standards and Recommended Practices API produced codes, standards, recommended practices,
and technical publications cover all segment of the industry Upstream Mid-stream Downstream Pipelines
Benefits Promote the use of safe, interchangeable equipment and
operations Reduce regulatory compliance costs through standardization Form the basis of API certification programs in conjunction with
APIs Quality Program The API standards program is global, through active
involvement with the International Organization for Standardization (ISO) and other international bodies
13
The Life-Cycle Management Process Construction Codes & Standards
API Design & Construction Standards
API Std 530/ISO 13704 Calculation of Heater-Tube Thickness in Petroleum Refineries
API Std 620 Design and Construction of Large, Welded, Low-Pressure Storage Tanks
API Std 650 Welded Tanks for Oil Storage
Note the co-branding on API Std 530 with ISO
14
The Life-Cycle Management Process Construction Codes & Standards
ASME Codes and Standards ASME codes and standards are primarily used for
construction of new equipment, some of the rules in these codes are referenced by the API in-service inspection codes
ASME codes and standards are also provided for Guidelines for assembly of bolted flange joints Repair of pressure equipment and piping Risk-Based Inspection, harmonized with API Standard 580/581
ASME has also produced a guideline document to provide a summary of the codes, standards and regulations that are used to assist manufacturers, users, regulators and other stakeholders in maintaining the integrity of fixed pressure equipment in general industrial use
15
The Life-Cycle Management Process Construction Codes & Standards
ASME Codes and Standards
Pressure Vessels
ASME B&PV Code, Section VIII Division 1 Rules for Construction of Pressure Vessels
ASME B&PV Code, Section VIII - Division 2 Rules for Construction of Pressure Vessels Alternative Rules
ASME B&PV Code Section VIII Division 3 Rules for Construction of Pressure Vessels Alternative Rules for Construction of High Pressure Vessels (VIII-3)
Piping
ASME B31.1 Power Piping
ASME B31.3 Process Piping
16
The Life-Cycle Management Process In-Service Inspection Codes
In-Service Inspection Codes API 510 Pressure Vessel Inspection Code: Maintenance
Inspection, Rerating, Repair and Alteration API 570 Piping Inspection Code: Inspection, Repair Alteration
and Rerating of In-Service Piping Systems API 653 Tank Inspection, Repair, Alteration, and
Reconstruction NB-23 National Board Inspection Code
Inspection codes listed above use half-life inspection interval; also permit use of Risk-Based Inspection (RBI) planning as provided in: API RP 580 Risk-Based Inspection, 2nd Edition, 2009 API RP 581 Risk-Based Inspection Technology, 2nd Edition,
2008 ASME PCC-3 Inspection Planning Using Risk-Based Methods
17
The Life-Cycle Management Process Other Inspection Resources
Other Inspection Resources API RP 572 Inspection Practices for Pressure Vessels API RP 574 Inspection Practices for Piping Components API RP 576 Inspection of Pressure Relieving Devices
Development of the following new references is under way: API RP 583 Corrosion Under Insulation API RP 584 Integrity Operating Windows API RP 585 Pressure Equipment Investigation API RP 681 Risk-Based Inspection of Rotating Equipment
18
The Life-Cycle Management Process FFS Standard
ASME and API jointly produce a co-branded Fitness-For-Service document, API 579-1/ASME FFS-1 2007 Fitness-For-Service Incorporates planned technical enhancements to the 2000
Edition of API 579 Organized into 13 Parts that address various damage
mechanisms; 11 Annexes provide additional information and guidance on conducting stress analysis for FFS
Provides three assessment levels of increasing complexity; Level 3 permits use of alternate FFS procedures such as BS 7910 and FITNET
Includes modifications to address the needs of fossil electric power, and the pulp and paper industries
May be applied to pressure containing equipment constructed to international recognized standards
19
The Life-Cycle Management Process Post Construction Standards & Repair Guidelines
ASME Post Construction Publications ASME PCC-1 Guidelines for Pressure Boundary Bolted
Flange Joint Assembly ASME PCC-2 Standard for the Repair of Pressure Equipment
and Piping ASME PCC-3 Inspection Planning Using Risk-Based Methods ASME PTB-3 Guide to Life-Cycle Management of Pressure
Equipment Integrity Provides a roadmap to identify the codes, standards, and other
documents that apply to the LCM of pressure equipment integrity
Does not address pressure equipment in; Oil and gas exploration and production, LNG, and LPG transport and storage, Pipeline and transport service, Nuclear industry
Mainly references ASME & API Codes and Standards
20
The Life-Cycle Management Process Important Aspects
The LCM process is dependent on the existence of effective industry codes, standards, and recommended practices that is dependent on input from Owner-Users Industry Experts Regulatory Bodies Group Sponsored Joint Industry Project (JIPs)
Note that Owner-User input is critical for the successful development of industry codes and standards; this is recognized by standards writing bodies and most have active recruitment and indoctrination programs in place
Input from regulatory bodies provides the safety expectations for both the public and workforce employees
23
The Life-Cycle Management Process Technology Integration
A key aspect of the successful implementation of LCM process is consistency in the technology used for design and in-service codes and standards
Consistency in the technology avoids ambiguities that typically arise when rules for construction are used for in-service inspection, FFS, and repair
Standards writing organizations need to develop consistency in approach not only in development of construction codes, but also in the development of in-service codes such as FFS and inspection standards ASME launching common rules effort; rules in codes will be
published once and appropriately referenced Benefit to end-users, simplifies training and easier to use Owner-Users need to be involved!
24
The Life-Cycle Management Process Best Practices
The LCM Process described thus far relies on industry codes and standards
What about Best Practices instituted by corporations that do not reside in industry codes, standards or recommended practices?
Definition: For purposes of the LCM process, a Best Practice is
a technique or methodology that upon rigorous evaluation through experience and research, demonstrates success, has had an impact, and can be replicated
Many corporations document their Best Practices in internal engineering standards; these internal standards address both construction and in-service equipment issues such as inspection, FFS, and repair guidelines.
25
The Life-Cycle Management Process Best Practices
In the proposed Life-Cycle Management (LCM) for pressurized fixed equipment, a best practice is an overlay in the process based on the corporate knowledge
Best Practices in pressurized fixed-equipment technology are becoming more difficult to cultivate because of lack of expertise; owner-users must rely on industry forums and/or codes, standards and recommended practices
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
26
LCM Case Study Analysis of Tubesheet Corrosion
TEMA Class R Shell & Tube Heat Exchanger
Hydrocarbon Service Shellside Design conditions
DP: 300 psig DT: 150 F
Tubeside Design conditions DP: 800 psig DT: 550 F
Materials of Construction Shell: CS Tubesheet: CS
Design Corrosion Allowance SS: 0.125 in TS: 0.125 in
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
27
LCM Case Study Analysis of Tubesheet Corrosion
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
TEMA Class R Shell & Tube Heat Exchanger
Construction Codes ASME B&PV Code, Section
VIII, Division 1 TEMA Class R
28
LCM Case Study Analysis of Tubesheet Corrosion
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
TEMA Class R Shell & Tube Heat Exchanger
Corrosion Monitoring Locations (CML) assigned
Initial thickness readings taken at commissioning
29
LCM Case Study Analysis of Tubesheet Corrosion
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
TEMA Class R Shell & Tube Heat Exchanger
Local corrosion on the shellside of a tubesheet found during a shutdown
Unanticipated damage based on operating conditions, fluids, and materials of construction
30
LCM Case Study Analysis of Tubesheet Corrosion
31
LCM Case Study Analysis of Tubesheet Corrosion
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
TEMA Class R Shell & Tube Heat Exchanger
Damage Mechanism, accelerated corrosion from carbonic acid corrosion
32
LCM Case Study Analysis of Tubesheet Corrosion
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
FFS Assessment performed per API 579-1/ASME FFS-1,
Part 5, Level 3
3D FEA model constructed to simulate metal loss profile, worst case metal profile modeled
Comparative analysis performed between corroded and un-corroded cases
FFS assessment indicated the vessel is acceptable for continued operation based on assumptions made for the future corrosion allowance
33
LCM Case Study Analysis of Tubesheet Corrosion
34
LCM Case Study Analysis of Tubesheet Corrosion
35
LCM Case Study Analysis of Tubesheet Corrosion
Recommendations Pressure boundary and
tubesheet were suitable for four years of operation
Tubesheet corrosion did not significantly increase likelihood of flange joint leakage at channel/shell joint
Limits were placed on bolt assembly stress for any future joint assembly or re-tightening
Benefits Allowed for 4 years of
additional service until planned bundle replacement
$200K saving identified for not having to expedite bundle
No additional plant shutdowns required
Construction CodeASME VIII-1, VIII-2, VIII-3, B31.3
API 530, 620, 650
Commissioning (Baseline Inspection)
In-Service Inspection(Establish Inspection Interval)
Prescriptive (API 510/570/653,NBIC) Risk-Based (API 580/581,PCC3)
InspectionResults
Fitness-For-ServiceAPI 579/ASME FFS-1
Run/Rerate ReplaceRepair
ASME PCC2
Continue Service
Tech
nolo
gy In
tegr
atio
n
Anticipated Damage
Specify Design Conditions and Identify Damage Mechanisms(API 571 & WRC 489)
Select Materials of Construction
Identify Damage Mechanisms (API 571, WRC 488, WRC 489, WRC 490)
UnanticipatedDamage
Bes
t Pra
ctic
e
36
Benefits of the LCM Process
The proposed LCM Process is based on the use of industry codes, standards, and recommended practices as well as corporate best practices to construct and maintain in-service equipment; the inherent benefits include Improved Safety & Risk Reduction Maximizing Equipment Availability
Fewer Incidents Extended Lifetimes Shorter Turnarounds Predictable Outcomes Enhanced Plant Performance
Optimization of Maintenance and Inspection Costs Regulatory Compliance
37
Conclusions
The LCM Process for fixed pressurized equipment has been defined for the refining and petrochemical industry
Key elements parts of the LCM Process are Damage Mechanism Identification
Construction Codes & Standards
In-Service Inspection Codes
FFS Standard
Post Construction & Repair Guidelines
The LCM Process can be calibrated to other industry segments and international locations by substituting appropriate documents for the key elements described above
38
20600 Chagrin Blvd. Suite 1200 Shaker Heights, OH 44122 USA
Phone: 216-283-9519 Fax: 216-283-6022 www.equityeng.com
Philip A. Henry email: [email protected]
Asset Integrity Management Overview Life-Cycle Management of Pressurized Fixed EquipmentPresentation OverviewIntroduction Life-Cycle ManagementRegulatory ViewpointsRefining & Petrochemical Industry GoalsOwner-User GoalsCooperative Achievement of GoalsSlide Number 8The Life-Cycle Management ProcessCalibration to Industry SegmentsThe Life-Cycle Management ProcessDamage Mechanism IdentificationThe Life-Cycle Management Process Damage Mechanism IdentificationThe Life-Cycle Management ProcessConstruction Codes & StandardsThe Life-Cycle Management ProcessConstruction Codes & StandardsThe Life-Cycle Management ProcessConstruction Codes & StandardsThe Life-Cycle Management ProcessConstruction Codes & StandardsThe Life-Cycle Management ProcessIn-Service Inspection CodesThe Life-Cycle Management ProcessOther Inspection ResourcesThe Life-Cycle Management ProcessFFS StandardThe Life-Cycle Management ProcessPost Construction Standards & Repair GuidelinesThe Life-Cycle Management ProcessImportant AspectsThe Life-Cycle Management ProcessTechnology IntegrationThe Life-Cycle Management ProcessBest PracticesSlide Number 25Slide Number 26Slide Number 27Slide Number 28Slide Number 29Slide Number 30Slide Number 31Slide Number 32Slide Number 33Slide Number 34Slide Number 35Benefits of the LCM ProcessConclusionsSlide Number 38