GP 43-50 31 January 2009
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Description
Document No.
GP 43-50
Applicability
Group
Date
31 January 2009
GP 43-50
Pigging, Pig Launchers, and Receivers
Group Practice
BP GROUP ENGINEERING TECHNICAL PRACTICES
31 January 2009
GP 43-50 Pigging, Pig Launchers, and Receivers
Foreword This revision of Engineering Technical Practice (ETP) GP 43-50 is the result of extensive operational comment and consultation as well as significant lessons learned from recent pig trap failures. The document has been restructured to bring relevant topics together while adding information on ATEX requirements and the Global ILI Framework Agreement. The new structure is as follows: •
Guidance on pig selection.
•
Basic requirements for pigging operations.
•
Design of pipelines and facilities for pigging.
•
Specific guidance on design, inspection, and maintenance of pig trap closures.
Because revisions were so extensive, revisions have not been identified in the margin as is normal practice.
Copyright © 2009 BP International Ltd. All rights reserved. This document and any data or information generated from its use are classified, as a minimum, BP Internal. Distribution is intended for BP authorized recipients only. The information contained in this document is subject to the terms and conditions of the agreement or contract under which this document was supplied to the recipient's organization. None of the information contained in this document shall be disclosed outside the recipient's own organization, unless the terms of such agreement or contract expressly allow, or unless disclosure is required by law. In the event of a conflict between this document and a relevant law or regulation, the relevant law or regulation shall be followed. If the document creates a higher obligation, it shall be followed as long as this also achieves full compliance with the law or regulation.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Table of Contents Page Foreword ........................................................................................................................................ 2 1.
Scope .................................................................................................................................... 5
2.
Normative references............................................................................................................. 5
3.
Symbols and abbreviations .................................................................................................... 6
4.
Pigging overview.................................................................................................................... 7 4.1. Reasons to pig............................................................................................................ 7 4.2. Pig types ..................................................................................................................... 7 4.3. Pig selection, design, and maintenance ...................................................................... 9 4.4. In-line inspection pigging requirements ..................................................................... 12 4.5. Pigging operational considerations ........................................................................... 13 4.6. Pig trap operations, inspection and maintenance...................................................... 16
5.
Pipeline design for pigging ................................................................................................... 20 5.1. General..................................................................................................................... 20 5.2. Internal diameters of linepipe .................................................................................... 21 5.3. Bends for pigging ...................................................................................................... 21 5.4. Valves, check valves, tees, and wyes ....................................................................... 22 5.5. Pig handling equipment............................................................................................. 23
6.
Design of pig trap installations ............................................................................................. 24 6.1. General..................................................................................................................... 24 6.2. Service conditions and code requirements................................................................ 27 6.3. Layout requirements ................................................................................................. 28 6.4. Structural supports and lifting lug design................................................................... 29 6.5. Pipework and pressure and instrumentation requirements........................................ 30 6.6. Valves....................................................................................................................... 34 6.7. Barrel design............................................................................................................. 35 6.8. Pig trap end closures ................................................................................................ 36 6.9. Materials, fabrication, welding, and marking.............................................................. 41
7.
Special applications ............................................................................................................. 42 7.1. Subsea traps............................................................................................................. 42 7.2. Pigging of flexibles .................................................................................................... 43 7.3. Tanker/barge loading lines........................................................................................ 43 7.4. Temporary pig traps.................................................................................................. 43
Annex A (Informative) Recommended pig trap closures................................................................ 44 Annex B (Informative) Tie rod type design pig trap closures ......................................................... 45 B.1
Qualification of use requirements for FAI, LTS, and TDW .................................................... 45 B.1.1 Introduction ............................................................................................................... 45 B.1.2 What are the main issues?........................................................................................ 45 B.1.3 Design of tie rod and associated fittings.................................................................... 46
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B.1.4 B.1.5 B.1.6 B.1.7
GP 43-50 Pigging, Pig Launchers, and Receivers
Gasket compression ................................................................................................. 46 Tie rod loading .......................................................................................................... 46 Clamp angles............................................................................................................ 47 Acceptable tie rod type design pig trap closures ....................................................... 49
Annex C (Informative) Onshore gas terminal incident at 16 in sphere receiver ............................. 50 C.1. Incident ................................................................................................................................ 50 C.2. Cause of the incident ........................................................................................................... 50 C.3. Recommendations ............................................................................................................... 51 C.4. Comment ............................................................................................................................. 51 Bibliography .................................................................................................................................. 52
List of Tables Table 1 - Managing risks of pig trap purging operations ................................................................ 18 Table 2 - Recognised purging practices across the BP Group ...................................................... 19 Table 3 - Pig trap closure design requirements ............................................................................. 39 Table 4 - Pig trap closure test requirements.................................................................................. 40 Table A.1 - GD Engineering (GD): Type BANDLOCK 2 ................................................................ 44 Table A.2 - Pipeline engineering (PE) ........................................................................................... 44
List of Figures Figure 1 - Barred tee design detail ................................................................................................ 23 Figure 2 - Typical pig launcher ...................................................................................................... 25 Figure 3 - Typical pig receiver ....................................................................................................... 26
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1.
GP 43-50 Pigging, Pig Launchers, and Receivers
Scope a.
This GP provides requirements for: 1.
Pigging practice.
2.
Pipeline design to accommodate pigging.
3.
Selection and design of pig traps, end closures, and appurtenances. Requirements on the need for pig traps and the locations within facilities are given in GP 43-20, GP 43-21, and GP 43-22.
b.
c.
2.
The scope of this GP includes: 1.
Onshore, offshore, and subsea pipeline systems.
2.
Horizontal and vertical launcher and receiver pig traps.
3.
Oil, gas, chemical, and liquid petroleum gas (LPG) service conditions.
4.
All pig types (i.e., utility pigs, intelligent pigs, and spheres).
5.
New and existing facilities.
This GP is relevant to the pipeline technical authority (TA), as well as design, installation, and operations personnel.
Normative references The following referenced documents may, to the extent specified in subsequent clauses and normative annexes, be required for full compliance with this GP: •
For dated references, only the edition cited applies.
•
For undated references, the latest edition (including any amendments) applies.
BP GP 06-20 GP 43-52
Materials for Sour Service. Inspection and Integrity Assessment of Pipeline Systems.
American Society of Mechanical Engineers (ASME)
ASME B16.5 ASME B16.9 ASME B31.3
ASME Boiler and Pressure Vessel Code Section II - Part A - Ferrous Material Specifications. ASME Boiler and Pressure Vessel Code Section II - Part B - Nonferrous Material Specifications. ASME Boiler and Pressure Vessel Code Section II - Part D - Properties. ASME Boiler and Pressure Vessel Code Section VIII - Rules for Construction of Pressure Vessels Division 1. ASME Boiler and Pressure Vessel Code Section VIII - Rules for Construction of Pressure Vessels Division 2 - Alternative Rules. Pipe Flanges and Flanged Fittings: NPS 1/2 through NPS 24. Factory-Made Wrought Buttwelding Fittings. Process Piping.
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GP 43-50 Pigging, Pig Launchers, and Receivers
International Standards Organization (ISO) ISO 13628-1
Petroleum and natural gas industries - Design and operation of subsea production systems - Part 1: General requirements and recommendations.
Manufacturers Standardization Society of the Valves and Fittings Industry (MSS) MSS SP-44 MSS SP-75
3.
Steel Pipeline Flanges. Specification for High Test Wrought Butt Weld Fittings.
Symbols and abbreviations For the purpose of this GP, the following symbols and abbreviations apply: ATEX
Explosive atmosphere (EU standards).
D
Diameter.
ESD
Emergency shutdown.
FEA
Finite element analysis.
GIS
Geographical information system.
HIC
Hydrogen induced cracking.
ID
Internal diameter.
ILI
In-line inspection.
LEL
Lower explosive limit.
LPG
Liquid petroleum gas.
MAOP
Maximum allowable working pressure.
MFL
Magnetic flux leakage.
NDE
Nondestructive examination.
NGL
Natural gas liquids.
OD
Outer diameter.
PPE
Personal protective equipment.
ROC
Rapid opening closure.
ROV
Remotely operated vehicle.
UT
Ultrasonic technique.
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4. 4.1.
GP 43-50 Pigging, Pig Launchers, and Receivers
Pigging overview Reasons to pig Use of a proper pigging program with the correct pig helps maintain the integrity and optimum efficiency of the pipeline while safeguarding both the environment and the pipeline asset. Maintenance of a clean pipeline is important, as build up of solids impacts throughput. Build-up of deposits can also create conditions for corrosion by reducing the effectiveness of inhibitors. a.
b.
c.
d.
Pipeline pigging is a key part of managing the integrity of pipeline systems. Pipelines require pigging at the start and end of life. Pipelines are normally pigged for: 1.
Commissioning and decommissioning.
2.
Cleaning or wax removal.
3.
Inventory management (sweeping out liquids, batching products, etc.).
4.
Corrosion and scale control.
5.
Inspection.
6.
Isolation and special operations.
New pipeline designs may consider permanent or temporary pig launcher and receiver facilities. 1.
Requirements shall be agreed with operations.
2.
The project shall provide necessary equipment to facilitate pigging.
3.
If traps are removed after commissioning, safe isolations and space for re-instatement of pig traps should be left such that future inspection pigging can be safely achieved.
Pipelines should be pigged for operational and inspection purposes on a regular basis. 1.
The timing for inspection is dependent on the corrosion risk assessment and the effectiveness of detection.
2.
Requirements on frequency of inspection are given in GP 43-52.
Projects shall hand over new pipelines to operations that have been verified to be free of debris, defects, and obstructions. A baseline ILI inspection should have been completed prior to handover. Further guidance on ILI requirements is given in GP 43-52.
4.2.
Pig types Pigs come in many different shapes and sizes, each of which requires care and attention for its selection, design, and use. Utility Utility pigs perform gaging of the internal bore, cleaning and debris removal, batch separation of products, and sweeping of liquids from the line. Pigs can either be unidirectional or bidirectional. Utility pigs are of the following types: • •
Foam: moulded from polyurethane foam in various densities with various configurations of solid polyurethane strips and/or abrasive materials permanently bonded to their surface. Elastomer: moulded from solid elastomer.
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GP 43-50 Pigging, Pig Launchers, and Receivers
•
Mandrel: a central metal body with various components (cups, discs, wire brushes/scraper blades, gaging plates) attached.
Utility pigs may be run as a dual module to facilitate negotiation of tight bends or wye configurations. The coupling may be subject to high transient and fatigue loads. Specialty pigs may be used for: • • • • • •
Wax detection. Removing hard scale with a pinwheel. Magnetic cleaning. Internal coating. Leak detection. Other functions.
Gel There are four main types of gel that are used in pipeline applications: • • • •
Batching or separator gel. Debris pickup gel. Hydrocarbon gel. Dehydrating gel.
If used with conventional pigs (e.g., constrained between two utility pigs), gel pigs can improve overall performance. Gel is normally a diesel based highly viscous product but can be made with water and a range of chemicals, depending on chemical compatibility requirements. Gel pigs can be susceptible to dilution and gas mixing. Sphere Sphere pigs are normally used to sweep liquids from gas lines. Sphere pigs are normally either made from foam throughout or consist of elastomer skin inflated with glycol and/or water. See 4.3.1.e for more detail. Soluble spheres are sometimes used in crude pipelines and are made from a microcrystalline wax and amorphous polyethylene that acts as a paraffin inhibitor. Soluble spheres are broken up by the crude oil and do not require a receiver trap. Inspection Simple gaging plate and calliper type pigs are used to detect small and large scale geometric variations in pipeline cross section, respectively. An intelligent pig is able to detect the presence of metal loss, cracks, and pipeline features (valves, fittings, etc.) within the pipe wall, normally using either MFL or UT. Some pigs may require an umbilical or fibre optic cable for detailed inspection close to the facility. These are called tethered pigs. Specialised pigs are also used to perform leak detection and mapping (GIS). Eddy current and video based techniques are also available. Isolation Isolation pigs are used to temporarily plug the line and may require a tether back to the launching facility.
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GP 43-50 Pigging, Pig Launchers, and Receivers
The differential pressure that can be resisted depends on the type of pig. Some pigs are dual module. Dual or multi-diameter A dual diameter pig functions in two distinct diameters, for example 200 mm (8 in) and 255 mm (10 in), and is able to negotiate both 200 mm (8 in) and 255 mm (10 in) pipe. 4.3.
Pig selection, design, and maintenance
4.3.1.
General
a.
The selection and type of pig to be used and its optimum configuration for a particular task in a pipeline shall be based upon several criteria, including: 1.
Purpose (e.g., linefill, batching, cleaning, or inspection).
2.
Type of information to be gathered (e.g., from an ILI pig run) and data requirements.
3.
Line contents (e.g., gas, oil, or water), with or without contaminants (e.g., wax) that may need to be displaced or removed during conventional pigging operations.
4.
Required driving pressure versus available pressure.
5.
Minimum and maximum internal diameter, including diameter restrictions or changes (e.g., corrosion probes, coupons, instrument taps, valves, check valves, barred or sphere tees). When multi-diameter pipelines are pigged, excessive wear of components in the smaller diameter line section shall be considered.
6.
Presence of tees and wyes that may require a longer pig to ensure that the pressure driving force is maintained as the pig traverses the connection. Foam pigs can be easily damaged and lose drive. They can also compress and enter smaller diameter connections, laterals, valves, and tappings.
7.
Minimum bend radius, bend angles, and position of back to back bends.
8.
Distance the pig needs to travel and the internal condition of the pipe, with regard to wear on the cups or discs. Large diameter pigs in gas pipelines may require wheeled supporting structure.
9.
Operating velocity range of the pig. Some pigs have bypass ports that enable the speed of the pig to be reduced below that of the pipeline fluid velocity. See 5.1.f.
10. Elevation profile (e.g., pig acceleration during linefill, slack line conditions for operating oil pipelines). 11. Maximum temperature and/or fluid pressure permitted. Due to onboard electronics, the maximum temperature for the UT and MFL inspection vehicles is approximately 60°C (140°F). Inspection tools may tolerate higher temperatures (approximately 80°C [176°F]) for short periods and can be launched in a batch of cold fluid. 12. Ability to drive pig in the reverse direction (e.g., for a bidirectional pig). 13. Requirements to track or communicate with the pig. Pigs can be fitted with transponders to enable external tracking of the pig and sensors to detect external electromagnetic or radioactive systems to improve positional accuracy for inspection pigs and to trigger setting and unsetting of isolation pigs.
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b.
GP 43-50 Pigging, Pig Launchers, and Receivers
Cleaning and brush/scraper pigs shall be configured to limit the amount of material that can be removed in a single pass to the amount that can be contained in the receiver. Bypass ports on the pig are commonly used. Otherwise, there is a risk of blocking the line or preventing entry of the pig into the receiver trap due to the overfilling of the pig trap with solids.
c.
Some pigs should be run in combination with other pigs (e.g., cleaning pig ahead of a batch pig) to determine wax quantities and number of cleaning runs required. Where gel pigs or chemicals are used for cleaning or commissioning, separation pigs can help minimize fluid bypass. Separation pigs are usually bi-directional utility pigs incorporating a number of discs.
d.
If multiple module pigs are used, the components shall be designed to allow removal if the toll separates into component parts. This may be avoided if the rear module includes a drive cup or disk. Alternatively, the tool can be designed to allow it to be pushed from behind.
e.
If inflatable spheres are utilized the following shall apply: 1.
Spheres shall be filled with a water/glycol mix and ring gaged to ensure that they are of the correct diameter. Water/glycol mix ratios are, typically 50:50 or 60:40 in accordance with manufacturer recommendations. Sphere diameters should typically be 1% to 3% greater than the ID, in accordance with manufacturer recommendations. If hydrate formation is a concern following rupture of a sphere, an increased percentage of glycol can be effective. Use of 100% glycol may deteriorate the sphere material. It is recommended that a sphere removal tool be available to remove spheres that may become stuck in launcher or receivers.
2.
Inspected to ensure that the filling plugs do not leak and are replaced, if necessary. Leaking plugs have resulted in safety incidents.
4.3.2.
Pig design requirements
The basic design of a pipeline pig should be simple and efficient as experience has shown the more complicated the pig the more prone it is to failure. Often the features incorporated into the design is based on experience and not readily apparent. The following components should be considered when designing a pig. a.
b.
Pig body and materials 1.
The pig body shall have sufficient strength to resist the load imposed on it, including fatigue. This includes proper design of the body attachments, pig nose, and lifting lugs.
2.
Materials shall be selected to suit the pipeline contents. This may include sour service or the special selection of plastic components when used in chemical service.
Cups and seals The correct material shall be specified for the cups and seals based on the pipeline service, temperature, and travel distance. The shape of the cup and seal are important to achieve the desired cleaning results.
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c.
GP 43-50 Pigging, Pig Launchers, and Receivers
Pig Connections Nuts, bolts, and welds shall be appropriately sized and designed to avoid failure due to direct loading conditions or fatigue. A number of pigs have failed due to improper selection and installation of components requiring special operations to recover debris left in the pipeline.
d.
Bypass By utilizing differential pressure across the pig, a fluid path is created front to back of the pig creating turbulence in front of the pig. This assists in the cleaning process and can be used to optimize cleaning. Excessive bypass may cause pig to stall in the pipeline.
e.
Cleaning elements A number of types of cleaning elements are available to suit the application if pipeline cleaning is required. Expert advice should be sought for difficult or unusual cleaning problems. When starting a pigging program several successive runs are required to achieve best efficiency. The first run may provide the most dramatic results but improvements are seen in each additional run. It is essential that good records are maintained to determine when the maximum cleaning benefit has been achieved. This also assists in determining the frequency of future runs.
4.3.3.
ATEX requirements for potentially explosive atmosphere service
Operation of launching and receiving pigs has the potential to introduce pigs to hazardous environment. a.
Pigs and associated equipment containing electronics shall have the correct certification for area of operation. 1.
This shall be consistent with ATEX regulations.
2.
Pigs used in hydrocarbon service or pigs deploying high powered lithium batteries shall comply with Zone 1 ATEX requirements. European regulations include requirements for ATEX certificates as a declaration of conformance for explosive atmosphere service. Pigging operations may introduce hazards due to high powered lithium batteries and there is potential for static buildup. These are covered by ATEX regulations. Guidance on application of ATEX requirements and application for pigging operations can be obtained from the ILI sector strategy team.
b.
If ATEX compliant tools are not available or do not meet this classification, additional procedures shall apply. If ATEX rated tools are not available, additional purging and isolation requirements may be needed. Requirements may be met if pigging operations can effectively remove hydrocarbons and valves seat effectively.
c.
A suitable cross bonding shall be used between the pig trap and any equipment necessary to perform the pigging operation (e.g., launch/receipt tray). To facilitate this, the pig trap should be designed with suitable lugs onto which the bonding cables can be attached.
d.
Pigging procedures shall address potential of ILI tools being damaged during operation, thereby exposing cables and/or components.
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4.3.4.
4.4.
GP 43-50 Pigging, Pig Launchers, and Receivers
Maintenance and inspection of pigs
a.
Formal maintenance and inspection procedures shall be developed for multi-use pigs to ensure optimum performance and reduce the chance of failure during operations.
b.
Each pig should have a unique reference number to facilitate record keeping on number of runs and maintenance/repair.
c.
The pig should be cleaned after each run with debris and cleaning materials disposal according to regulatory and HSSE requirements.
d.
The pig manufacturer’s recommendations shall be followed for disassembly and maintenance and/or replacement of components. Components should be inspected for fatigue and unusual wear patterns.
e.
Pigs should be stored either in cradles or on end prior to use to prevent damage to cups/disks.
In-line inspection pigging requirements The main technologies for detecting pipe wall loss defects and circumferential cracks are: • •
MFL. UT.
Factors that affect choice of technology include: • •
• • •
Accuracy of result: UT provides a direct measurement, while MFL readings require processing and interpretation. Pipeline product: UT generally requires to be run in a liquid to provide an acoustic couplant. This is less convenient for gas and multiphase lines in which arrangements have to be made to enable the pig to run within a slug of liquid. MFL is unaffected. Cleanliness of line: UT requires a higher level of pipe wall cleanliness than MFL. Pig speed: MFL technology may be run at higher speeds compared to UT. Wall thickness: The magnets of MFL pigs may be unable to fully saturate heavy wall thickness pipes with magnetic flux, resulting in incomplete pipe wall inspection. Heavy wall thickness pipelines can reduce the reflection time of UT signals, causing data loss.
Effectiveness of MFL inspection in thick wall, small diameter pipes is reduced due to the small volumetric space for magnets and ability to fully magnetise the pipe wall. Thick wall lines may require a separate run to magnetise the pipe wall. An MFL tool that is set up to inspect the heavy wall pipe could over saturate thinner wall pipe, resulting in the inability to inspect the thin wall pipe. Specialised inspection pigs are required to detect cracks or laminations. a.
The performance standards for the inspection run(s) and reporting requirements shall be agreed between the operator and the ILI supplier. The BP Global Contract for ILI sets clear expectations and requirements on both the operator and the ILI supplier. The Contract provides a common approach to the supply of ILI services with a focus on tool performance, while providing the opportunity to obtain these services through a cost efficient and transparent selection process.
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b.
GP 43-50 Pigging, Pig Launchers, and Receivers
Operational requirements of the (pre-inspection) pigs and inspection vehicles shall be reviewed in conjunction with operational envelope of the pipeline. This includes consideration of pipeline product (and/or specified pigging medium), vehicle material, vehicle wear, in addition to temperature, pressure, and flow (velocity) limitations. ILI tools should, at a minimum, meet the specifications required under the BP Global Contract for ILI.
c.
Operator and ILI supplier shall agree on acceptable cleanliness levels ahead of the inspections and verify the cleanliness before launching the inspection pig.
d.
Pipeline cleaning programme may require modifying, depending on the quantity of debris being removed from the pipeline and the condition of the pigs being recovered. Inspection pigs require a clean pipeline to function correctly.
e.
A final calliper or gaging pig run shall be performed just before launch of the ILI tool to verify that the inspection tool will not get stuck. ILI tools should only be launched if the gage/calliper run indicates no adverse features, such as valves not fully open, corrosion probes left in the line, or mechanical damage.
4.5.
Pigging operational considerations
4.5.1.
General
4.5.2.
a.
Pigging operations shall be carried out using formally documented operating procedures.
b.
Only competent personnel who have had the necessary training, experience and assessment shall be used in pigging operations.
c.
There are specific requirements associated with the operation, maintenance, and inspection of pigging facilities. These are addressed in 4.6.
Safety and risk assessment
a.
Pigging operations shall have a suitably documented operating and risk assessment.
b.
Personnel involved in the pigging activities shall be fully informed and aware of the associated hazards and risks. Pigging is one of the most hazardous operations undertaken during operation of a pipeline.
c.
The risk assessment shall include: 1.
2.
Operating procedures including: a)
Understanding of pipeline condition and facilities.
b)
Previous pigging experience.
c)
Level of available documentation.
d)
Previous successful use of the procedures.
e)
Competency of personnel.
f)
Management of Change procedures.
g)
Simultaneous operations.
Pig selection and handling including: a)
Pig performance (refer to 4.3).
b)
ATEX requirements.
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GP 43-50 Pigging, Pig Launchers, and Receivers
3.
c)
Cleaning requirements and assessment of pipeline condition.
d)
Effect of pipeline fluid on pig components.
e)
Potential for separation of multi-module pigs.
f)
Handling of pigs.
g)
Effect of pigging on pipeline pressure fluctuations during pigging operation.
Effect of pigging operations on upstream and downstream process facilities including: a)
Handling the pig and any associated materials and fluids (e.g., inhibitor slugs).
b)
Effect on batch processes (e.g., introduction of methanol, biocide, and inhibitor slugs) and requirements for product separation.
c)
Impact on processing requirements and filtration systems. There may be an increased volume of liquids received in multiphase lines or unplanned shut-down due to filter blockages.
d)
Impact of pigging operations on alarms, trips, and shutdown systems.
e)
Impact of process conditions on pigging operations. Process conditions may require a shut down of the pipeline.
f)
4.
5.
4.5.3.
Handling and disposing of waste from the pipeline found in the receiver pig trap (e.g., wax, contaminants, such as mercury and radioactive scale and pyrophoric material).
Pig trap facilities including: a)
Effectiveness of isolations.
b)
Purging of pig traps.
c)
Flammability of deposits.
d)
Operation and maintenance of trap end closures/doors.
e)
Lighting (may be required for 24 hour operation).
f)
Access and lifting.
Potential failure of operation requiring a contingency plan including: a)
A stuck, damaged or lost pig.
b)
Pig location.
c)
Removal or recovery of a stuck or damaged pig or pig components.
d)
Communications.
Operating procedures
a.
A survey shall be performed to establish the physical constraints and condition of equipment found along the system, including valves position, sealing, and maintenance.
b.
A review shall be carried out of previous operating history, including any operating limits or restrictions.
c.
A pigging plan, including documented operating procedures, shall be developed for each pipeline based on the risk assessment. Special consideration shall be given to new and existing pipelines: 1.
That have not been pigged before or recently.
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d.
GP 43-50 Pigging, Pig Launchers, and Receivers
2.
That have been modified since the last pigging operation (e.g., hot tapped or repaired).
3.
If there is uncertainty about the condition of line (e.g., corrosion or excessive buildup of deposits, such as hydrates and wax, or the potential of water ingress into dry gas lines, illegal hot taps, and other third party interference).
The pigging plan shall address the number and sequence of pigs to be used in the pipeline. Pigs may need to run in a sequential and progressive manner to build a picture of the pipeline conditions and minimise the risk to the pipeline operations and the potential for a stuck pig. Examples of a pigging sequence are: • • •
A foam pig may be run before a gaging pig. An additional gage plate larger than the initial gage plate can subsequently be run on one of the cleaning pigs to further increase the known bore of the pipeline. There could be a requirement for multiple cleaning runs and possible special procedures to achieve a successful inspection. Debris collected and/or damaged pigs/gage plates should be evaluated as an ongoing process and the pigging programme adjusted to achieve the best results.
1.
If there is any doubt about condition of the bore, a foam pig should be initially run in pipeline.
2.
Only one pig should be allowed in the pipeline (or a pipeline section between pig traps) at any time, and pig should be received and evaluated before running the next pig.
3.
If two pigs, including a dual module pig, are run in the line at the same time, second pig should be capable of driving first pig in the event of seal failure of the pig.
4.
Multiple pigs should only be deployed for specific reasons, such as commissioning, line purges, and special cleaning operations.
e.
Pipeline inlet and outlet pressures and flows shall be monitored and recorded throughout the pigging operation.
f.
Effects of pigging on the downstream process shall be assessed in design process and prior to commencement of any pigging operation.
g.
Pigging operations shall be formally recorded, including the quantity of material removed from the pipeline and the condition of the pig.
h.
Pigging procedures shall address what actions are to be taken in event of a stuck pig or loss of components from the pig before pigging operations begin.
i.
If the known location of the pig is required, transponders should be fitted to a pig to aid detection. The type of transponder used should consider the length of time required to mobilize and detect the pig. This is preferable on early pig runs and if there is a change in pig size. If response could be delayed due to accessibility, the use of radioactive isotopes with half life of up to 12 mo is recommended.
4.5.4.
Contingency plans
a.
Potential contingencies available in the event of a stuck or damaged pig include: 1.
Increasing the driving pressure (this shall not exceed the MAOP) and/or reducing the downstream pressure in order to place a higher differential pressure across the pig.
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GP 43-50 Pigging, Pig Launchers, and Receivers
2.
Monitoring pressure and flows carefully. a)
If the pig moves, it may accelerate and drive a high speed slug of debris downstream.
b)
This may damage the inspection tool or downstream facilities and therefore requires assessment before pigging operations begin such that procedures are clear and can be effectively communicated to all personnel involved.
c)
If hydrates are the likely cause of restriction, decreasing the pressure on both sides of the pig should melt the hydrate plug.
Differential pressure across the hydrate plug should be avoided to prevent sudden plug movement. 3.
Sending a driving pig behind the stuck pig, if the first pig has become stuck as a result of loss of sealing and hence driving pressure. A foam pig is often chosen on the basis that if it too gets stuck it can be broken up by applying a high differential pressure.
b.
4.
Reversing the direction of flow if the stuck pig is of the bidirectional type.
5.
Detection of the pig and investigation of the pipeline in the vicinity to establish the cause of the blockage.
6.
In an extreme case, selecting the option to resort to cutouts, replacement pipelines, or abandonment.
A contingency plan shall be prepared to cover loss of components from the pig. The plan may require installation of strainers and use of a pig to sweep out the components.
4.6.
Pig trap operations, inspection and maintenance
4.6.1.
General
a.
Operators shall have formal training of pig trap operation, maintenance, and door interlock system. There have been fatalities worldwide associated with incorrect operation or inadequate maintenance of the door.
4.6.2.
b.
Detailed launch or receive procedure shall be developed for each location and for the type of pig being launched and/or received.
c.
Detailed procedures shall be developed and used for each pig trap door type, pig trap facility, and associated fittings and equipment. These shall include the relevant manufacturer’s operating, maintenance, and inspection requirements.
d.
Manufacturers’ requirements and recommendations shall be reviewed and supplementary information shall be developed if these are vague or unclear.
e.
Procedures shall be prepared to address the inspection, maintenance, and replacement of components with recommended frequencies.
f.
Elastomeric and polymeric seals shall be selected for suitability with process conditions, including any trace media, such as methanol, glycol, and corrosion inhibitors. Seals used in gas service shall also be selected for resistance to explosive decompression.
g.
Pig trap end closures shall comply with the requirements of 6.8.
Operating procedures
a.
Pig traps shall be regularly inspected to ensure containment and verify that the pressure within the trap is in accordance with operating procedures.
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GP 43-50 Pigging, Pig Launchers, and Receivers
This is due to the potential for valves to pass over time and for the trap to pressurise. The practice of leaving the pig trap pressurised and online depends on operational circumstances. For multiproduct pipelines, pig traps are often left online to prevent contamination of batches. Keeping a flow through the pig traps can reduce the effect of dead legs, solid drop out, and corrosion risk. Each case is subject to local conditions. b.
Spheres shall not be left in pressurised launchers/receivers for extended periods. Gas from the pipeline may enter the spheres through leaking plug seals, causing spheres to expand in the enlarged diameter of the launcher/receiver, resulting in a tight fit. This could result in a serious injury if the pig trap depressurised and gas was trapped behind the over inflated sphere. See lesson learned in Annex C.
c.
Risks of leaving the pig trap pressurised and online shall be assessed, including appropriate settings for relief valves.
d.
When pig traps are left offline, a path for thermal pressure relief, complete with suitable discharge, shall be included to protect against temperature and pressure changes.
e.
Air that may have been introduced into a pig trap from loading pigs or spheres should be removed before repressurising the pig trap. Removal can be achieved through direct gas or liquid purging or with nitrogen. This applies to pig traps used for hydrocarbon gas systems and volatile hydrocarbon liquids.
f.
Pig trap door seals shall be tested before the pig trap is left unattended. This can be done as an initial seal test followed by a full in service product test.
g. 4.6.3.
Sour gas or wet gas service traps should be left purged and depressurised.
Flushing and purging of pig traps
a.
Selection of flushing and purging method shall depend on the: 1.
Fluid or product transported. N2 can be used with NGL pipelines and ethylene and dense phase CO2 pipelines to manage the phase transition temperatures on depressurisation. Extreme cold temperatures generated can cause damage to pigs and reducing pressures in nitrogen rather than with product can mitigate this effect. For multi-product lines, a higher flash point liquid is often used as a flush medium with a N2 purge.
2.
Expected contents of pig trap receiver. Pigs shall be cleaned immediately on removal from the pig trap if pyrophoric material is present. Pyrophoric material can be a hazard in some systems. These require purging and facilities to keep any solids wet.
3.
Design of the pig trap. Effectiveness of purging depends on the design of the pig trap and the presence of hydrocarbon liquids or solids. Liquids or solids can become trapped in dead legs in the bottom of the trap or between the drain point and the pig trap door. In some systems, residual gas pressure is used to aid sweep out of liquids. N2 has been used in some cases. Effectiveness of purging also depends on the effectiveness of the pig trap valve seals.
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31 January 2009
b.
GP 43-50 Pigging, Pig Launchers, and Receivers
4.
Frequency of pigging operations.
5.
ATEX rating of pigs and equipment used.
Risks associated with the use of the selected purging medium shall be assessed. N2 can introduce additional risks and has limited benefit if hydrocarbon liquids or solids are present. Nitrogen may be available from onsite generation or bottles. There have been a significant number of incidents with N2 asphyxiation, and N2 may not be the most appropriate medium for purging or flushing pig traps. Flushing with hot fluids, particularly water and steam, can introduce other problems of static discharge. On tanker cleaning operations, these are combined with inert blanket systems.
c.
For a gas pipeline that has potential for water dropout (which would be disturbed by pig, leading to hydrate blockage), a slug of hydrate inhibitor should be introduced in front of pig. 1.
Availability of purge medium onsite. Alternative purging and flushing media to N2, including air, water, or C02, may be possible. Such a sequence may include water flush followed by an air purge.
2. d.
Competency of personnel.
For managing risks associated with pig trap operations, purging shall not be taken in isolation to the other mitigation measures available. See Table 1. Table 1 - Managing risks of pig trap purging operations
Media Gas
Hazard
Mitigation
Explosion
Design to zone. Natural venting. Purge.
Asphyxiation or narcotic
PPE (breathing apparatus). Purging to give safe atmosphere O2 rich (can still cause asphyxiation). Remote actuation. Procedures.
Explosion plus asphyxiation or narcotic plus spillage
As above for gas.
Procedures.
Liquids
Solids
Zone design. Verify empty before opening door. Containment. Flush trap.
Mercury
Flush and use of protective clothing and equipment.
General
Flush. Zone design.
Pyrophoric material
Purge/flush and keep wet.
Radioactive scales
Flush and use of protective clothing and equipment.
The volume of purging medium required for large diameter pig trap can be considerable. This can introduce additional risks of transporting multiple packs of nitrogen bottles or from generation equipment with pressure vessels. The risks from these activities can exceed the risks associated with the initial operational risk of free hydrocarbons at the pig trap. e.
Specialised equipment shall be used to determine effectiveness of an inert gas purge.
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GP 43-50 Pigging, Pig Launchers, and Receivers
If monitoring LEL limits, it is important to recognise that gas monitors may not work accurately in atmospheres that are deficient in oxygen. f.
Subject to local conditions, equipment available, and risk assessment outcomes, Table 2 summarises recognised practices. Table 2 - Recognised purging practices across the BP Group
Product
4.6.4.
Comment
Sour gas
Purge to bring toxicity levels down.
Chemicals
Product specific - purge if highly flammable or toxic.
Dry gas (sales gas - water and hydrocarbon liquid dry)
Purging can be effective, but should be site specific, as it depends on frequency of operation and introduces new risks. Purging needs a risk evaluation.
Wet gas (hydrocarbon liquids and water present)
Limited effect depending upon pig trap design.
NGL/gas condensate
Limited effect depending upon pig trap design.
Aviation fuel
Purging has limited effect, as it is difficult to remove hydrocarbons. N2 may introduce additional risks.
Multi products
Purging has limited effect, as it is difficult to remove hydrocarbons. N2 may introduce additional risks.
Live crude
Light oil flush followed by water flush.
Stabilised crude
Water flush.
Pyrophoric material
Purge and keep wet.
Radioactive scale
Flush and use containment.
Inspection and maintenance
a.
End closure 1.
The end closure shall be included in the pipeline or facility integrity management system and shall be maintained in accordance with the manufacturer’s recommendations.
2.
The pig trap and end closure shall be regularly inspected for damaged or worn parts in accordance with the manufacturer’s recommendations. The trap shall not be used unless it meets these requirements or is repaired. Particular attention should be given to potential defects in any securing bolts, nuts, and nut housing, their method of attachment, and buildup of corrosion products that interfere with the correct operation of the mechanism. Particular attention should be taken to ensure that water/moisture cannot collect in the crevice at the bottom of the door, which may affect seal faces.
3.
Some surfaces on clamp type designs should not be greased because the retention of the pig is part based on friction.
4.
Dismantling and close visual inspection of main load bearing components for any sign of deterioration, including corrosion, distortion, deformation, cracking, wear or loss of surface finish on sealing surfaces, shall be undertaken as recommended by the closure manufacturer.
5.
Seals shall be inspected each time door is opened and shall be replaced as necessary.
6.
Replacement is required if seals show signs of compression set (permanent deformation), extrusion, splitting, blistering, softening, hardening, aging, and/or any mechanical damage, such as scuffing.
7.
If failures are repeated, a failure investigation shall be conducted, with a view of selecting alternative materials.
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GP 43-50 Pigging, Pig Launchers, and Receivers
8.
Seals shall be replaced in accordance with manufacturer recommendations.
9.
Spare seals shall be stored in accordance with manufacturer recommendations.
10. If there are problems in obtaining leak tightness of end closure, causes should be investigated and, if appropriate, a leak test should be performed. Bolting shall not be over tightened. 11. Bolts and threaded fittings shall not be tightened or loosened under pressure. 4.6.5.
5. 5.1.
Inspection and revalidation of pig traps
a.
Pig traps shall be inspected and revalidated for continued operation at regular intervals not normally exceeding 5 yr. Local regulations, requirements, or service conditions may require more frequent inspection and testing.
b.
Inspections shall be performed by a competent engineer, who shall make reference to the manufacturer recommendations for inspection and maintenance of end closures.
c.
Revalidation may require periodic hydrotesting in accordance with manufacturer’s recommendations.
Pipeline design for pigging General The following design requirements shall be considered for pigging: a.
Strategy for selecting equipment should be developed early in the project to ensure that equipment will operate as intended (pig compatibility with wyes and tees, etc).
b.
Design of pig trap facilities should include input from operations personnel.
c.
Type of pigging activities required (construction, operation/inspection/maintenance, shutdown, or repair). Preference for permanent or temporary pig launchers/receiver depends on size, pipeline risk assessment, and frequency of pigging. Portable traps may be appropriate for use in pipelines that form part of a network and if pigging is required only for inspection and not routine operations. Temporary pig traps for pipelines larger than 600 mm (24 in) may not be practical because of difficulties in transport and lifting.
d.
The beginning and end of a pipeline shall have pig launchers and receivers. Intermediate pigging station requirements should be dictated by changes in pipeline diameter, pig driver cup wear, and the quantities of solids or liquids likely to build up in front of a pig. Other factors for consideration that could influence the wear rate of the pig seal mechanics include pipe wall condition, pipe wall lining, if any, pig material compatibility with the product, pigging medium, and pigging speed.
e.
Type of product, including any contaminants or additives.
f.
Minimum and maximum design velocities for oil and gas service are driven by pressure drop, noise, and vibration. The optimum pig speed is typically 1 m/s to 3 m/s (3 ft/s to 10 ft/s). Use of variable speed control systems or bypass arrangements may be considered to achieve this range. If pig speeds are outside of this range, effectiveness of the pigging operation may be compromised. Specialised advice is normally required from ILI vendors on the maximum pig speed range to achieve the inspection requirements.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Flow rates may need to be adjusted for the time of pigging operation. Pig speeds may be achieved in high velocity lines by using variable flow bypass controls or fixed bypass arrangements. Some inspection pigs cannot operate at low velocities. This depends on the type of signal generated and if the signal is recorded by time or distance. The minimum speed for some tools is typically 0,3 m/s (1 ft/s). Receipt of pigs may be controlled by having no flow or low flow through the kicker line such that the pigs stop in the main line tee before entry into the receiver trap. Inspection pigs require a restricted flow range to ensure smooth passage along the pipeline, avoiding any tendency for stick and slip. g.
Relative position and distance between valves, tees and/or laterals, type of bends (cold, heat inducted, fabricated), and bend radii.
h.
Pipelines should be designed to allow deployment of isolation pigs for safe pipeline and facilities maintenance. Deployment of isolation plugs may impose greater restrictions on changes to internal diameter close to the facility. Deployment of isolation plugs has been necessary on some installations when pig trap isolation valves or the facility Isolation or Emergency Shut Down valves need maintenance work. The ability to deploy an isolation plug can reduce pipeline shut down times.
5.2.
i.
Proven capability of a multidiameter pig to pass through pipeline system if significant bore changes are present in the pipeline system.
j.
Potential for enhanced internal corrosion if the pipeline requires frequent use of scraper pigs.
k.
Use of temporary tankage to collect debris.
Internal diameters of linepipe a.
Consideration should be given to minimize changes to the internal diameter of the pipeline, including ovality tolerances.
b.
Internal diameter changes should be made with a minimum transition slope of 1:4.
c.
If the use of plugs is anticipated, required tolerances on ID should be strictly controlled.
d.
New pipelines should be designed to allow deployment of an isolation plug beyond the ESD valve.
e.
Diameter changes should occur only at the ends of the pipeline system or pipeline section (at pig traps, valves, subsea sleds, etc.). Since nominal pipe sizes are based on outside diameter, changes in wall thickness result in changes to the internal diameter. Typical limits for deviation of internal diameter from the normal is approximately 4 mm (0,16 in) and 20 mm (0,8 in) for a 100 mm (4 in) and 500 mm (20 in) pipeline, respectively. For thick wall pipe applications (e.g., deep water), consideration may be given to specifying pipe based on a constant ID to avoid large transition changes.
5.3.
Bends for pigging a.
Bends for pigging should be limited to an out of roundness of 5% of diameter.
b.
Bends for pigging should be 3D or greater (where the radius is three times the nominal pipe diameter).
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GP 43-50 Pigging, Pig Launchers, and Receivers
Longer radii may need to be considered if thick wall bends are used. Most ILI vehicles will pass a three dimensional radius bend, and some are available that will pass a tighter radius. Pipelines less than 100 mm (4 in) diameter may require longer bend radii for ILI.
5.4.
c.
Offset bends of 30 degrees or greater should have a minimum straight length between them of 2D. Back to back bends should not be used, as they may limit suitability for ILI.
d.
Mitred bends shall not be used.
e.
If there is the potential need for the use of a tethered pig for inspection, use of bends should be kept to a minimum to avoid excessive loads on the cable connection.
Valves, check valves, tees, and wyes a.
Valves specified for pigging purposes should be full bore, with specified minimum internal diameter, limited or zero bypass, and compatible with product. Valves shall facilitate uninterrupted passage of pig.
b.
Check valves should be through conduit (full bore) type valves or have method of externally locking flapper in fully open position for inline inspections.
c.
Check valves and wyes shall be verified to confirm that pig length between front and rear cups is longer than any opening or cavity.
d.
Barred or sphere tees shall be installed on branches larger than 50% of pipeline diameter and if sphere or foam pigs are intended to be used. If there is a risk of corrosion, consideration should be given to using alternative materials or providing a drain connection on the sphere tee, since dead leg areas of sphere tees are more susceptible to corrosion.
e.
If spheres or foam pigs are to be used, sphere tees should be installed in preference to barred tees.
f.
Wyes shall have a demonstrated capability for passage of inspection pigs (i.e., test at full scale before using the pig in the pipeline). The bore may be 10% oversized to reduce friction within the wye. A wye may be arranged such that gravity assists the pig passage. Convergence angles of 30 degrees have been found to be optimal.
g.
Barred tees 1.
Barred tees shall be designed such that the barring does not cause excessive stresses at the junction of bars and tee crotch area as the tee dilates under pressure.
2.
A minimum of two guide plates should be used to prevent the pig from entering the branch pipe.
3.
Guide plates shall be welded across the tee branch pipe and along the flow direction to prevent pigs from becoming stuck at the junction or from being wrongly diverted with the flow.
4.
Welds shall be ground to avoid stress concentrations where tee branch pipe connects to main pipe and where guide plates are welded to and tapered along blend radius.
5.
Guide plates and weldments shall be smooth and free from sharp edges to prevent damage to pipeline pigs.
6.
Guide plate thickness and plate to plate spacing varies depending on tee branch size. A nominal guide plate thickness of 9 mm to 19 mm (0,375 in to 0,750 in) and guide plate spacing of 64 mm to 76 mm (2,5 in to 3,0 in) are typical.
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GP 43-50 Pigging, Pig Launchers, and Receivers
7.
Optimum guide plate spacing is equidistant from adjacent plates and tee branch pipe walls.
8.
Figure 1 provides barring design details. Figure 1 - Barred tee design detail
NOM. PIPE SIZE
NO. OF T SCRAPER IN. (MM) BARS
H IN. (MM)
6”
2
(9.5)
1 (25.4)
8”
2
(9.5)
1 (25.4)
10”
3
(9.5)
1½ (38.1)
12”
3
(9.5)
1½ (238.1)
14”
3
(9.5)
1½ (38.1)
16”
4
½ (12.7)
2 (50.8)
18”
4
½ (12.7)
2 (50.8)
20”
4
½ (12.7)
2 (50.8)
24”
5
¾ (19)
3 (76.2)
30”
6
1 (25.4)
5 (127)
36”
7
1 (25.4
5 (127)
NOTES:
MAX. CLEARANCE = 6 mm (¼”) AND MIN. CLEARANCE = 0. SCRAPER BARS SHALL BE EQUALLY SPACED OVER THE INTERNAL DIAMETER OF THE TEE. SCRAPER BAR MATERIAL SHALL BE THE SAME MATERIAL AS THE TEE. MATERIAL SHALL BE APPROPRIATE TO PIPELINE DESIGN CODE
• • • •
5.5.
Pig handling equipment a.
Permanent pig handling facilities, such as anchor points, winches, and a lifting gantry or hoist to facilitate loading or removal of pigs from the pig trap, may be required, depending on the size and type of pigs used and frequency of operation. The requirements for pig handling depend on the type and weight of pig and the pipeline size. Pigs less than 30 kg (66 lb) (corresponding to approximately 300 mm [12 in] and smaller pipe size) may be manually loaded into or out of the pig traps. Davit and branch refers to a manually operated system consisting of a cradle bench with a winch and a free standing swing jib crane, with the cradle bench either trolley mounted or suitable for fixing structurally adjacent to the trap end closure.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Cassettes enable the pig or spheres to be preloaded in multiples and loaded into a launching trap in one operation. Cradles, if used with launching traps, can be loaded externally and allow pig to be moved into its launch position via a winch/plunger mechanism, and for receiving traps, the incoming pig comes to rest in the internal cradle, allowing for its removal from the trap. b.
Cassette and cradle pig handling equipment shall be designed and installed as an integrated part of the trap to preserve its integrity as a pressure vessel. Consideration should be given to ensuring unimpaired use of any high pressure cleaning nozzles located within the barrel to facilitate removal of debris and wax from the trap.
6. 6.1.
Design of pig trap installations General a.
Design of pig trap facilities shall include input from operations personnel and take account of layout, access, lighting, equipment handling, cleaning, etc.
b.
Typical pig launchers should be configured as shown in Figure 2 and pig receivers as shown in Figure 3.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Figure 2 - Typical pig launcher
*
"
#
"
%
% &%
$
% TO CONFIRM PIG ENGAGED
LONGEST ILI PIG
XI
SHORT AS POSSIBLE
TRAP ISOLATION VALVE
!
LONGEST ILI PIG XI
TO CONFIRM PIG CLEARED TRAP VALVE
*
Note: Kicker and balance lines and purge points omitted to simplify drawing.
* 3 M IF REQUIRED FOR
ISOLATION PLUG BUT MAY NOT BE NEEDED IN MOST INSTALLATIONS
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GP 43-50 Pigging, Pig Launchers, and Receivers
Figure 3 - Typical pig receiver "
Bypass Valve Balance Line
Relief Valve
*
"
&%
% TO CONFIRM PIG ARRIVAL
XI
TRAP ISOLATION VALVE
%
%
MORE THAN LONGEST ILI PIG XI
TO CONFIRM PIG CLEARED TRAP VALVE
LONGEST ILI PIG + 0.5 M
Note: Kicker and balance lines and purge points omitted to simplify drawing.
c.
* LONG ENOUGH TO * BARREL HOLD DRIVE MODULE + DEBRIS. (SOME PIGS MAY HAVE DRIVE ON LAST MODULE)
In addition to the factors for pipeline design, in 5, design of pig traps should incorporate the following: 1.
Applicable design codes.
2.
Service conditions.
3.
Minimum temperature.
4.
Physical interface with pipeline (e.g., insulation flange).
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GP 43-50 Pigging, Pig Launchers, and Receivers
5.
Types of pigs to be run.
6.
Pigging schedule.
7.
Materials of construction (compatibility with product, brittle fracture).
8.
External loadings (from pipework, particularly subsea).
9.
Operating cyclic loading and nozzle reinforcements (e.g., as a result of repeated trap pressurisation and depressurisation).
10. Structural supports and lifting lugs. 11. Wind and seismic loadings. 12. Snow and ice loadings. 13. Blast loading, if applicable. 14. Transportation loads. 15. Pig handling systems (e.g., lifting gantry, pig trays). 16. Permanent or modular skid mounted unit. 17. Trap closure mechanism. 18. Barrel venting/draining rate. 19. Volume of debris (e.g., wax) to be removed and capable of being retained in the trap. Inspection pigs usually require longer pig traps than utility pigs, which in turn affects the volume of product that may need to be disposed of before the trap is opened following a utility pig run. 6.2.
Service conditions and code requirements a.
Pig trap is part of the pipeline system, and applicability of pipeline design code should extend to the trap, pipework, and up to and including the first isolation valve out of the pig trap. Local regulations may influence selection of the code break point.
b.
Pig traps, including barrel, fittings, and attachments, shall be designed, fabricated, and tested as part of pipeline system. Pig trap door closure shall be designed in accordance with relevant pressure vessel codes. Requirements for pressure vessels are given in GP 46-01, and standard details are in GIS 46-020. Pressure vessel codes include ASME Boiler and Pressure Vessel Code Section VIII, Division 1, PD 5500, or BS EN 13445.
c.
Design pressure of pig trap shall be no less than pressure of pipeline.
d.
Pig trap shall be: 1.
Suitable for testing with pipeline.
2.
Assessed for stresses during pipeline hydrotest condition and pressure vessel hydrotest condition, whichever is greater.
e.
Pig trap system may be hydrostatically tested either together with or separately from pipeline.
f.
Cyclic loading shall be considered for trap and trap closure mechanism due to temperature and pressure. Cases are on record for which there has been pipeline movement due to “ratchetting” caused by successive temperature cycles over time.
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GP 43-50 Pigging, Pig Launchers, and Receivers
g.
Maximum design temperature shall not be less than maximum temperature that the pig trap system could attain or to which it could be exposed during operation, startup, or shutdown.
h.
Consideration shall be given to pressure increases arising from thermal gain in the event of shut-in conditions (e.g., due to solar radiation).
i.
A minimum design temperature shall be stated and shall be based on minimum ambient temperature and on the conditions (e.g., blowdown, which could occur during operations).
j.
An internal corrosion allowance should be considered, even if such an allowance has not been made for pipeline to which it is connected. A corrosion allowance may be required because of the different internal and external conditions associated with the trap.
6.3.
Layout requirements
6.3.1.
General
a.
Pig traps shall be designed to allow access to the pipeline for inspection and maintenance.
b.
Pig traps shall generally be: 1.
Located based on overall site risk assessments, considering potential release of hydrocarbons, potential for ignition, and classification of areas.
2.
Adjacent to each other for ease of pigging operations. Separation distance from launcher closure to receiver closures should be at least 1,5 times the length of the longest inline inspection tool anticipated.
3.
Orientated with their end closures pointing away from personnel and critical items of equipment. Accidents have occurred resulting in door failure and pigs exiting the pig trap at high speed.
c.
Suitable access space should be provided beyond the end closure door for pig handling. A covered protection to the trap enclosure area may be required, depending on the climatic conditions.
d.
Suitable access space should be provided for maintenance of equipment.
e.
The trap should normally be horizontal, with vertical traps used if space is a premium. Vertical orientation of the pig receiver is not normally recommended, as debris can fall and accumulate in the pig trap valve.
f.
The elevation of the bottom of the end closure on horizontal pig traps should be approximately 700 mm (28 in) and not more than 1 100 mm (43 in) above the working surface to provide sufficient room to slope the drain lines, as well as facilitate easy handling of end closure and pigs.
g.
A platform shall be provided adjacent to any equipment (e.g., valve, pig signallers) that is:
h.
1.
More than 1 500 mm (60 in) above grade (centre of the handwheel in the case of a valve).
2.
Used during pigging operations and/or for maintenance.
Consideration shall be given to the requirements for handling of contaminated pigs and displaced solids. There may be a need for sumps, containment areas, cleaning facilities, and an ergonomic layout such that contaminated pigs can readily be transferred from the receiver to the cleaning area.
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6.3.2.
GP 43-50 Pigging, Pig Launchers, and Receivers
i.
Pig trap layout should be such that operation and maintenance of equipment, valves, and instruments shall be possible without temporary ladders and scaffolding.
j.
Access ways shall be provided to and from pig storage area.
k.
Pig traps shall drain by gravity into appropriate drainage area.
l.
Consideration should be given to potential blockage of permanent drains and tanks.
m.
If a drain system is not available, provision shall be made for waste to be collected for disposal to designated disposal area.
n.
Adequate lighting shall be provided for pigging operations if 24 hr operations are required.
o.
Spading is not recommended as a regular method of providing positive isolation of the launcher/receiver vessel.
p.
Protection of door and locking mechanism from the elements/weather should be considered for traps in exposed locations and may be subjected to sea spray or debris from drilling operations.
Onshore additional requirements
a.
Pig traps generally should be located at least 15 m (50 ft) away from any type of equipment that could provide a source of ignition.
b.
Pig trap systems should be fenced (either separately or as part of adjoining facilities), and facilities should be provided for vehicle access. Access may also be required for lifting equipment, etc.
c.
If the facility is unattended, valves shall be secured and locked in their proper position.
d.
A catch pit or tray shall be constructed directly underneath end closure with sufficient volume and surface area to prevent any oil or debris contamination of surrounding ground. Pit or tray shall be easy to empty and clean and shall have a safe means of access. The use of a sump instead of a closed drain system may be appropriate if significant volumes of wax, debris, and unwanted liquids, etc., are removed from the pipeline.
6.3.3.
6.4.
Offshore additional requirements and vertical pig traps
a.
Pig traps shall be installed in open areas to ensure adequate ventilation.
b.
Vertical pig traps shall have a pig lifting facility.
c.
Convenient access to the door locking mechanism should be provided, particularly for vertical traps in which the barrel and end enclosure are above deck level.
d.
A vertical ladder or local stairway shall be provided to allow access between deck levels local to pig trap.
e.
Barrel drain port should be located near main trap valve on vertical launchers.
f.
Any branch connection reinforcement shall be designed for minimum weight.
g.
Vertical vessels shall have lifting lugs or trunnions to facilitate handling during transport and erection at site.
h.
During each operation, door centralising mechanism/lugs should be inspected to ensure correct landing of door each time it is used. Any damage to this system shall be repaired as soon as possible.
Structural supports and lifting lug design a.
Permanent supports/clamps shall be used to support and restrain pig traps.
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GP 43-50 Pigging, Pig Launchers, and Receivers
b.
Supports/clamps shall be designed to carry the weight of the pig trap system filled with highest density fluid likely in service (usually water), together with the weight of intelligent pigs, if applicable.
c.
Saddle supports shall be designed to applicable pipeline code or vessel code being applied to trap. For ASME Boiler and Pressure Vessel Code Section VIII vessels, see GIS 46-010, AA 7.2.e.
d.
Supports under the barrel should normally be sliding/clamp type to compensate for expansion of unrestrained part of pipeline.
e.
Welded supports, if used, shall comply with applicable pipeline design codes.
f.
If there would normally be a potential for corrosion occurring under clamps, isolation material shall be used between clamp and pipe and provisions shall be made to facilitate inspection. Other support requirements may apply to vertical traps.
g.
Piping supports may be fixed if design calculations indicate that sufficient flexibility is incorporated in pipework to compensate for axial and transverse movements of trap.
h.
Electrical isolation joints, if used, shall allow sufficient movement to avoid stressing of joint above its design limit.
i.
Supports may need to be electrically isolated if isolated joints are not used. Typical earthing (grounding) details are given in GIS 46-020.
j.
Supports should be positioned such that pig trap valves can be removed for maintenance or replacement without removal of barrel.
k.
Lifting lugs and trunnions shall comply with GIS 46-010.
l.
Launchers and receivers shall be bonded into earthing (grounding) grid for facility. Integrity of the pipeline cathodic protection system shall be maintained.
m.
Electrical surge arrestor installation should be considered for insulation joints in launcher/receiver pipework.
6.5.
Pipework and pressure and instrumentation requirements
6.5.1.
General
a.
Pipework not designed to the pipeline code should comply with ASME B31.3.
b.
Closed drain systems should be designed to handle debris flushed from pig traps.
c.
Pipework connections should be flanged to allow maximum flexibility during commissioning and future modification, if required.
d.
Pipework should be a minimum of 50 mm (2 in) for robustness. Sizing of drains, vent lines, and pressure gage tappings shall take account of trapped volume, phase of product, and risk of blockage. Pressure gages have produced false readings because of blockage.
e.
For pipelines above 350 mm (14 in) and any prone to waxing or other blockage, consideration shall be given to using 100 mm (4 in) connections off trap to first valve, even if it is reduced thereafter. The size of the pipework may be dictated by use of the pig trap during pipeline testing. In these circumstances, a larger diameter connection may be needed with a reducer fitted to the line, if necessary.
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31 January 2009
f.
GP 43-50 Pigging, Pig Launchers, and Receivers
System interlocks 1.
System interlocks or special provisions shall be used to ensure the safety of personnel operating the pig trap and prevent accidental release of pressure from the pig trap. Well written, risk assessed, operating procedures executed by competent operating personnel qualified on the procedures are needed to satisfy the definition of “special provisions”.
6.5.2.
2.
Interlocks should be provided between the closure and isolating valves, namely main inlet and outlet, vent, and drain isolating valves.
3.
System interlocks or special provisions may be incorporated to prevent accidental opening of both end closure and any valves (e.g., particularly remotely operated pig trap valves and isolating valves) exposed to pipeline pressure while the trap vessel is open.
4.
The interlock mechanism should allow for precommissioning and commissioning of the system (e.g., by providing additional keys).
Kicker and bypass lines
The kicker line enables diversion of the pipeline fluid through the barrel to launch and through the bypass line to receive a pig. a.
For launch traps the kicker line shall be connected to major barrel as close as possible to the end closure.
b.
For receiver traps the bypass line shall be connected as close as possible to the reducer. For bidirectional pig traps, the kicker line could be located approximately halfway along the major barrel, or twin kicker lines could be provided.
c.
Kicker line should be at least 25% of the pipeline diameter and not positioned at bottom of the barrel. The usual positions are 9 o’clock, 12 o’clock, or 3 o’clock on the barrel but not at 6 o' clock.
d. 6.5.3.
For receive traps where the kicker and bypass lines are more than 50% of the pipe diameter a barred tee or sphere tee design shall be used.
Balance line
Balance lines prevent the pig from moving forward from the launch position, hitting and potentially damaging the main trap valve, or moving backwards and losing its seal in the trap reducer. On receivers, the balance line ensures that the pressure across the pig is balanced throughout the depressurisation of the trap such that there is no risk of trapped pressure which could eject the pig if the door is opened. There have been fatal accidents because of this.
6.5.4.
a.
Launchers shall have product balance lines to enable barrel to be filled and pressurised on both sides of pig at the same time.
b.
Receivers shall have balance lines or vents as specified in 6.5.6 to ensure depressurisation on both sides of pig.
c.
Balance line that branches off from kicker line shall be connected to minor barrel as close as possible to the pig trap valve.
Pressurising lines
a.
Pressurising lines should be provided around kicker valve and mainline bypass valve to facilitate pressurisation of pig trap.
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31 January 2009
b. 6.5.5.
GP 43-50 Pigging, Pig Launchers, and Receivers
Size of pressurisation lines should be appropriate for line size.
Drain line
a.
Drain lines that may be prone to blockage and minimum size of pipework shall comply with 6.5.1.d and 6.5.1.e.
b.
Potential for blockage shall be addressed in the risk assessment and pressure rating for the system.
c.
For pipelines larger than 305 mm (12 in), minimum size of pipework shall be 100 mm (4 in). If line is in clean service products, a smaller diameter may be used.
6.5.6.
d.
Provision shall be made for flanges and break points to add extra connections and temporary tankage or to clear blockages.
e.
Dead legs shall be avoided.
f.
The barrel drains shall: 1.
Be located near trap end closure on horizontal launchers.
2.
Be located near main trap valve on horizontal receivers susceptible to presence of liquids.
3.
Have two drain points located together near the trap end closure and be separated by half a sphere diameter on receivers that are sloped for sphere pigs such that drains cannot be blocked by the spheres.
g.
Barrel drain lines should be sloped at least (1:300) towards closed drain system or designated open drain.
h.
Drain point near end closure shall have a 50 mm (2 in) branch connection incorporating a 25 mm (1 in) telltale valve to provide a means to check that liquid is drained before opening the end closure.
i.
If pig traps are used for both launch and receive operations, special requirements apply.
Vent/flare/blowdown lines
a.
A vent line shall be provided to vent/purge the barrel. The vent should be connected to a drain or vent system to minimise the potential for ignition. The position of vent lines on vertical traps may result in pockets of trapped air if operating in liquid service. Operational procedures may require bleeding air from the system prior to full pressurisation.
b.
Barrel blowdown/vent lines shall be at least 50 mm (2 in) and positioned near trap end closure or the highest point on the trap barrel assembly.
c.
Vent lines shall also be positioned near pig trap valve to ensure depressurisation behind a pig in the event of being stuck in minor barrel. The latter recommendation particularly applies to horizontal pig traps and sphere launchers/receivers.
d.
High pressure gas systems shall have a blowdown line, incorporating a globe valve or restriction orifice, for controlled depressurisation. Note: If a restriction orifice is used in the vent line, pipework upstream of orifice should be designed and hydrotested to withstand full line pressure.
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31 January 2009
e. 6.5.7.
GP 43-50 Pigging, Pig Launchers, and Receivers
Pig traps can contain air or air/hydrocarbon mixtures, which shall be taken into account if connecting to flare systems.
Other service lines and storage facilities
Service lines may be required for air, water, steam, and nitrogen for purging of the pig trap, etc. a.
Facilities shall be provided for cleaning and purging of sand, wax, and debris from receivers and launchers. Facilities may include nozzles for the injection of steam or hot oil for the removal of residual wax. Dedicated tankage may be required to receive contaminated product at the receiver trap. For example, chemical treatment slugs and “pig clouds” generated at the interface between different refined products.
b.
Chemical injection points shall be fitted as illustrated in Figure 2. See 6.1. This is required for injection of chemicals used in batch processes, etc., product separation, and gel pigs.
6.5.8.
Thermal relief and pressure gages
a.
Thermal relief valve shall be provided at trap locations in which the anticipated shutin pressure of the product could possibly exceed the design pressure of the trap (e.g., as might arise from solar radiation in liquid pipelines).
b.
Pressure gages with a gage dial of 100 mm to 150 mm (4 in to 6 in) diameter shall be located at the 12 o’clock position on the barrel to be visible to trap operator. The gage is normally positioned near the end closure, but other locations to consider include positioned on the neck piping, downstream/upstream of the trap bypass valve, and downstream of the mainline trap valve. Requirements about fitting details are given in GIS 46-020.
6.5.9.
Pig passage indicators
a.
Pig passage indicators shall have a mechanism that provides a position indication that a pig has passed and that can be installed, removed, or replaced without pipeline shutdown. Optional types of indicators to consider include temporary external nonintrusive electrical, manual/electrical, extended lengths.
b.
Pig passage indicators shall be bidirectional, installed flush with the internal pipe wall, and retractable/replaceable under pressure. They may have a micro switch for remote signalling and may include an external temporary mount for pig tracking.
c.
Pig passage indicators 1.
Pig passage indicators shall be considered on both sides of the main trap valve.
2.
On launchers, one sited upstream of the mainline trap valve and one sited downstream of the mainline valve at a distance at least the length of longest pig anticipated to confirm the pig has left the trap and valve.
3.
On receivers, one sited on the trap neck piping and separated upstream from the mainline trap valve by a distance that is equal to the length of the longest pig anticipated to confirm receipt of the pig and that the pig has cleared the valve.
4.
An indicator should be provided upstream of the main pig trap isolation valve to confirm arrival of the pig at the installation. Page 33 of 52
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GP 43-50 Pigging, Pig Launchers, and Receivers
6.6.
Valves
6.6.1.
General
The general issues of isolation and valve type selection for pig trap valves are covered in detail in GP 43-35, GIS 43-351, and GIS 43-352. General requirements on valve type selection are provided in GP 62-01. a.
Double block and bleed isolation is required for any pigging operation. Preference is always for two separate pig trap isolation valves, especially for pipelines in which pigging is a frequent activity or critical to ongoing operations and failure of a seal cannot be tolerated.
b.
A strategy shall be developed to facilitate maintenance or replacement of pig trap isolation valves.
c.
Isolation of the main pig trap should be designed to facilitate maintenance and/or future modifications to the pig trap and pig trap isolation valve without a pipeline shutdown. This can mean inclusion of sufficient distance between the receiver/launcher main trap valve and the local bypass tee to allow setting of a remote setting plug to provide isolation, if a second valve is not available.
d.
Appropriate valve seats shall be selected for the particular service conditions. This is affected by the type of service (e.g., solids content and chemical) and degree of leak tightness required (e.g., LPG).
6.6.2.
Pig trap valve
For mainline valves on sphere traps, consideration shall be given to designing for multisphere launching with or without automated valve actuation. Such arrangements require careful design and have proven troublesome in the past due to spheres hitting the valve and damaging the seats. 6.6.3.
Other valves
a.
The bypass valve shall be a tight shutoff ball, lubricated balanced plug valve, or slab type gate valve.
b.
Kicker line valves in gas service shall be capable of withstanding high velocities if used in throttling mode against differential pressure. Kicker line valves shall also be capable of opening against differential pressure and providing acceptable shutoff.
c.
Lubricated balanced plug valves are recommended. Metal seated ball valves are also acceptable.
d.
If there may be a throttling requirement, soft seated ball valves and gate valves of any kind shall not be used for this duty. Gate valves have no effect on flow until they are almost closed but generate high velocities. Soft seated ball valves may suffer damage to the soft seat insert.
e.
Pressurising valve arrangements shall include an isolating valve and, preferably, include a throttling valve.
f.
Isolating valve shall be installed on bypass line side for tight shutoff of the pressurising line, and the throttling valve shall be installed on the balance line side to control the flow in the pressurising line.
g.
A balance valve shall be provided in the balance line such that flow can be diverted behind the pig by closing balance valve.
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h.
GP 43-50 Pigging, Pig Launchers, and Receivers
Drain valves for receivers shall be quarter turn valves having a high degree of abrasion resistance, such as tungsten carbide coated ball valves and stellite/carbide coated balanced plug valves. Receiver drain valves usually have to cope with highly abrasive service.
i.
Vent valves may be globe type but shall have a tight shutoff isolation valve (soft seated ball or balanced plug) in series.
j.
For gas service, blowdown valve shall be a tight shutoff ball or balanced plug valve with a downstream globe valve or orifice restriction.
k.
A 50 mm (2 in) isolating valve and a 50 mm (2 in) check valve shall be installed in purge connection, if applicable. The isolating valve shall be installed on the barrel side for tight shutoff of purge connection. The check valve is intended to prevent hydrocarbons entering the purge/flush line.
l.
Chemical injection connection, if required, shall include a tight shutoff valve of minimum diameter of 50 mm (2 in). Diameter of the connection shall be at least 50 mm (2 in).
m.
For LPG service, a double valve arrangement shall be installed in each drain and vent. Second valve in a double valve arrangement shall be placed sufficient distance apart from the first to provide an alternative means of closing the line. This is because the first valve may freeze, preventing it from being closed.
n.
Unless isolating valves are provided on each side, modified ball valves having a side entry point that allows the insertion and removal of pigs shall not be used on a live system. At least one valve manufacturer offers such modified ball valves that, while offering some operational facility, only provide single isolation between operator and the live process.
6.7.
Barrel design
6.7.1.
General
a.
Trap barrel shall be capable of launching one and receiving two standard cleaning or batching pigs.
b.
For launchers, the length of the barrel shall be sufficient to launch the longest ILI pig anticipated (See Figure 2). Development of crack detection tools may require the use of longer inspection tools than are currently available.
c.
For receivers, the length from the taper to the main valve shall be at least as long as longest pig. Total length of the major and minor barrel should be greater than the longest pig or the cleaning pig and maximum amount of debris (see Figure 3).
d.
For receivers, the length of pipe before expanding into the barrel shall be sufficient to ensure that the ILI tool fully passes through the receiver isolation valve.
e.
The major barrel shall be at least D plus 50 mm (2 in) for D less than or equal to 400 mm (16 in).
f.
For larger diameter, the major barrel shall be at least D plus 100 mm (4 in).
g.
The trap reducer shall be: 1.
Eccentric design for horizontal traps without an internal tray or basket and for inclined launcher traps (with the bottom of the entire barrel at the same level).
2.
Concentric design for vertical traps, inclined sphere receiver traps, or horizontal traps with an internal tray or basket.
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GP 43-50 Pigging, Pig Launchers, and Receivers
h.
Internal diameter of the minor barrel (neck pipe) shall be the same as that of the pipeline.
i.
If a trap may be used for facilitating hydrotesting or commissioning, an additional connection with a blind flange may be added.
j.
Transitions in the internal diameter due to wall thickness variations greater than 2,4 mm (0,094 in) shall be tapered to a minimum angle of 14 degrees to the pipe axis to allow for the smooth passage of pig.
k.
For horizontal receivers, barrel should be sloped (typically 1:100) down towards the drain at the end closure to improve draining of liquids from barrel.
l.
Horizontal launchers should be sloped (typically 1:100) down towards the pipeline.
m.
Sleeves may be required to facilitate launching in concentric vertical traps or if multiple module tools are used.
n.
Sleeves may be used to facilitate launching of separate cleaning tools to avoid the need to open the pig trap between launches.
o.
Universal pig traps may be used in some locations. These can be used to both launch and receive pigs.
p.
Sleeves and specialist launching systems may be used to facilitate multiple launches without the need to open and close pig trap between each launch.
q.
Length of the receive pig trap needs to be able to accommodate all pigs launched together with any products or debris that may be removed.
r.
If automatic sphering is intended: 1.
Major barrel length for launching and receiving shall be based on the number of spheres to be handled.
2.
Launcher barrel shall be inclined at sufficient angle to allow spheres to roll forward for launching and launcher barrel shall include retractable launcher pins.
3.
Receiver barrel shall be inclined at sufficient angle to allow spheres to roll away from the minor barrel/reducer. The minimum angle of inclination depends on the diameter of the pipeline and may range between 2 degrees and 10 degrees to the horizontal.
s.
Sphere release mechanisms, depending on environment location and pigging schedule, shall be of the mechanical finger, flap, or valve type. Mechanical fingers are not practical for use with traps in which the spheres exceed 500 mm (20 in). This is because of the high loads that a large sphere can exert.
6.8.
Pig trap end closures
6.8.1.
General
There have been a number of significant failures associated with pig trap end closures resulting in fatalities and release of hydrocarbons. These failures are attributable to design, operating, and maintenance practices. a.
End closure of new traps shall be designed in accordance with functional and safety requirements of the pressure vessel code. For example, ASME Boiler and Pressure Vessel Code Section VIII, Division 1, UG-35.2b.
b.
New trap closures shall have a double locking mechanism to prevent opening of closure under pressure.
Page 36 of 52
31 January 2009
c.
GP 43-50 Pigging, Pig Launchers, and Receivers
Recommended trap closures for new construction and replacement closures on existing launchers and receivers are one of the following: 1.
GD Engineering BANDLOCK2 type, which has a duplex stainless steel conical band fitted between the door and neck to transmit loads uniformly to the full 360 degree circumference of the neck.
2.
Pipeline Engineering (PE) (UK) ROC which is similar in design to the GD engineering closure. Double locking refers to redundancy in the mechanical retention system such that failure of any component will not cause accidental release of the closure door. It does not refer to interlock systems that are used to manage operational sequences.
d.
Guidance on end closure selection and testing requirements is given in Tables 3 and 4.
e.
Closure mechanisms involving the use of external clamp rings and threaded screws are not preferred but specific TDW, FAI, and LTS end closures are acceptable. Guidance on the use of external clamp type closures, including three acceptable vendors is provided in Annex B. These designs have lead to significant failures resulting in uncontrolled releases of hydrocarbons. If these designs are in current use, special operating and maintenance procedures are required. Annex B provides further requirements for safe application.
f.
Corrosion resistant overlays shall normally be provided on sealing surfaces. There have been a number of failures of end closures due to corrosion pitting on the seal surfaces. If this type of failure could occur either due to the pipeline contents or the external environment, use of overlays is recommended.
6.8.2.
External clamp ring closures
a.
Closure mechanisms involving the use of external clamps and threaded screws shall only be used if all of the following design conditions apply or have been verified: 1.
Full redundancy/safety system of the screws is achieved, as required in ASME Boiler and Pressure Vessel Code Section VIII, Division 1, Mandatory Appendix 24, such that even if the screw fails in service, the redundancy device would safely accommodate the loading. Redundancy device shall be designed for the same loading as the screw(s) and using the same design method.
2.
Redundancy device is connected to the interlock arrangement such that the redundancy device cannot be removed while the trap is under pressure.
3.
The screws are subject to the full stress analysis required by ASME Boiler and Pressure Vessel Code Section VIII, Division 1, Mandatory Appendix 24, including requirements for minimum angles and friction coefficients.
4.
Supporting devices for the screws, including trunnions, brackets, hinges, and webs, are designed for the full screw load in accordance with the pressure vessel calculations.
5.
If friction coefficients are critical to design and screw loads, the coefficient of friction shall be determined by practical trials.
6.
Screws shall be subject to strain gage testing during factory tests to demonstrate that the actual screw loads are less than the calculated values and that changes in stress with pressure are as predicted.
7.
During operation, screws shall be examined in accordance with manufacturer recommendations to ensure that they are fit for continued operation and are not excessively worn and have not been over strained. Page 37 of 52
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GP 43-50 Pigging, Pig Launchers, and Receivers
8.
Closure clamp angles (in radians) shall be less than the coefficient of friction used in design.
9.
A full finite element analysis of closure shall be conducted and all deflections and rotations shall be assessed to demonstrate that design assumptions remain valid under application of pressure (e.g., clamp angles are not changed significantly by the pressure loading).
10. Controls exist to ensure that tie rod cannot be overloaded during the preloading operation (e.g., torque limiting devices). Note: 1 through 10 are required even if the manufacturer claims satisfactory previous designs. b.
Existing end closures of this type shall be surveyed to identify components that could affect loading on the parts (e.g., wear, tolerances, out of alignment, damage). If the condition is acceptable, it is recommended that a redundancy device(s) be fitted, if not previously equipped.
c.
If an existing bolted external clamp end closure is non-compliant with 6.8.2.a, one of the following actions shall be taken: 1.
Replace the trap end closure or the entire trap.
2.
Conduct a formal review of pig trap operating procedures to ensure minimal risk to personnel using the existing trap. Determine whether pressurisation of pig traps can be achieved safely without having to operate valves in the immediate vicinity of closure.
3. 6.8.3.
Modify the pressurising system to enable valves to be operated at a safe distance from the closure).
End closure design and testing requirements
a.
b.
c.
The design shall include: 1.
Pressure vessel calculations and supporting stress analysis, typically in accordance with ASME Boiler and Pressure Vessel Code Section VIII, Division 2, Part 4.
2.
If the design is justified by calculation, a full design file shall be provided.
3.
Sealing areas and joints shall be assessed for relative displacement, deflection, opening, and/or closing of gaps.
4.
A full finite element analysis shall be provided for any new design.
5.
Use of materials other than those listed in the relevant pressure vessel codes shall be subject to agreement with BP. Allowable stresses for these materials shall also be subject to agreement with BP.
End closure testing 1.
Additional requirements, to the ones listed in Table 3, apply if the size and pressure rating are above the current range of operating experience.
2.
Proof testing, typically in accordance with requirements provided in ASME Boiler and Pressure Vessel Code Section VIII, Division 1, UG 101, is given in Table 4.
3.
Test reports and evidence of successful relevant operational experience of the closure shall be established.
Design and testing requirements for closures up to 1500 ANSI are summarised in Table 3.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Note: Additional requirements apply if the required pressure rating is above 1500 ANSI. Table 3 - Pig trap closure design requirements Size and pressure size and pressure made before of same design.
Size and pressure above those made before but < 1,2 x size and pressure.
Size and pressure > 1,2 x size and pressure made before or any new design.
GD, PE, and other internal and approved type closures
Review track record. Check design calculations. Design in accordance with ASME VIII, Div 1 or 2, and App 24 requirements. Supporting calculations and FEA to be included. Satisfactory experience without calculations is NOT acceptable. Independent design review optional.
Design verified by scaling previous designs. Review shall include detailed design, stresses, strains, clearances, extrusion gaps by scaling. Design verified by scaling. Independent design review recommended.
Full design review in accordance with ASME VIII, Div 2 Part 4, including full FEA of all parts, checking stresses, deflections, extrusion gaps, deflections and fits. Independent design review required.
External tie rod type (nonpreferred option)
Full design review in accordance with ASME VIII, Division 1, or ASME VIII, Div 2 with FEA. Tie rods shall have redundancy, and design parameters of App 24 (including minimum angles) to be adopted. (See design section). Satisfactory experience without calculations is NOT acceptable. Independent design review required.
Full design review in accordance with ASME VIII, Div 2 App 4, including full FEA of all parts, checking stresses, deflections, extrusion gaps, deflections and fits. Backup design in accordance with Div 1 App 24 also. Independent design review required.
Not permitted unless agreed otherwise.
Note: Term “size and pressure” refers to product size in mm/inches and pressure in bar/psi.
d.
End closure safety and operating gear shall be designed to ensure safety in operation and comply with the following: 1.
Failure of any single component of the locking and holding mechanism shall not lead to release of closure.
2.
Locking mechanism shall incorporate redundancy of critical components.
3.
At least one positively located safety bleed device shall be provided on the door to relieve any residual pressure before the door can be opened.
4.
Any release of residual pressure shall be directed away from the operator.
5.
Visual examination of the security and integrity of the locking and holding elements, if in the closed position, shall be enabled.
e.
Allow for full maintenance, including greasing and realignment of mating surfaces in situ.
f.
Manually operated closures shall be easy to operate by one person using hand tools only.
g.
Door closure mechanism shall be able to be maintained without removal of whole trap.
h.
Pig trap door should have mechanical device to ensure that the door cannot be accidentally dislodged from mountings.
i.
Materials for appurtenances, including bleed valve, hinges, locking, and holding mechanisms, shall be selected to provide good environmental corrosion resistance, as well as long term reliable operation.
j.
If required, end closure shall be suitable for vacuum conditions. This is to allow the pipeline to be vacuum dried.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Table 4 - Pig trap closure test requirements Size and pressure size and pressure made before.
Size x pressure < 1,2 x size and pressure made before.
Size and pressure > 1,2 x size and pressure made before.
GD, PE, and other internal type closures
Hydrotest in accordance with the design code followed by a leak test at a minimum of 1,1 x design pressure at least two cycles, using water for liquid service traps and gas (nitrogen/helium) for gas service traps. Check seals and all moving parts for extrusion and degradation after test.
Hydrotest in accordance with the design code. Check for any shakedown and dimensional changes after pressure test. Check dimensions for any deformation and clearances against design valves. After hydrotest, leak tests at 1,1 x design pressure, 5 cycles minimum, using water for liquid service and gas (nitrogen/helium) for gas service traps. Check seals and moving parts for extrusion and degradation after test.
Hydrotest in accordance with the design code, with strain gages in critical stress locations. Check for any nonelastic behaviour during test and for any inconsistencies between strain gage and theoretical stress values. Check for any shakedown and dimensional changes after pressure test. Check any deformation and clearances against design valves. After hydrotest, leak test at 1,1 x design pressure, 10 cycles minimum, using water for liquid service and gas (nitrogen/helium) for gas service traps. Check seals and moving parts for extrusion and degradation after test.
External tie rod type (nonpreferred option)
Hydrotest in accordance with the design code. Tie rod(s) to be strain gaged during hydrotest, and strain values judged against design values. Note: redundancy device to be removed during strain gage test of tie rod. After hydrotest, leak test at a minimum of 1,1 x design pressure at least 5 cycles, using water followed by 5 cycles on gas (nitrogen/helium) for gas service traps. Redundancy device removed for water tests, and installed for gas tests. Check seals and all moving parts for extrusion and degradation after each cycle.
Hydrotest in accordance with the design code, with strain gages in critical stress locations including tie rods. Note: redundancy device to be removed during strain gage test of tie rod(s). Check for any nonelastic behaviour during test and for any inconsistencies between strain gage and theoretical stress values. Check for any shakedown and dimensional changes after pressure test. Check any deformation and clearances against design valves. After hydrotest, leak test at a minimum of 1,1 x design pressure at least 10 cycles, using water followed by 10 cycles on gas (nitrogen/helium) for gas service traps. Redundancy device removed for water tests and installed for gas tests. Check seals and moving parts for extrusion and degradation after each cycle.
Not permitted.
Note: Term “size and pressure” refers to product size in inches/mm and pressure in psi/bar.
k.
Closure hinges and locking mechanisms shall be suitable for repeated operation. Failures of pig traps have occurred due to mechanical wear after period of time.
l.
Fatigue calculations shall include the end closure.
m.
Fillet welds and the hinges shall be fabricated, designed, and mounted to prevent sagging of the door, if opened, over the specified design life of the pig trap end closure.
n.
Blind flanges shall not be considered for frequently used trap end closures. Blind flanges are sometimes useful for temporary or infrequently used pig traps.
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GP 43-50 Pigging, Pig Launchers, and Receivers
6.9.
Materials, fabrication, welding, and marking
6.9.1.
Materials
a.
Materials shall comply with the pipeline design code. Materials selected shall be suitable for the design minimum temperature for pig trap.
b.
For sour service applications, GP 06-20 shall apply.
c.
Plate and forged materials are preferred for manufacture of pig traps.
d.
Plate may be subject to HIC testing for sour service applications.
e.
Castings shall only be allowed if:
f.
1.
Suitable NDE is applied, including volumetric.
2.
Repaired welds are mapped.
3.
No weld repairs require removal of more than 25% of the weld thickness.
4.
A pilot casting approach has been used.
5.
Pouring simulations/finite element analysis of the method has been used.
Flanges shall be specified in accordance with ASME B16.5 or MSS SP-44, as appropriate according to size, and shall be the same as those of connected pipeline. Requirements on bolt tightening is given in GP 46-01, Annex Q.
6.9.2.
6.9.3.
g.
Fittings shall comply with ASME B16.9 or MSS SP-75 as appropriate. Threaded connections shall not be used.
h.
Attention shall be given to the compatibility of any weld end pup pieces with the pipeline.
Fabrication
a.
Fabrication shall comply with applicable pipeline code or GIS 46-010 and GP 46-01.
b.
Fabrication shall take into account tolerances required for door closure, timing of any required heat treatment, and machined finish.
c.
The inside of the trap shall be free from obstructions that could prevent the free rolling of spheres or travel of pigs or carriers.
d.
External nonmachined surfaces shall be coated.
e.
Machined surfaces shall be suitably coated to prevent corrosion and shall be protected against damage during transport, storage, and installation.
f.
If the end closure is manufactured by a different vendor than the pig trap fabricator, the end closure shall be fully inspected in accordance with manufacturer recommendations to ensure that the end closure functions correctly and has not been damaged.
Marking
a.
A stainless steel plate shall be fitted to end closure with permanent marking stating that the operator shall refer to the manufacturer instructions for the safe operation of the closure. Typical nameplates for pressure vessels are given in GIS 46-020.
b.
Each pig trap shall have a nameplate with the following information: 1.
Name of the pipeline in which the trap is installed.
2.
Vendor name.
3.
Order number and date.
4.
Year of manufacture. Page 41 of 52
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6.9.4.
GP 43-50 Pigging, Pig Launchers, and Receivers
5.
Design pressure.
6.
Maximum and minimum design temperatures.
7.
Test pressure.
8.
Weight empty.
9.
Class of flange connections.
Inspection and hydrotest of new and refurbished traps
a.
Inspection shall be performed in accordance with applicable requirements of the code. Additional requirements may be required for thick material and low temperature applications in accordance with GIS 46-010.
6.9.5.
7. 7.1.
b.
Parent material for the main barrel, reducer, and neck shall be subject to 100% visual inspection.
c.
Radiographic examination should be by X-ray.
d.
Ultrasonic examination shall be used for pig traps intended for onerous service and for wall thickness over 30 mm (1,2 in).
e.
Surface examination shall be by wet magnetic particle.
f.
End closure, mating clamp and flange machined surfaces, door hinges, hinge attachments, and locking mechanisms shall be subject to magnetic particle inspection (or dye penetrant inspection if fabricated from nonmagnetic materials).
g.
Hydrotest shall be performed with clean fresh water at a temperature not lower than that permitted by the code.
h.
Duration of the test shall comply with applicable code and be at least 1 hr.
i.
Any gaskets to be supplied with the pig trap shall be replaced with new ones following the hydrotest.
j.
Closures intended for gas service shall be subject to a gas leak test of 1,1 times design pressure as part of the factory acceptance test and following the hydrotest.
k.
Leakage rates shall be assessed using helium trace and acceptance criteria shall be 0,14 m3/yr (5 scf/yr).
Inspection and testing of existing pig traps
a.
Pig traps shall be inspected and revalidated for continued operation at regular intervals not normally exceeding 5 yr. Local regulations, requirements, or service conditions may require more frequent inspection and testing.
b.
Inspections shall be performed by a competent engineer, who shall make reference to the manufacturer recommendations for inspection and maintenance of end closures.
c.
Revalidation may require periodic hydrotest in accordance with manufacturer recommendations.
Special applications Subsea traps a.
Permanent subsea traps should be avoided, if possible. Subsea traps are difficult to maintain and may require a large protection structure.
b.
Design should comply with the applicable pipeline code and ISO 13628-1.
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GP 43-50 Pigging, Pig Launchers, and Receivers
This may apply additional restraints on material selection and requirements for marking. c.
Valves requiring onsite subsea operation shall be ROV operable. The standard interface with ROV should comply with the applicable pipeline code or ISO 13628-8.
d. 7.2.
Anchor points shall be provided to assist pig loading and unloading.
Pigging of flexibles The following features of flexibles affect the choice of pigging: Some flexibles have a corrugated stainless steel inner carcass, as opposed to a smooth polymeric liner. This has the following implications: • •
To reduce fluid bypass, a double cup arrangement is recommended. The stainless steel carcass can be damaged or contaminated if incompatible materials, such as carbon steel wire brushes or gaging plates, are used.
Nominal pipe dimensions are referenced to the ID rather than the OD, which means that the nominal bore is likely to be significantly different than that of the corresponding steel pipe. There may be further ID reductions at the end connectors. The complicated construction makes interpretation of intelligent pigging by MFL or UT difficult and suitable inspection techniques are in development (e.g., by use of eddy current sensors). No limitations on minimum radii are required, since the minimum bend radius of flexibles is usually greater than that for pigging. 7.3.
7.4.
Tanker/barge loading lines a.
For some pipelines that may have been installed with only one pig trap, pigging shall be performed from one end only. If tethered tools are used, safe isolation procedures shall be used.
b.
Pigging of the line requires use of bidirectional pigs and capability to reverse the flow, or tethered pigs should be used.
c.
The following factors shall be taken into consideration if determining the piggability of a line: 1.
History of the line.
2.
Means of reversing the flow and associated modifications required to the line.
3.
Space and equipment requirements needed for the pig trap if not already installed.
4.
The scope to use gel pigs rather than conventional pigs to minimise intervention for debris removal.
Temporary pig traps a.
If temporary pig traps are used on several systems, a record shall be maintained of where and if the traps have been used.
b.
Traps shall be visually inspected before each use, with periodic revalidation.
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GP 43-50 Pigging, Pig Launchers, and Receivers
Annex A
(Informative)
Recommended pig trap closures Table A.1 and Table A.2 are current recommended pig trap end closures and their potential operation range based on information provided by vendors. a.
Cells marked with “ ” indicate that a design is available with supporting design documentation and test verification data.
b.
Cells marked with “?” indicate that a design is available, but further verification and testing is required.
c.
Cells marked with “X” indicate that no design is currently available. Table A.1 - GD Engineering (GD): Type BANDLOCK 2
ANSI class Diameter (in)
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