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API calls for pipeline permit reforms following shutdowns

Written By pipeline-engineer.com on Saturday, July 11, 2020 | 12:24:00 AM


WASHINGTON – The American Petroleum Institute released the following statement from President and CEO Mike Sommers in response to the cancellation of the Atlantic Coast Pipeline and a court ruling to shut down the Dakota Access Pipeline. "Between the Atlantic Coast Pipeline cancellation and now the ruling to shut down the Dakota Access Pipeline – we are deeply troubled by these setbacks for U.S. energy leadership. Our nation’s outdated and convoluted permitting rules are opening the door for a barrage of baseless, activist-led litigation, undermining American energy progress and denying local communities the environmental, employment and economic benefits modern pipelines provide. The need to reform our broken permitting system has never been more urgent." API represents all segments of America’s oil and natural gas industry. Its more than 600 members produce, process, and distribute most of the nation’s energy. The industry supports 10.9 million U.S. jobs and is backed by a growing grassroots movement of millions of Americans. API was formed in 1919 as a standards-setting organization. In its first 100 years, API has developed more than 700 standards to enhance operational and environmental safety, efficiency and sustainability.
12:24:00 AM | 0 comments

PT Perusahaan Gas Negara (PGN) begin construction on a 367 km Crude Oil Pipeline in the Rokan Block.

Written By pipeline-engineer.com on Sunday, June 21, 2020 | 7:00:00 PM


Jakarta (ANTARA) - Indonesia's state gas utility PT Perusahaan Gas Negara (PGN) will begin construction on a 367-kilometer (km) crude oil pipeline in the Rokan Block, Riau, in July.



The project, located in the corridors of Minas-Duri-Dumai and Balam-Bangko Dumai, will connect the Rokan oil block to Pertamina's Dumai refinery in the province.



PGN's Director of Infrastructure and Technology Redy Ferryanto stated here on Friday that the project aimed to boost synergy between subsidiaries of the PT Pertamina Group.



The project is projected to boost oil production and lifting from the Rokan Block, the backbone of national oil production, which constitutes one-third of the country's output.



"With budget allocation of some US$300 million, PGN has cut capital expenditure, with efficiency of some 30 percent. The project is estimated to become one of PGN's major projects in its target of capital expenditure for 2020. The Financial Investment Decision (FID) of the Rokan pipelines project is expected to optimize efforts to enhance efficiency," he noted.

Ferryanto affirmed that 250 thousand barrels of oil per day will be transported from Rokan to Pertamina’s refinery in Dumai.



The construction project is targeted for completion by the end of 2021.

The pipeline comprise 12 segments and three stations: Duri, Dumai, and Manifold Batang.



Pertagas, part of Indonesia's Gas Holding, will handle the construction project as well as its operations and maintenance.

The project is envisioned to have a positive impact to augment the company's revenue from crude oil transportation business, particularly for its contractors of the cooperation contract (KKKS), such as PT Chevron Pasific Indonesia (CPI), BOB Bumi Siak Posako, and other KKKS.



"Construction of the pipelines is a national strategic project to support national energy resilience. Oil production in the Rokan Block is expected to increase national oil lifting as a primary energy to boost the national economy," Ferryanto added.
7:00:00 PM | 0 comments

Fire fighting System An Overview

Written By pipeline-engineer.com on Tuesday, May 26, 2020 | 8:20:00 AM

Firefighting

Ian Sutton, in  Plant Design and Operations (Second Edition), 2017


Firewater Systems generally has four main sections:

1.
A supply of firewater. This can come from storage tanks, a firewater lagoon, or a natural body of water such as the sea or a lake or river.
2.
A pumping system that provides a sufficient flow of water to extinguish the fire.
3.
A header network of pipes, often in the form of a ring main that transfers the water from the pumps to the fire.
4.
Hydrants, nozzles, sprinklers, or other local devices for directing the firewater to the location of the emergency.




Fig.1 Below can be used to describe some of the major components of a firefighting system.


The facility is divided into zones. If a fire starts in a particular area, water will flow through the nozzles that protect that area.





If a fire occurs in one of the zones, a fusible link will fail, causing the pressure control deluge valve (PCDV) to open and the main firewater pumps to start. Water will flow out of the sprinkler heads in that zone only. The PCDV can also be tripped manually.
Individual sections can be isolated for maintenance. However, the isolation of one zone should not lead to the isolation of other parts of the system. For example, if Zone 2 in Fig. 12.1 has to be isolated, then Valves A and B will be closed. However, Valve C remains open so that firewater remains available to Zone 3.




The only exception to this policy of having two routes to a zone is with regard to noncritical areas such as the fire training grounds. Such areas can be isolated with a single valve.
There are two firefighting pumps, each with 100% capacity. If one is down for maintenance, the facility still has full firefighting capability.




Pressure is maintained in the header through use of a jockey pump. If the pressure in the header falls—indicating that the firewater is being used somewhere —the main pumps turn on. In some facilities, the jockey pump is primed with cooling water.




If freshwater is used, the main header will generally be liquid full. If it was dry, it would take a long time to fill it—something that would delay the emergency response. However, if seawater is used as the firefighting medium, the headers will normally be dry because they would otherwise be subject to corrosion. If during an emergency a normally freshwater-filled system has to be replenished with more corrosive water (such as seawater), the system can still be considered a freshwater system, assuming that prompt flushing takes place after emergency use to replace the corrosive water in the system.
The sprinkler systems downstream of their own block valves  are generally dry. It will not take long to fill them and having water permanently present could lead to leaks and corrosion.




Fig.1 shows the location of a “Critical Equipment Item.” This means that a high level of fire protection should be applied to that area, either because it is of high value or because a release could cause a major safety problem, maybe by making the fire worse. This area, therefore, is protected from both Zones 4 and 5. Consequently, were one of those zones to be out of service for any reason, the critical equipment would still be protected.




Once the fire has been brought under control the system is reset. If seawater is used, then it is important to flush the zone headers and deluge nozzles with freshwater, otherwise  corrotion products will build up.



Problems with firewater systems can be overlooked for the following reasons:
The system is rarely tested at full capacity so it is possible that it will not work as it should during an emergency. (There are less likely to be problems with hoses, hydrants, and monitors because these items are used on a more regular basis and can be tested more readily.)
The firewater pumps are usually located remotely hence they may not be checked as regularly as process equipment.




For onshore facilities, the firewater header is frequently located underground, thus protecting it from an explosion and vehicle impact. However, putting the header underground can create an “out of sight, out of mind” problem—buried systems may not be inspected and checked as thoroughly as those above ground, hence any problems are not easily seen during the routine external inspections discussed in Chapter 11, Inspection.




They may also be more subject to external corrosion  than if they were above ground. A compromise is to place the header in a below-grade trench. Doing so protects it from explosions but also allows for easy access for inspection and maintenance. This option may also reduce the cost of installation.

8:20:00 AM | 0 comments

Hot Bend and How it's Made

Written By pipeline-engineer.com on Saturday, May 16, 2020 | 10:56:00 AM


Induction Bending is a controlled means of bending pipes through the application of local heating using high frequency induced electrical power.




Originally used for the purpose of surface hardening steels, induction technology when used in pipe bending consists basically of an induction coil placed around the pipe to be bent. The induction coil heats a narrow, circumferential section of the pipe to a temperature of between 850 and 1100 degrees Celsius (dependant on the material to be formed). As the correct bending temperature range is reached, the pipe is moved slowly through the induction coil whilst the bending force is applied by a fixed radius arm arrangement.



Manufacture of Induction Bends

Induction bends are formed in a factory by passing a length of straight pipe through an induction bending machine. This machine uses an induction coil to heat a narrow band of the pipe material. The leading end of the pipe is clamped to a pivot arm.

As the pipe is pushed through the machine, a bend with the desired radius of curvature is produced. The heated material just beyond the induction coil is quenched with a water spray on the outside surface of the pipe. Thermal expansion of the narrow heated section of pipe is restrained due to the unheated pipe on either side, which causes diameter shrinkage upon cooling.

The induction bending process also causes wall thickening on the intrados and thinning on the extrados. The severity of thickening/thinning is dependant on the bending temperature, the speed at which the pipe is pushed through the induction coil, the placement of the induction coil relative to the pipe (closer to the intrados or extrados), and other factors.



Most induction bends are manufactured with tangent ends (straight sections) that are not affected by the induction bending process. Field welds are made or pipe pup sections are attached to the unaffected tangent ends, allowing for fitup similar to that found when welding straight sections of pipe together.



Induction bends come in standard bend angles (e.g. 45°, 90°, etc.) or can be custom made to specific bend angles. Compound bends (out-of-plane) bends in a single joint of pipe can also be produced. The bend radius is specified as a function of the diameter. For example, common bend radii for induction bends are 3D, 5D and 7D, where D is the nominal pipe diameter.



Benefits of Induction Bends

  • Large radii for smooth flow of fluid.
  • Cost efficiency, straight material is less costly than standard components (e.g. elbows) and bends can be produced faster than standard components can be welded.


  • Elbows can be replaced by larger radius bends where applicable and subsequently friction, wear and pump energy can be reduced.
  • Induction bending reduces the number of welds in a system. It removes welds at the critical points (the tangents) and improves the ability to absorb pressure and stress.


  • Induction bends are stronger than elbows with uniform wall thickness.
  • Less non-destructive testing of welds, such as X-ray examination will save cost.
  • Stock of elbows and standard bends can be greatly reduced.
  • Faster access to base materials. Straight pipes are more readily available than elbows or standard components and bends can almost always be produced cheaper and faster.

  • A limited amount of tools is needed (no use of thorns or mandrels as required in cold bending).
  • Induction bending is a clean process. No lubrication is needed for the process and water needed for the cooling is recycled.



ASME B16.49

ASME B16.49 Standard covers design, material, manufacturing, testing, marking, and inspection requirements for factory-made pipeline bends of carbon steel materials having controlled chemistry and mechanical properties, produced by the induction bending process, with or without tangents.


This standard covers induction bends for transportation and distribution piping applications (e.g., ASME B31.4, B31.8, and B31.11). Process and power piping have differing requirements and materials that may not be appropriate for the restrictions and examinations described herein, and therefore are not included in this Standard


10:56:00 AM | 0 comments

Talking About Pig Launcher and Receiver

Written By pipeline-engineer.com on Monday, March 23, 2020 | 6:15:00 AM

Variety of applications, locations and product types of Pig Launcher and Receiver, along with a wide array of designs – some good, some bad, natural gas and liquid pig launchers and receivers should differ in design but share some common features. Certain applications require specially designed units. For example:
  • Offshore sites where space is limited, and vertical units are more suitable.
  • Wet gas gathering systems when lines may need to be pigged several times a day or week to remove liquids. Automating these units saves manpower, reduces gas releases, cuts valves maintenance cost, and addresses safety concerns.
PIG Launcher & Receiver

Some companies attempt to design a combination pig launcher and receiver unit to perform both functions. This can be done. However, it is costly, complicates the launching and receiving process and very few pipelines flow bi-directionally.


Launching and receiving pigs is not as simple as some people think. You are venting or draining high-pressure gas or liquids, which requires certain valves to be opened and closed in the proper sequence. A quick opening closure must be opened to allow access to either the launcher or receiver for insertion or removal a pig. At this point, an explosive environment has been created and often the valves isolating the unit are leaking slightly.
What are the key considerations when building pig launchers and receivers?
1) Purpose of pigging – Pipelines are normally pigged for one or more of the following reasons:
  • Cleaning: To improve flow efficiency or reduce internal corrosion.
  • Displacement: To displace the line contents.
  • Batching: To separate different products within an operating pipeline.
  • Inline inspection: To perform an internal inspection with an inline inspection (ILI) tool for integrity purposes.
One must establish a need to pig a pipeline before investing in the installation and operation of a pig launcher and receiver.
2) Size – A typical designation for pig launchers/receivers would be:
  • 10-inch by 12-inch 300# pig launcher or pig launch system
    • This would indicate a launcher for a 10-inch pipeline with a 12-inch oversize barrel that allows the operator to slide the pig into launch position. The maximum operating pressure could be 740 psi. The word “system” generally implies that all valves and associated piping are included.
  • 20-inch by 24-inch 600# pig receiver or pig receive system
    • This would indicate a receiver for a 20-inch pipeline with a 24-inch oversize barrel and could have a maximum operating pressure of 1480 psi.


We recommend the oversize barrel be one size larger than the pipe size for pipe diameters up to 10-inch (i.e., 6-by-8, 10-by-12). On any pipe size of 12 inches or larger, the barrel size should be at least two pipe sizes larger (such as 16-by-20, 20-by-24). An odd sized barrel would be a reason to increase the barrel size to the next readily available pipe size, such as 24-by-30.


3) Length – The launcher or receiver length is determined by the type of pigs used. Today, most launchers and receivers are designed to accommodate the length of an ILI tool. A unit long enough for an ILI tool is certainly a sufficient length for cleaning, batching, and displacement pigs. The ILI tools have gotten longer due to multi-data set technologies. Each section of an ILI tool collects different types of data, which provides detailed information on the integrity of the pipeline. As a rule of thumb, we consider an ILI tool to be 15 feet long on average. Therefore, the oversize barrel should be slightly longer than 15 feet and the receiver should have a length of line size pipe to ensure the ILI tool has cleared the mainline trap valve. A receiver designed to handle an ILI tool will need to be over 30 feet long. The launcher can be shorter due to the line size portion being 8 feet to 10 feet shorter. If the pipeline is not to be designed for ILI tools, the length of the launcher and receiver can be reduced accordingly. Cleaning, batching, and displacement pigs are approximately two pipe diameters in length. Receivers should be designed to be long enough to hold at least two pigs.


4) Pressure rating – Launchers and receivers are normally designated to a flange rating of 300#, 600#, 900#, etc. However, the actual working pressure and test pressure are determined by the operating conditions and design code of the pipeline system. Most operators will designate the Max Operating Pressure (MOP) and set a pressure rating to which the launchers and receivers are to be designed. We recommend the design factor be at least 0.5 since launchers and receivers see multiple pressure cycles throughout their lifetime that the pipeline does not experience.
5) Launcher design vs. receiver design – We have already discussed why the launcher is generally shorter than the receiver. The launcher and receiver have the same number of nozzles but differ in location for a variety of reasons. The launcher should have a “kicker line” located near the closure, allowing flow to be directed behind the pig for a successful launch. This “kicker line” is normally sized one-third to one-half the size of the pipeline. A 12-inch pipeline would have a 4-inch to 6-inch kicker line. For a 12-inch line, we recommend a 6-inch kicker on a natural gas pipeline and a 4-inch kicker on a liquid pipeline. On the receiver, we call this line the “receiver bypass line.” This line should be located near the reducer entering the oversize barrel. This location allows the flow to exit the receiver without the pig interrupting the flow, space for the pig to come to rest in the oversize barrel without striking the closure door and easy retrieval.
Both launchers and receivers should have a vertical vent line above head height located near the closure and a pressure gauge connection near the closure allowing the operator to view the line pressure within the unit. Liquid units should have a drain system that allows the liquid to drain into a sump tank. This drain system on the receiver should have a minimum of two drain connections in front of and behind where the pig comes to rest. This prevents the drains from being blocked by the pig and allows the entire barrel to be drained. These vents and drains should be appropriately sized to allow for the venting and draining to be achieved in a reasonable timeframe. It is not ideal to drain a 36-inch by 40-inch receiver through a 2-inch drain. The other crucial nozzles on both the launcher and receiver are the equalization lines. These lines allow the pressure and product to be filled, vented and equalized on either side of the pig. The loading of long and heavy ILI tools can be difficult because the tools have flexible joints with several sections. These tools can be loaded using a tray or a system of nozzles and cables to assist with loading. Pig indicators are critical in determining if the pig has been launched or received and must be installed in the correct position. The pig indicator on the launcher should not be installed on the launch barrel but downstream of the mainline bypass tee. The pig indicator on the receiver should be installed on the line size pipe near the reducer on the receiver barrel. Pig indicators are a critical component; we recommend that two be installed at each location for redundancy, should one fail.



6) Launcher/receiver systems vs. launcher/receiver barrels – The term “system” indicates the unit includes all valves and associated piping. Systems are normally skid mounted, and a completed pigging system requires two major field tie-ins to put it in service. The system is hydro-tested as a complete unit and functionally tested prior to delivery. The site is usually prepared by pouring concrete piers to support the skid weight, then set into position, then bolt connected to the inlet and outlet. This saves a tremendous amount of field installation cost. This also allows for easy access to all the major components for future maintenance needs. A launcher/receiver barrel does not include the valves, piping and skid mounted assembly, which must be assembled, fabricated and tested in the field. Complete pigging systems will save money in the short- and long-term and, if necessary, can be relocated.


7) Product type – Gas launchers and receivers differ from liquid launchers and receivers for some of the same reasons. The primary differences are:
  • Design Code (ASME B31.8 Gas vs. ASME B31.4 Liquid)
  • Drains and sump tanks are required on liquid launchers and receivers and may also be needed on gas receivers when handling liquids.
When pig launchers and receivers are designed correctly, the benefits you receive are: 
  • The right design has safety features that eliminate accidents.
  • The right design reduces operation and field installation cost.
  • The right design eases the launching and receiving process.
  • The right design allows for consistency in launching and receiving procedures and operator qualifications.
  • The right design assures the unit complies with applicable codes and standards.


6:15:00 AM | 0 comments

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