I have worked in oil and gas for 4 years and I decided to share my information with others, maybe it helps somebody. I will write about piping, oil and gas equipments.
What is piping?
Within industry, piping is a system of pipes used to convey fluids (liquids and gases) from one location to another. The engineering discipline of piping design studies the efficient transport of fluid.
Industrial process piping (and accompanying in-line components) can be manufactured from wood, fiberglass, glass, steel, aluminum, plastic, copper, and concrete. The in-line components, known as fittings, valves, and other devices, typically sense and control the pressure, flow rate and temperature of the transmitted fluid, and usually are included in the field of Piping Design (or Piping Engineering). Piping systems are documented in piping and instrumentation diagrams (P&IDs). If necessary, pipes can be cleaned by the tube cleaning process.
"Piping" sometimes refers to Piping Design, the detailed specification of the physical piping layout within a process plant or commercial building. In earlier days, this was sometimes called Drafting, Technical drawing, Engineering Drawing, and Design but is today commonly performed by Designers who have learned to use automated Computer Aided Drawing / Computer Aided Design (CAD) software.
Plumbing is a piping system that most people are familiar with, as it constitutes the form of fluid transportation that is used to provide potable water and fuels to their homes and business. Plumbing pipes also remove waste in the form of sewage, and allow venting of sewage gases to the outdoors. Fire sprinkler systems also use piping, and may transport nonpotable or potable water, or other fire-suppression fluids.
Piping also has many other industrial applications, which are crucial for moving raw and semi-processed fluids for refining into more useful products. Some of the more exotic materials of construction are titanium, chrome-moly and various other steel alloys.
Pipes:
Based on the NPS (Nominal Pipe Size) and schedule(wall thickness) of a pipe, the pipe outside
diameter (OD) and wall thickness can be obtained from reference tables such as
those below, which are based on ASME standards B36.10M and B36.19M. For
example, NPS 14 Sch 40 has an OD of 14 inches and a wall thickness of 0.437
inches. However the NPS and OD values are not always equal, which can create
confusion.
- For NPS ⅛ to 12 inches, the NPS
and OD values are different. For example, the OD of an NPS 12 pipe is
actually 12.75 inches. To find the actual OD for each NPS value, refer to
the tables below. (Note that for tubing,
the size is always the actual OD.)
- For NPS 14 inches and up, the
NPS and OD values are equal. In other words, an NPS 14 pipe is actually 14
inches OD.
The reason for the discrepancy for
NPS ⅛ to 12 inches is that these NPS values were originally set to give the
same inside diameter (ID) based on wall thicknesses standard at the
time. However, as the set of available wall thicknesses evolved, the ID changed
and NPS became only indirectly related to ID and OD.
For a given NPS, the OD stays fixed
and the wall thickness increases with schedule. For a given schedule, the OD
increases with NPS while the wall thickness stays constant or increases. Using
equations and rules in ASME B31.3 Process Piping, it can be shown that pressure
rating decreases with increasing NPS and constant schedule.
Some specifications use pipe
schedules called standard wall (STD), extra strong (XS), and double extra
strong (XXS), although these actually belong to an older system called iron
pipe size (IPS). The IPS number is the same as the NPS number. STD is identical
to SCH 40S, and 40S is identical to 40 for NPS 1/8 to NPS 10, inclusive. XS is
identical to SCH 80S, and 80S is identical to 80 for NPS 1/8 to NPS 8,
inclusive. XXS wall is thicker than schedule 160 from NPS 1/8" to NPS
6" inclusive, and schedule 160 is thicker than XXS wall for NPS 8"
and larger.
The "S" designation, for
example "NPS Sch 10S", most often indicates stainless steel pipes.
However some stainless steel pipes are available in steel designations, so
strictly speaking the "S" designation only differentiates B36.19M
pipe from B36.10M pipe.
piping codes
& standards
The integrity of a piping system depends on the
considerations and principles used in design, construction and maintenance of
the system. Piping systems are made of many components as pipes, flanges,
supports, gaskets, bolts, valves, strainers, flexibles and expansion joints.The
components can be made in a variety of materials, in different types and sizes
and may be manufactured to common national standards or according a
manufacturers proprietary item. Some companies even publish their own internal
piping standards based upon national and industry sector standards.
Piping
codes and standards from standardization organizations as ANSI, ASME, ISO, DIN
and others, are the most common used in pipes and piping systems
specifications. Here are some abbreviations:
ASME
ASTM
ANSI
AWWA
API
BSi
DIN
ISO
JIS
|
American
Society Of Mechanical Engineers
American
Society for Testing and Materials
American
National Standards Institute
American
Water Works Association
American
Petroleum Institute
British standards and specifications
Deutsches Institut für Normung
International Organization for Standardization
Japanese Industrial Standards
|
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B31.1
B31.2
B31.3
B31.5
B31.9
|
Power
Piping
Fuel Gas
Piping
Chemical
Plant And Petroleum Refinery Piping
Refrigeration
Piping
Building
Service Piping
|
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PPI
AWS
PFI
MMS
|
Plastic
Pipe Institute
American
Welding Society
Pipe
Fabrication Institute
Manufacturers
Standardization Society of Valve
and
fitting Industry
|
Piping connection types:
BUTT WELDED
SOCKET WELDED
SCREWED
The buttwelding ends are prepared by beveling each end of the
valve to match a similar bevel on the pipe. The two ends are then butted to the
pipeline and joined with a full penetration weld.This type of joint is used on
all valve styles and the end preparation must be different for each schedule of
pipe. These are generally furnished for control valves in sizes 2-1/2-inch and
larger.
Socket
Weld Connection
The socket welding ends are prepared by
boring in each end of the valve a socket with an inside diameter slightly
larger than the pipe outside diameter. The pipe slips into the socket where it
butts against a shoulder and then joins to the valve with a fillet weld.
Socket welding ends in a given size are
dimensionally the same regardless of pipe schedule. They are usually furnished
in sizes through 2-inch.
