Saturday, May 5, 2012

Access Provisions-Process Unit and Offsites Layout

Minimum Access Provisions-Process Unit and Offsites Layout

Guide



Minimum
Access

Type of
Item to be Accessed

Platform
- Items Located
Over Platform

Elevated
heat exchangers
Elevated
control valves (all sizes)
Manholes
(higher than 3658 mm (12 ft.) above grade)
Relief
valves (NPS 102 mm (4”) inlet and larger on vertical vessel)
Process
blinds (higher than 3658 mm (12 ft.) above grade)
Furnace
soot blowers
Furnace
burners (when not accessible from grade)
Furnace
observation doors and sample ports (higher than 3658 mm
(12
ft.) above grade)
Elevated cleanouts

Platform
- Items Located
at Edge of Platform

NPS
102 mm (4”) and larger gate and globe valves at vessels
Battery
limit valves in elevated pipe racks
Elevated
motor operated valves
Relief
valves - NPS 77 mm (3”) inlet and smaller on vertical vessels
Relief
valves - All sizes on horizontal vessels
Level
controllers (higher than 3658 mm (12 ft.) above grade)
Sampling
devices on vessels (higher than 3658 mm (12 ft.) above
grade)

Permanent Ladder

All
sizes of check valves at vessels
NPS
77 mm (3”) and smaller gate and globe valves at vessels
Level
controllers between 2134-3658 mm (7-12 ft.) above grade
Level
gauges and valves
Furnace
observation ports between 2134-3658 mm (7-12 ft.) above grade
Instruments
requiring routine access
Handholes
Elevated electrical
substations and equipment

Mobile Stair

All
servicing between 2134-3658 mm (7-12 ft.) above grade except as
noted in this Table

No Permanent Access

Block
valves in pipe racks (except at battery limit)
Elevated
orifices or meter runs
Nozzles
on vessels (without process blinds or valves)
Check
valves not at vessels
Temperature
connections in piping
Pressure
connections in piping
Silencers
or exhaust heads
Metal
temperature measuring points on vessels
Instrument
connections on furnaces

PIPE - CHAPTER 1

INTRODUCTION

DEFINITION:
Piping engineering is all about designing, fabricating and constructing lines for conveying fluids.

IMPORTANCE OF PIPING ENGINEERING:
  • To maintain pressure difference (Δp)
  • To maintain temperature difference (Δt)
  • To maintain flow rate (Δq)


APPLICATIONS:
·               Pipelines carry crude oil from oil wells to tank farms for storage or to refineries for processing.
·               The natural gas transportation and distribution lines convey natural gas from the source and storage tank forms to points of utilization, such as power plants, industrial facilities etc,
·               In chemical plants, paper mills, food processing plants, and other similar industrial establishments, the piping systems are utilized to carry liquids, chemicals, mixtures, gases, vapors, and solids from one location to another.
·               The fire protection piping networks in residential, commercial, industrial, and other buildings carry fire suppression fluids, such as water, gases, and chemicals to provide protection of life and property.
·               The piping systems in thermal power plants convey high-pressure and high temperature steam to generate electricity. Other piping systems in a power plant transport high- and low-pressure water, chemicals, low-pressure steam, and condensate.
·               Sophisticated piping systems are used to process and carry hazardous and toxic substances.
·               The piping systems in laboratories carry gases, chemicals, vapors, and other fluids that are critical for conducting research and development.

DEFINE PIPING
Piping is an assembly of pipe, fittings, valves, instruments and specialty components.
Piping is divided into three major categories:

  • Large bore pipe generally includes piping which is greater than two inches in diameter.
  • Small bore pipe generally includes piping which is two inches and smaller in diameter.
  • Tubing is supplied in sizes up to four inches in diameter but has a wall thickness less than that of either large bore or small bore piping and is typically joined by compression fittings.


Piping system includes:
Pipe
Fittings (e.g. elbows, reducers, branch connections, etc.)
Flanges, gaskets, bolting
Valves
Pipe supports

ASSOCIATION INVOLVED IN GENERATING CODES FOR PIPING DESIGN ENGINEERING:

ASME
-American Society of Mechanical Engineers

ANSI
-American National Standardization Institute

These standards give technical recommendations for designing piping system for power plants and chemical plants

They contain formulas to calculate the minimum thickness of pipelines
They contain formulas to calculate the extra thickness that a pipe must have when a branch is cut into it.
They contain regulations for stress analysis
They contain tables that give maximum allowable stress for metallic materials accepted by ANSI for pipeline construction depending on temperatures.



PIPING CODES:

ASME B31.1 - Power Piping
ASME B31.2 - Fuel Gas .Piping
ASME B31.3 - Process Piping
ASME B31.4 - Liquid Piping
ASME B31.5 - Refrigeration Piping
ASME B31.8 - Gas Distribution and Transportation
ASME B31.9 - Building Service Piping
ASME B31.11 - Slurry Piping




ASSOCIATION INVOLVED IN GENERATING MATERIAL SPECIFICATION FOR PIPING:

ASTM
-American Society for Testing Materials

ASTM developed a collection of documents called material specifications for
standardising materials of large use in the industry. Specifications starting with “a” are for steel. Specifications starting with “b” are for non-ferrous alloys (bronze, brass, copper nickel alloys, aluminium alloys and so on). Specifications starting with “d” are for plastic material, as PVC.

An ASTM specification does not only specify the basic chemical composition of material, but also the process through which the material is shaped into the final product.

This is why for a given base material seamless pipe have a specification, welded pipe have another specification wrought fittings have another specification, forged fittings have another specification, large valve bodies (normally cast) have another specification

API
-American Petroleum Institute

Rules, practices and standards for oil and gas industry are issued by this institute and followed by almost all oil and gas companies in the world.

Among the many standards issued by the institute there is also a standard for design of pipelines: API STANDARD 5l

Within this standard materials for oil and gas transportation pipelines are specified, with denomination API 5l

This is a family of carbon steels almost equivalent to ASTM A53 / A106.

PIPE - CHAPTER 2

INTRODUCTION:


Ø A pressure tight cylinder used to convey fluids under pressure through materials of
commercially available designation.
Ø Pipe is always designated through nominal bore size(NBS) also called as nominal pipe
size(NPS)
Ø A pipeline conveys a fluid from one given point of the plant usually called inlet
point of the line, to another part of the plant usually called outlet point of the line.

NOMINAL PIPE SIZE (NPS):

Pipe size is specified with two non-dimensional numbers: a Nominal Pipe Size (NPS) and a schedule (SCH). The relationship of these numbers to the actual pipe dimensions is a bit strange.
The NPS is very loosely related to the inside diameter in inches, but only for NPS 1/8 to NPS 12.
For NPS 14 and larger, the NPS is equal to the outside diameter (OD) in inches. For a given NPS, the OD stays constant and the wall thickness increases with larger SCH. For a given SCH, the OD increases with increasing NPS while the wall thickness increases or stays constant.

NOMINAL DIAMETER (DN):

It is same as nominal pipe size, but in mm.

SCHEDULE (WALL THICKNESS):

Schedule:
Carbon steel : 5, 10, 20, 30, 40, 60, 80, 100, 120, 160.
Stainless steel : 5S, 10S, 20S, 30S, 40S, 60S, 80S.
Weight series:
  • STD : Standard
  • XS : Extra Strong
  • XXS : Double Extra Strong
Wall thickness is designated by schedule number or descriptive classification, rather than the actual wall thickness. The original thicknesses were referred to as standard (STD), extra strong (XS) and double extra strong (XXS).
Wall thickness for the schedule 40 and STD are same for sizes ⅛ to 10”.schedule 80 and XS also have the same wall thickness for ⅛ to 8” diameter pipe.

CODES:

Ø ASME B36.10 - CARBON STEEL
Ø ASME B36.19 - STAINLESS STEEL

MATERIAL:

Carbon steel:
Steel is basically a solution of carbon (C) into iron (Fe). The presences of
carbon into the crystal structure of the iron improve very much the mechanical characteristics of the iron alone. Carbon steel is a conventional denomination for steel that has almost no other metallic elements added into it.
Carbon steel material specification ASTM A106 is available in grades A, B
and C. These refer to the tensile strength of the steel, with grade C having the highest strength.
Common practice is to manufacture the pipe as A106 grade B
ASTM A53 is also commonly specified for galvanized or lined pipe or as an
alternate to A106.the testing requirement for A53 are less stringent(rigorous or tight) than for A106. Three types of carbon steel pipe are covered by A53. These are type E or Electric resistance welded, type F or Furnace-butt welded, and type S or Seamless. Type E and S are available in grade A and B, comparable to grades A and B of A106.
Stainless steel:
Austenitic stainless steel pipe commonly referred to as “Stainless Steel” is
virtually non-magnetic. Stainless steel is manufactured in accordance with
ASTM A312 when 8” or smaller sizes are needed. There are eighteen different grades, of which type 304L is the most widely used.
Grade 316L has high resistance to chemical and salt water corrosion and is
best suited for welding. Large sizes (8” and up) of stainless steel pipe are covered by ASTM A358. Extra light wall thickness (schedule 5S) and light wall thickness (schedule 10S) stainless steel pipe is covered byASTM A409.

PIPE MANUFACTURING METHOD:

Ø Seamless
Hot rolled, cold drawn etc
Ø Electric resistance welding
No material is added during welding process
Ø Electric fusion welding
Filler material is added during welding process

CHARACTERISTICS OF A PIPELINE:

Ø Nominal pipe size(NPS)
Ø Wall thickness
Ø Type of joint between pieces

Welded joints

Ø Butt welded
Ø Socket welded
 Threaded joints
 Flanged joints
Ø External finishing
 Painting
 Insulation

OTHER CHARACTERISTICS OF A PIPELINE:

Routing:

Ø The routing is how the Pipeline is developed into the space.
Ø There are rules and regulations to route a Pipeline according the
“Good Engineering Practice”
Ø Cold Pipelines connecting static objects (something that does not move
like Tanks, Vessels, other Pipelines, and Headers) can be straightly
routed between the inlet and the outlet point.
Ø Cold Pipelines connecting machines that vibrate or rotate may need a
flexible part between the inlet and the outlet point.
Ø Hot Pipelines must be flexible enough to adsorb the thermal expansion
of the Pipeline from cold to hot condition

Supporting System:

Ø Every Pipeline must be supported. Not all Pipelines are supported in
the same way.
Ø Cold Pipelines can be supported everywhere with fixed points
Ø Hot Pipelines cannot be supported only with fixed points, but certain
points must be only guided, meaning that in those points the Pipeline
retains a certain numbers of degree of freedom in certain directions,
while are constrained in certain other directions.

TYPE OF JOINT BETWEEN PIECES:

1. Butt welded joint:

The end is machined to allow head to head full penetrating welding
Butt weld Joint 

2. Socket welded joint:

A socket is provided where pipe can be inserted
Socket weld joint 

3. Threaded joint:

Parts to be connected are threaded.
image

PIPE ENDS:

Pipe may be obtained with
Ø Plain ends are cut square and reamed to remove burns. This
type of end is needed when being joined by mechanical couplings, socket weld fittings, or slip-on flange.
Ø Bevelled ends are required for most butt weld application.
Ø Threaded ends are used with screwed joints and are ordered
noting threaded on both ends or one end.

Various combination of pipe end:

  • POE: Plain one end
  • PBE: Plain both end
  • BOE: Bevelled one end
  • BBE: Bevelled both end
  • TOE: Threaded one end
  • TBE: Threaded both end

PIPE REPRESENTATION:

Up to 12 inch

image

Above 14 inch

image

SPECIFICATION OF A PIPE:

Example:
Size : NPS 12”
Diameter : DN 300
Wall thickness: Sch. 40
Material : ASTM A106 Gr. B