This document provides standards for stainless steel pipe, including specifications for size, materials, wall thickness, weights, and permissible variations. It defines the scope as covering dimensions of welded and seamless stainless steel pipe for high or low temperatures and pressures. Size is identified by nominal pipe size. Wall thicknesses for various pipe schedules are provided in Table 1. Nominal weights are calculated using provided formulas and rounded values for outside diameter and wall thickness.
This Presentation is about the basic fundamentals one needs to know to begin Piping Engineering. All the basic formulas and questions that are usually asked in interviews are answered in this presentation. Feel free to ask any doubts in the comments and iI may try my best to answer them for you.
Here's a presentation on piping engineering in PDF format, now available for all. This presentation covers the basics points of piping for our EPC industry. This presentation covers various aspects of piping engineering
Refinery mechanical piping systems a fundamental overviewChetan vadodariya
This paper is based on experience gained by the author in fabrication, design and installation in multinational
manufacturing, contracting and client companies in India, Saudi Arabia and Bahrain. Piping systems in
any oil refinery is the most critical mechanical hardware for the transportation of feed product i.e. crude oil to
processing units, process piping intra and inter process units and further movement of intermediate distillates
from one processing unit to another for the purpose of processing, blending, value addition and maximization of
recovery from feed stock to finish products. Pipelines are the ultimate transportation solution for despatch of final
product to storage tank farms and to the shipping terminal for internal consumption and for export. This paper lists
proven and established international design
For the pipe stress analysis of any piping system, different kinds of loads need to be considered. Let us take a look at different kind of loads that are required to be considered for stress analysis of any piping system.
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
Piping Training course-How to be an Expert in Pipe & Fittings for Oil & Gas c...Varun Patel
Course Description
Piping a must know skill to work in Oil & Gas and similar Process Industries.
Oil and Gas industry is become a very competitive in the current time. Getting right mentor and right exposer within industry is difficult. With limited training budget spent by company on employee training, it is difficult to acquire the knowledge to success.
Knowing cross-functional skill give you an edge over others in your career success.
This course design based on years of field experience to ensure student will comprehend technical details easily and enjoy overall journey.
Learn in detail every aspect of Pipe & Pipe Fittings used in process industry
•Different types of Pipe, Pipe fittings (Elbow, Tee, reducers, Caps etc.), Flanges, Gaskets, Branch Connection, Bolting materials
•Materials (Metal-Carbon Steel, Stainless Steel, Alloy Steel etc. Non-Metal- PVC/VCM, HDPE, GRE-GRP etc.)
•Manufacturing methods
•Heat treatment requirements
•Inspection and Testing requirements (Non Destructive Testing, Mechanical & Chemical testing)
•Dimensions & Markings requirements
•Code & Standard used in piping
Content and Overview
With 2 hours of content including 30 lectures & 8 Quizzes, this course cover every aspect of Pipe, Pipe fittings, flanges, gaskets, branch connections and bolting material used in Process Piping.
This Course is divided in three parts.
1st part of the course covers fundamental of process industries. In this Part, you will learn about fundamental process piping. You will also learn about Code, Standard & Specification used in process industries.
2nd part cover various types of material used in process industries. In this part, you will learn about Metallic and Non-Metallic material used to manufacture pipe and other piping components.
3rd parts covers in detail about pipe and piping components used in Process piping. In this part we will learn about Industry terminology of Piping components, types of industrial material grade used in manufacturing and entire manufacturing process of these components. You will learn about different manufacturing methods, Heat treatment requirements, Destructive and Non-destructive testing, Visual & Dimensional inspection and Product marking requirements.
Upon completion, you will be able to use this knowledge direct on your Job and you can easily answer any interview question on pipe & fittings.
This Presentation is about the basic fundamentals one needs to know to begin Piping Engineering. All the basic formulas and questions that are usually asked in interviews are answered in this presentation. Feel free to ask any doubts in the comments and iI may try my best to answer them for you.
Here's a presentation on piping engineering in PDF format, now available for all. This presentation covers the basics points of piping for our EPC industry. This presentation covers various aspects of piping engineering
Refinery mechanical piping systems a fundamental overviewChetan vadodariya
This paper is based on experience gained by the author in fabrication, design and installation in multinational
manufacturing, contracting and client companies in India, Saudi Arabia and Bahrain. Piping systems in
any oil refinery is the most critical mechanical hardware for the transportation of feed product i.e. crude oil to
processing units, process piping intra and inter process units and further movement of intermediate distillates
from one processing unit to another for the purpose of processing, blending, value addition and maximization of
recovery from feed stock to finish products. Pipelines are the ultimate transportation solution for despatch of final
product to storage tank farms and to the shipping terminal for internal consumption and for export. This paper lists
proven and established international design
For the pipe stress analysis of any piping system, different kinds of loads need to be considered. Let us take a look at different kind of loads that are required to be considered for stress analysis of any piping system.
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
Piping Training course-How to be an Expert in Pipe & Fittings for Oil & Gas c...Varun Patel
Course Description
Piping a must know skill to work in Oil & Gas and similar Process Industries.
Oil and Gas industry is become a very competitive in the current time. Getting right mentor and right exposer within industry is difficult. With limited training budget spent by company on employee training, it is difficult to acquire the knowledge to success.
Knowing cross-functional skill give you an edge over others in your career success.
This course design based on years of field experience to ensure student will comprehend technical details easily and enjoy overall journey.
Learn in detail every aspect of Pipe & Pipe Fittings used in process industry
•Different types of Pipe, Pipe fittings (Elbow, Tee, reducers, Caps etc.), Flanges, Gaskets, Branch Connection, Bolting materials
•Materials (Metal-Carbon Steel, Stainless Steel, Alloy Steel etc. Non-Metal- PVC/VCM, HDPE, GRE-GRP etc.)
•Manufacturing methods
•Heat treatment requirements
•Inspection and Testing requirements (Non Destructive Testing, Mechanical & Chemical testing)
•Dimensions & Markings requirements
•Code & Standard used in piping
Content and Overview
With 2 hours of content including 30 lectures & 8 Quizzes, this course cover every aspect of Pipe, Pipe fittings, flanges, gaskets, branch connections and bolting material used in Process Piping.
This Course is divided in three parts.
1st part of the course covers fundamental of process industries. In this Part, you will learn about fundamental process piping. You will also learn about Code, Standard & Specification used in process industries.
2nd part cover various types of material used in process industries. In this part, you will learn about Metallic and Non-Metallic material used to manufacture pipe and other piping components.
3rd parts covers in detail about pipe and piping components used in Process piping. In this part we will learn about Industry terminology of Piping components, types of industrial material grade used in manufacturing and entire manufacturing process of these components. You will learn about different manufacturing methods, Heat treatment requirements, Destructive and Non-destructive testing, Visual & Dimensional inspection and Product marking requirements.
Upon completion, you will be able to use this knowledge direct on your Job and you can easily answer any interview question on pipe & fittings.
Cung cấp <a href="https://canhovietreal.com/thue-ban">căn hộ hạng sang</a> khu vực quận 6, đánh giá hạ tầng xung quanh dự án từ đó đưa ra kết quả tốt nhất cho khách hàng.
Saudi Arabia stands as a titan in the global energy landscape, renowned for its abundant oil and gas resources. It's the largest exporter of petroleum and holds some of the world's most significant reserves. Let's delve into the top 10 oil and gas projects shaping Saudi Arabia's energy future in 2024.
Final project report on grocery store management system..pdfKamal Acharya
In today’s fast-changing business environment, it’s extremely important to be able to respond to client needs in the most effective and timely manner. If your customers wish to see your business online and have instant access to your products or services.
Online Grocery Store is an e-commerce website, which retails various grocery products. This project allows viewing various products available enables registered users to purchase desired products instantly using Paytm, UPI payment processor (Instant Pay) and also can place order by using Cash on Delivery (Pay Later) option. This project provides an easy access to Administrators and Managers to view orders placed using Pay Later and Instant Pay options.
In order to develop an e-commerce website, a number of Technologies must be studied and understood. These include multi-tiered architecture, server and client-side scripting techniques, implementation technologies, programming language (such as PHP, HTML, CSS, JavaScript) and MySQL relational databases. This is a project with the objective to develop a basic website where a consumer is provided with a shopping cart website and also to know about the technologies used to develop such a website.
This document will discuss each of the underlying technologies to create and implement an e- commerce website.
Cosmetic shop management system project report.pdfKamal Acharya
Buying new cosmetic products is difficult. It can even be scary for those who have sensitive skin and are prone to skin trouble. The information needed to alleviate this problem is on the back of each product, but it's thought to interpret those ingredient lists unless you have a background in chemistry.
Instead of buying and hoping for the best, we can use data science to help us predict which products may be good fits for us. It includes various function programs to do the above mentioned tasks.
Data file handling has been effectively used in the program.
The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
CFD Simulation of By-pass Flow in a HRSG module by R&R Consult.pptxR&R Consult
CFD analysis is incredibly effective at solving mysteries and improving the performance of complex systems!
Here's a great example: At a large natural gas-fired power plant, where they use waste heat to generate steam and energy, they were puzzled that their boiler wasn't producing as much steam as expected.
R&R and Tetra Engineering Group Inc. were asked to solve the issue with reduced steam production.
An inspection had shown that a significant amount of hot flue gas was bypassing the boiler tubes, where the heat was supposed to be transferred.
R&R Consult conducted a CFD analysis, which revealed that 6.3% of the flue gas was bypassing the boiler tubes without transferring heat. The analysis also showed that the flue gas was instead being directed along the sides of the boiler and between the modules that were supposed to capture the heat. This was the cause of the reduced performance.
Based on our results, Tetra Engineering installed covering plates to reduce the bypass flow. This improved the boiler's performance and increased electricity production.
It is always satisfying when we can help solve complex challenges like this. Do your systems also need a check-up or optimization? Give us a call!
Work done in cooperation with James Malloy and David Moelling from Tetra Engineering.
More examples of our work https://www.r-r-consult.dk/en/cases-en/
Hierarchical Digital Twin of a Naval Power SystemKerry Sado
A hierarchical digital twin of a Naval DC power system has been developed and experimentally verified. Similar to other state-of-the-art digital twins, this technology creates a digital replica of the physical system executed in real-time or faster, which can modify hardware controls. However, its advantage stems from distributing computational efforts by utilizing a hierarchical structure composed of lower-level digital twin blocks and a higher-level system digital twin. Each digital twin block is associated with a physical subsystem of the hardware and communicates with a singular system digital twin, which creates a system-level response. By extracting information from each level of the hierarchy, power system controls of the hardware were reconfigured autonomously. This hierarchical digital twin development offers several advantages over other digital twins, particularly in the field of naval power systems. The hierarchical structure allows for greater computational efficiency and scalability while the ability to autonomously reconfigure hardware controls offers increased flexibility and responsiveness. The hierarchical decomposition and models utilized were well aligned with the physical twin, as indicated by the maximum deviations between the developed digital twin hierarchy and the hardware.
Explore the innovative world of trenchless pipe repair with our comprehensive guide, "The Benefits and Techniques of Trenchless Pipe Repair." This document delves into the modern methods of repairing underground pipes without the need for extensive excavation, highlighting the numerous advantages and the latest techniques used in the industry.
Learn about the cost savings, reduced environmental impact, and minimal disruption associated with trenchless technology. Discover detailed explanations of popular techniques such as pipe bursting, cured-in-place pipe (CIPP) lining, and directional drilling. Understand how these methods can be applied to various types of infrastructure, from residential plumbing to large-scale municipal systems.
Ideal for homeowners, contractors, engineers, and anyone interested in modern plumbing solutions, this guide provides valuable insights into why trenchless pipe repair is becoming the preferred choice for pipe rehabilitation. Stay informed about the latest advancements and best practices in the field.
Immunizing Image Classifiers Against Localized Adversary Attacksgerogepatton
This paper addresses the vulnerability of deep learning models, particularly convolutional neural networks
(CNN)s, to adversarial attacks and presents a proactive training technique designed to counter them. We
introduce a novel volumization algorithm, which transforms 2D images into 3D volumetric representations.
When combined with 3D convolution and deep curriculum learning optimization (CLO), itsignificantly improves
the immunity of models against localized universal attacks by up to 40%. We evaluate our proposed approach
using contemporary CNN architectures and the modified Canadian Institute for Advanced Research (CIFAR-10
and CIFAR-100) and ImageNet Large Scale Visual Recognition Challenge (ILSVRC12) datasets, showcasing
accuracy improvements over previous techniques. The results indicate that the combination of the volumetric
input and curriculum learning holds significant promise for mitigating adversarial attacks without necessitating
adversary training.
1. A N A M E R I C A N N A T I O N A L S TA N D A R D
Stainless Steel
Pipe
ASME B36.19M-2004
(Revision of ANSI/ASME B36.19M-1985)
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2. A N A M E R I C A N N A T I O N A L S T A N D A R D
STAINLESS STEEL
PIPE
ASME B36.19M-2004
(Revision of ANSI/ASME B36.19M-1985)
Copyright ASME International
Provided by IHS under license with ASME
Not for ResaleNo reproduction or networking permitted without license from IHS
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5. FOREWORD
This Standard for corrosion resistant piping, designated categorically as stainless, is based on
the same principles that formed the background for the development of ASME B36.10M, Welded
and Seamless Wrought Steel Pipe, and reference is made to this source of information.
The more recent development of the highly alloyed stainless steels has brought about a minor
conflict with convention. With these newer materials, the need for standards is just as great and
the present types of threads are just as satisfactory, but the basic cost of the metal is much higher
and the art of fusion welding has developed concurrently. The character of stainless steel permits
the design of thin-wall piping systems without fear of early failure due to corrosion, and the use
of fusion welding to join such piping has eliminated the necessity of threading it. For these
reasons, the wall thickness dimensions shown under Schedule 10S have been developed, based
on the conventional formula, but then modified to correspond to the nearest Birmingham Wire
Gage (B.W.G.) number.
Following publication of the 1949 edition, a demand developed for a still lighter wall pipe. A
Schedule 5S was determined cooperatively by representatives of chemical companies, processing
industries, and manufacturers of welding fittings. This was endorsed by the American Standards
Association (ASA) Chemical Industry Correlating Committee and the Manufacturers Standardiza-
tion Society of the Valve and Fittings Industry. The new schedule was included in the revised
standard that was approved by ASA (now ANSI) on April 7, 1952.
In 1956, it was recommended that the wall thickness of 12 in. 5S be lessened, and a new revision
of the standard was issued shortly after its approval by ASA on February 27, 1957. In this fourth
edition, dimensions were expanded beyond 12 in. pipe size by inclusion of, and reference to,
ASTM Specification A 409. This revision was approved by ASA on October 29, 1965.
The B36 Standards Committee membership was asked in March 1970 for recommendations as
to what action should be taken on ANSI B36.19-1965 since, according to ANSI procedures, this
standard was due for revision or affirmation. The B36 Standards Committee recommended
reaffirmation. This action was approved by the Secretariat and by the American National Standards
Institute on May 26, 1971.
In 1975, the B36 Standards Committee undertook a review of the standard, considering its
acceptability and usefulness. The results were favorable; some editorial refinements and updating
were proposed, along with the incorporation of factors for conversion to SI (metric) units. The
revision was approved by the Standards Committee, the Secretariat, and subsequently the Ameri-
can National Standards Institute on October 4, 1976.
The standard was revised in 1984 to include SI (metric) dimensions. The outside diameters
and wall thicknesses were converted to millimeters by multiplying the inch dimensions by 25.4.
Outside diameters larger than 16 in. were rounded to the nearest 1 mm, and outside diameters
16 in. and smaller were rounded to the nearest 0.1 mm. Wall thicknesses were rounded to the
nearest 0.01 mm. These converted and rounded SI dimensions were added in Table 2A. A formula
to calculate the SI plain end mass, kg/m, using SI diameters and thicknesses, was added to para.
5. The SI plain end mass was calculated for each size and thickness, and added in Table 3A.
These changes in the standard were approved by the Standards Committee, the Sponsor, and
ANSI, and it was designated an American National Standard on October 7, 1985.
The current edition revises the text to conform to the format and content, as appropriate, of
ASME B36.10M-2004. Tables 2, 2A, 3, and 3A are replaced with a new Table 1, combining the
information in the previous tables into a single table. Also, the roster of the disbanded B36
Committee is replaced by the roster of the B32 Committee. This edition was approved as an
American National Standard on June 23, 2004.
iv
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6. ASME B32 COMMITTEE
Metal and Metal Alloy
Wrought Mill Product Nominal Sizes
(The following is the roster of the Committee at the time of approval of this Standard.)
OFFICERS
J. A. Gruber, Chair
J. H. Karian, Secretary
COMMITTEE PERSONNEL
F. M. Christensen, F. M. Christensen Metallurgical Consulting, Inc.
A. Cohen, Arthur Cohen & Associates
J. A. Gruber, Wheatland Tube Co.
W. N. Holliday, LTV Steel Co.
L. T. Ingels, American Gas Association, Inc.
J. H. Karian, The American Society of Mechanical Engineers
K. O. Kverneland, Kok Metric Co.
A. R. Machell, Jr.
P. Pollak, Aluminum Association, Inc.
R. N. Rau
v
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7. vi
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8. ASME B36.19M-2004
STAINLESS STEEL PIPE
1 SCOPE
This Standard covers the standardization of dimen-
sions of welded and seamless wrought stainless steel
pipe for high or low temperatures and pressures.
The word pipe is used, as distinguished from tube, to
apply to tubular products of dimensions commonly used
for pipeline and piping systems. Pipes NPS 12 (DN 300)
and smaller have outside diameters numerically larger
than their corresponding sizes. In contrast, the outside
diameters of tubes are numerically identical to the size
number for all sizes.
The wall thicknesses for NPS 14 through 22, inclusive
(DN 350–550, inclusive), of Schedule 10S; NPS 12 (DN
300) of Schedule 40S; and NPS 10 and 12 (DN 250 and
300) of Schedule 80S are not the same as those of ASME
B36.10M. The suffix “S” in the schedule number is used
to differentiate B36.19M pipe from B36.10M pipe. ASME
B36.10M includes other pipe thicknesses that are also
commercially available with stainless steel material.
2 SIZE
The size of all pipe in Table 1 is identified by the
nominal pipe size.
The manufacture of pipe NPS 1
⁄8 (DN 6) through NPS
12 (DN 300), inclusive, is based on a standardized out-
side diameter (OD). This OD was originally selected so
that pipe with a standard OD and having a wall thick-
ness that was typical of the period would have an inside
diameter (ID) approximately equal to the nominal size.
Although there is no such relation between the existing
standard thicknesses — OD and nominal size — these
nominal sizes and standard ODs continue in use as
“standard.”
The manufacture of pipe NPS 14 (DN 350) and larger
proceeds on the basis of an OD corresponding to the
nominal size.
3 MATERIALS
The dimensional standards for pipe described here
are for products covered in ASTM specifications.
4 WALL THICKNESS
The nominal wall thicknesses are given in Table 1.
1
5 WEIGHTS
The nominal weights1
of steel pipe are calculated val-
ues and are tabulated in Table 1.
(a) The nominal plain end weight, in pounds per foot,
is calculated using the following formula:
Wpe p 10.69(D − t)t
where
D p outside diameter to the nearest 0.001 in. (the
symbol D is used for OD only in mathematical
equations or formulas)
Wpe p nominal plain end weight, rounded to the
nearest 0.01 lb/ft
t p specified wall thickness, rounded to the near-
est 0.001 in.
(b) The nominal plain end mass, in kilograms per
meter, is calculated using the following formula:
Wpe p 0.0246615(D − t)t
where
D p outside diameter to the nearest 0.1 mm for
outside diameters that are 16 in. (406.4 mm)
and smaller, and 1.0 mm for outside diameters
larger than 16 in. (the symbol D is used for OD
only in mathematical equations or formulas)
Wpe p nominal plain end mass, rounded to the near-
est 0.01 kg/m
t p specified wall thickness, rounded to the near-
est 0.01 mm
6 PERMISSIBLE VARIATIONS
Variations in dimensions differ depending upon the
method of manufacture employed in making the pipe
to the various specifications available. Permissible varia-
tions for dimensions are indicated in each specification.
7 PIPE THREADS
Unless otherwise specified, the threads of threaded
pipe shall conform to ANSI/ASME B1.20.1, Pipe
Threads, General Purpose (Inch).
1
The different grades of stainless steel have different specific
densities and hence may weigh more or less than the values listed
in Table 1 would indicate [see Table 1, General Note (e)].
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9. ASME B36.19M-2004 STAINLESS STEEL PIPE
Schedules 5S and 10S wall thicknesses do not permit
threading in accordance with ANSI/ASME B1.20.1.
8 WALL THICKNESS SELECTION
When the selection of wall thickness depends primar-
ily upon capacity to resist internal pressure under given
conditions, the designer shall compute the exact value
2
of wall thickness suitable for conditions for which the
pipe is required, as prescribed in detail in the ASME
Boiler and Pressure Vessel Code, ASME B31 Code for
Pressure Piping, or other similar code, whichever gov-
erns the construction. A thickness shall be selected from
the schedules of nominal thickness contained in Table
1 to suit the value computed to fulfill the conditions for
which the pipe is desired.
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12. STAINLESS STEEL PIPE ASME B36.19M-2004
Table 1 Dimensions of Welded and Seamless Stainless Steel Pipe and Nominal Weights of
Steel Pipe, Plain End (Cont’d)
U.S. Customary Units SI Units
Schedule
NPS OD, in. Wall, in. Wpe, lb/ft No. DN OD, mm Wall, mm Wpe, kg/m
22 22.000 0.188 (1) 43.84 5S 550 559 4.78 (1) 65.33
22 22.000 0.218 (1), (2) 50.76 10S 550 559 5.54 (1), (2) 75.62
22 22.000 . . . . . . 40S 550 559 . . . . . .
22 22.000 . . . . . . 80S 550 559 . . . . . .
24 24.000 0.218 (1) 55.42 5S 600 610 5.54 (1) 82.58
24 24.000 0.250 (1) 63.47 10S 600 610 6.35 (1) 94.53
24 24.000 0.375 (2) 94.71 40S 600 610 9.53 (2) 141.12
24 24.000 0.500 (2) 125.61 80S 600 610 12.70 (2) 187.07
30 30.000 0.250 (1) 79.51 5S 750 762 6.35 (1) 118.34
30 30.000 0.312 (1) 99.02 10S 750 762 7.92 (1) 147.29
30 30.000 . . . . . . 40S 750 762 . . . . . .
30 30.000 . . . . . . 80S 750 762 . . . . . .
GENERAL NOTES:
(a) 1 in. p 25.4 mm.
(b) For tolerances, see para. 6.
(c) 1 lb/ft p 1.4895 kg/m.
(d) Weights are given in pounds per linear foot (kilograms per meter) and are for carbon steel pipe with plain ends.
(e) The different grades of stainless steel permit considerable variations in weight. The ferritic stainless steels may be
about 5% less, and the austenitic stainless steels about 2% greater, than the values shown in this Table, which are
based on weights for carbon steel.
NOTES:
(1) These wall thicknesses do not permit threading in accordance with ANSI/ASME B1.20.1.
(2) These dimensions do not conform to ASME B36.10M.
5
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14. ASME B36.19M-2004
M01304Copyright ASME International
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