These standards are used and accepted worldwide and cover areas such as metals, paints, plastics, textiles, petroleum, construction, energy, the environment, consumer products, medical services and devices, and electronics. The open process in which ASTM standards are developed is one reason why so many and such a broad range of industries have done their diverse standards development work within ASTM International.
Professionals from all over the globe participate in the ASTM system which recognizes technical expertise, not country of origin. To facilitate broad global input, ASTM International uses online technologies that encourage open participation and responsiveness to industry needs. In addition to this accommodating standards development atmosphere, ASTM International provides services that expand the knowledge and application of standards.
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ASTM publishes a monthly magazine, Standardization News, which covers the topic of standards development around the world. The standards of ASTM International are used in research and development, quality systems, product testing and acceptance, and commercial transactions all around the globe.
- Standards in the ASU Library: AS-AWWA: ASME;
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They are integral components of today's competitive business strategies. It contains formally approved ASTM standard classifications, guides, practices, specifications, test methods and terminology and related material such as proposals. Mechanical properties yield point, tensile strength, notch toughness. When deemed useful, steel type, manufacturing method, thickness of plate, heat treatment, and other data are described. Many pro? You will not find that standards, because they do not exist. My Account.
Welcome to Trupply LLC! Login Create Account. Shopping Cart. Who is ASME? Notes: A Standard can be defined as a set of technical definitions and guidelines that function as instructions for designers, manufacturers, operators, or users of equipment.
Development of Standards The open process in which ASTM standards are developed is one reason why so many and such a broad range of industries have done their diverse standards development work within ASTM International. Use of standards The standards of ASTM International are used in research and development, quality systems, product testing and acceptance, and commercial transactions all around the globe.
Covers: Steel Pipes, Tubes and Fittings Steel Plates for General Structure Steel Plates for Boiler and Pressure Vessels Steels for Machine Structural Use Steels for Special Purposes The following data is given for each standard: Standard number and year Grade Chemical composition Mechanical properties yield point, tensile strength, notch toughness When deemed useful, steel type, manufacturing method, thickness of plate, heat treatment, and other data are described.
Construction is an allinclusive term comprising materials, design, fabrication, examination, inspection, testing, certification, and overpressure protection. Continued service is an all-inclusive term referring to inspection, testing, repair, alteration, and recertification of a transport tank that has been in service.
This section contains modal appendices containing requirements for vessels used in specific transport modes and service applications. Rules pertaining to the use of the T code symbol stamp are included. Code case revisions in the form of supplements are sent automatically to purchasers up to the publication of the code.
Without these essential documents in place, it is impossible to deliver a project that meets international safety levels and engineering quality necessary for the plant owner to be granted an operating license. Over the years, several sections of the code for pressure piping were published to cover various sectors of the energy industry.
ASME B A portion of the B The code prescribes requirements for materials and components, design, fabrication, assembly, erection, examination, inspection, and testing of piping. This code applies to piping for all fluids, including 1 raw, intermediate, and finished chemicals; 2 petroleum products; 3 gas, steam, air, and water; 4 fluidized solids; 5 refrigerants; and 6 cryogenic fluids. Also included is piping that interconnects pieces or stages within a packaged equipment assembly.
Piping consists of pipe, flanges, bolting, gaskets, valves, relief devices, fittings, and the pressure-containing parts of other piping components. It also includes hangers and supports and other equipment items necessary to prevent overstressing the pressure-containing parts.
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It does not include support structures such as frames of buildings, buildings stanchions, or foundations. Requirements for offshore pipelines are found in Chapter IX of the code. Also included within the scope of this code are 1 primary and associated auxiliary liquid petroleum and liquid anhydrous ammonia piping at pipeline terminals marine, rail, and truck , tank farms, pump stations, pressure reducing stations, and metering stations, including scraper traps, strainers, and prover loops; 2 storage and working tanks, including pipe-type storage fabricated from pipe and fittings and the piping interconnecting these facilities; 3 liquid petroleum and liquid anhydrous ammonia piping located on property set aside for such piping within the petroleum refinery, natural gasoline, gas processing, ammonia, and bulk plants; 4 those aspects of operation and maintenance of liquid pipeline systems relating to the safety and protection of the general public, operating company personnel, environment, property, and the piping systems.
Printed with the permission of Bentley Systems Incorporated. Users are advised that other piping code sections may provide requirements for refrigeration piping in their respective jurisdictions. This code does not apply to 1 any self-contained or unit systems subject to the requirements of Underwriters Laboratories or other nationally recognized testing laboratory; 2 water piping; 3 piping designed for external or internal gauge pressure not exceeding 15 psig kPa regardless of size; or 4 pressure vessels, compressors, or pumps but does include all connecting refrigerant and secondary coolant piping starting at the first joint adjacent to such apparatus.
Included within the scope of this code are gas transmission and gathering pipelines, including appurtenances, that are installed offshore 18 Chapter 1—Piping Codes, Standards, and Specifications for the purpose of transporting gas from production facilities to onshore locations; gas storage equipment of the closed pipe type, fabricated or forged from pipe or fabricated from pipe and fittings; and gas storage lines. Pipeline system means all parts of physical facilities through which gas is transported, including pipe, valves, appurtenances attached to pipe, compressor units, metering stations, regulator stations, delivery stations, holders, and fabricated assemblies.
The principles and processes embodied in integrity management are applicable to all pipeline systems. This standard is specifically designed to provide the operator as defined in section 13 with the information necessary to develop and implement an effective integrity management program utilizing proven industry practices and processes. The processes and approaches within this standard are applicable to the entire pipeline system. This code prescribes requirements for the design, materials, fabrication, installation, inspection, examination, and testing of piping systems for building services.
It includes piping systems in the building or within the property limits. It covers piping systems that transport aqueous slurries of no hazardous materials, such as coal, mineral ores, and other solids, between a slurry processing plant and the receiving plant. This manual is not applicable to new construction covered under the B31 code sections. That is, it is not intended that this manual be used to establish acceptance standards for pipe that may have become corroded prior to or during fabrication or installation.
This manual is intended solely for the purpose of providing guideline information for the designer, owner, and operator.
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Therefore, the specific use of this manual is the responsibility of the designer, owner, or operator. This document provides a minimum set of rules covering the design, materials, fabrication, examination, and testing of process piping systems, which includes but is not limited to petroleum refineries, oil and gas separation facilities, LNG plants, petrochemical complexes, and pharmaceutical plants. By no means does this code cover all of the requirements for a process piping system, and it covers the broad spectrum of the subject and must be supplemented by other standards and specifications referenced within its pages.
It covers the design of chemical and petroleum plants and refineries processing chemicals and hydrocarbons, water, and steam. The code contains rules for piping typically found in petroleum refineries; chemical, pharmaceutical, textile, paper, semiconductor, and cryogenic plants; and related processing plants and terminals. The code applies to piping for all fluids, including 1 raw, intermediate, and finished chemicals; 2 petroleum products; 3 gas, steam, air, and water; 4 fluidized solids; 5 refrigerants; and 6 cryogenic fluids.
The various ASME design codes listed were introduced starting at the turn of the century, after a series of disasters that caused loss of life and major damage to facilities. These are for commercial projects. Plants that demand a very high level of reliability, because downtime has an immediate impact on power delivered to the general public are designed to ASME B In comparison, a process unit is in one geographical location that will be of several hundred acres but subjected to only one climate and, in a vast majority of cases, a common elevation, also known as grade.
It is very important for a piping engineer to study ASME Remember that this code covers a wide spectrum of piping engineering—design, stress, materials, construction. If you are a specialist piping engineer, then there are sectors of this code you will rarely, if ever, use. Even so, it is important to know what the information is and who will use it.
It is not essential to memorize the text and data, but it is very important to know what information is held within the pages of code and be able to access it and interpret it accurately. Committee Personnel. Summary of Changes. Chapter I, Scope and Definitions. Chapter II, Design. Part 1, Conditions and Criteria. Part 2, Pressure Design of Piping Components. Part 6, Systems.
Chapter III, Materials. Chapter V, Fabrication, Assembly, and Erection. Part 5, Flexibility and Support. Part 7, Materials. Part 8, Standards for Piping Components. Part 9, Fabrication, Assembly, and Erection. Part 10, Inspection, Examination, and Testing. Part 7, Metallic Materials.
Parts 11 through 20 correspond to Chapter VII. Part 11, Conditions and Criteria.