Saturday, September 30, 2006

Designing to Codes and Standards

Regardless of the material to be used, most design projects are exercises in creative problem solving. If the project is a very advanced one, pushing the boundaries of available technical knowledge, there are few guidelines available for the designer. In such instances, basic science, intuition, and discussions with peers are common approaches that combine to produce an approach to solving the problem. With the application of skill, daring, a little bit of luck, money, and patience, a workable solution usually emerges.

However, most design projects just are not that challenging or different from what has been done in the past. Historically, such information was carefully guarded and was often kept secret. With the passage of time, however, these privately developed methods of solving design problems became common knowledge, ever more firmly established. Eventually they evolved into published standards of practice. Some government entities, acting under their general duty to preserve general welfare and to protect life and property from harm, added the standards to their legal bases.

The need for codes and standards
The fundamental need for codes and standards in design is based on two concepts, interchangeability and compatibility. When manufactured articles were made by artisans working individually, each item was unique and the craftsman made the parts to fit each other. When a replacement part was required, it had to be made specially to fit.

However, as the economy grew and large numbers of an item were required, the handcrafted method was grossly inefficient. Economies of scale dictated that parts should be as nearly identical as possible, and that a usable replacement part would be available in case it was needed. The key consideration was that the replacement part had to be interchangeable with the original one.

Standardization of parts within a particular manufacturing company to ensure interchangeability is only one part of the industrial production problem. The other part is compatibility. What happens when parts from one company, working to their standards, have to be combined with parts from another company, working to their standards? Will parts from company A fit with parts from company B? Yes, but only if the parts are compatible. In other words, the standards of the two companies must be the same.

Purposes and objectives of codes and standards
The protection of general welfare is one of the common reasons for the establishment of a government agency. The purpose of codes is to assist that government agency in meeting its obligation to protect the general welfare of the population it serves. The objectives of codes are to prevent damage to property and injury to or loss of life by persons. These objectives are accomplished by applying accumulated knowledge to the avoidance, reduction, or elimination of definable hazards.

Before going any further, the reader needs to understand the differences between "codes" and "standards". Which items are codes and which are standards? One of the several dictionary definitions for "code" is "any set of standards set forth and enforced by a local government for the protection of public safety, health, etc., as in the structural safety of buildings (building code), health requirements for plumbing, ventilation, etc. (sanitary or health code), and the specifications for fire escapes or exits (fire code)". "Standard" is defined as "something considered by an authority or by general consent as a basis of comparison; an approved model".

As a practical matter, codes tell the user what to do and when and under what circumstances to do it. Codes are often legal requirements that are adopted by local jurisdictions that then enforce their provisions. Standards tell the user how to do it and are usually regarded only as recommendations that do not have the force of law.

As noted in the definition for code, standards are frequently collected as reference information when codes are being prepared. It is common for sections of a local code to refer to nationally recognized standards. In many instances, entire sections of the standards are adopted into the code by reference, and then become legally enforceable.

How standards develop
Whenever a new field of economic activity emerges, inventors and entrepreneurs scramble to get into the market, using a wide variety of approaches. After a while the chaos decreases, and a consensus begins to form as to what constitutes "good practice" for that economic activity.

As an industry matures, more and more companies get involved as suppliers, subcontractors, assemblers, and so forth. Establishing national trade practices is the next step in the standards development process. This is usually done through special institutions like the American National Standards Institute (ANSI), which provides the necessary forum. A sponsoring trade association will request that ANSI review its standard. A review group is then formed that includes members of many groups other than the industry, itself. This expands the area of consensus and is an essential feature of the ANSI process.

ANSI circulates copies of the proposed standard to all interested parties, seeking comments. A time frame is set up for receipt of comments, after which a Board of Standards Review considers the comments and makes what it considers necessary changes. After more reviews, the standard is finally issued and published by ANSI, listed in their catalog, and available to anyone who wishes to purchase a copy.

A similar process is used by the International Standards Organization (ISO), which began to prepare an extensive set of worldwide standards in 1996.

One of the key features of the ANSI system is the unrestricted availability of its standards. Company, trade, or other proprietary standards may not be available to anyone outside that company or trade, but ANSI standards are available to everyone. With the wide consensus format and easy accessibility, there is no reason for designers to avoid the step of searching for and collecting any and all standards applicable to their particular projects.

Types of codes
There are two broad types of codes: performance codes and specification or prescriptive codes. Performance codes state their regulations in the form of what the specific requirement is supposed to achieve, not what method is to be used to achieve it. The emphasis is on the result, not on how the result is obtained. Specification or prescriptive codes state their requirements in terms of specific details and leave no discretion to the designer. There are many of each type in use.

Trade codes relate to several public welfare concerns. For example, the plumbing, ventilation, and sanitation codes relate to health. The electrical codes relate to property damage and personal injury. Building codes treat structural requirements that ensure adequate resistance to applied loads. Mechanical codes are involved with both proper component strength and avoidance of personal injury hazards. All of these codes, and several others, provide detailed guidance to designers of buildings and equipment that will be constructed, installed, operated, or maintained by persons skilled in those particular trades.

Safety codes, on the other hand, treat only the safety aspects of a particular entity. The safety codes sets forth detailed requirements for safety as it relates to buildings.

Professional society codes have been developed, and several have wide acceptance. The American Society of Mechanical Engineers (ASME) publishes the Boiler and Pressure Vessel Code, which have been used as a design standard for many decades. The Institute of Electrical and Electronic Engineers (IEEE) publishes a series of books that codify recommended good practices in various areas of their discipline. The Society of Automotive Engineers (SAE) publishes hundreds of standards relating to the design and safety requirements for vehicles and their appurtenances. The American Society for Testing and Materials (ASTM) publishes thousands of standards relating to materials and the methods of testing to ensure compliance with the requirements of the standards.

Statutory codes are those prepared and adopted by some governmental agency, local, stale, or federal. They have the force of law and contain enforcement provisions, complete with license requirements and penalties for violations. There are literally thousands of these, each applicable within its geographical area of jurisdiction.

Regulations. Laws passed by legislatures are written in general and often vague language. To implement the collective wisdom of the lawmakers, the agency staff then comes in to write the regulations that spell out the details.

Types of standards
Proprietary (in-house) standards are prepared by individual companies for their own use. They usually establish tolerances for various physical factors such as dimensions, fits, forms, and finishes for in-house production. When outsourcing is used, the purchasing department will usually use the in-house standards in the terms and conditions of the order.

Quality assurance provisions are often in-house standards, but currently many are being based on the requirements of ISO 9000. Operating procedures for material review boards are commonly based on in-house standards. It is assumed that designers, as a function of their jobs, are intimately familiar with their own employer’s standards.

Government specification standards for federal, state, and local entities involve literally thousands of documents. Because government purchases involve such a huge portion of the national economy, it is important that designers become familiar with standards applicable to this enormous market segment. To make certain that the purchasing agency gets precisely the product it wants, the specifications are drawn up in elaborate detail. Failure to comply with the specifications is cause for rejection of the seller’s offer, and there are often stringent inspection, certification, and documentation requirements included.

It is important for designers to note that government specifications, particularly Federal specifications, contain a section that sets forth other documents that are incorporated by reference into the body of the primary document. These other documents are usually federal specifications, federal and military standards, and applicable industrial or commercial standards. The MIL standards and Handbooks for a particular product line should be a basic pan of the library of any designers working in the government supply area.

Product definition standards are published by the National Institute of Standards and Technology under procedures of the Department of Commerce. It establishes the grading rules, names of specific varieties of soft wood, and sets the uniform lumber sizes for this very commonly used material.

Commercial standards (denoted by the letters CS) are published by the Commerce Department for articles considered to be commodities. Commingling of such items is commonplace, and products of several suppliers may be mixed together by vendors. The result can be substantial variations in quality. To provide a uniform basis for fair competition, the Commercial Standards set forth test methods, ratings, certifications, and labeling requirements. Testing and certification standards are developed for use by designers, quality assurance agencies, industries, and testing laboratories.

International standards have been proliferating rapidly for the past two decades. This has been in response to the demands of an increasingly global economy for uniformity, compatibility, and inter-changeability demands for which standards are ideally suited.

Beginning in 1987, the International Standards Organization (ISO) attacked one of the most serious international standardization problems, that of quality assurance and control. These efforts resulted in the publication of the ISO 9000 Standard for Quality Management. This has been followed by ISO 14000 for Environmental Management Standards, which is directed at international environmental problems.

The ISO has several Technical Committees (TC) that publish handbooks and standards in their particular fields. Examples are the ISO Standards Handbooks on Mechanical Vibration and Shock, Statistical Methods for Quality Control, and Acoustics. All of these provide valuable information for designers of products intended for the international market.

Codes and standards preparation organizations
U.S. Government Documents. For Federal government procurement items, other than for the Department of Defense, the Office of Federal Supply Services of the General Services Administration issues the Index of Federal Specifications, Standards and Commercial Item Descriptions every April.

The American National Standards Institute also publishes a catalog of all their publications and distributes catalogs of standards published by 38 other ISO member organizations. They also distribute ASTM and ISO standards and English language editions of Japanese Standards, Handbooks, and Materials Data Books. ANSI does not handle publications of the British Standards Institute or the standards organizations in Germany and France.

As mentioned previously, there are many organizations that act as sponsors for the standards that ANSI prepares under their consensus format. The sponsors are good sources for information on forthcoming changes in standards and should be consulted by designers wishing to avoid last-minute surprises. Listings in the ANSI catalog will have the acronym for the sponsor given after the ANSI symbol. The field of interest of each sponsor is usually obvious from the name of the organization.

Designer’s responsibility
As soon as a designer has been able to establish a solid definition of the problem at hand, and to formulate a promising solution to it, the next logical step is to begin the collection of available reference materials such as codes and standards. This is a key part of the background phase of the design effort. Awareness of the existence and applicability of codes and standards is a major responsibility of the designer.

One of the designer’s responsibilities in the background phase is to make certain that the collection of reference codes and standards is both complete and comprehensive. Considering the enormous amount of information available, and the ease of access to it, this can be a formidable task. However, a designer’s failure to acquire a complete and comprehensive collection of applicable standards is ill advised in today’s litigious environment. In addition, failure of the designer to meet the requirements set forth in the standards can be considered professional malpractice.

Introduction to the Unified Numbering System of Ferrous Metals and Alloys

The Unified Numbering System for Metals and Alloys (UNS) provides means of correlating many internationally used metal and alloy numbering systems currently administered by societies, trade associations, and those individual users and producers of metals and alloys. This system avoids the confusion caused by the use of more than one identification number for the same metal or alloy, and the opposite situation of having the same number assigned to two or more different metals or alloys. It provides the uniformity necessary for efficient indexing, record keeping, data storage and retrieval, and cross-referencing.

CA UNS designation is not, in itself, a specification, because it establishes no requirements for form, condition, property, or quality. It is a unified identifier of a metal or an alloy for which controlling limits have been established in specifications published elsewhere.

The UNS establishes 9 series of designations for ferrous metals and alloys. Each UNS designation consists of a single-letter prefix followed by five digits. In most cases the letter is suggestive of the family of metals identified: for example, F for cast irons, T for tool steel, S for stainless steels.

Although some of the digits in certain UNS designation groups have special assigned meanings, each series of UNS designations is independent of the others in regard to the significance of digits, thus permitting greater flexibility and avoiding complicated and lengthy UNS designations.

Wherever feasible, and for the convenience of the user, identification "numbers" from existing systems are incorporated into the UNS designations. For example, carbon steel presently identified by the American Iron and Steel Institute as "AISI 1020" is covered by the UNS designation "G10200".

The UNS designation assignments for certain metals and alloys are established by the relevant trade associations which in the past have administered their own numbering systems; for other metals and alloys, UNS designation assignments are administered by the Society of Automotive Engineers (SAE). Each of these assigners has the responsibility for administering a specific UNS series of designations. Each considers requests for the assignment of new UNS designations, and informs the applicants of the action taken. UNS designation assigners report immediately to the office of the Unified Numbering System for Metals and Alloys the details of each new assignment for inclusion into the system.

The listed cross-referenced specifications are representative only and are not necessarily a complete list of specifications applicable to a particular UNS designation.

D00001-D99999 Steels with specified mechanical properties
D40450-D40900 Carbon Steels
D50400-D52101 Alloy Steels Casting
F00001-F99999 Cast irons
F 10001-F15501 Cast Iron, Gray
F 10090-F10920 Cast Iron Welding Filler Metal
F 20000-F22400 Cast Iron, Malleable
F 22830-F26230 Cast Iron, Pearlitic Malleable
F 30000-F36200 Cast Iron, Ductile (Nodular)
F 41000-F41007 Cast Iron, Gray, Austenitic
F 43000- F43030 Cast Iron, Ductile (Nodular), Austenitic
F45000 F 45009 Cast Iron, White
F47001-F47006 Cast Iron, Corrosion
G00001-G99999 AISI and SAE carbon and alloy steels (except tool steels)
G10050-G10950 Carbon Steel
G15130-G15900 Carbon Steel
G11080-G11510 Resulfurized Carbon Steel
G12110-G12150 Rephosphorized and Resulfurized Carbon Steel
G13300-G13450 Mn Alloy Steel
G40120-G48200 Mo Alloy Steel, Cr-Mo Alloy Steel, Ni-Cr-Mo Alloy Steel, Ni-Mo Alloy Steel
G81150-G88220 Ni-Cr-Mo Alloy Steel
G50150-G52986 Cr Alloy Steel, Cr-B Alloy Steel
G61180-G61500 Cr-V Alloy Steel
G92540-G98500 Cr-Si Alloy Steel, Si-Mn Alloy Steel, Cr-S-Mn Alloy Steel, Ni-Cr-Mo Alloy Steel, Ni-Cr-Mo-B Alloy Steel
H00001-H99999 AISI and SAE H-steels
H10380-H15621 H-Carbon Steel, C-Mn H-Alloy Steel, C-B H Carbon Steel, Mn H-Carbon Steel, B- Mn H -Carbon Steel
H40270-H48200 C-Mo H-Alloy Steel, Cr-Mo H-Alloy Steel Ni-Mo H-Alloy Steel
H50401-H51601 C-Cr-B H-Alloy Steel, C-Cr H-Alloy Steel
H61180-H61500 Cr-V H-Alloy Steel
H81451-H94301 Ni-Cr-Mo H-Alloy Steel
J00001-J99999 Cast steels (except tool steels)
J01700-J05003 Carbon Steel Casting
J11442-J84090 Alloy Steel Casting
J91100-J92001 Austenitic Manganese Steel Casting, Alloy Steel Casting
J92110-J93000 Alloy Steel Casting Precipitation Hardening, Alloy Steel Casting, Cast Cr-Ni-Mo Stainless Steel, Cast Cr-Ni Stainless Steel, Cast Cr-Mn-Ni-Si-N Stainless Steel
J93001-J95705 Stainless Steel Casting, Cast Cr-Ni-Mo Stainless Steel, Alloy Steel Casting, Maraging Cast Ferritic-Austenic Stainless Steel, Duplex Alloy Steel Casting, Alloy Steel Casting
K00001-K99999 Miscellaneous steels and ferrous alloys
K00040-K08500 Carbon Steel, Carbon Steel with Special Magnetic Properties, Steel Welding Rod, Enameling Steel
K10614-K52440 Alloy Steel, Alloy Steel Electrode and Welding Wire, High-Strength Low-Alloy Steel
K90901-K95000 Alloy Steel, Superstrength; Ferritic Cr-Mo-V Steel; Manganese Steel, Nonmagnetic; Ni-Co Steel Welding Wire; Iron, Electrical Heating Element Alloy; Iron Thermostat Alloy; Martensitic Age-Hardenable Alloy; Maraging Alloy; Fe-Co Soft Magnetic Alloy; Nickel Steel; Invar; Iron, Nickel Sealing Alloy; etc.
S00001-S99999 Heat and corrosion resistant steels (stainless), valve steels, iron-base "super alloys"
S13800-S17780 Precipitation Hardenable Cr-Ni-Al-Mo-(Cu, Ti) Stainless Steels
S20100-S39000 Austenitic Cr-Mn-Ni (Si,Mo,Cu,Al) Stainless Steel; Thermal Spray Wire; Austenitic Cr-Mn-Ni Stainless Steel and Welding Filler Metal; Austenitic Cr-Ni Heat Resisting Steel and Welding Filler Metal; Precipitation Hardenable Cr-Ni-(Si, Ti, Mo, Al) Stainless Steel, etc.
S40300-S46800 Martensitic Cr Stainless Steel; Ferritic Cr Stainless Steel with Ti or Ni or Mo; Martensitic Cr-Ni-Mo Stainless Steel; Hardenable Cr Stainless Steel
S50100-S50500 Cr Heat Resisting Steels and Filler Metal
S63005-S64007 Valve Steel
S65006-S65007 Valve Steel
S65150-S67956 Iron Base Super alloy
T00001-T99999 Tool steels, wrought and cast
T11301-T12015 High-Speed Tool Steels
T20810-T20843 Hot-Work Tool Steels
T30102-T 30407 Cold Work Tool Steels
T31501-S31507 Oil-Hardening Steels
T41901-T41907 Shock-Resisting Tool Steels
T51602-T51621 Mold Steels
T60601-T60602 C-W Tool Steels
T61202-T61206 Low-Alloy Tool Steels
T72301-T72305 Water Hardening Tool Steels
T74000-T75008 Cr-Steels Solid Welding Wire for Machinable Surfaces and Tool and Die Surfaces
T87510-T87520 Thermal Spray Wire
T90102-T91907 Cast Tool Steels

Friday, September 29, 2006

Group of ASTM standards for steel plate, sheet, strip and wire

This group of ASTM standards covers the requirements to be met by:
  1. Steel plate, sheet, and strip used in various applications
  2. The properties of assorted types of steel wire, e.g., stainless and heat resisting steel wire, drawn galvanized wire for mechanical springs, and alloy steel coarse round wire
  3. Industrial sizing screens.

STEEL PLATE, SHEET AND STRIP

A109 A109/A109M-98a Specification for Steel, Strip, Carbon (0.25 Maximum Percent), Cold-Rolled
A167 A167-99 Specification for Stainless and Heat-Resisting Chromium-Nickel Steel Plate, Sheet, and Strip
A176 A176-99 Specification for Stainless and Heat-Resisting Chromium Steel Plate, Sheet, and Strip
A240 A240/A240M-00 Specification for Heat-Resisting Chromium and Chromium-Nickel Stainless Steel Plate, Sheet, and Strip for Pressure Vessels
A262 A262-98 Practices for Detecting Susceptibility to Intergranular Attack in Austenitic Stainless Steels
A263 A263-94a (1999) Specification for Corrosion-Resisting Chromium Steel-Clad Plate, Sheet, and Strip
A264 A264-94a (1999) Specification for Stainless Chromium-Nickel Steel-Clad Plate, Sheet, and Strip
A265 A265-94a (1999) Specification for Nickel and Nickel-Base Alloy-Clad Steel Plate
A345 A345-98 Specification for Flat-Rolled Electrical Steels for Magnetic Applications
A366 A366/A366M-97e1 Specification for Commercial Steel (CS) Sheet, Carbon (0.15 Maximum Percent) Cold-Rolled
A370 A370-97a Test Methods and Definitions for Mechanical Testing of Steel Products
A380 A380-99e1 Practice for Cleaning, Descaling, and Passivation of Stainless Steel Parts, Equipment, and Systems
A414 A414/A414M-00 Specification for Steel, Sheet, Carbon, for Pressure Vessels
A417 A417-93 (1998) Specification for Steel Wire, Cold-Drawn, for Zig-Zag, Square-Formed, and Sinuous-Type Upholstery Spring Units
A424 A424-00 Specification for Steel, Sheet, for Porcelain Enameling
A480 A480/A480M-99b Specification for General Requirements for Flat-Rolled Stainless and Heat-Resisting Steel Plate, Sheet, and Strip
A505 A505-00 Specification for Steel, Sheet and Strip, Alloy, Hot-Rolled and Cold-Rolled, General Requirements for
A506 A506-93 (1998) Specification for Steel, Sheet and Strip, Alloy, Hot-Rolled and Cold-Rolled, Regular Quality and Structural Quality
A507 A507-93 (1998) Specification for Steel, Sheet and Strip, Alloy, Hot-Rolled and Cold-Rolled, Drawing Quality
A568 A568/A568M-00 Specification for Steel, Sheet, Carbon, and High-Strength, Low-Alloy, Hot-Rolled and Cold-Rolled, General Requirements for
A569 A569/A569M-98 Specification for Steel, Carbon (0.15 Maximum, Percent), Hot-Rolled Sheet and Strip Commercial Quality
A570 A570/A570M-98 Specification for Steel, Sheet and Strip, Carbon, Hot-Rolled, Structural Quality
A604 A604-93 (1998) Test Method for Macroetch Testing of Consumable Electrode Remelted Steel Bars and Billets
A606 A606-98 Specification for Steel, Sheet and Strip, High-Strength, Low-Alloy, Hot-Rolled and Cold-Rolled, with Improved Atmospheric Corrosion Resistance
A607 A607-98 Specification for Steel, Sheet and Strip, High-Strength, Low-Alloy, Columbium or Vanadium, or Both, Hot-Rolled and Cold-Rolled
A611 A611-97 Specification for Structural Steel (SS), Sheet, Carbon, Cold-Rolled
A620 A620/A620M-97 Specification for Drawing Steel (DS), Sheet, Carbon, Cold-Rolled
A622 A622/A622M-97 Specification for Drawing Steel (DS), Sheet and Strip, Carbon, Hot-Rolled
A635 A635/A635M-98 Specification for Steel, Sheet and Strip, Heavy-Thickness Coils, Carbon, Hot-Rolled
A659 A659/A659M-97 Specification for Commercial Steel (CS), Sheet and Strip, Carbon (0.16 Maximum to 0.25 Maximum Percent), Hot-Rolled
A666 A666-00 Specification for Annealed or Cold-Worked Austenitic Stainless Steel Sheet, Strip, Plate, and Flat Bar
A682 A682/A682M-98a Specification for Steel, Strip, High-Carbon, Cold-Rolled, General Requirements For
A684 A684/A684M-86 (1998) Specification for Steel, Strip, High-Carbon, Cold-Rolled
A693 A693-93 (1999) Specification for Precipitation-Hardening Stainless and Heat-Resisting Steel Plate, Sheet, and Strip
A700 A700-99 Practices for Packaging, Marking, and Loading Methods for Steel Products for Domestic Shipment
A702 A702-89 (1994) e1 Specification for Steel Fence Posts and Assemblies, Hot Wrought
A715 A715-98 Specification for Steel Sheet and Strip, High-Strength, Low-Alloy, Hot-Rolled, and Steel Sheet, Cold-Rolled, High-Strength, Low-Alloy, with Improved Formability
A749 A749/A749M-97 Specification for Steel, Strip, Carbon and High-Strength, Low-Alloy, Hot-Rolled, General Requirements for
A751 A751-96 Test Methods, Practices, and Terminology for Chemical Analysis of Steel Products
A763 A763-93 (1999) e1 Practices for Detecting Susceptibility to Intergranular Attack in Ferritic Stainless Steels
A793 A793-96 Specification for Rolled Floor Plate, Stainless Steel
A794 A794-97 Specification for Commercial Steel (CS), Sheet, Carbon (0.16% Maximum to 0.25% Maximum), Cold-Rolled
A829 A829/A829M-95 Specification for Alloy Structural Steel Plates

STEEL WIRE

A227 A227/A227M-99 Specification for Steel Wire, Cold-Drawn for Mechanical Springs
A228 A228/A228M-93 Specification for Steel Wire, Music Spring Quality
A229 A229/A229M-99 Specification for Steel Wire, Oil-Tempered for Mechanical Springs
A230 A230/A230M-99 Specification for Steel Wire, Oil-Tempered Carbon Valve Spring Quality
A231 A231/A231M-96 Specification for Chromium-Vanadium Alloy Steel Spring Wire
A232 A232/A232M-99 Specification for Chromium-Vanadium Alloy Steel Valve Spring Quality Wire
A313 A313/A313M-98 Specification for Stainless Steel Spring Wire
A368 A368-95a Specification for Stainless Steel Wire Strand
A401 A401/A401M-98 Specification for Steel Wire, Chromium-Silicon Alloy
A407 A407-93 (1998) Specification for Steel Wire, Cold-Drawn, for Coiled-Type Springs
A478 A478-97 Specification for Chromium-Nickel Stainless Steel Weaving and Knitting Wire
A492 A492-95 Specification for Stainless Steel Rope Wire
A493 A493-95 Specification for Stainless Steel Wire and Wire Rods for Cold Heading and Cold Forging
A510M A510M-00 Specification for General Requirements for Wire Rods and Coarse Round Wire, Carbon Steel [Metric]
A510 A510-00 Specification for General Requirements for Wire Rods and Coarse Round Wire, Carbon Steel
A555 A555/A555M-97 Specification for General Requirements for Stainless Steel Wire and Wire Rods
A580 A580/A580M-98 Specification for Stainless Steel Wire
A581 A581/A581M-95b Specification for Free-Machining Stainless Steel Wire and Wire Rods
A679 A679/A679M-00 Specification for Steel Wire, High Tensile Strength, Cold Drawn
A713 A713-93 (1998) Specification for Steel Wire, High-Carbon Spring, for Heat-Treated Components
A752M A752M-93 (1998) Specification for General Requirements for Wire Rods and Coarse Round Wire, Alloy Steel [Metric]
A752 A752-93 (1998) Specification for General Requirements for Wire Rods and Coarse Round Wire, Alloy Steel
A764 A764-95 Specification for Metallic Coated Carbon Steel Wire, Coated at Size and Drawn to Size for Mechanical Springs
A805 A805-93 (1998) Specification for Steel, Flat Wire, Carbon, Cold-Rolled

Group of ASTM standards for steel castings and forgings

This group of ASTM specifications covers standard properties of steel and iron castings and forgings for valves, flanges, fittings, and other pressure containing parts for high-temperature and low-temperature service.

Additionally, in the table below standards for evaluating the microstructure of graphite in iron castings and methods for mechanical testing of cast irons are presented.

STEEL CASTINGS

A27 A27/A27M-95 Specification for Steel Castings, Carbon, for General Application
A47 A47/A47M-99 Specification for Ferritic Malleable Iron Castings
A48M A48M-94e1 Specification for Gray Iron Castings [Metric]
A48 A48-94ae1 Specification for Gray Iron Castings
A74 A74-98 Specification for Cast Iron Soil Pipe and Fittings
A126 A126-95e1 Specification for Gray Iron Castings for Valves, Flanges, and Pipe Fittings
A128 A128/A128M-93 (1998) Specification for Steel Castings, Austenitic Manganese
A148 A148/A148M-93b (1998) Specification for Steel Castings, High Strength, for Structural Purposes
A159 A159-83 (1993) Specification for Automotive Gray Iron Castings
A216 A216/A216M-93 (1998) Specification for Steel Castings, Carbon, Suitable for Fusion Welding, for High- Temperature Service
A217 A217/A217M-99 Specification for Steel Castings, Martensitic Stainless and Alloy, for Pressure- Containing Parts, Suitable for High-Temperature Service
A247 A247-67 (1998) Test Method for Evaluating the Microstructure of Graphite in Iron Castings
A278M A278M-93e1 Specification for Gray Iron Castings for Pressure-Containing Parts for Temperatures Up to 350°C
A278 A278-93 Specification for Gray Iron Castings for Pressure-Containing Parts for Temperatures Up to 650°F
A297 A297/A297M-97 (1998) Specification for Steel Castings, Iron-Chromium and Iron-Chromium-Nickel, Heat Resistant, for General Application
A319 A319-71 (1995) Specification for Gray Iron Castings for Elevated Temperatures for Non-Pressure Containing Parts
A327M A327M-91 (1997) Test Methods for Impact Testing of Cast Irons (Metric)
A327 A327-91 (1997) Test Methods for Impact Testing of Cast Irons
A351 A351/A351M-94a (1999) Specification for Castings, Austenitic, Austenitic-Ferritic (Duplex), for Pressure-Containing Parts
A352 A352/A352M-93 (1998) Specification for Steel Castings, Ferritic and Martensitic, for Pressure-Containing Parts, Suitable for Low-Temperature Service
A356 A356/A356M-98e1 Specification for Steel Castings, Carbon, Low Alloy, and Stainless Steel, Heavy-Walled for Steam Turbines
A367 A367-60 (1999) Test Methods of Chill Testing of Cast Iron
A389 A389/A389M-93 (1998) Specification for Steel Castings, Alloy, Specially Heat-Treated, for Pressure-Containing Parts, Suitable for High-Temperature Service
A395 A395/A395M-99 Specification for Ferritic Ductile Iron Pressure-Retaining Castings for Use at Elevated Temperatures
A426 A426-92 (1997) Specification for Centrifugally Cast Ferritic Alloy Steel Pipe for High-Temperature Service
A436 A436-84 (1997) e1 Specification for Austenitic Gray Iron Castings
A438 A438-80 (1997) Test Method for Transverse Testing of Gray Cast Iron
A439 A439-83 (1999) Specification for Austenitic Ductile Iron Castings
A447 A447/A447M-93 (1998) Specification for Steel Castings, Chromium-Nickel-Iron Alloy (25-12 Class), for High-Temperature Service
A451 A451-93 (1997) Specification for Centrifugally Cast Austenitic Steel Pipe for High-Temperature Service
A476M A476M-84 (1993) Specification for Ductile Iron Castings for Paper Mill Dryer Rolls [Metric]
A476 A476-90 (1997) Specification for Ductile Iron Castings for Paper Mill Dryer Rolls
A487 A487/A487M-93 (1998) Specification for Steel Castings Suitable for Pressure Service
A488 A488/A488M-99 Practice for Steel Castings, Welding, Qualifications of Procedures and Personnel
A494 A494/A494M-00 Specification for Castings, Nickel and Nickel Alloy
A518 A518/A518M-99 Specification for Corrosion-Resistant High-Silicon Iron Castings
A532 A532/A532M-93a (1999) e1 Specification for Abrasion-Resistant Cast Irons
A536 A536-84 (1999) e1 Specification for Ductile Iron Castings
A560 A560/A560M-93 (1998) Specification for Castings, Chromium-Nickel Alloy
A571M A571M-84 (1997) Specification for Austenitic Ductile Iron Castings for Pressure-Containing Parts Suitable for Low-Temperature Service [Metric]
A571 A571-84 (1997) Specification for Austenitic Ductile Iron Castings for Pressure-Containing Parts Suitable for Low-Temperature Service
A583 A583-93 (1999) Specification for Cast Steel Wheels for Railway Service
A597 A597-87 (1999) Specification for Cast Tool Steel
A602 A602-94 (1998) Specification for Automotive Malleable Iron Castings
A608 A608-91a (1998) Specification for Centrifugally Cast Iron-Chromium-Nickel High-Alloy Tubing for Pressure Application at High Temperatures
A609 A609/A609M-91 (1997) Practice for Castings, Carbon, Low-Alloy, and Martensitic Stainless Steel, Ultrasonic Examination Thereof
A644 A644-98 Terminology Relating to Iron Castings
A667 A667/A667M-87 (1998) Specification for Centrifugally Cast Dual Metal (Gray and White Cast Iron) Cylinders
A703 A703/A703M-99 Specification for Steel Castings, General Requirements, for Pressure-Containing Parts
A732 A732/A732M-98 Specification for Castings, Investment, Carbon and Low Alloy Steel for General Application, and Cobalt Alloy for High Strength at Elevated Temperatures
A743 A743/A743M-98ae1 Specification for Castings, Iron-Chromium, Iron-Chromium-Nickel, Corrosion Resistant, for General Application
A744 A744/A744M-98a Specification for Castings, Iron-Chromium-Nickel, Corrosion Resistant, for Severe Service
A747 A747/A747M-99 Specification for Steel Castings, Stainless, Precipitation Hardening
A748 A748/A748M-87 (1998) Specification for Statically Cast Chilled White Iron-Gray Iron Dual Metal Rolls for Pressure Vessel Use
A757 A757/A757M-00 Specification for Steel Castings, Ferritic and Martensitic, for Pressure-Containing and Other Applications, for Low-Temperature Service
A781 A781/A781M-99a Specification for Castings, Steel and Alloy, Common Requirements, for General Industrial Use
A799 A799/A799M-92 (1997) Practice for Steel Castings, Stainless, Instrument Calibration, for Estimating Ferrite Content
A800 A800/A800M-91 (1997) e1 Practice for Steel Casting, Austenitic Alloy, Estimating Ferrite Content Thereof
A802 A802/A802M-95 (1996) Practice for Steel Castings, Surface Acceptance Standards, Visual Examination
A823 A823-99 Specification for Statically Cast Permanent Mold Gray Iron Castings
A834 A834-95 Specification for Common Requirements for Iron Castings for General Industrial Use
A842 A842-85 (1997) Specification for Compacted Graphite Iron Castings
A872 A872-91 (1997) Specification for Centrifugally Cast Ferritic/Austenitic Stainless Steel Pipe for Corrosive Environments
A874 A874/A874M-98 Specification for Ferritic Ductile Iron Castings Suitable for Low-Temperature Service
A888 A888-98e1 Specification for Hubless Cast Iron Soil Pipe and Fittings for Sanitary and Storm Drain, Waste, and Vent Piping Applications
A890 A890/A890M-99 Specification for Castings, Iron-Chromium-Nickel-Molybdenum Corrosion-Resistant, Duplex (Austenitic/Ferritic) for General Application
A897M A897M-90 (1997) Specification for Austempered Ductile Iron Castings [Metric]
A897 A897-90 (1997) Specification for Austempered Ductile Iron Castings
A903 A903/A903M-99 Specification for Steel Castings, Surface Acceptance Standards, Magnetic Particle and Liquid Penetrant Inspection
A915 A915/A915M-93 (1998) Specification for Steel Castings, Carbon, and Alloy, Chemical Requirements Similar to Standard Wrought Grades
A942 A942-95 Specification for Centrifugally Cast White Iron/Gray Iron Dual Metal Abrasion- Resistant Roll Shells
A957 A957-96 Specification for Investment Castings, Steel and Alloy, Common Requirements, for General Industrial Use
A958 A958-96e1 Specification for Steel Castings, Carbon, and Alloy, with Tensile Requirements, Chemical Requirements Similar to Standard Wrought Grades
A985 A985-98a Specification for Steel Investment Casting General Requirements, for Pressure-Containing Parts
A993 A993-98 Test Method for Dynamic Tear Testing of Cast Irons to Establish Transition Temperature
A1002 A1002-99 Specification for Castings, Nickel-Aluminum Ordered Alloy

FORGINGS

A105 A105/A105M-98 Specification for Carbon Steel Forgings for Piping Applications
A181 A181/A181M-95b Specification for Carbon Steel Forgings, for General-Purpose Piping
A182 A182/A182M-99 Specification for Forged or Rolled Alloy-Steel Pipe Flanges, Forged Fittings, and Valves and Parts for High-Temperature Service
A266 A266/A266M-99 Specification for Carbon Steel Forgings for Pressure Vessel Components
A275 A275/A275M-98 Test Method for Magnetic Particle Examination of Steel Forgings
A288 A288-91 (1998) Specification for Carbon and Alloy Steel Forgings for Magnetic Retaining Rings for Turbine Generators
A289 A289/A289M-97 Specification for Alloy Steel Forgings for Nonmagnetic Retaining Rings for Generators
A290 A290-95 (1999) Specification for Carbon and Alloy Steel Forgings for Rings for Reduction Gears
A291 A291-95 (1999) Specification for Steel Forgings, Carbon and Alloy, for Pinions, Gears and Shafts for Reduction Gears
A314 A314-97 Specification for Stainless Steel Billets and Bars for Forging
A336 A336/A336M-99 Specification for Alloy Steel Forgings for Pressure and High-Temperature Parts
A350 A350/A350M-99 Specification for Carbon and Low-Alloy Steel Forgings, Requiring Notch Toughness Testing for Piping Components
A369 A369/A369M-92 Specification for Carbon and Ferritic Alloy Steel Forged and Bored Pipe for High-Temperature Service
A372 A372/A372M-99 Specification for Carbon and Alloy Steel Forgings for Thin-Walled Pressure Vessels
A388 A388/A388M-95 Practice for Ultrasonic Examination of Heavy Steel Forgings
A418 A418-99 Test Method for Ultrasonic Examination of Turbine and Generator Steel Rotor Forgings
A456 A456/A456M-99 Specification for Magnetic Particle Examination of Large Crankshaft Forgings
A469 A469-94a (1999) Specification for Vacuum-Treated Steel Forgings for Generator Rotors
A471 A471-94 (1999) Specification for Vacuum-Treated Alloy Steel Forgings for Turbine Rotor Disks and Wheels
A472 A472-98 Test Method for Heat Stability of Steam Turbine Shafts and Rotor Forgings
A473 A473-99 Specification for Stainless Steel Forgings
A484 A484/A484M-98 Specification for General Requirements for Stainless Steel Bars, Billets, and Forgings
A493 A493-95 Specification for Stainless Steel Wire and Wire Rods for Cold Heading and Cold Forging
A503 A503/A503M-99 Specification for Ultrasonic Examination of Large Forged Crankshafts
A508 A508/A508M-95 (1999) Specification for Quenched and Tempered Vacuum-Treated Carbon and Alloy Steel Forgings for Pressure Vessels
A522 A522/A522M-95b Specification for Forged or Rolled 8 and 9% Nickel Alloy Steel Flanges, Fittings, Valves, and Parts for Low-Temperature Service
A541 A541/A541M-95 (1999) Specification for Quenched and Tempered Carbon and Alloy Steel Forgings for Pressure Vessel Components
A565 A565-97 Specification for Martensitic Stainless Steel Bars, Forgings, and Forging Stock for High-Temperature Service
A579 A579-99 Specification for Superstrength Alloy Steel Forgings
A592 A592/A592M-89 (1999) Specification for High-Strength Quenched and Tempered Low-Alloy Steel Forged Fittings and Parts for Pressure Vessels
A638 A638/A638M-00 Specification for Precipitation Hardening Iron Base Superalloy Bars, Forgings, and Forging Stock for High-Temperature Service
A646 A646-95 (1999) Specification for Premium Quality Alloy Steel Blooms and Billets for Aircraft and Aerospace Forgings
A649 A649/A649M-99 Specification for Forged Steel Rolls Used for Corrugating Paper Machinery
A668 A668/A668M-96e1 Specification for Steel Forgings, Carbon and Alloy, for General Industrial Use
A694 A694/A694M-00 Specification for Carbon and Alloy Steel Forgings for Pipe Flanges, Fittings, Valves, and Parts for High-Pressure Transmission Service
A705 A705/A705M-95 Specification for Age-Hardening Stainless Steel Forgings
A707 A707/A707M-00 Specification for Forged Carbon and Alloy Steel Flanges for Low-Temperature Service
A711 A711-92 (1996) e1 Specification for Steel Forging Stock
A723 A723/A723M-94 (1999) Specification for Alloy Steel Forgings for High-Strength Pressure Component Application
A727 A727/A727M-97 Specification for Carbon Steel Forgings for Piping Components with Inherent Notch Toughness
A730 A730-93 (1999) Specification for Forgings, Carbon and Alloy Steel, for Railway Use
A745 A745/A745M-94 (1999) Practice for Ultrasonic Examination of Austenitic Steel Forgings
A765 A765/A765M-98a Specification for Carbon Steel and Low-Alloy Steel Pressure-Vessel-Component Forgings with Mandatory Toughness Requirements
A768 A768-95 Specification for Vacuum-Treated 12% Chromium Alloy Steel Forgings for Turbine Rotors and Shafts
A788 A788-98a Specification for Steel Forgings, General Requirements
A831 A831/A831M-95 Specification for Austenitic and Martensitic Stainless Steel Bars, Billets, and Forgings for Liquid Metal Cooled Reactor Core Components
A836 A836/A836M-95b Specification for Titanium-Stabilized Carbon Steel Forgings for Glass-Lined Piping and Pressure Vessel Service
A837 A837-91 (1996) e1 Specification for Steel Forgings, Alloy, for Carburizing Applications
A859 A859/A859M-95 (1999) Specification for Age-Hardening Alloy Steel Forgings for Pressure Vessel Components
A891 A891-98 Specification for Precipitation Hardening Iron Base Superalloy Forgings for Turbine Rotor Disks and Wheels
A909 A909-94 (1999) Specification for Steel Forgings, Microalloy, for General Industrial Use
A921 A921/A921M-93 (1999) Specification for Steel Bars, Microalloy, Hot-Wrought, Special Quality, for Subsequent Hot Forging
A952 A952/A952M-98 Specification for Forged Grade 80 and Grade 100 Steel Lifting Components and Welded Attachment Links
A961 A961-99 Specification for Common Requirements for Steel Flanges, Forged Fittings, Valves, and Parts for Piping Applications
A965 A965/A965M-99 Specification for Steel Forgings, Austenitic, for Pressure and High Temperature Parts
A966 A966/A966M-96 Test Method for Magnetic Particle Examination of Steel Forgings Using Alternating Current

Thursday, September 28, 2006

Group of ASTM standards for steel pipes, tubes and fittings

This article contains ASTM standards for various types of steel pipes which specify requirements for high-temperature service, ordinary use and special applications such as fire protection use.

Specifications for steel tubes list standard requirements for:

  • Boiler and superheater tubes
  • General service tubes
  • Still tubes in refinery service
  • Heat exchanger and condenser tubes
  • Mechanical tubing and
  • Structural tubing.

New standards, which cover the general requirements for alloy and stainless steel pipes, and editorial form and style for writing product specifications are also included.

STEEL PIPES

A53 A53/A53M-99b Specification for Pipe, Steel, Black and Hot-Dipped, Zinc-Coated, Welded and Seamless
A74 A74-98 Specification for Cast Iron Soil Pipe and Fittings
A106 A106-99e1 Specification for Seamless Carbon Steel Pipe for High-Temperature Service
A126 A126-95e1 Specification for Grey Iron Castings for Valves, Flanges, and Pipe Fittings
A134 A134-96 Specification for Pipe, Steel, Electric-Fusion (Arc)-Welded (Sizes NPS 16 and Over)
A135 A135-97c Specification for Electric-Resistance-Welded Steel Pipe
A139 A139-96e1 Specification for Electric-Fusion (Arc)-Welded Steel Pipe (NPS 4 and Over)
A182 A182/A182M-99 Specification for Forged or Rolled Alloy-Steel Pipe Flanges, Forged Fittings, and Valves and Parts for High-Temperature Service
A252 A252-98 Specification for Welded and Seamless Steel Pipe Piles
A312 A312/A312M-00 Specification for Seamless and Welded Austenitic Stainless Steel Pipes
A333 A333/A333M-99 Specification for Seamless and Welded Steel Pipe for Low-Temperature Service
A335 A335/A335M-99 Specification for Seamless Ferritic Alloy-Steel Pipe for High-Temperature Service
A338 A338-84 (1998) Specification for Malleable Iron Flanges, Pipe Fittings, and Valve Parts for Railroad, Marine, and Other Heavy Duty Service at Temperatures Up to 650°F (345°C)
A358 A358/A358M-98 Specification for Electric-Fusion-Welded Austenitic Chromium-Nickel Alloy Steel Pipe for High-Temperature Service
A369 A369/A369M-92 Specification for Carbon and Ferritic Alloy Steel Forged and Bored Pipe for High-Temperature Service
A376 A376/A376M-98 Specification for Seamless Austenitic Steel Pipe for High-Temperature Central-Station Service
A377 A377-99 Index of Specifications for Ductile-Iron Pressure Pipe
A409 A409/A409M-95ae1 Specification for Welded Large Diameter Austenitic Steel Pipe for Corrosive or High-Temperature Service
A426 A426-92 (1997) Specification for Centrifugally Cast Ferritic Alloy Steel Pipe for High-Temperature Service
A451 A451-93 (1997) Specification for Centrifugally Cast Austenitic Steel Pipe for High-Temperature Service
A523 A523-96 Specification for Plain End Seamless and Electric-Resistance-Welded Steel Pipe for High-Pressure Pipe-Type Cable Circuits
A524 A524-96 Specification for Seamless Carbon Steel Pipe for Atmospheric and Lower Temperatures
A530 A530/A530M-99 Specification for General Requirements for Specialized Carbon and Alloy Steel Pipe
A648 A648-95e1 Specification for Steel Wire, Hard Drawn for Prestressing Concrete Pipe
A674 A674-95 Practice for Polyethylene Encasement for Ductile Iron Pipe for Water or Other Liquids
A691 A691-98 Specification for Carbon and Alloy Steel Pipe, Electric-Fusion-Welded for High-Pressure Service at High Temperatures
A694 A694/A694M-00 Specification for Carbon and Alloy Steel Forgings for Pipe Flanges, Fittings, Valves, and Parts for High-Pressure Transmission Service
A716 A716-99 Specification for Ductile Iron Culvert Pipe
A733 A733-99 Specification for Welded and Seamless Carbon Steel and Austenitic Stainless Steel Pipe Nipples
A742 A742/A742M-98 Specification for Steel Sheet, Metallic Coated and Polymer Precoated for Corrugated Steel Pipe
A746 A746-99 Specification for Ductile Iron Gravity Sewer Pipe
A760 A760/A760M-99 Specification for Corrugated Steel Pipe, Metallic-Coated for Sewers and Drains
A761 A761/A761M-98 Specification for Corrugated Steel Structural Plate, Zinc-Coated, for Field-Bolted Pipe, Pipe-Arches, and Arches
A762 A762/A762M-98 Specification for Corrugated Steel Pipe, Polymer Precoated for Sewers and Drains
A790 A790/A790M-99 Specification for Seamless and Welded Ferritic/Austenitic Stainless Steel Pipe
A796 A796/A796M-99 Practice for Structural Design of Corrugated Steel Pipe, Pipe-Arches, and Arches for Storm and Sanitary Sewers and Other Buried Applications
A798 A798/A798M-97a Practice for Installing Factory-Made Corrugated Steel Pipe for Sewers and Other Applications
A807 A807/A807M-97 Practice for Installing Corrugated Steel Structural Plate Pipe for Sewers and Other Applications
A810 A810-94 Specification for Zinc-Coated (Galvanized) Steel Pipe Winding Mesh
A813 A813/A813M-95e2 Specification for Single- or Double-Welded Austenitic Stainless Steel Pipe
A814 A814/A814M-96 (1998) Specification for Cold-Worked Welded Austenitic Stainless Steel Pipe
A849 A849-99 Specification for Post-Applied Coatings, Pavings, and Linings for Corrugated Steel Sewer and Drainage Pipe
A861 A861-94e1 Specification for High-Silicon Iron Pipe and Fittings
A862 A862/A862M-98 Practice for Application of Asphalt Coatings to Corrugated Steel Sewer and Drainage Pipe
A865 A865-97 Specification for Threaded Couplings, Steel, Black or Zinc-Coated (Galvanized) Welded or Seamless, for Use in Steel Pipe Joints
A872 A872-91 (1997) Specification for Centrifugally Cast Ferritic/Austenitic Stainless Steel Pipe for Corrosive Environments
A885 A885/A885M-96 Specification for Steel Sheet, Zinc and Aramid Fiber Composite Coated for Corrugated Steel Sewer, Culvert, and Underdrain Pipe
A888 A888-98e1 Specification for Hubless Cast Iron Soil Pipe and Fittings for Sanitary and Storm Drain, Waste, and Vent Piping Applications
A926 A926-97 Test Method for Comparing the Abrasion Resistance of Coating Materials for Corrugated Metal Pipe
A928 A928/A928M-98 Specification for Ferritic/Austenitic (Duplex) Stainless Steel Pipe Electric Fusion Welded with Addition of Filler Metal
A929 A929/A929M-97 Specification for Steel Sheet, Metallic-Coated by the Hot-Dip Process for Corrugated Steel Pipe
A930 A930-99 Practice for Life-Cycle Cost Analysis of Corrugated Metal Pipe Used for Culverts, Storm Sewers, and Other Buried Conduits
A943 A943/A943M-95e1 Specification for Spray-Formed Seamless Austenitic Stainless Steel Pipes
A949 A949/A949M-95e1 Specification for Spray-Formed Seamless Ferritic/Austenitic Stainless Steel Pipe
A954 A954-96 Specification for Austenitic Chromium-Nickel-Silicon Alloy Steel Seamless and Welded Pipe
A972 A972/A972M-99 Specification for Fusion Bonded Epoxy-Coated Pipe Piles
A978 A978/A978M-97 Specification for Composite Ribbed Steel Pipe, Precoated and Polyethylene Lined for Gravity Flow Sanitary Sewers, Storm Sewers, and Other Special Applications
A984 A984/A984M-00 Specification for Steel Line Pipe, Black, Plain-End, Electric-Resistance-Welded
A998 A998/A998M-98 Practice for Structural Design of Reinforcements for Fittings in Factory-Made Corrugated Steel Pipe for Sewers and Other Applications
A999 A999/A999M-98 Specification for General Requirements for Alloy and Stainless Steel Pipe
A1005 A1005/A1005M-00 Specification for Steel Line Pipe, Black, Plain End, Longitudinal and Helical Seam, Double Submerged-Arc Welded
A1006 A1006/A1006M-00 Specification for Steel Line Pipe, Black, Plain End, Laser Beam Welded

STEEL TUBES

Boiler, Superheater, and Miscellaneous Tubes

A178 A178/A178M-95 Specification for Electric-Resistance-Welded Carbon Steel and Carbon-Manganese Steel Boiler and Superheater Tubes
A179 A179/A179M-90a (1996) e1 Specification for Seamless Cold-Drawn Low-Carbon Steel Heat-Exchanger and Condenser Tubes
A192 A192/A192M-91 (1996) e1 Specification for Seamless Carbon Steel Boiler Tubes for High-Pressure Service
A209 A209/A209M-98 Specification for Seamless Carbon-Molybdenum Alloy-Steel Boiler and Superheater Tubes
A210 A210/A210M-96 Specification for Seamless Medium-Carbon Steel Boiler and Superheater Tubes
A213 A213/A213M-99a Specification for Seamless Ferritic and Austenitic Alloy-Steel Boiler, Superheater, and Heat-Exchanger Tubes
A249 A249/A249M-98e1 Specification for Welded Austenitic Steel Boiler, Superheater, Heat-Exchanger, and Condenser Tubes
A250 A250/A250M-95 Specification for Electric-Resistance-Welded Ferritic Alloy-Steel Boiler and Superheater Tubes
A254 A254-97 Specification for Copper-Brazed Steel Tubing
A268 A268/A268M-96 Specification for Seamless and Welded Ferritic and Martensitic Stainless Steel Tubing for General Service
A269 A269-98 Specification for Seamless and Welded Austenitic Stainless Steel Tubing for General Service
A270 A270-98ae1 Specification for Seamless and Welded Austenitic Stainless Steel Sanitary Tubing
A334 A334/A334M-99 Specification for Seamless and Welded Carbon and Alloy-Steel Tubes for Low-Temperature Service
A423 A423/A423M-95 Specification for Seamless and Electric-Welded Low-Alloy Steel Tubes
A450 A450/A450M-96a Specification for General Requirements for Carbon, Ferritic Alloy, and Austenitic Alloy Steel Tubes
A608 A608-91a (1998) Specification for Centrifugally Cast Iron-Chromium-Nickel High-Alloy Tubing for Pressure Application at High Temperatures
A618 A618-99 Specification for Hot-Formed Welded and Seamless High-Strength Low-Alloy Structural Tubing
A632 A632-98 Specification for Seamless and Welded Austenitic Stainless Steel Tubing (Small-Diameter) for General Service
A688 A688/A688M-98 Specification for Welded Austenitic Stainless Steel Feedwater Heater Tubes
A771 A771/A771M-95 Specification for Seamless Austenitic and Martensitic Stainless Steel Tubing for Liquid Metal-Cooled Reactor Core Components
A778 A778-98 Specification for Welded, Unanneled Austenitic Stainless Steel Tubular Products
A789 A789/A789M-00 Specification for Seamless and Welded Ferritic/Austenitic Stainless Steel Tubing for General Service
A803 A803/A803M-98 Specification for Welded Ferritic Stainless Steel Feedwater Heater Tubes
A822 A822-90 (1995) e1 Specification for Seamless Cold-Drawn Carbon Steel Tubing for Hydraulic System Service
A826 A826/A826M-95 Specification for Seamless Austenitic and Martensitic Stainless Steel Duct Tubes for Liquid Metal-Cooled Reactor Core Components
A847 A847-99a Specification for Cold-Formed Welded and Seamless High Strength, Low Alloy Structural Tubing with Improved Atmospheric Corrosion Resistance
A908 A908-91 (1998) Specification for Stainless Steel Needle Tubing
A953 A953-96 Specification for Austenitic Chromium-Nickel-Silicon Alloy Steel Seamless and Welded Tubing

Heat-Exchanger and Condenser Tubes

A179 A179/A179M-90a (1996) e1 Specification for Seamless Cold-Drawn Low-Carbon Steel Heat-Exchanger and Condenser Tubes
A213 A213/A213M-99a Specification for Seamless Ferritic and Austenitic Alloy-Steel Boiler, Superheater, and Heat-Exchanger Tubes
A214 A214/A214M-96 Specification for Electric-Resistance-Welded Carbon Steel Heat-Exchanger and Condenser Tubes
A249 A249/A249M-98e1 Specification for Welded Austenitic Steel Boiler, Superheater, Heat-Exchanger, and Condenser Tubes
A498 A498-98 Specification for Seamless and Welded Carbon, Ferritic, and Austenitic Alloy Steel Heat-Exchanger Tubes with Integral Fins
A851 A851-96 Specification for High-Frequency Induction Welded, Unannealed, Austenitic Steel Condenser Tubes

Mechanical Tubing

A511 A511-96 Specification for Seamless Stainless Steel Mechanical Tubing
A512 A512-96 Specification for Cold-Drawn Buttweld Carbon Steel Mechanical Tubing
A513 A513-98 Specification for Electric-Resistance-Welded Carbon and Alloy Steel Mechanical Tubing
A519 A519-96 Specification for Seamless Carbon and Alloy Steel Mechanical Tubing
A554 A554-98e1 Specification for Welded Stainless Steel Mechanical Tubing

Structural Tubing

A500 A500-99 Specification for Cold-Formed Welded and Seamless Carbon Steel Structural Tubing in Rounds and Shapes
A501 A501-99 Specification for Hot-Formed Welded and Seamless Carbon Steel Structural Tubing
A847 A847-99a Specification for Cold-Formed Welded and Seamless High Strength, Low Alloy Structural Tubing with Improved Atmospheric Corrosion Resistance
A618 A618-99 Specification for Hot-Formed Welded and Seamless High-Strength Low-Alloy Structural Tubing

WELDING FITTINGS

A234 A234/A234M-99 Specification for Piping Fittings of Wrought Carbon Steel and Alloy Steel for Moderate and High Temperature Service
A403 A403/A403M-99a Specification for Wrought Austenitic Stainless Steel Piping Fittings
A420 A420/A420M-99 Specification for Piping Fittings of Wrought Carbon Steel and Alloy Steel for Low-Temperature Service
A758 A758/A758M-98 Specification for Wrought-Carbon Steel Butt-Welding Piping Fittings with Improved Notch Toughness
A774 A774/A774M-98 Specification for As-Welded Wrought Austenitic Stainless Steel Fittings for General Corrosive Service at Low and Moderate Temperatures

ASTM standards for steel

The Annual Book of ASTM Standards for Steel consists of 8 volumes. It contains formally approved ASTM standard classifications, guides, practices, specifications, test methods and terminology and related material such as proposals. These terms are defined as follows in the Regulations Governing ASTM Technical Committees.

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.

Wednesday, September 27, 2006

Casting Defects in Steels

Metal casters try to produce perfect castings. Few castings, however, are completely free of defects. Modern foundries have sophisticated inspection equipment can detect small differences in size and a wide variety of external and even internal defects.

For example, slight shrinkage on the back of a decorative wall plaque is acceptable whereas similar shrinkage on a position cannot be tolerated. No matter what the intended use, however, the goal of modern foundries is zero defects in all castings.

Scrap castings cause much concern. In industry, scrap results in smaller profits for the company and ultimately affects individual wages. Scrap meetings are held daily. Managers of all the major departments attend these meeting. They gather a castings that have been identified as scrap by in inspector. The defect(s) is circled with chalk. An effort is made to analyze the cause of the defect, and the manager whose department was responsible for it is directed to take corrective action to eliminate that specific defect in future castings.

There are so many variables in the production of a metal casting that the cause is often a combination of several factors rather than a single one. All pertinent data related to the production of the casting (sand and core properties, pouring temperature) must be known in order to identify the defect correctly. After the defect is identified you should attempt to eliminate the defect by taking appropriate corrective action.

The system used here for classifying defects is one based on a physical description of the defect under consideration. It is intended to permit an identification to be made either by direct observation of the defective casting or from a precise description of the defect, involving only the criteria of shape, appearance, location and dimensions. This unique system of classification, based upon the morphology of the defects, is more logical than one based upon causes since it requires no prior assumptions to be made.

Seven basic categories of defects have been established, as listed below and for each basic category only one typical defect is being presented here.

1. Metallic Projections
Joint flash or fins. Flat projection of irregular thickness, often with lacy edges, perpendicular to one of the faces of the casting. It occurs along the joint or parting line of the mold, at a core print, or wherever two elements of the mold intersect.

Possible Causes

* Clearance between two elements of the mold or between mold and core;
* Poorly fit mold joint.

Remedies

* Care in pattern making, molding and core making;
* Control of their dimensions;
* Care in core setting and mold assembly;
* Sealing of joints where possible.

2. Cavities
Blowholes, pinholes. Smooth-walled cavities, essentially spherical, often not contacting the external casting surface (blowholes). The largest cavities are most often isolated; the smallest (pinholes) appear in groups of varying dimensions. In specific cases, the casting section can be strewn with blowholes of pinholes. The interior walls of blowholes and pinholes can be shiny, more or less oxidized or, in the case of cast iron, can be covered with a thin layer of graphite. The defect can appear in all regions of the casting.

Possible Causes
Blowholes and pinholes are produced because of gas entrapped in the metal during the course of solidification:

* Excessive gas content in metal bath (charge materials, melting method, atmosphere, etc.); Dissolved gases are released during solidification;
* In the case of steel and cast irons: formation of carbon monoxide by the reaction of carbon and oxygen, presents as a gas or in oxide form. Blowholes from carbon monoxide may increase in size by diffusion of hydrogen or, less often, nitrogen;
* Excessive moisture in molds or cores;
* Core binders which liberate large amounts of gas;
* Excessive amounts of additives containing hydrocarbons;
* Blacking and washes which tend to liberate too much gas;
* Insufficient evacuation of air and gas from the mold cavity; -insufficient mold and core permeability;
* Entrainment of air due to turbulence in the runner system.

Remedies

* Make adequate provision for evacuation of air and gas from the mold cavity;
* Increase permeability of mold and cores;
* Avoid improper gating systems;
* Assure adequate baking of dry sand molds;
* Control moisture levels in green sand molding;
* Reduce amounts of binders and additives used or change to other types; -use blackings and washes, which provide a reducing atmosphere; -keep the spree filled and reduce pouring height;
* Increase static pressure by enlarging runner height.

3. Discontinuities
Hot cracking. A crack often scarcely visible because the casting in general has not separated into fragments. The fracture surfaces may be discolored because of oxidation. The design of the casting is such that the crack would not be expected to result from constraints during cooling.

Possible Causes
Damage to the casting while hot due to rough handling or excessive temperature at shakeout.
Remedies

* Care in shakeout and in handling the casting while it is still hot;
* Sufficient cooling of the casting in the mold;
* For metallic molds; delay knockout, assure mold alignment, use ejector pins.

4. Defective Surface
Flow marks. On the surfaces of otherwise sound castings, the defect appears as lines which trace the flow of the streams of liquid metal.
Possible Causes
Oxide films which lodge at the surface, partially marking the paths of metal flow through the mold.
Remedies

* Increase mold temperature;
* Lower the pouring temperature;
* Modify gate size and location (for permanent molding by gravity or low pressure);
* Tilt the mold during pouring;
* In die casting: vapor blast or sand blast mold surfaces which are perpendicular, or nearly perpendicular, to the mold parting line.

5. Incomplete Casting
Poured short. The upper portion of the casting is missing. The edges adjacent to the missing section are slightly rounded, all other contours conform to the pattern. The spree, risers and lateral vents are filled only to the same height above the parting line, as is the casting (contrary to what is observed in the case of defect).

Possible Causes

* Insufficient quantity of liquid metal in the ladle;
* Premature interruption of pouring due to workman’s error.

Remedies

* Have sufficient metal in the ladle to fill the mold;
* Check the gating system;
* Instruct pouring crew and supervise pouring practice.

6. Incorrect Dimensions or Shape
Distorted casting. Inadequate thickness, extending over large areas of the cope or drag surfaces at the time the mold is rammed.
Possible Causes
Rigidity of the pattern or pattern plate is not sufficient to withstand the ramming pressure applied to the sand. The result is an elastic deformation of the pattern and a corresponding, permanent deformation of the mold cavity. In diagnosing the condition, the compare the surfaces of the pattern with those of the mold itself.
Remedy
Assure adequate rigidity of patterns and pattern plates, especially when squeeze pressures are being increased.
7. Inclusions or Structural Anomalies
Metallic Inclusions. Metallic or intermetallic inclusions of various sizes which are distinctly different in structure and color from the base material, and most especially different in properties. These defects most often appear after machining.

Heat Treating of Nodular Irons Part Two

Austenitizing Ductile Cast Iron
The usual objective of austenitizing is to produce an austenitic matrix with as uniform carbon content as possible prior to thermal processing. For a typical hypereutectic ductile cast iron, an upper critical temperature must be exceeded so that the austenitizing temperature is in two-phase (austenite and graphite) field. This temperature varies with alloy content.

The "equilibrium" austenite carbon content in equilibrium with graphite increases with an increase in austenitizing temperature. This ability to select (within limits) the matrix austenite carbon content makes austenitizing temperature control important in processes that depend on carbon in the matrix to drive a reaction. This is particularly true in structures to be austempered, in which the hardenability (or austemperability) depends to a significant degree on matrix carbon content. In general, alloy content, the original microstructure, and the section size determine the time required for austenitizing. The sections to follow on annealing, normalizing, quenching and tempering, and austempering discuss austenitizing when it is of concern.

Annealing Ductile Cast Iron
When maximum ductility and good machinability are desired and high strength is not required, ductile iron castings are generally given a full ferritizing anneal. The microstructure is thus converted to ferrite, and the excess carbon is deposited on the existing nodules. This treatment produces ASTM grade 60-40-18. Amounts of manganese, phosphorus, and alloying elements such as chromium and molybdenum should be as low as possible if superior machinability is desired because these elements retard the annealing process.

Recommended practice for annealing ductile iron castings is given below for different alloy contents and for castings with and without eutectic carbides:

* Full anneal for unalloyed 2 to 3% Si iron with no eutectic carbide: Heat and hold at 870 to 900°C (1600 to 1650°F) for 1 h per inch of section. Furnace cool at 55°C/h (100°F/h) to 345°C (650°F). Air cool.
* Full anneal with carbides present: Heat and hold at 900 to 925°C (1650 to 1700°F) for 2 h minimum, longer for heavier sections. Furnace cool at 110°C/h (200°F/h) to 700°C (1300°F). Hold 2 h at 700°C (1300°F). Furnace cool at 55°C/h (100°F/h) to 345°C (650°F). Air cool.
* Subcritical anneal to convert pearlite to ferrite: Heat and hold at 705 to 720°C (1300 to 1330°F), 1 h per inch of section. Furnace cool at 55°C/h (100°F/h) to 345°C (650°F). Air cool. When alloys are present, controlled cooling times through the critical temperature range down to 400°C (750°F) must be reduced to below 55°C/h (100°F/h).

However, certain carbide-forming elements, mainly chromium, form primary carbides that are very difficult, if not impossible, to decompose. For example, the presence of 0.25% Cr results in primary intercellular carbides that cannot be broken down in 2 to 20 h heat treatments at 925°C (1700°F). The resulting matrix after pearlite breakdown is carbides in ferrite with only 5% elongation. Other examples of carbide stabilizers are molybdenum contents greater than 0.3%, and vanadium and tungsten contents exceeding 0.05%.

Hardenability of Ductile Cast Iron
The hardenability of ductile cast iron is an important parameter for determining the response of a specific iron to normalizing, quenching and tempering, or austempering.

Hardenability is normally measured by the Jominy test, in which a standard-sized bar (1 inch diameter by 4 inch in length) is austenitized and water quenched from one end. The variation in cooling rate results in micro-structural variations, giving hardness changes that are measured and recorded.

The higher matrix carbon content resulting from the higher austenitizing temperature results in an increased hardenability (the Jominy curve is shifted to larger distances from the quenched end) and a greater maximum hardness.

The purpose of adding alloy elements to ductile cast irons is to increase hardenability. Manganese and molybdenum are much more effective in increasing hardenablitty, per weight percent added, than nickel or copper. However, as is the case with steel, combinations of nickel and molybdenum, or copper and molybdenum, or copper, nickel, and manganese are more effective than the separate elements. Thus heavy-section castings that require through hardening or austempering usually contain combinations of these elements. Silicon, apart from its effect on matrix carbon content, does not have a large effect on hardenability.

Normalizing Ductile Cast Iron
Normalizing (air cooling following austenitizing) can result in a considerable improvement in tensile strength and may be used in the production of ductile iron of ASTM type 100-70-03.

The microstructure obtained by normalizing depends on the composition of the castings and the cooling rate. The composition of the casting dictates its hardenability that is, the relative position of the fields in the time-temperature CCT diagram. The cooling rate depends on the mass of the casting, but it also may be influenced by the temperature and movement of the surrounding air, during cooling.

Normalizing generally produces a homogeneous structure of fine pearlite, if the iron is not too high in silicon content and has at least a moderate manganese content (0.3 to 0.5% or higher). Heavier castings that require normalizing usually contain alloying elements such as nickel, molybdenum, and additional manganese, for higher hardenability to ensure the development of a fully pearlitic structure after normalizing. Lighter castings made of alloyed iron may be martensitic or may contain an acicular structure after normalizing.

The normalizing temperature is usually between 870 and 940°C (1600 and 1725°F). The standard time at temperature of 1 h per inch of section thickness or 1 h minimum is usually satisfactory. Longer times may be required for alloys containing elements that retard carbon diffusion in the austenite. For example, tin and antimony segregate to the nodules, effectively preventing the solution of carbon from the nodule sites.

Normalizing is sometimes followed by tempering to attain the desired hardness and relieve residual stresses that develop upon air cooling when various parts of a casting, with different section sizes, cool at different rates. Tempering after normalizing is also used to obtain high toughness and impact resistance. The effect of tempering on hardness and tensile properties depends on the composition of the iron and the hardness level obtained in normalizing. Tempering usually consists of reheating to temperatures of 425 to 650°C (800 to 1200°F) and holding at the desired temperature for 1 h per inch of cross section. These temperatures are varied within the above range to meet specification limits.

Quenching and Tempering Ductile Cast Iron
An austenitizing temperature of 845 to 925°C (1550 to 1700°F) is normally used for austenitizing commercial castings prior to quenching and tempering. Oil is preferred as a quenching medium to minimize stresses and quench cracking, but water or brine may be used for simple shapes. Complicated castings may have to be oil quenched at 80 to 100°C (180 to 210°F) to avoid cracks.

The influence of the austenitizing temperature on the hardness of water-quenched cubes of ductile iron shows that the highest range of hardness (55 to 57 HRC) was obtained with austenitizing temperatures between 845 and 870°C (1550 and 1600°F). At temperatures above 870°C, the higher matrix carbon content resulted in a greater percentage of retained austenite and therefore a lower hardness.

Castings should be tempered immediately after quenching to relieve quenching stresses. Tempered hardness depends on as-quenched hardness level, alloy content, and tempering temperature, as well as time. Tempering in the range from 425 to 600°C (800 to 1100°F) results in a decrease in hardness, the magnitude of which depends upon alloy content, initial hardness, and time. Vickers hardness of quenched ductile iron alloys change with tempering temperature and time.

Tempering ductile iron is a two-stage process. The first involves the precipitation of carbides similar to the process in steels. The second stage (usually shown by the drop in hardness at longer times) involves nucleation and the growth of small, secondary graphite nodules at the expense of the carbides. The drop in hardness accompanying secondary graphitization produces a corresponding reduction in tensile and fatigue strength as well. Because alloy content affects the rate of secondary graphitization, each alloy will have a unique range of useful tempering temperatures.

Austempering Ductile Cast Iron
When optimum strength and ductility are required, the heat treater has the opportunity to produce an austempered structure of austenite and ferrite. The austempered matrix is responsible for a significantly better tensile strength-to-ductility ratio than is possible with any other grade of ductile cast iron. The production of these desirable properties requires careful attention to section size and the time-temperature exposure during austenitizing and austempering.

Section Size and Alloying. As section size increases, the rate of temperature change between the austenitizing temperature and austempering temperature decreases. Quenching and austempering techniques include the hot-oil quench (up to 240°C, or 460°F, only), nitrate/nitrite sail quenches, fluidized-bed method (for thin, small parts only), and, in tool-type applications, lead baths.

In order to avoid high-temperature reaction products (such as pearlite in larger section sizes), salt bath quench severities can be increased with water additions or with alloying elements (such as copper, nickel, manganese, or molybdenum) that enhance pearlite hardenability. It is important to understand that these alloying elements tend to segregate during solidification so that a nonuniform distribution exists throughout the matrix. This has a potentially detrimental effect on the austempering reaction and therefore on mechanical properties. Ductility and impact toughness are the most severely affected.

Manganese and molybdenum have the most powerful effect upon pearlite hardenability but will also segregate and freeze into intercellular regions of the casting to promote iron or alloy carbides. While nickel and copper do not affect hardenability nearly as much, they segregate to graphite nodule sites and do not form detrimental carbides. Combinations of these elements, which segregate in opposite fashions, are selected for their synergistic effect on hardenability.

Austenitizing Temperature and Time. Usual schematic phase diagram shows that as austenitizing temperature increases, so does the matrix carbon content; the actual matrix carbon content depends in a complex way on the alloy elements present, their amount, and their location (segregation) within the matrix.

The most important determinant of matrix carbon content in ductile irons is the silicon content; as silicon content increases for a given austenitizing temperature, the carbon content in the matrix decreases. Austenitizing temperatures between 845 and 925°C (1550 and 1700°F) are normal, and austenitizing times of approximately 2 h have been shown to be sufficient to recarburize the matrix fully. Austenitizing temperature, through its effect upon matrix carbon, has a significant effect on hardenability. The higher austenitizing temperature with its higher carbon content promotes increased hardenability, which causes a slower rate of isothermal austenite transformation.

Austempering Temperature and Time. The austempering temperature is the primary determinant of the final microstructure and therefore the hardness and strength of the austempered product. As the austempering temperature increases, the strength and impact toughness vary.

The attainment of maximum ductility at any given austempering temperature is a sensitive function of time. The initial increase in elongation occurs as stage I and elongation progresses to completion, at which point the fraction of austenite is a maximum. Further austempering merely serves to reduce ductility as the stage II reaction causes decomposition to the equilibrium bainite product. Typical austempering times vary from 1 to 4 h.

Tuesday, September 26, 2006

Heat Treating of Nodular Irons Part One

Nodular cast irons (or ductile, or spheroidal graphite iron) are primarily heat treated to create matrix microstructures and associated mechanical properties not readily obtained in the as-cast condition. As-cast matrix microstructures usually consist of ferrite or pearlite or combinations of both, depending on cast section size and/or alloy composition.

The most important heat treatments and their purposes are:

  • Stress relieving, a low-temperature treatment, to reduce or relieve internal stresses remaining after casting
  • Annealing, to improve ductility and toughness, to reduce hardness, and to remove carbides
  • Normalizing, to improve strength with some ductility
  • Hardening and tempering, to increase hardness or to improve strength and raise proof stress ratio
  • Austempering, to yield a microstructure of high strength, with some ductility and good wear resistance
  • Surface hardening, by induction, flame, or laser, to produce a locally selected wear-resistant hard surface
The normalizing, hardening, and austempering heat treatment, which involve austenitization, followed by controlled cooling or isothermal reaction, or a combination of the two, can produce a variety of microstructures and greatly extend the limits on the mechanical properties of ductile cast iron.

These microstructures can be separated into two broad classes:

  • Those in which the major iron-bearing matrix phase is the thermodynamically stable body-centered cubic (ferrite) structure
  • Those with a matrix phase that is a meta-stable face-centered cubic (austenite) structure.
  • The former are usually generated by the annealing, normalizing, normalizing and tempering, or quenching and tempering processes. The latter are generated by austempering, an isothermal reaction process resulting in a product called austempered ductile iron (ADI).

    Other heat treatments in common industrial use include stress-relief annealing and selective surface heat treatment. Stress-relief annealing does not involve major micro-structural transformations, whereas selective surface treatment (such as flame and induction surface hardening) does involve microstructural transformations, but only in selectively controlled parts of the casting.

    The basic structural differences between the ferritic and austenitic classes are explained in the Fig 1 and 2. Figure 1 shows a continuous cooling transformation (CCT) diagram and cooling curves for furnace cooling, air-cooling, and quenching.

    It can be seen from Fig 1 that slow furnace cooling results in a ferritic matrix (the desired product of annealing), whereas the cooling curve for air cooling, or normalizing, results in a pearlitic matrix, and quenching produces a matrix microstructure consisting mostly of martensite with some retained austenite. Tempering softens the normalized and quenched conditions, resulting in microstructures consisting of the matrix ferrite with small panicles of iron carbide (or secondary graphite).

    Fig.1: CCT diagram showing annealing, normalizing and quenching;
    Ms stand martensite start, Mf for martensite finish.

    Figure 2 shows an isothermal transformation (IT) diagram for a ductile cast iron, together with a processing sequence depicting the production of ADI. In this process, austenitizing is followed by rapid quenching (usually in molten salt) to an intermediate temperature range for a time that allows the unique metastable carbon-rich (≈2% C) austenitic matrix (γH) to evolve simultaneously with nucleation and growth of a plate-like ferrite (α) or of ferrite plus carbide, depending on the austempering temperature and time at temperature.

    This austempering reaction progresses to a point at which the entire matrix has been transformed to the metastable product (stage I in Fig 2), and then that product is "frozen in" by cooling to room temperature before the true bainitic ferrite plus carbide phases can appear (stage II in Fig 2).

    In ductile cast irons the presence of 2 to 3 wt% Si prevents the rapid formation of iron carbide (Fe3C). Hence the carbon rejected during ferrite formation in the first stage of the reaction (stage I in Fig 2) enters the matrix austenite, enriching it and stabilizing it thermally to prevent martensite formation upon subsequent cooling. Thus the processing sequence in Fig 2 shows that the austempering reaction is terminated before stage II begins and illustrates the decrease in the martensite start (Ms) and martensite finish (Mf) temperatures as γH forms in stage I. Typical austempering times range from 1 to 4 h depending on alloy content and section size. If the part is austempered too long, undesirable bainite will form. Unlike steel, bainite in cast iron microstructures exhibits lower toughness and ductility.

    Fig.2: IT diagram of a processing sequence for austempering.