Steel grades
Steel grades are standardized classifications that define the chemical composition, mechanical properties, metallurgical characteristics, and intended uses of various steel alloys, enabling precise specification and quality control in manufacturing and engineering applications.[1] These grades encompass thousands of variations, with over 3,500 distinct types identified based on factors such as carbon content, alloying elements, and heat treatment processes.[2] The primary categories of steel grades include carbon steels, which comprise about 90% of global steel production and are subdivided into low-carbon (up to 0.3% carbon, e.g., mild steels like ASTM A36), medium-carbon (0.3–0.6% carbon), and high-carbon (over 0.6% carbon) variants valued for their strength and ductility.[3] Alloy steels incorporate elements like chromium, nickel, or molybdenum (typically 1–50% total alloys) to enhance properties such as hardness, corrosion resistance, and toughness, with common examples including SAE 4130 and 4140 for structural and automotive uses.[4] Stainless steels, distinguished by at least 10.5% chromium content, offer superior corrosion resistance and are grouped into austenitic (e.g., 304 grade), ferritic, martensitic, and duplex subtypes for applications in food processing, medical devices, and harsh environments.[2] Tool steels, engineered for high wear resistance and durability, contain elements like tungsten and vanadium and are used in cutting tools and dies, with series such as AISI W1 or D2.[3] Classification systems for steel grades are maintained by international organizations to ensure interoperability and standardization. The ASTM International system uses alphanumeric designations, such as "A" for ferrous metals followed by a number (e.g., A36 for carbon structural steel), specifying properties for products like plates, bars, and pipes.[1] The SAE/AISI system employs a four-digit code for carbon and alloy steels, where the first two digits indicate the alloy type (e.g., 10xx for plain carbon, 41xx for chromium-molybdenum) and the last two denote carbon content in hundredths of a percent (e.g., 1040 has 0.40% carbon).[5] European standards under ISO and EN (e.g., EN 10025 for structural steels) provide similar compositional and performance-based grading, often harmonized with ASTM for global trade.[4] These systems facilitate selection based on microstructure—such as ferrite, pearlite, or martensite—which directly influences performance traits like tensile strength and weldability.[2]Fundamentals of Steel Grading
Definition and Purpose
Steel is an alloy primarily composed of iron and a small percentage of carbon, typically ranging from 0.02% to 2.1% by weight, along with possible alloying elements such as manganese, silicon, or chromium that influence its properties.[6][7] Steel grades serve as standardized alphanumeric designations that classify different types of steel based on their chemical composition, mechanical properties, heat treatment processes, or intended applications.[6] These classifications enable precise specification of material characteristics, such as strength levels or corrosion resistance, allowing engineers and manufacturers to select steels suited to specific performance needs.[7] The primary purpose of steel grades is to facilitate material selection, quality control, regulatory compliance, and global trade by providing a common framework for describing and verifying steel properties.[8] For instance, in structural engineering, adhering to appropriate grades helps prevent failures in load-bearing components like bridges or buildings by ensuring the material meets required thresholds for yield strength and ductility.[6] This standardization supports interoperability across supply chains, from production to end-use. Key benefits of steel grading systems include achieving consistency in material performance, optimizing costs through targeted alloying and processing, and enabling traceability throughout the lifecycle of steel products.[7] By linking grades to verifiable properties like tensile strength or weldability, these systems minimize variability in manufacturing and enhance safety in demanding applications.[8]Historical Development
The development of steel grading systems began in the 19th century with informal practices in the UK and US, where classification relied on rudimentary composition tests to assess carbon content and impurities in wrought iron and early steel products. The introduction of the Bessemer process in the 1850s marked a pivotal shift, enabling mass production of steel and prompting initial efforts to categorize materials based on their mechanical suitability for applications like railways and machinery.[9][10] These early systems were largely empirical, often conducted by individual manufacturers without standardized protocols, reflecting the nascent industrial demand for consistent material quality.[11] In the early 20th century, formalization accelerated with the establishment of key organizations in North America. The American Society for Testing and Materials (ASTM) was founded in 1898 to develop reliable testing methods for steel properties, laying the groundwork for objective grading criteria. The American Iron and Steel Institute (AISI), formed in 1908, introduced composition-based coding systems to specify alloy elements systematically. Complementing this, the Society of Automotive Engineers (SAE), established in 1905, began developing specialized grades for automotive applications around 1911, focusing on strength and durability requirements for emerging vehicle designs.[12] These advancements shifted grading from ad hoc assessments to structured, industry-driven standards. Post-World War II globalization drove further evolution, as international trade necessitated harmonized systems. The International Organization for Standardization (ISO) initiated efforts in 1947 to promote global consistency, including technical committees for steel specifications.[13] In Japan, the Japanese Industrial Standards (JIS) were first formalized in 1921 but underwent significant updates post-1950 following the 1949 Industrial Standardization Law, incorporating modern testing for export-oriented production.[14] European standards (EN) emerged in the 1970s under the European Economic Community (EEC), with the European Committee for Standardization (CEN), founded in 1961, coordinating unified norms to replace disparate national codes.[15] A key milestone was the 1980s transition from German DIN standards to EN equivalents, streamlining specifications across member states.[16] In the 21st century, grading systems have incorporated advanced performance metrics and digital innovations. The American Institute of Steel Construction (AISC) issued revisions in 2025 to accommodate high-performance grades optimized for seismic and sustainable applications.[17] Emerging trends include blockchain-enabled digital traceability, which enhances grading verification by providing immutable records of composition and processing from mill to end-use, addressing supply chain transparency demands.[18] Additionally, in the 2010s, the American Petroleum Institute (API) updated standards like API 5L to better suit sour service environments, incorporating enhanced resistance to hydrogen-induced cracking through refined HIC testing protocols.[19]Classification Approaches
By Mechanical Properties
Steel grades are classified by mechanical properties to emphasize their performance in service, prioritizing attributes like strength, ductility, and toughness over elemental makeup. This method allows engineers to select materials based on how they behave under load, ensuring reliability in demanding environments.[20] Key criteria include yield strength, which is the stress level at which the steel starts to deform plastically and is specified as a minimum value in megapascals (MPa); tensile strength, the maximum stress before fracture; elongation, a measure of ductility expressed as a percentage of length increase before breaking; and impact resistance, which gauges toughness against sudden loads.[21][22] Grade notations often feature numeric suffixes representing the minimum yield strength, such as 235 for 235 MPa, paired with letters denoting the application type, like S for structural steels.[20] Mechanical properties are assessed through standardized tests. Tensile testing per ASTM E8 involves applying uniaxial tension to a machined specimen at room temperature (10–38°C) to derive yield strength, tensile strength, and elongation from the stress-strain curve. Yield strength is computed as \sigma_y = \frac{F_y}{A} where \sigma_y is the yield strength, F_y is the load at yield, and A is the original cross-sectional area. Impact resistance uses the Charpy V-notch method under ISO 148-1, where a pendulum strikes a notched specimen to quantify absorbed energy in joules, indicating fracture toughness at specified temperatures.[23] In applications, high-yield-strength steels support structural beams in buildings and bridges for efficient load-bearing. Toughness-focused grades suit pressure vessels, resisting brittle failure under pressure and thermal cycling. High-strength low-alloy (HSLA) steels illustrate this approach, providing yield strengths above 250 MPa and good weldability for automotive frames and heavy machinery components.[7][24] This classification advantages lie in verifying fitness-for-purpose through verifiable performance metrics, enabling proprietary formulations while meeting design requirements for strength and durability.[20]By Chemical Composition
Steel grades classified by chemical composition are defined primarily through the precise control and specification of elemental percentages, which serve as a blueprint for achieving consistent material behavior during manufacturing and application. This approach emphasizes the "recipe" of alloying elements, allowing manufacturers flexibility in heat treatment and processing to tailor properties while ensuring reproducibility across batches. Key elements include carbon, which typically ranges from 0.05% to 2.0% and acts as the primary hardener, along with manganese (up to 2%), silicon (0.2-2.5%), and intentional additions of alloying elements such as chromium, nickel, and molybdenum to enhance specific attributes like corrosion resistance or toughness. Tolerances for these elements are tightly controlled, often to ±0.01% for critical components like carbon, to minimize variations that could affect performance. Notation systems for these grades often employ numeric codes that directly reflect the composition. For plain carbon steels, a common scheme uses codes like 10xx, where "10" denotes a plain carbon steel and "xx" represents the average carbon content in hundredths of a percent (e.g., 1040 for 0.40% carbon). The AISI/SAE 4-digit system extends this to alloy steels, with the first two digits indicating the alloy type (e.g., 51 for 1.00% chromium steels) and the last two specifying the average carbon content in hundredths of a percent. These notations facilitate quick identification of the base composition without delving into mechanical testing results. A distinction exists between heat analysis and product analysis in compositional verification. Heat analysis, performed on samples from the molten steel ladle, reports the average composition of the entire heat and guides initial alloying adjustments. In contrast, product analysis examines the finished steel product, accounting for potential segregation or losses during solidification and processing, with allowable deviations typically up to ±0.03% for carbon and similar for other elements. To assess weldability based on composition, the carbon equivalent (CE) formula is widely used: CE = C + \frac{Mn}{6} + \frac{Cr + Mo + V}{5} + \frac{Ni + Cu}{15} This empirical equation integrates the effects of multiple elements on hardenability and cracking susceptibility, with CE values below 0.4 generally indicating good weldability for low-alloy steels. Steels are categorized by carbon content into low-carbon (less than 0.3% C, prized for ductility and formability), medium-carbon (0.3-0.6% C, balancing strength and machinability), and high-carbon (greater than 0.6% C, valued for hardness and wear resistance). Stainless steels form a separate group, requiring at least 10.5% chromium to form a passive oxide layer for corrosion protection, often combined with nickel or molybdenum. High-alloy tool steels, featuring elevated levels of tungsten, vanadium, or cobalt, are designed for extreme wear and heat resistance in cutting tools and dies. In automotive applications, precise compositional control in low-alloy steels ensures optimal formability for body panels and structural components. Composition directly influences achievable mechanical properties, such as how higher carbon increases hardness but reduces ductility.Major Regional Standards
European Standards (EN)
The European Standards (EN) for steel grades are established by the European Committee for Standardization (CEN) and provide a unified system for designating steels across Europe, primarily through EN 10027-1, which outlines rules for steel names using symbolic letters and numbers to indicate application, mechanical properties, or chemical composition.[25] This system divides designations into two main categories: Category 1, which prioritizes purpose and properties, and Category 2, which focuses on chemical composition, ensuring consistency in specifications for non-alloy and alloy steels used in construction, machinery, and other sectors.[25] In Category 1, steel names begin with letters denoting the type, such as S for structural steels or C for case-hardening steels, followed by numbers representing minimum yield strength in megapascals (e.g., S355 indicates 355 MPa yield strength), and additional symbols for quality and treatment.[25] Sub-standards like EN 10025 specify structural steels with grades ranging from S235 to S460, suitable for hot-rolled products in building and infrastructure applications.[21] For quenched and tempered steels, EN 10083 defines grades such as 25CrMo4, an alloy steel with chromium and molybdenum for enhanced hardenability in mechanical components.[26] Additional symbols include delivery conditions like +A for soft annealed, +N for normalized, and +QT for quenched and tempered, appended after the base name to specify processing; quality levels such as JR (27 J impact energy at 20°C), J0 (at 0°C), J2 (at -20°C), and K2 (40 J at -20°C) indicate Charpy V-notch toughness requirements.[27] Full designations, such as S355J2G3 in older notations (now simplified to S355J2), incorporate these elements for precise material selection.[25] Category 2 employs a numeric system for composition-based identification, starting with a digit from 1 to 9 for steel families (e.g., 1 for non-alloy quality steels), followed by four digits for specific analysis, such as 1.0503 for C45, a medium-carbon steel with approximately 0.45% carbon used in general engineering.[25] For stainless steels, EN 10088 applies this system, with grades like 1.4301 (X5CrNi18-10) denoting an austenitic composition of about 18% chromium and 10% nickel, equivalent to common 304 stainless for corrosion-resistant applications.[28] These designations support diverse applications, with the S series predominantly used in construction for beams and plates due to its balance of strength and weldability, while the E series targets machinery and engineering components requiring specific toughness and machinability.[29]North American Standards (ASTM/AISI/SAE)
In North America, the American Iron and Steel Institute (AISI) and Society of Automotive Engineers (SAE) designation systems provide a standardized numerical framework for identifying carbon and low-alloy steels based primarily on chemical composition. These systems employ a four-digit code where the first digit classifies the steel type—such as 1 for non-resulfurized carbon steels—while the subsequent digits approximate the carbon content in hundredths of a percent by weight; for instance, SAE 1018 indicates a plain carbon steel with approximately 0.18% carbon and no significant alloying elements beyond manganese. Alloy series extend from 2xxx (nickel-bearing steels) through 9xxx (various high-alloy types like silicon-manganese or nickel-chromium-molybdenum), encompassing over 150 grades tailored for diverse industrial uses, with SAE maintaining the active standards since AISI ceased issuing new designations in the 1990s.[30][5][31] Complementing these composition-focused systems, ASTM International specifications—prefixed with "A" for ferrous materials—emphasize performance requirements including mechanical properties, test methods, and end-use suitability, often referencing AISI/SAE compositions for alignment. A prominent example is ASTM A36, a versatile carbon structural steel for riveted, bolted, or welded construction in bridges and buildings, mandating a minimum yield strength of 36 ksi (250 MPa) and tensile strength of 58-80 ksi (400-550 MPa). Many ASTM standards, such as those for bars and plates, incorporate AISI/SAE chemistry limits to ensure consistency across wrought products.[1][32] Representative grades highlight the systems' versatility: AISI 4140, a chromium-molybdenum alloy steel (approximately 0.40% carbon, 0.8-1.1% chromium, 0.15-0.25% molybdenum), offers high hardenability, fatigue resistance, and toughness for applications like axles, gears, and aircraft components, achieving yield strengths up to 95 ksi (655 MPa) after quenching and tempering. SAE 52100, a through-hardening high-carbon chromium steel (0.93-1.05% carbon, 1.35-1.60% chromium), provides exceptional wear resistance and rolling contact fatigue strength, making it the standard for ball and roller bearings with hardness levels of 58-65 HRC. In structural contexts, ASTM A514 delivers high-yield quenched and tempered alloy plates (yield strength 90-100 ksi or 620-690 MPa depending on thickness) for heavy welded fabrications like crane booms and offshore platforms, balancing strength with weldability.[33][34][35] Heat treatment conditions are denoted by suffixes in AISI/SAE-related specifications for bars and forgings, such as "A" for annealed (full or subcritical to refine microstructure and enhance ductility) and "S" for spheroidize annealed (prolonged heating just below the eutectoid temperature to form globular carbides, improving machinability in high-carbon grades without sacrificing strength potential). The 4th edition (2024) of the American Institute of Steel Construction (AISC) Seismic Design Manual incorporates updates for grades like ASTM A913 Grade 65 or 80, high-strength low-alloy steels with enhanced notch toughness and ductility (yield strengths of 65 ksi or 80 ksi), enabling lighter seismic-resistant framing in high-risk zones while meeting ductility demands under cyclic loading.[36] These standards find broad application in sector-specific contexts: SAE J403 outlines chemical ranges for carbon steels in automotive parts like frames and panels, ensuring formability and crash performance across grades from 1005 to 1095. ASTM A53 covers seamless and welded black or galvanized steel pipes for low-pressure conveyance of fluids such as water, gas, or steam in pipelines and structural tubing, with Grade B offering a minimum yield of 35 ksi (240 MPa) and seamless options for higher integrity. Historically, AISI focused on wrought steel compositions for general manufacturing, whereas SAE emphasizes automotive and mobility engineering, though the designations are now largely interchangeable with SAE as the primary steward.[30][37][38]Asian Standards (JIS/GB)
The Japanese Industrial Standards (JIS) and Chinese national standards (GB) represent key frameworks for steel grading in Asia, adapting international principles to support regional manufacturing, construction, and engineering needs, with JIS emphasizing precision engineering and GB focusing on high-volume production for infrastructure.[39][40] JIS employs an alphanumeric designation system for steel grades, where prefixes indicate the application and category, followed by numbers denoting mechanical properties such as tensile strength in megapascals (MPa). For instance, the grade SS400 under JIS G 3101 specifies structural rolled steels for general use, with "SS" denoting structural steel and "400" indicating a minimum tensile strength of 400 MPa. The G series standards cover a range of steels, including G 3101 for carbon structural steels and G 4053 for free-cutting steels used in tool applications. Key examples include S45C from JIS G 4051, a medium-carbon steel (approximately 0.45% carbon) suitable for machine structural components like shafts and gears due to its balanced strength and machinability, and SM490 from JIS G 3106, a high-strength low-alloy (HSLA) structural steel with a minimum yield strength of 325 MPa, valued for welded structures. These grades align with ISO frameworks but incorporate Japan-specific testing protocols, such as JIS Z 2241 for tensile testing, ensuring compliance with rigorous quality controls.[41][42] In contrast, GB standards, managed by the Standardization Administration of China, use a numeric system prefixed by letters to denote steel type and key properties, prioritizing yield strength for structural applications. The grade Q235, governed by GB/T 700-2006 for carbon structural steels, exemplifies this with "Q" indicating low-carbon steel and "235" representing a minimum yield strength of 235 MPa for thicknesses up to 16 mm, making it suitable for general fabrication with tensile strengths ranging from 370-500 MPa. GB/T 1591 addresses low-alloy high-strength structural steels, such as Q345 series with yield strengths from 295-345 MPa depending on thickness, enhancing weldability and toughness for demanding uses. These standards specify dimensions, chemical compositions (e.g., carbon ≤0.22% for Q235B), and testing methods, including impact toughness for grades like Q235D at -20°C.[43][44][45] Recent developments in these standards reflect Asia's evolving industrial priorities. JIS G 3114 specifies hot-rolled atmospheric corrosion-resisting steels (SMA series) for welded structures, particularly in earthquake-prone regions, where grades like SMA570W provide superior weathering resistance and ductility for bridges and architectural elements, supporting seismic resilience through controlled alloying with elements like copper and chromium (total ≤0.15% for Ti, V, Zr additions).[46][47] Applications of these standards highlight regional distinctions: JIS grades like SS400 and SM490 are extensively used in shipbuilding for hulls, decks, and bulkheads due to their weldability and corrosion resistance in marine environments, aligning with Japan's precision-focused shipyards. GB grades, such as Q345 under GB/T 1591, dominate infrastructure projects like bridges and high-rise buildings in China, benefiting from cost-effective, high-volume production that supports rapid urbanization. Overall, GB steels prioritize scalability for mass infrastructure, while JIS emphasizes quality and specialized performance for export-oriented sectors.[48][49][50]International and Specialized Standards
ISO and Global Harmonization Efforts
The International Organization for Standardization (ISO) has been instrumental in advancing global harmonization of steel grades since the establishment of its Technical Committee 17 (ISO/TC 17) in 1947, which focuses on standardizing cast iron, wrought steel, and cold-formed steel products, including technical delivery conditions.[13] This committee oversees efforts to create unified nomenclature and specifications that reduce trade barriers and ensure consistency in material properties across borders. ISO's designation systems, outlined in documents like ISO/TR 15510 (an earlier technical report on stainless steel compositions, evolved into ISO 15510:2014), employ numeric symbols for grades, such as Fe E 355 in ISO 630 for structural steels, where "Fe" denotes iron, "E" indicates normalized or equivalent treatment, and "355" specifies the minimum yield strength in MPa.[51] [52] [53] These systems facilitate cross-referencing with national standards, promoting interoperability without mandating a complete overhaul of regional practices. Key ISO standards further support this harmonization by defining precise requirements for specific steel types. For instance, ISO 683 (a multi-part series, with ISO 683-1:2016 covering non-alloy steels for quenching and tempering) specifies technical delivery conditions for heat-treatable steels, alloy steels, and free-cutting steels intended for machine parts and components.[54] Similarly, ISO 4950-1:1995 addresses high-yield-strength flat steel products for structural applications, emphasizing manufacturing methods, acceptance criteria, and marking, with qualities akin to those in European EN S-series grades.[55] EN standards frequently align with or reference ISO equivalents to streamline global supply chains.[56] Despite these advances, challenges remain in achieving a single global steel grading system, as national and regional standards continue to evolve independently, leading to persistent discrepancies in testing methods and tolerances. ISO acts as a vital bridge, with ongoing TC 17 work integrating feedback from international stakeholders to refine specifications. In 2025, sustainability initiatives gained prominence through ISO/TC 17/SC 21 (established in 2023 for climate change and the steel industry), which is developing guidelines for low-carbon processes and recycled content labeling to address environmental impacts, such as traceability of secondary materials in steel production.[57] [58] These efforts align with broader ISO frameworks like ISO 14021 for environmental declarations, enabling labels that quantify recycled content to support circular economy goals. In practice, ISO-referenced grades are essential for international projects requiring cross-border collaboration, such as large-scale bridges where uniform material performance ensures structural integrity and regulatory compliance. For example, the Øresund Bridge between Denmark and Sweden used S460 steel qualities harmonized via ISO-aligned standards to meet diverse national requirements while maintaining global quality benchmarks.API Standards for Petroleum Applications
The American Petroleum Institute (API) develops specialized standards for steel grades used in the petroleum industry, particularly for applications involving high-pressure oil and gas extraction, transportation, and production. These standards ensure materials can withstand extreme conditions such as corrosive environments, elevated pressures, and mechanical stresses unique to upstream and midstream operations. Unlike general-purpose steels, API grades prioritize attributes like resistance to hydrogen sulfide (H2S) cracking, collapse resistance, and burst strength to support safe and reliable performance in drilling and pipeline systems.[59] API 5L specifies requirements for seamless and welded steel line pipe used in the transportation of oil, gas, and related fluids over long distances. It defines two product specification levels: PSL 1, which provides standard quality with basic chemical and mechanical requirements, and PSL 2, which imposes stricter controls on composition, testing, and properties for enhanced performance. Common grades include X52, designated by its minimum yield strength of 52 ksi (360 MPa), and X70 with a minimum yield strength of 70 ksi (485 MPa); tensile strengths typically range from 66 ksi for X52 to 82 ksi for X70, ensuring pipes can handle high internal pressures during fluid conveyance. These grades are manufactured from carbon or low-alloy steels optimized for pipeline integrity.[60][61] In contrast, API 5CT covers steel tubing and casing for oil and gas wells, focusing on downhole applications during drilling and production. Grades range from H40, with a minimum yield strength of 40 ksi, to P110 at 110 ksi, offering progressively higher strength for deeper and more demanding wells; for example, P110 provides a minimum tensile strength of 125 ksi, suitable for high-pressure environments. These components isolate production zones, prevent well collapse, and facilitate fluid extraction, with manufacturing processes including seamless, electric-resistance welded, or coupled configurations.[62][63] Key mechanical requirements across API 5L and 5CT grades include minimum yield and tensile strengths tailored to service conditions, along with Charpy impact toughness testing to ensure ductility at low temperatures. For sour service involving H2S exposure, compliance with NACE MR0175/ISO 15156 is mandatory, limiting hardness to 22 HRC for carbon steels to mitigate sulfide stress cracking while specifying environmental and metallurgical controls. Color coding with painted bands on pipe ends aids rapid identification: L80 grade features one red band and one brown band, while P110 uses a white band, standardizing logistics in field operations.[60][62][64][65] Recent updates in 2025 reaffirm API 5LC, which specifies seamless, centrifugal cast, and welded alloy line pipe with enhanced corrosion-resistant properties for sour service, emphasizing low-carbon equivalents and alloying elements to improve resistance in aggressive H2S environments without compromising mechanical integrity. In applications, API 5CT casings and tubings are critical for drilling to contain formation pressures and protect well integrity, while API 5L line pipes enable efficient transport from wells to processing facilities; both differ from general steels by mandating rigorous hydrostatic testing, non-destructive examination, and pressure-containment design to address petroleum-specific hazards like sour corrosion and cyclic loading.[66][67][68]Grade Equivalents and Comparisons
Cross-Reference Tables
Cross-reference tables offer practical overviews of steel grade equivalents across key international standards, facilitating quick comparisons for engineers and manufacturers. These equivalencies are determined by aligning similar chemical compositions (e.g., carbon content), minimum yield strengths, and intended applications, such as structural or general-purpose use. While not exact matches due to variations in testing methods and specifications, they provide reliable starting points for material selection. The examples below are sourced from authoritative references, including the Handbook of Comparative World Steel Standards (ASTM DS67A, 2007 edition) for carbon, alloy, and HSLA steels, and ISO 15510:2010 for stainless steels.[69][70]Carbon Steels
The table below lists common low-carbon structural steels with equivalents based on yield strengths around 200-300 MPa and carbon contents typically under 0.25%, suitable for general fabrication and construction.[69]| EN Designation | ASTM/SAE | JIS | GB | Notes (Yield Strength, MPa) |
|---|---|---|---|---|
| S235JR (1.0038) | A283 Grade C | SS400 | Q235B | 235 min; general structural use |
| S275JR (1.0044) | A36 | SS400 | Q275B | 275 min; welding applications |
| S235J0 (1.0114) | A283 Grade B | SS330 | Q235A | 235 min; similar ductility |
| S275J0 (1.0143) | A570 Grade 30 | SS400 | Q275A | 275 min; plate forms |
| P235GH (1.0345) | A285 Grade A | SB410 | 20g | 235 min; pressure vessels |
Alloy Steels
This table focuses on medium-carbon alloy steels with carbon contents of 0.4-0.5% and added elements like manganese for improved strength and machinability, often used in shafts and gears. Equivalents align on tensile strengths of 500-700 MPa.[69]| EN Designation | AISI/SAE | JIS | GB | Notes (Carbon %, Tensile Strength, MPa) |
|---|---|---|---|---|
| 1.0503 (C45) | 1045 | S45C | 45# | 0.42-0.50%; 540-700 |
| C45E (1.1191) | 1045 | S45C | 45Mn | 0.42-0.50%; heat-treatable |
| 1.0401 (Ck45) | 1045 | S45C | 40Mn | 0.42-0.50%; case hardening |
| 1.0511 (40Mn4) | 1536 | SCMn1 | 36Mn | 0.32-0.39%; higher manganese |
| 1.0722 (11SMn30) | 1213 | SUM21 | Y15 | Free-machining; sulfur added |
Stainless Steels
Austenitic stainless steels in this table share chromium (17-19%) and nickel (8-10%) contents for corrosion resistance, with equivalents verified through chemical composition matches in ISO 15510:2010. They are widely used in food processing and chemical equipment.[70]| EN Designation | AISI/UNS | JIS | GB | Notes (Cr/Ni %) |
|---|---|---|---|---|
| 1.4301 (X5CrNi18-10) | 304/S30400 | SUS304 | 0Cr18Ni9 | 18/8; general purpose |
| 1.4307 (X2CrNi18-9) | 304L/S30403 | SUS304L | 00Cr19Ni10 | 18/9; low carbon variant |
| 1.4401 (X5CrNiMo17-12-2) | 316/S31600 | SUS316 | 0Cr17Ni12Mo2 | 17/12; molybdenum enhanced |
| 1.4571 (X6CrNiMoTi17-12-2) | 316Ti/S31635 | SUS316Ti | 0Cr18Ni12Mo2Ti | 17/12; stabilized |
| 1.4541 (X6CrNiTi18-10) | 321/S32100 | SUS321 | 0Cr18Ni10Ti | 18/10; titanium stabilized |
High-Strength Low-Alloy (HSLA) Steels
HSLA grades here feature yield strengths of 345-450 MPa with microalloying elements like niobium and vanadium for enhanced toughness, ideal for bridges and heavy machinery. Equivalents are based on mechanical properties and applications from the handbook.[69]| EN Designation | ASTM | JIS | GB | Notes (Yield Strength, MPa) |
|---|---|---|---|---|
| S355JR (1.0045) | A572 Grade 50 | SM490A | Q345B | 355 min; structural beams |
| S355J0 (1.0553) | A572 Grade 50 | SM490B | Q345C | 355 min; normalized |
| S355J2 (1.0570) | A572 Grade 50 | SM490C | Q345D | 355 min; low temperature |
| S355K2 (1.0595) | A572 Grade 65 | SM520B | Q390B | 355 min; impact tested |
| S460N (1.8902) | A572 Grade 60 | SM570 | Q460C | 460 min; high strength |