Nominal Pipe Size
Nominal Pipe Size (NPS) is a dimensionless North American standard designation used to identify the size of pipes, fittings, flanges, and valves in plumbing, piping, and industrial applications, where the numerical value loosely approximates the inside diameter in inches but does not precisely match the actual inside or outside dimensions.[1] The term "nominal" reflects this historical approximation, originating from early 20th-century conventions to standardize pipe sizing without requiring exact measurements for interchangeability across manufacturers.[2] Governed primarily by the American Society of Mechanical Engineers (ASME) B36.10 standard for welded and seamless wrought steel pipe, NPS ensures consistent outside diameters (OD) for a given size, allowing compatibility in systems handling high or low pressures and temperatures.[3] For pipes with NPS 1/8 through 12, the actual OD exceeds the NPS value—for instance, NPS 2 has an OD of 2.375 inches (60.3 mm)—while for NPS 14 and larger, the OD equals the NPS number in inches, such as NPS 14 with an OD of 14 inches (355.6 mm). Wall thickness is specified separately using "schedule" designations (e.g., Schedule 40 or 80), which determine the pipe's pressure rating and internal diameter, with thicker walls reducing the ID further from the nominal value.[3] This system, established by the American National Standards Institute (ANSI) and ASME, applies to various materials including carbon steel, stainless steel, and alloys, and contrasts with the metric Diamètre Nominal (DN) equivalent under ISO 6708, where sizes are directly tied to approximate inside diameters in millimeters.[4] NPS standardization facilitates global trade and engineering design by prioritizing OD consistency for fittings and connections over precise ID measurements.[1]Overview
Definition and Purpose
Nominal Pipe Size (NPS) is a North American standard for designating pipe sizes used in applications involving high or low pressures and temperatures.[2] It provides a dimensionless identifier that applies to pipes, fittings, flanges, and valves, ensuring compatibility across various piping systems.[1] The primary purpose of NPS is to establish a consistent nomenclature that facilitates design, manufacturing, and procurement in industries such as oil and gas, water supply, and chemical processing.[2] By standardizing size designations, NPS enables interoperability of components from different manufacturers, reducing errors in system assembly and maintenance. The term "nominal" in NPS indicates an approximate or named size rather than a precise measurement, offering convenience in engineering and production without directly reflecting the pipe's actual inside or outside diameter for most sizes.[1] For instance, an NPS 2 pipe has an outside diameter of 2.375 inches, illustrating how the designation loosely relates to physical dimensions.[2] Wall thickness, specified through schedules, further influences the inside diameter but maintains the fixed outside diameter for a given NPS.[1]Historical Development
The Nominal Pipe Size (NPS) system traces its roots to the early 19th century in the United States, where iron pipe standards emerged to support the growing demands of steam engines, water distribution, and early industrial plumbing. During this period, pipe sizing was largely empirical, based on approximate inside diameters derived from manufacturing dies and common practices in foundries like Pascal Iron Works, which produced wrought iron pipes for gas and water systems. These early measurements, known as Iron Pipe Size (IPS), prioritized practical fit over precise dimensions, reflecting the limitations of hand-crafted production and the need for interchangeable components in nascent infrastructure projects.[5][6] By the late 19th and early 20th centuries, inconsistencies in pipe dimensions across manufacturers led to calls for unification, particularly as steel production advanced and piping became integral to railroads, factories, and urban utilities. The American Society of Mechanical Engineers (ASME) and other industry groups began advocating for standardized approaches, transitioning from purely arbitrary IPS values to nominal designations that approximated inside diameters while accommodating varying wall thicknesses. A pivotal milestone occurred in March 1927, when the American Standards Association (ASA, predecessor to ANSI) authorized a sectional committee to establish uniform dimensions for wrought steel and iron pipes, resulting in the tentative approval of the first ASME B36.10 standard in November 1935. This formalized NPS as a system where sizes below 12 inches denoted approximate inside diameters, and larger sizes reflected outside diameters, aligning with prevalent manufacturing norms to enhance compatibility and safety.[7] The evolution continued through the mid-20th century, with NPS refining its structure to better support industrial scalability. Post-World War II, as postwar economic expansion demanded larger-scale piping for chemical plants, power generation, and transportation, refinements emphasized consistent outside diameters for all sizes to simplify fittings and threading, moving away from the variable IPS conventions. These adjustments, incorporated into updated ASME standards, prioritized efficiency in mass production without altering the core nominal framework. The American Petroleum Institute (API) integrated NPS into its line pipe specifications through API 5L, first issued in 1928, ensuring seamless integration with broader U.S. engineering practices.[8][9]Standards and Designations
Governing Organizations and Documents
The primary organizations governing Nominal Pipe Size (NPS) standards are the American Society of Mechanical Engineers (ASME) and the American National Standards Institute (ANSI), with ASME developing the core dimensional specifications under ANSI accreditation to ensure uniformity in pipe manufacturing and application across industries.[10] Key documents establishing NPS include ASME B36.10M, which standardizes dimensions for welded and seamless wrought steel pipe suitable for high or low temperatures and pressures.[11] Another essential standard is ASME B36.19M, focusing on welded and seamless wrought stainless steel pipe dimensions for similar service conditions.[12] For line pipe applications in the oil and gas sector, API Specification 5L defines requirements for seamless and welded steel pipes, incorporating NPS designations to support pipeline transportation of hydrocarbons.[13] These standards cover NPS sizes ranging from 1/8 inch to 60 inches, specifying manufacturing tolerances to maintain consistency in pipe dimensions and performance.[11] As of 2025, the current editions—ASME B36.10-2022, ASME B36.19-2022, and API 5L (46th edition, 2018 with errata)—remain consistent with prior revisions from 2015 and 2004, with no major structural changes to NPS frameworks, though minor technical updates address material and testing refinements.[14][15][13] The American Society for Testing and Materials (ASTM) complements these by providing material specifications integrated with NPS, such as ASTM A53/A53M for seamless and welded black and hot-dipped galvanized steel pipe, ensuring compatibility with ASME dimensional standards in structural and pressure applications.Size Ranges and Nomenclature
The Nominal Pipe Size (NPS) nomenclature provides a standardized, dimensionless designation for identifying pipe sizes in North American piping systems, where the numerical value implies inches without requiring explicit units. For smaller sizes ranging from NPS 1/8 to NPS 12, the designation typically uses fractions such as 1/8, 1/4, 3/8, 1/2, 3/4, 1, 1¼, 1½, 2, 2½, 3, 3½, 4, 5, 6, 8, 10, and 12 to facilitate precise identification in common applications.[1] Beyond NPS 12, the nomenclature shifts to whole numbers starting at NPS 14, continuing in increments like 16, 18, 20, and so on, reflecting a simplified labeling for larger diameters.[16] This system, outlined in standards such as ASME B36.10M, ensures consistency across manufacturing and usage without tying the label directly to physical measurements.[17] NPS sizes are categorized into ranges based on typical usage contexts, with smaller designations from NPS 1/8 to NPS 12 commonly applied in general plumbing, instrumentation, and low-flow systems where compact piping is essential.[1] In contrast, larger sizes from NPS 14 upward are predominantly used for industrial transport lines, such as in oil, gas, and water conveyance, accommodating higher volumes and pressures in extensive infrastructure.[18] The standard maximum NPS covered in ASME B36.10M extends to 60 inches, beyond which custom specifications may apply for specialized large-scale projects.[17] Special notations within the NPS framework distinguish pipe end configurations, such as threaded ends (often using NPT threading for smaller sizes) versus plain ends (suitable for welding or grooving), while the nominal size remains consistent regardless of end type.[18] Similarly, NPS applies to associated components like fittings, flanges, and valves through matching nominal sizes, ensuring compatibility in assembly—for instance, a valve designated NPS 4 connects seamlessly with corresponding pipe and fitting elements.[1] Although the NPS itself is a dimensionless identifier, it is inherently linked to inch-based measurements in design and fabrication processes, distinguishing it from metric systems like DN.[16]Pipe Dimensions
Outside Diameter Specifications
The outside diameter (OD) serves as the primary fixed dimension in the Nominal Pipe Size (NPS) system, remaining constant for each designated size regardless of wall thickness variations. This standardization is defined in ASME B36.10M-2022, which establishes nominal OD values for wrought steel pipes used in various applications. For instance, NPS 1/2 pipe has an OD of 0.840 inches (21.3 mm), while NPS 6 pipe has an OD of 6.625 inches (168.3 mm).[19][11] Tolerances on the OD ensure manufacturing precision and interchangeability, with ASME B36.10M-2022 referencing material specifications such as ASTM A53 and A106 for detailed limits. For NPS 1/8 to 1½, the OD tolerance is ±1/64 inch (±0.4 mm); for NPS 2 to 4, ±1/32 inch (±0.79 mm); for NPS 5 to 8, +1/16 inch (+1.6 mm) and -1/32 inch (-0.79 mm); for NPS >8 to 18, +3/32 inch (+2.4 mm) and -1/32 inch (-0.79 mm); and for even larger sizes, the over tolerance increases further while the under tolerance remains -1/32 inch (-0.79 mm). These tolerances apply at any point around the pipe circumference, with no upper limit specified for wall thickness but strict conformance required for OD to maintain system integrity.[20][21][22][11] The rationale for standardizing the OD lies in ensuring compatibility with pipe fittings, flanges, and welding components across piping systems, facilitating seamless assembly and maintenance. Historically, these OD values originated from early 20th-century manufacturing practices, where tooling and rolling mills were designed around fixed external dimensions to achieve consistent production efficiency.[11] Both seamless and welded pipes adhere to the same OD specifications under ASME B36.10M-2022, with no dimensional differences in external diameter between the two manufacturing methods, though individual material standards may impose additional requirements on weld quality or forming processes.[19]Wall Thickness and Schedules
The schedule system for nominal pipe sizes designates varying levels of wall thickness to accommodate different pressure requirements and structural demands in piping applications. Schedules such as SCH 10, SCH 20, SCH 30, SCH 40 (also known as Standard or STD), SCH 60, SCH 80 (Extra Strong or XS), SCH 100, SCH 120, SCH 140, SCH 160, and Double Extra Strong (XXS) provide standardized options, with higher numbers indicating thicker walls for the same nominal size. For example, a NPS 2 pipe with SCH 40 has a wall thickness of 0.154 inches, enabling it to handle moderate pressures while maintaining compatibility with fittings.[19][23] These schedules are primarily defined in ASME B36.10M-2022 for welded and seamless wrought steel pipe, categorizing them into light wall options like STD/SCH 40 for general use, heavy walls like SCH 80 for elevated pressures, and extra heavy like SCH 160 or XXS for severe conditions. For stainless steel pipes, ASME B36.19M employs a similar schedule nomenclature but with adjustments for metric alignment and corrosion resistance, such as SCH 5S, 10S, 40S, and 80S, ensuring dimensional consistency across materials. The wall thickness directly influences the pipe's pressure-handling capability, where thicker schedules resist higher internal pressures by increasing the hoop stress capacity; the minimum required thickness t is calculated using the formula from ASME B31.3: t = \frac{P D}{2 (S E + P Y)} Here, P is the internal design pressure, D is the outside diameter, S is the allowable stress of the material, E is the joint efficiency (typically 1.0 for seamless pipes), and Y is a wall thickness coefficient (e.g., 0.4 for ferritic steels at temperatures up to 900°F or 0.5 for austenitic stainless steels). This equation derives from the thin-wall approximation of Lame's theory for cylindrical pressure vessels, adjusted for piping codes to account for material behavior and safety factors, ensuring the pipe withstands hoop stress without yielding.[24][25][26] Pipe weight, which impacts handling and support design, can be estimated from wall thickness using the formula for steel pipes: weight per foot w = 10.68 (D - t) t in pounds, where D is the outside diameter and t is the wall thickness, both in inches; this accounts for the cross-sectional area of steel assuming a density of approximately 0.283 lb/in³. Thicker schedules thus increase weight proportionally, for instance, elevating costs and requiring stronger supports in installations.[27][28]Inside Diameter and Flow Capacity
The inside diameter (ID) of a pipe conforming to Nominal Pipe Size (NPS) standards is determined by subtracting twice the wall thickness (t) from the outside diameter (OD), yielding the formula ID = OD - 2t.[19] This ID varies with the selected schedule, which specifies the wall thickness for a given NPS; for instance, an NPS 4 Schedule 40 pipe has an ID of approximately 4.026 inches.[29] Flow capacity in NPS pipes depends fundamentally on the ID, as it defines the cross-sectional area (A) available for fluid passage, calculated asA = \pi \left( \frac{\text{ID}}{2} \right)^2.
The resulting flow velocity (v) for a given volumetric flow rate (Q) follows from
v = \frac{Q}{A}.
These relationships underpin the assessment of throughput in piping systems. The ID also acts as the hydraulic diameter in circular pipes, serving as a key parameter for evaluating friction losses via the Darcy-Weisbach equation, which quantifies pressure drop without deriving the full formula here.[30] This hydraulic role is vital for optimizing system design, including pump selection to match required flow rates and minimizing energy losses for efficiency.[31] Notably, the ID does not match the nominal size exactly, leading to discrepancies in expected versus actual dimensions that must be accounted for in engineering calculations.[29] Furthermore, while the ID governs flow in straight sections, overall system capacity is reduced by fittings, valves, and bends that introduce additional resistance.[32]
Comparisons with International Standards
Nominal Diameter (DN) Equivalents
The Nominal Diameter (DN), as defined by the International Organization for Standardization (ISO) in ISO 6708:1995, is an alphanumeric designation of size for components of a pipework system, comprising the letters "DN" followed by a dimensionless number that serves as a reference for ordering and compatibility, without directly corresponding to any specific physical dimension such as inside or outside diameter.[33] This metric system contrasts with the inch-based Nominal Pipe Size (NPS) primarily used in North America, providing a standardized equivalent for international interoperability in piping systems.[1] Direct mappings between NPS and DN exist through established conversion tables, where equivalents are approximate due to historical and dimensional differences between the systems; for instance, NPS ½ corresponds to DN 15, NPS 2 to DN 50, and NPS 12 to DN 300.[34] The following representative table illustrates common small to medium equivalents:| NPS (inches) | DN (mm) |
|---|---|
| ½ | 15 |
| 1 | 25 |
| 2 | 50 |
| 4 | 100 |
| 6 | 150 |
| 12 | 300 |
Other Global Systems
The British Standard Pipe (BSP) system employs inch-based nominal sizing akin to NPS but features distinct Whitworth threading with a 55-degree angle, contrasting with the 60-degree angle in NPS threads like NPT, rendering them non-interchangeable without adapters.[36] Pipe dimensions under BSP align closely with NPS for outer diameter (OD) and inner diameter (ID) based on schedule, facilitating some compatibility in pipe bodies; for instance, a 1/2-inch BSP pipe has an OD of 21.3 mm, matching that of NPS 1/2-inch pipe. However, variations in thread engagement and sealing can affect joint integrity, particularly in high-pressure applications. Japanese Industrial Standards (JIS), such as JIS G 3452 for carbon steel pipes used in low-pressure conveyance of fluids like water and gas, incorporate hybrid nomenclature with "A" sizes approximating metric DN values and "B" sizes mirroring NPS inch designations.[37] For example, 15A in JIS G 3452 corresponds roughly to NPS 1/2 inch, with an OD of 21.7 mm suitable for plumbing and general piping.[38] This dual approach accommodates both imperial legacies and metric adoption in Japan's manufacturing sector. A core philosophical divergence lies in how these systems define nominal size: NPS prioritizes OD for standardization in manufacturing and fitting interfaces—exactly equaling OD in inches for sizes NPS 14 and above—while British and other non-ISO European systems, using Nominal Bore (NB), emphasize approximate ID to optimize flow capacity calculations.[39] This OD-centric NPS methodology supports efficient production of large-diameter pipes, whereas ID-focused NB aids hydraulic design but complicates direct substitutions. Such discrepancies pose challenges in global supply chains, where mismatched threads or dimensions can lead to compatibility issues, increased costs for adapters, and potential flow inefficiencies.[40] Efforts toward harmonization include dual-certification under international standards like API 5L for line pipes, which specifies dimensions using both NPS (from 2 inches) and metric OD equivalents up to 36 inches, enabling pipes to meet requirements across imperial and metric markets.[41] This approach, detailed in API 5L's PSL1 and PSL2 levels, promotes interoperability in oil and gas pipelines without altering core sizing philosophies.[42]Applications in Industry
Usage in Piping Systems
Nominal Pipe Size (NPS) plays a central role in piping systems by standardizing component dimensions to ensure seamless interoperability among pipes, valves, flanges, and fittings. This uniformity allows engineers to select compatible elements without custom fabrication, such as choosing an NPS 4 pipe for process lines in refineries where valves and flanges must align precisely with the pipe's outside diameter. By adhering to NPS designations, systems achieve reliable connections that support fluid transport across various configurations.[1][43] In piping design, NPS facilitates sizing based on flow requirements, where the nominal size guides the selection of pipe diameters to accommodate desired velocities and volumes while matching ancillary components like elbows and reducers. For instance, designers evaluate NPS options to optimize layouts, favoring longer straight runs to minimize pressure losses from bends and reduce overall system complexity. This approach integrates NPS with established outside diameter specifications to maintain consistent flow paths in industrial setups.[1][44][45] Installation practices rely on NPS to dictate precise procedures, such as preparing pipe ends with bevels matching the nominal outside diameter for butt welding, ensuring strong joints in assembled systems. NPS is prevalent in sectors like HVAC for ductless ventilation lines, plumbing for water distribution, and process industries for chemical conveyance, where standardized sizing streamlines on-site assembly. These practices promote efficient fieldwork by aligning all elements to the same nominal framework.[46][47] The adoption of NPS offers key advantages in North American piping systems, including simplified inventory management through interchangeable parts and straightforward specifications that reduce procurement errors. This standardization enhances project efficiency by enabling rapid sourcing of off-the-shelf components tailored to common nominal sizes.[48][49]Material and Pressure Considerations
Nominal Pipe Size (NPS) standards are applied across various pipe materials, including carbon steel, stainless steel, polyvinyl chloride (PVC), and copper, with specifications tailored to each material's properties for compatibility in piping systems. For carbon steel pipes suitable for high-temperature service, ASTM A106 covers seamless pipes in NPS sizes from 1/8 inch to 48 inches, ensuring uniformity in dimensions regardless of material grade. Stainless steel pipes, such as those under ASTM A312, follow the same NPS nomenclature for seamless and welded constructions, while PVC pipes adhere to similar schedule-based wall thicknesses under standards like ASTM D1785, though their pressure capacities are lower due to material limitations. Copper tubing, often sized by Copper Tube Size (CTS), can be cross-referenced to NPS equivalents for integration in hybrid systems, but NPS primarily governs ferrous and thermoplastic pipes.[50][51][1][52] Pressure ratings for NPS pipes are determined by the combination of schedule (wall thickness) and material strength, ensuring the pipe can withstand internal pressures without exceeding allowable stress limits. The primary calculation uses Barlow's formula for hoop stress: \sigma = \frac{P \cdot D}{2 \cdot t} where \sigma is the hoop stress, P is the internal pressure, D is the outside diameter, and t is the wall thickness; \sigma must remain below the material's yield strength, typically limited to one-third of the tensile strength or two-thirds of the yield strength per code requirements. This formula derives from thin-walled cylinder theory and is applied in standards like ASME B31.3 for process piping to compute maximum allowable working pressure (MAWP). For a given NPS and schedule, higher-strength materials like stainless steel allow greater pressures than carbon steel at equivalent thicknesses.[53][54] Key factors influencing pressure ratings include temperature derating and corrosion allowances, which adjust the effective wall thickness and allowable stress. Under ASME B31.3, allowable stress values are reduced for temperatures above ambient, with Table A-1 providing derating factors for carbon steel; for instance, stresses decrease progressively above 800°F (427°C) to account for material softening, potentially halving the rating at elevated temperatures. Corrosion allowance adds extra thickness to t in design calculations, typically 1.5 to 3 mm for carbon steel in corrosive environments, as specified in ASME B31.3 Section 302.4, to maintain integrity over the pipe's service life without increasing the NPS designation. These adjustments ensure safe operation, with derating applied multiplicatively to base pressure ratings.[54][55][24] For example, an NPS 8 Schedule 80 carbon steel pipe (ASTM A106 Grade B, outside diameter 8.625 inches, wall thickness 0.500 inches) has a pressure rating of approximately 2,300 psi at ambient temperature based on an allowable stress of 20 ksi, calculated via Barlow's formula. However, for stainless steel alloys like Type 304 under similar conditions, the rating may derate by approximately 15% at 800°F due to lower elevated-temperature strength, while PVC equivalents in the same NPS and schedule are limited to around 200-300 psi at room temperature owing to the material's lower modulus. These examples highlight how material selection directly modulates NPS pipe performance under pressure.[56][57][54]Testing Methods
Blockage or Ball Test Procedure
The blockage or ball test procedure, also known as the drift test, serves to verify that manufactured pipes maintain a minimum internal diameter while ensuring no obstructions or significant deformities impede flow or tool passage. This method confirms dimensional compliance essential for operational integrity, particularly in ensuring pipes can accommodate pigs, scrapers, or other internal devices without restriction.[58] In the procedure, a spherical ball or cylindrical mandrel sized to the specified minimum internal diameter is inserted and passed through the full length of the pipe, which must be properly supported to avoid sagging and cleared of any foreign matter. The test piece passes if the ball or mandrel travels end-to-end with reasonable force applied, indicating the internal diameter meets or exceeds the minimum requirement; for instance, in a NPS 2 pipe with wall thickness up to 3.91 mm, the minimum drift diameter is 52.5 mm (equivalent to 2.067 inches). This full-length assessment applies to pipe segments typically up to 12.2 m (40 feet), as per standard manufacturing lengths for line pipe.[58] The test is detailed in API Specification 5L for line pipe, including tables defining minimum drift diameters by nominal pipe size (NPS) and wall thickness (e.g., Table 11 for full-length tests and Table 18 for ball sizes at pipe ends). Comparable requirements appear in ASTM standards for steel pipes, such as those governing dimensional tolerances and internal inspections. The procedure is optional unless specified by the purchaser but is routinely required for product-level 2 (PSL 2) certification.[58] While effective at identifying major blockages, dents, or reductions in internal diameter, the test has limitations in detecting minor ovality or elliptical distortions, as the ball may still pass through narrowed sections exceeding the minimum diameter. It is predominantly used in the manufacturing of oil and gas line pipes to uphold quality assurance during production.[58]Dimension Verification Techniques
Dimension verification techniques for Nominal Pipe Size (NPS) pipes ensure compliance with specified outside diameters (OD), wall thicknesses, and other geometric parameters as defined in standards like ASME B36.10M. These methods are essential in manufacturing and quality assurance to confirm that pipes meet tolerances, preventing issues in assembly and performance. Verification typically involves a combination of direct contact measurements for smaller diameters and advanced non-destructive techniques for larger or installed pipes, with checks performed at multiple points along the pipe length to account for variations. For pipes under 6 inches NPS, outside diameter and wall thickness are commonly measured using precision calipers or micrometers, which provide accurate contact-based readings to within 0.001 inches. These tools are applied at several circumferential points to detect any deviations, ensuring the OD remains within tolerances such as +1/64 in. (0.40 mm) / −1/32 in. (0.79 mm) for NPS 1/8 to 1½, and wall thickness meets the minimum -12.5% allowance from nominal values. Full-length verification, including straightness and end-to-end dimensions, follows ASME B36.10M guidelines, where length tolerances are typically +1/4 inch with no minus allowance for standard lengths.[59][60] Ultrasonic thickness gauging is a widely adopted non-destructive method for assessing wall thickness, particularly useful for both new and in-service pipes where access to the interior is limited. This technique employs pulse-echo principles to measure the time-of-flight of sound waves through the material, converting it to thickness with an accuracy of ±0.001 inches, as outlined in ASTM E797. It is especially effective for verifying minimum wall thickness compliance (-12.5% tolerance) without surface preparation beyond basic cleaning, and multiple readings are taken longitudinally and circumferentially for representative sampling.[61] For larger NPS pipes (above 6 inches), where manual contact methods become impractical, laser scanning systems are employed to measure internal diameter (ID), ovality, and overall geometry non-destructively. These systems use multiple laser line sensors to generate a 360-degree profile, detecting ovality (deviation from circularity) to within 0.1% of diameter and confirming ID alignment with calculated values from OD and wall thickness per ASME B36.10M. Such scanning is particularly valuable for assessing large-diameter pipes during fabrication or inspection, ensuring tolerances like OD +1% / −0.75% for NPS 8 and larger are met across the full length.[62][63][64] Non-destructive methods like eddy current testing complement dimensional verification by identifying surface and near-surface defects that could impact effective dimensions, such as pitting or thinning, in accordance with ASTM E426. While not a direct sizing tool, it flags anomalies affecting wall integrity, with scans covering 100% of the surface for critical applications. Hydrostatic testing, though primarily for pressure integrity, indirectly supports dimensional stability by confirming no leaks from manufacturing variations but does not measure size directly. Quality control in pipe production involves statistical sampling for dimension checks, often following ANSI/ASQ Z1.4 guidelines, where a representative sample—such as 10% of a production lot for normal inspection levels—is selected for full verification. Pipes passing these checks receive certification of compliance with ASME B36.10M, including mill test reports documenting measured OD, wall thickness, and tolerances. This process ensures traceability and reliability in industrial applications.[65]Reference Tables
Small Diameter Pipes (NPS 1/8 to 3½)
Small diameter pipes, ranging from NPS 1/8 to 3½, are essential for applications involving low-flow rates, instrumentation, and auxiliary piping systems where precision and compactness are prioritized over high-volume transport. These sizes are particularly suited for utility lines, hydraulic systems, and process control in industries like chemical processing and oil and gas, offering ease of installation and compatibility with smaller fittings.[1] Fractional NPS designations apply to the smallest sizes, such as NPS 1/8 with an outside diameter of 0.405 inches, facilitating fine-tuned flow control. Stainless steel versions adhere to ASME B36.19M standards and incorporate "S" suffixes for schedules like 5S and 10S, which provide thinner walls for corrosion resistance in demanding environments compared to the thicker carbon steel options in ASME B36.10M.[23][19] The table below details the outside diameter, nominal wall thickness, and weight per foot for common schedules in these sizes, based on ASME standards. Higher schedules (e.g., 60, 120, 140) are less common for diameters below NPS 2 and are marked as N/A where not typically specified; weights assume carbon steel density, with minor variations for stainless. Representative examples include NPS ½ with SCH 40 wall thickness of 0.109 inches and weight of 0.85 lb/ft, and NPS 3 with SCH 80 wall thickness of 0.300 inches and weight of 7.58 lb/ft.[19][17]| NPS | OD (in) | SCH 5/5S t (in) / wt (lb/ft) | SCH 10/10S t (in) / wt (lb/ft) | SCH 20 t (in) / wt (lb/ft) | SCH 30 t (in) / wt (lb/ft) | SCH 40/STD t (in) / wt (lb/ft) | SCH 60 t (in) / wt (lb/ft) | SCH 80/XS t (in) / wt (lb/ft) | SCH 120 t (in) / wt (lb/ft) | SCH 140 t (in) / wt (lb/ft) | SCH 160/XXS t (in) / wt (lb/ft) |
|---|---|---|---|---|---|---|---|---|---|---|---|
| 1/8 | 0.405 | N/A / N/A | 0.049 / 0.19 | N/A / N/A | N/A / N/A | 0.068 / 0.24 | N/A / N/A | 0.095 / 0.31 | N/A / N/A | N/A / N/A | N/A / N/A |
| 1/4 | 0.540 | N/A / N/A | 0.065 / 0.33 | N/A / N/A | N/A / N/A | 0.088 / 0.42 | N/A / N/A | 0.119 / 0.54 | N/A / N/A | N/A / N/A | N/A / N/A |
| 3/8 | 0.675 | N/A / N/A | 0.065 / 0.42 | N/A / N/A | N/A / N/A | 0.091 / 0.57 | N/A / N/A | 0.126 / 0.74 | N/A / N/A | N/A / N/A | N/A / N/A |
| 1/2 | 0.840 | 0.065 / 0.54 | 0.083 / 0.67 | 0.109 / 0.85 | N/A / N/A | 0.109 / 0.85 | N/A / N/A | 0.147 / 1.09 | N/A / N/A | N/A / N/A | 0.294 / 1.71 |
| 3/4 | 1.050 | 0.065 / 0.69 | 0.083 / 0.86 | 0.113 / 1.13 | N/A / N/A | 0.113 / 1.13 | N/A / N/A | 0.154 / 1.47 | N/A / N/A | N/A / N/A | 0.308 / 2.44 |
| 1 | 1.315 | 0.065 / 0.87 | 0.109 / 1.40 | 0.133 / 1.68 | 0.150 / 1.84 | 0.133 / 1.68 | N/A / N/A | 0.179 / 2.17 | N/A / N/A | N/A / N/A | 0.358 / 3.66 |
| 1¼ | 1.660 | 0.065 / 1.11 | 0.109 / 1.81 | 0.140 / 2.27 | 0.156 / 2.55 | 0.140 / 2.27 | N/A / N/A | 0.191 / 3.00 | N/A / N/A | N/A / N/A | 0.382 / 5.21 |
| 1½ | 1.900 | 0.065 / 1.28 | 0.109 / 2.09 | 0.145 / 2.72 | 0.166 / 3.14 | 0.145 / 2.72 | N/A / N/A | 0.200 / 3.63 | N/A / N/A | N/A / N/A | 0.400 / 6.41 |
| 2 | 2.375 | 0.065 / 1.61 | 0.109 / 2.64 | 0.154 / 3.65 | 0.172 / 4.07 | 0.154 / 3.65 | 0.188 / 4.37 | 0.218 / 5.02 | N/A / N/A | N/A / N/A | 0.436 / 9.03 |
| 2½ | 2.875 | 0.083 / 2.48 | 0.120 / 3.53 | 0.203 / 5.79 | 0.227 / 6.48 | 0.203 / 5.79 | 0.249 / 7.13 | 0.276 / 7.66 | 0.344 / 9.11 | N/A / N/A | 0.552 / 13.69 |
| 3 | 3.500 | 0.083 / 3.03 | 0.120 / 4.33 | 0.216 / 7.58 | 0.241 / 8.47 | 0.216 / 7.58 | 0.281 / 9.65 | 0.300 / 10.25 | 0.438 / 14.33 | N/A / N/A | 0.600 / 18.58 |
| 3½ | 4.000 | 0.083 / 3.48 | 0.120 / 4.97 | 0.226 / 9.11 | 0.277 / 11.0 | 0.226 / 9.11 | 0.308 / 12.2 | 0.318 / 12.50 | N/A / N/A | N/A / N/A | 0.636 / 22.85 |
Medium Diameter Pipes (NPS 4 to 12)
Medium diameter pipes under Nominal Pipe Size (NPS) 4 to 12 serve as transitional sizes in industrial piping systems, accommodating higher volume flows compared to smaller diameters while remaining manageable for installation and maintenance. These sizes mark a shift from fractional to whole-inch nominal designations, with outside diameters standardized slightly larger than the nominal value to ensure compatibility with fittings and valves across the NPS system.[35] The increased weights of these pipes—ranging from approximately 10.79 lb/ft for NPS 4 Schedule 40 to 53.52 lb/ft for NPS 12 Schedule 40—require adherence to support spacing guidelines to limit deflection under load. According to ASME B31.1, recommended maximum spans for horizontal Schedule 40 steel pipes in water service are 14 ft for NPS 4, 17 ft for NPS 6, 19 ft for NPS 8, and 23 ft for NPS 12, with longer spans permissible for lighter fluids like air or gas.[66] In chemical processing plants, NPS 4 to 12 pipes are frequently employed for moderate flow rates of corrosive liquids, gases, and slurries, balancing capacity needs with corrosion resistance and pressure containment.[67] Stainless steel versions of these pipes often utilize Schedule 10S for lighter-duty applications, featuring a wall thickness of 0.120 inches for NPS 4 to better align with international metric equivalents and facilitate exports.[23] The following table presents representative dimensions and weights for carbon steel pipes in Schedules 40 and 80, per ASME B36.10M. Outside diameters are in inches, wall thicknesses (t) in inches, and weights in lb/ft.| NPS (in) | OD (in) | SCH 40 t (in) | SCH 40 wt (lb/ft) | SCH 80 t (in) | SCH 80 wt (lb/ft) |
|---|---|---|---|---|---|
| 4 | 4.500 | 0.237 | 10.79 | 0.337 | 14.98 |
| 5 | 5.563 | 0.375 | 14.62 | 0.500 | 20.80 |
| 6 | 6.625 | 0.280 | 18.97 | 0.432 | 28.57 |
| 8 | 8.625 | 0.322 | 28.55 | 0.500 | 43.39 |
| 10 | 10.750 | 0.365 | 40.48 | 0.593 | 64.43 |
| 12 | 12.750 | 0.406 | 53.52 | 0.687 | 88.51 |
Large Diameter Pipes (NPS 14 to 24)
Large diameter pipes in the NPS 14 to 24 range represent a significant scale up from smaller sizes, enabling high-volume fluid transport in applications like oil and gas pipelines and industrial process lines, where the larger bore diameters support greater flow capacities while maintaining structural integrity under high pressures. These pipes are standardized by the ASME B36.10M, with outside diameters exactly matching the NPS designation in inches, and wall thicknesses defined by schedule numbers to balance strength, weight, and cost. Welded construction with longitudinal or spiral seams is common for economy in production, as seamless manufacturing becomes more expensive at this scale, though both types must meet the same dimensional and tolerance requirements.[19] Tolerances for these sizes emphasize precision to ensure fit-up and performance in long-distance transport systems. For outside diameter, the tolerance is ±0.5% for seamless pipes and ±1% (maximum deviation 0.01 in) for welded pipes in NPS 14 to 18, increasing to ±0.75% / -0.50% for NPS 20 to 24 to account for manufacturing challenges at larger scales. Wall thickness tolerances are -12.5% for thicknesses ≤0.188 in and ±12.5% for thicker walls, with no allowance for positive deviation in the negative direction beyond specified limits to prevent under-strength pipes. Unlike smaller diameters, these sizes do not use fractional schedules (e.g., Sch 5S or 10S), focusing instead on integer schedules optimized for line pipe use in oil and gas sectors, where economy and durability are paramount.[19] The following table summarizes the outside diameter (OD), wall thickness (t in inches), and plain-end weight (lb/ft) for key schedules (STD, XS, 80, 120, 140, 160) across NPS 14 to 24, based on the ASME B36.10M 2022 edition. Weights are calculated using the standard formula for carbon steel pipe density, Wt = 10.68 × t × (OD - t). Note: For NPS 14 and larger, STD is 0.375 in up to certain sizes; Sch 40 is thicker. Values assume carbon steel; consult full standard for stainless or alloys. Representative examples include NPS 14 STD with t = 0.375 in and weight 54.57 lb/ft, and NPS 24 XS with t = 0.500 in and weight 125.49 lb/ft, illustrating the range from standard wall to heavy-duty configurations.[70][71]| NPS | OD (in) | STD t (in) / weight (lb/ft) | XS t (in) / weight (lb/ft) | Sch 80 t (in) / weight (lb/ft) | Sch 120 t (in) / weight (lb/ft) | Sch 140 t (in) / weight (lb/ft) | Sch 160 t (in) / weight (lb/ft) |
|---|---|---|---|---|---|---|---|
| 14 | 14.000 | 0.375 / 54.57 | 0.500 / 72.09 | 0.750 / 106.13 | 1.094 / 150.93 | 1.250 / 170.37 | 1.406 / 189.29 |
| 16 | 16.000 | 0.375 / 62.58 | 0.500 / 82.77 | 0.750 / 121.93 | 1.219 / 190.47 | 1.406 / 215.29 | 1.593 / 238.04 |
| 18 | 18.000 | 0.375 / 70.59 | 0.500 / 93.37 | 0.938 / 162.45 | 1.500 / 255.81 | 1.719 / 287.34 | 1.938 / 318.66 |
| 20 | 20.000 | 0.375 / 78.60 | 0.500 / 104.00 | 1.000 / 204.37 | 1.531 / 306.66 | 1.750 / 345.00 | 1.969 / 382.00 |
| 22 | 22.000 | 0.375 / 86.61 | 0.500 / 114.62 | 1.000 / 228.66 | 1.656 / 370.00 | 1.875 / 414.00 | 2.125 / 463.00 |
| 24 | 24.000 | 0.375 / 94.62 | 0.500 / 125.49 | 1.219 / 296.86 | 1.812 / 429.79 | 2.062 / 483.57 | 2.344 / 542.64 |
Extra-Large Diameter Pipes (NPS 26 and above)
Extra-large diameter pipes, designated as NPS 26 and above, are utilized in high-volume fluid transportation systems, including long-distance pipelines for oil, gas, and water, as well as structural applications in major infrastructure projects. For these sizes, the outside diameter equals the NPS value in inches, distinguishing them from smaller diameters where OD exceeds NPS. Wall thicknesses are specified through schedules to balance structural integrity, pressure capacity, and material efficiency, with common options limited to higher designations due to the scale of these pipes. Dimensions conform to ASME B36.10M standards, while API 5L provides specifications for line pipe applications in energy sectors. The table below presents representative dimensions for key extra-large NPS sizes, focusing on selected schedules (30, 40, STD, 60, 80, 100, 120, 140, 160 where applicable). Wall thicknesses and weights are based on standard carbon steel pipe data, with weights calculated using the formula Wt = 10.68 × (OD - t) × t lb/ft for plain-end pipe. These examples illustrate typical configurations; actual values may vary slightly by manufacturer. Note: For sizes above NPS 24, Sch 40 thicknesses increase with NPS (e.g., NPS 26 Sch 40 t=0.719 in); consult ASME B36.10M for exact values per size.[19][72]| NPS | OD (in) | Schedule | Wall Thickness t (in) | Weight (lb/ft) |
|---|---|---|---|---|
| 26 | 26.000 | STD/30 | 0.375 | 102.65 |
| 26 | 26.000 | 40 | 0.719 | 190.00 |
| 26 | 26.000 | 60 | 0.938 | 244.00 |
| 26 | 26.000 | 80 | 1.156 | 297.00 |
| 26 | 26.000 | 120 | 1.750 | 435.00 |
| 36 | 36.000 | STD/30 | 0.500 | 189.00 |
| 36 | 36.000 | 40 | 0.813 | 295.00 |
| 36 | 36.000 | 60 | 1.000 | 359.00 |
| 36 | 36.000 | 80 | 1.250 | 444.00 |
| 36 | 36.000 | 140 | 1.938 | 667.00 |
| 48 | 48.000 | STD/30 | 0.500 | 252.00 |
| 48 | 48.000 | 40 | 1.094 | 530.00 |
| 48 | 48.000 | 60 | 1.344 | 646.00 |
| 48 | 48.000 | 80 | 1.656 | 789.00 |
| 48 | 48.000 | 120 | 2.250 | 1050.00 |
| 48 | 48.000 | 160 | 2.719 | 1250.00 |
| 60 | 60.000 | STD/30 | 0.562 | 354.00 |
| 60 | 60.000 | 40 | 1.359 | 830.00 |
| 60 | 60.000 | 60 | 1.672 | 1010.00 |
| 60 | 60.000 | 80 | 2.000 | 1190.00 |
| 60 | 60.000 | 120 | 2.844 | 1650.00 |
| 60 | 60.000 | 160 | 3.500 | 2000.00 |