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Pipe support

Pipe supports are structural components designed to bear the vertical and horizontal loads of piping systems, including the weight of pipes, fluids, insulation, and attached fittings, while accommodating thermal expansion, vibration, and dynamic forces to prevent excessive stress, sagging, or failure.^[1]^[2] In engineering applications, particularly in oil and gas, chemical, and power industries, they ensure the longevity, safety, and efficiency of pipelines by maintaining alignment, restricting unwanted movements, and distributing loads to supporting structures like beams or foundations.^[3]^[1] Pipe supports are broadly classified into rigid and flexible types, with rigid supports such as shoes, saddles, and trunnions providing fixed positioning for stable loads, while flexible options like variable or constant spring hangers allow controlled movement to handle thermal variations and vibrations without compromising structural integrity.^[1]^[3] Restraints, a subset of supports, include guides, anchors, and limit stops that direct or limit pipe displacement in axial, lateral, or vertical directions, essential for mitigating risks from seismic events, wind, or water hammer.^[1]^[2] Design considerations, guided by standards like ASME B31.3, involve calculating support spacing—typically up to 12 meters for large carbon steel pipes—to avoid sagging, selecting materials such as carbon steel or stainless steel based on environmental conditions, and integrating stress analysis to protect nozzles and equipment from overload.^[1]^[3] Key types include hanger supports, which suspend pipes from overhead structures and can incorporate springs for adjustability; clamp and U-bolt supports for securing smaller or non-insulated lines; and specialized wear pads or cardels to minimize friction during sliding.^[3] Anchors fully restrict movement to define expansion zones in long pipelines, while guides maintain alignment without impeding axial growth.^[3]^[1] Proper implementation reduces leakage risks, operational downtime, and maintenance costs, making pipe supports indispensable for compliant and reliable infrastructure in high-stakes environments.^[2]

Overview of Pipe Supports

Definition and Purpose

Pipe supports are structural elements or assemblies designed to suspend, brace, or anchor piping systems from buildings, equipment, or other structures, thereby bearing the weight of the pipes and controlling their movement. These devices transfer loads from the piping to the supporting framework, ensuring the system remains stable under various conditions. According to engineering standards, pipe supports primarily handle the weight of pipes, fittings, contents, insulation, and associated components while containing longitudinal stresses within permissible limits.^[4]^[1] The primary purpose of pipe supports is to prevent sagging, excessive deflection, vibration, and stress accumulation in piping systems, which could otherwise result in leaks, ruptures, or catastrophic failure. By maintaining proper alignment and limiting thermal expansion or contraction—such as those induced by weight and thermal forces—they safeguard the integrity of the piping network during operation. This role is critical in industrial settings where fluid transport occurs under pressure, as unsupported or inadequately supported pipes risk structural compromise.^[5]^[6] Basic components of pipe supports typically include hardware such as clamps, hangers, rods, and bases that interface directly between the pipe and the supporting structure. These elements work collectively to provide attachment points and load distribution mechanisms, allowing for secure installation without compromising the pipe's functionality.^[1]^[5] Proper implementation of pipe supports not only enhances operational safety by complying with regulations in high-risk environments but also reduces long-term maintenance costs through minimized wear and failure risks. In environments prone to dynamic loads or temperature fluctuations, well-designed supports prevent downtime and extend system lifespan, contributing to economic efficiency.^[5]^[6]

Applications in Industry

Pipe supports play a vital role in the oil and gas industry, where they ensure the structural integrity of pipelines and equipment transporting hydrocarbons under high pressures and temperatures, absorbing shocks and guiding movements to prevent failures in refineries and offshore platforms.^[7] In petrochemical facilities, these supports handle the transport of chemical products, mitigating mechanical stresses and environmental corrosion to enhance safety and operational efficiency.^[7] In power generation, pipe supports are essential for high-pressure steam lines in boiler systems and turbine setups, managing thermal expansion and cycling while adhering to standards such as ASME B31.1 for power piping.^[7] Chemical processing plants rely on them to secure lines conveying corrosive or reactive fluids, reducing risks from vibrations and ensuring system longevity in demanding environments.^[7] Water treatment facilities utilize similar supports for pipes in filtration, distribution, and wastewater systems, where they maintain alignment amid varying fluid loads and chemical exposures akin to those in chemical industries.^[8] HVAC systems in commercial and high-rise buildings employ pipe supports to accommodate thermal movements in piping risers and hydronic systems, addressing expansion and contraction challenges in vertical installations.^[9] A key example is their use in seismic bracing for earthquake-prone nuclear facilities, where longitudinal and transverse restraints prevent piping sway or rupture during seismic events, complying with the ASME Boiler and Pressure Vessel Code Section III.^[10] These supports are engineered for extreme environmental conditions, including high temperatures up to 1000°F in process plants for steam and hot fluid lines, as well as cryogenic applications down to -300°F in LNG pipelines to preserve insulation and stability.^[11] Since the 2000s, the adoption of modular pipe supports in prefabricated piping has grown significantly, particularly in industrial construction, enabling offsite assembly for improved efficiency, reduced waste, and faster project timelines in sectors like oil and gas and power generation.^[12]

Functions and Loads

Key Functions

Pipe supports serve essential operational roles in piping systems by managing the transfer of forces, controlling movements, and ensuring system integrity under various conditions. Their primary functions include supporting the weight of the piping, guiding thermal movements, anchoring against thrusts, and absorbing shocks from dynamic events, as outlined in engineering standards for process piping.^[13] The supporting function involves transferring the weight of the pipe, its contents, insulation, and any attachments to the supporting structure, thereby preventing excessive deflection and maintaining structural stability. This is critical for handling sustained loads such as the dead weight of the piping assembly.^[13]^[7] In the guiding function, supports allow controlled thermal expansion and contraction of the piping while restricting unwanted lateral or vertical movements to prevent misalignment and stress concentrations. This ensures the piping remains aligned during temperature fluctuations without compromising flexibility.^[13]^[6] The anchoring function fixes the piping at specific points to absorb and resist thrusts generated by equipment such as valves, pumps, or sudden pressure changes, providing restraint in multiple directions to maintain positional stability. Anchors are typically designed to offer six-way restraint at key locations like structural tie-ins or equipment nozzles.^[13]^[1] Shock absorption is achieved by damping vibrations and dynamic forces arising from fluid flow, machinery operation, or external events like earthquakes, thereby protecting the piping from fatigue and potential failure. This function mitigates impacts from transient loads such as water hammer or seismic activity through appropriate restraint designs.^[13]^[5] Collectively, these roles—anchoring, guiding, absorbing shock, and supporting designated loads—form the core responsibilities of pipe supports, ensuring reliable performance in industrial applications as per established piping codes.^[7]

Classification of Loads

Loads acting on piping systems are broadly classified into primary and secondary categories, with primary loads further subdivided into sustained and occasional types. Primary loads are non-self-limiting and must be resisted to maintain structural integrity, as they arise from equilibrium conditions between internal and external forces. Sustained primary loads include the deadweight of the pipe, contained fluid, and insulation, which impose constant gravitational and pressure forces during normal operation.^[14] Occasional primary loads, occurring infrequently, encompass environmental forces such as wind, snow accumulation, and seismic events, which can temporarily elevate stresses beyond sustained levels.^[14] Secondary loads, in contrast, are self-limiting and result from imposed displacements that cause temporary distortions, allowing higher allowable stresses since they diminish upon yielding. These include stresses induced by thermal expansion due to temperature variations, support settlements from foundation movements, and pressure changes leading to volumetric shifts.^[14] For instance, thermal expansion in restrained piping generates compressive or tensile forces that can lead to fatigue over cycles if not accommodated.^[14] Load combinations arise from the interaction of primary and secondary loads, where secondary effects like thermal displacements can amplify primary stresses, such as inducing bending moments up to 1.5 times those from sustained loads in flexible configurations.^[15] This interaction requires evaluating combined scenarios to prevent ratcheting or incremental collapse, with codes permitting secondary stress ranges that exceed primary limits to account for their transient nature.^[14] Several factors influence the magnitude of these loads. Pipe diameter affects both sustained deadweight and pressure-induced forces, with larger diameters increasing gravitational loads proportionally to cross-sectional area. Material density contributes to the overall weight, particularly for heavier alloys in sustained loading. Operating temperature drives secondary thermal loads via the material's expansion coefficient; for carbon steel, this is typically \alpha = 6.5 \times 10^{-6} /^\circ \mathrm{F}. Fluid dynamics, including flow velocity and transients like water hammer, can generate occasional dynamic loads that interact with primary stresses.^[16]^[17] The classification and formal recognition of secondary loads evolved through ASME B31 codes, with the stress range concept for secondary thermal expansion adopted in the 1955 edition following fatigue testing that highlighted risks in early piping designs. This framework was further refined in the 1970s with the development of ASME B31.3 for process piping, addressing failures attributed to unaccounted thermal effects in industrial applications.^[18]^[19]

Types of Pipe Supports

Rigid Supports

Rigid supports are fixed structural elements that allow no significant movement of the pipe, serving to anchor or hold piping in a precise position to ensure stability under load.^[1] These supports primarily constrain vertical, horizontal, or rotational displacements, making them essential for maintaining pipe alignment and preventing sagging or misalignment.^[3] They are designed in accordance with standards such as ASME B31.3, which specifies requirements for supporting sustained loads like pipe weight, contents, insulation, and fittings to keep longitudinal stresses within allowable limits.^[1] Subtypes of rigid supports include hangers, base supports, and welded lugs, each tailored to specific installation needs. Hangers, such as rod hangers, clevis hangers, and beam attachments, suspend pipes from overhead structures; rod and clevis types use threaded rods for vertical adjustment, while beam attachments secure pipes directly to beams via clamps or similar hardware.^[3] Base supports encompass shoes, saddles, and clamps: shoes are T-shaped or flat plates placed under the pipe to rest on a structure, often accommodating insulation; saddles feature a curved cradle (typically 90° to 120° arc) welded or bolted to distribute load evenly; and clamps encircle the pipe for secure hold on vertical or horizontal runs.^[20] Welded lugs, including trunnions or dummy supports, involve tubular members or pads directly welded to the pipe or elbow, providing robust attachment points for vertical or horizontal restraint, with trunnion lengths kept short to minimize bending stresses at welds.^[1]^[3] Rigid supports find primary applications in cold, static piping lines where thermal expansion is minimal, as well as at anchor points requiring zero displacement in all directions to control system forces.^[1] They are commonly used in pipe racks, control valve stations, pump connections, and sloping lines in industrial facilities like oil and gas processing plants, where maintaining fixed positions prevents vibration transmission and ensures operational integrity.^[20]^[3] These supports offer high load-bearing capacity and simplicity in design, making them cost-effective and widely applicable for straightforward installations without the need for complex adjustments.^[3] However, their lack of flexibility limits accommodation for thermal growth or dynamic movements, potentially leading to stress concentrations, pipe distortion, or failure if expansion forces are not properly managed elsewhere in the system.^[1] Misapplication can exacerbate issues like ovality in pipes under uneven loading. A representative example is the saddle support for horizontal pipes, which employs a curved cradle to distribute weight over a larger contact area, thereby minimizing localized stresses and pipe deformation while allowing for height variations to support insulation or sloping.^[20]^[1]

Resilient and Dynamic Supports

Resilient supports in piping systems are designed to accommodate controlled vertical movement, typically due to thermal expansion, while providing necessary load-bearing capacity. These supports incorporate spring elements that allow deflection without compromising structural integrity, contrasting with rigid supports by permitting gradual adjustments to varying loads. Variable spring hangers, a common type of resilient support, feature a coil spring whose load varies proportionally with deflection, making them suitable for systems experiencing moderate thermal growth. For instance, these hangers can handle deflections up to 3 inches in applications like steam lines, where temperature fluctuations cause pipe elongation.^[21] The spring constant for variable supports is calculated using the formula k = \frac{F}{\delta}, where F represents the applied load and \delta the resulting deflection, ensuring the support's stiffness aligns with anticipated movements.^[4] Constant spring supports, another resilient variant, maintain a nearly uniform load across a range of deflections through an integrated cam mechanism that balances the spring force against displacement. This design is essential in hot piping systems, such as those in power plants, where consistent support prevents excessive stress on sensitive equipment during operation.^[22] Dynamic supports address rapid or oscillatory forces, such as those from seismic events or machinery vibrations, by selectively restricting motion. Snubbers function as hydraulic or mechanical locks that permit slow, thermal-induced movements—typically at rates below 8 inches per minute—but rigidify during high-acceleration transients, with activation thresholds around 0.02g to absorb shocks like earthquakes or water hammer.^[23] Sway braces provide lateral seismic restraint, damping vibrations and controlling side-to-side sway in vibration-prone areas, such as near pumps or compressors, often installed in pairs to handle bidirectional forces.^[24] These supports find primary applications in industrial settings with significant dynamic influences, including steam distribution lines for thermal expansion and compressor outlets for vibrational control, enhancing system reliability under secondary loads like thermal growth.^[25] However, resilient and dynamic supports incur higher initial costs due to their complex mechanisms and require regular maintenance, such as load verification and debris clearance, to ensure functionality over time.^[26]

Design Considerations

Load Analysis and Spacing

Load analysis for pipe supports begins with identifying and categorizing the primary load types acting on the piping system, including sustained loads from weight and pressure, expansion loads due to thermal changes, and occasional loads such as wind or seismic events.^[27] These loads are typically analyzed using specialized pipe stress software like CAESAR II, which models the piping system to simulate combined operating conditions and identify stress hotspots.^[28] Stresses are limited according to ASME B31.3, with sustained loads not exceeding the basic allowable stress Sh, and occasional loads (including sustained) up to 1.33 Sh.^[29] Determining support spacing involves calculating the maximum allowable span between supports to limit deflection and stress, often using empirical formulas or tables tailored to pipe material and conditions. Key factors influencing spacing include pipe schedule (wall thickness), which affects stiffness and load-carrying capacity; insulation thickness, which adds weight and requires reduced spans to prevent sagging; and support type, where rigid supports may allow slightly longer spans compared to spring supports that accommodate dynamic movements but demand closer placement for stability.^[30] Spans are determined to limit bending stress to allowable values (e.g., Sh/4) or deflection (e.g., to 0.25 inches or span/360), with typical values for uninsulated carbon steel pipes filled with water ranging from 7 feet for 1-inch diameter to 23 feet for 12-inch diameter, as provided in standard engineering charts.^[31] In special cases, spacing is adjusted variably near anchors, valves, or fittings to control localized stresses and prevent excessive pipe movement. Friction coefficients, such as \mu = 0.3 for steel-on-steel contact, are incorporated into the analysis to account for sliding resistance during thermal expansion.^[32] For complex piping systems with irregular geometries or multiple load interactions, finite element analysis (FEA) methods are employed to provide detailed stress distributions and optimize support placement, with widespread adoption in the industry beginning in the 1980s through advancements in computational tools.^[33]

Movement and Flexibility

Piping systems must accommodate thermal expansion and contraction to prevent excessive stresses from temperature-induced displacements. The linear thermal expansion of a pipe segment is calculated using the formula \Delta L = \alpha L \Delta T, where \Delta L is the change in length, \alpha is the coefficient of thermal expansion for the pipe material, L is the original length, and \Delta T is the temperature change.^[34] Supports are positioned to facilitate this movement by incorporating flexible configurations, such as U-shaped loops or expansion joints, which absorb the growth while directing it away from rigid connections and equipment.^[34] Flexibility analysis evaluates whether the system can handle these displacements without overstressing the pipe. The expansion stress range must be limited to ensure it remains below the allowable value, as defined in ASME B31.3: S_A = f (1.25 S_c + 0.25 S_h), where S_A is the allowable displacement stress range, f is the stress range reduction factor based on the number of thermal cycles, S_c is the basic allowable stress at the cold (installation) temperature, and S_h is the basic allowable stress at the hot (operating) temperature.^[35] This criterion helps verify that the combined effects of bending, torsion, and axial forces from movement do not exceed fatigue limits, often requiring computational modeling for complex routings. Effective support strategies include guides, which permit axial thermal movement while restraining lateral and vertical shifts to maintain alignment; limit stops, which allow controlled displacement up to a predefined gap before engaging to prevent excessive over-travel; and adjustments for cold and hot positions, such as preloading variable spring supports to their operating (hot) load at installation to minimize cycling effects.^[1] For dynamic movements like seismic events, energy-absorbing braces, such as wire rope assemblies or dampers, are employed to dissipate vibrational energy and accommodate displacements, with designs rated against site-specific spectral acceleration values to limit pipe deflections to safe thresholds (e.g., under 2 inches for moderate accelerations).^[24]^[36] A common issue arises from over-constraint, where excessive restraints during installation generate unintended "cold pull" forces, introducing residual stresses that amplify thermal loads and potentially lead to fatigue or deformation upon heating.^[37] Resilient supports, like springs, can briefly reference allowance for such movements in constrained setups.

Materials and Construction

Selection of Materials

The selection of materials for pipe supports is primarily driven by the need to withstand anticipated loads while ensuring durability under specific environmental conditions, such as temperature extremes and exposure to corrosive elements.^[5] Key criteria include temperature rating, corrosion resistance, and load-bearing capacity, with material choices tailored to prevent failure in applications ranging from industrial plants to outdoor installations.^[38] Carbon steel, particularly ASTM A36 grade, is commonly used for general-purpose pipe supports due to its cost-effectiveness and structural reliability in moderate conditions.^[39] It offers a minimum yield strength of 36 ksi, suitable for supporting typical piping loads up to 650°F.^[40] For environments requiring enhanced corrosion resistance, such as chemical processing plants, stainless steels like 304 and 316 are preferred; 304 provides good general resistance, while 316, with added molybdenum, excels against chlorides and acids.^[41] Galvanized steel, featuring a zinc coating on carbon steel, is standard for outdoor exposures to protect against atmospheric corrosion.^[42] Temperature ratings guide material choices, with carbon steels limited to around 650°F before strength degradation, necessitating alloy steels like chromium-molybdenum grades for applications exceeding 800°F to maintain integrity under thermal stress.^[43] Corrosion potential influences selections, such as opting for stainless steels or applying epoxy coatings in wet or humid settings to mitigate degradation.^[44] Load-bearing strength is evaluated via yield metrics, ensuring supports exceed 36 ksi for structural steel to handle dead, live, and dynamic loads without deformation.^[45] Material compatibility with the supported pipe is essential to avoid galvanic corrosion, where dissimilar metals like carbon steel and stainless steel in contact with an electrolyte can accelerate degradation; isolation barriers are often employed to prevent this.^[46] Weight considerations are critical for overhead hangers, favoring lighter options to reduce installation stress and long-term deflection.^[47] Since the 2010s, there has been a shift toward composite materials like fiber-reinforced polymers (FRP) for pipe supports, particularly in offshore applications, due to their lightweight nature, non-conductive properties, and inherent corrosion resistance, which reduce maintenance needs and structural loads.^[48]

Fabrication and Corrosion Protection

Pipe supports are fabricated using methods tailored to their structural requirements and material properties, ensuring durability under load and environmental exposure. Common techniques include welding for attaching components such as hanger rods and brackets, where fillet welds are employed in accordance with AWS D1.1/D1.1M standards for structural steel welding, which specify procedures for qualification, preheat, and post-weld heat treatment to prevent defects. Forging is utilized for custom clamps and eye nuts, producing components like forged steel clevises (Type 14 per MSS SP-58) with enhanced strength through controlled deformation, ensuring the metal area exceeds 1.25 times the rod area for load-bearing integrity. Prefabrication of spring assemblies involves cutting, forming, threading, and welding in controlled shop environments, allowing for precise assembly of variable or constant support units before site delivery, as outlined in MSS SP-58 Section 12. Corrosion protection is essential for extending the service life of pipe supports, particularly in harsh industrial settings. Hot-dip galvanizing, per ASTM A123/A123M, applies a zinc coating to carbon steel components after fabrication, forming alloy layers that provide both barrier and cathodic protection; typical minimum thicknesses range from 1.8 to 3.9 mils (45-100 μm) depending on steel thickness and shape, offering decades of durability in atmospheric exposure. For milder environments, painting with alkyd-based primers on mild steel creates a moisture-resistant barrier, often applied in multiple coats for enhanced adhesion and corrosion inhibition, though it requires careful surface preparation to avoid undercutting.^[49] In buried applications, cathodic protection systems are integrated, using sacrificial anodes like zinc or magnesium to prevent electrochemical corrosion on steel supports in soil, ensuring long-term integrity without frequent intervention.^[50] Quality control during fabrication verifies compliance and performance through rigorous testing and dimensional checks. Non-destructive testing (NDT) methods, such as dye penetrant inspection for surface-breaking weld defects and magnetic particle testing for subsurface flaws in spring components over 1.5 inches in diameter, are standard per MSS SP-58 and ASME Section V, detecting discontinuities without compromising the structure. Tolerances are tightly controlled, with hanger rod lengths held to ±1/2 inch (13 mm) and clamp inner diameters to ±1/16 inch (1.6 mm) for pipes up to 2 inches, ensuring proper fit and load distribution as specified in MSS SP-58 Table 6 and Section 9. Special considerations apply in hazardous areas, where fireproofing enhances safety. Intumescent coatings are applied to steel supports in petrochemical facilities, expanding under heat to form an insulating char layer that maintains structural integrity for up to 3-4 hours during hydrocarbon fires, complying with UL 1709 testing for passive fire protection.^[51] Maintenance of these protections involves periodic inspections and recoating; for painted or galvanized surfaces, recoating every 5-10 years based on environmental exposure prevents degradation, with visual and thickness checks guiding interventions to sustain corrosion resistance.^[52] Recent advancements in fabrication include 3D printing for custom prototypes in research and development, enabling rapid iteration of complex support designs since the early 2020s. Using materials like carbon fiber-reinforced polymers, additive manufacturing produces lightweight, tailored components for testing, reducing lead times from weeks to days and facilitating optimization before full-scale production.^[53]

Standards and Compliance

Major Standards

The ASME B31 series of codes, developed by the American Society of Mechanical Engineers, forms the foundational standards for pressure piping design, including specific provisions for pipe supports in various applications. ASME B31.3, applicable to process piping in industries such as petroleum, chemical, and power generation, addresses support spacing requirements and stress limits to ensure structural integrity under operational loads like pressure, weight, and thermal expansion. Similarly, ASME B31.1 governs power piping systems in electric power generation facilities and industrial plants, incorporating seismic provisions that require supports to accommodate earthquake-induced forces while maintaining system stability. The Manufacturers Standardization Society (MSS) provides complementary standards focused on pipe hanger and support components. MSS SP-58 outlines specifications for materials, design, manufacture, selection, application, and installation of pipe hangers and supports, ensuring compatibility with piping codes like ASME B31 and emphasizing load-bearing capacity and durability.^[54] MSS SP-69 offers guidance on the selection and application of specific elements such as rod hangers and clevises, recommending practices for all service temperatures to prevent failures in suspension systems.^[55] Additional key codes extend regulatory coverage to inspection, structural design, and international seismic requirements. API 570, the Piping Inspection Code from the American Petroleum Institute, establishes procedures for in-service inspection, rating, repair, and alteration of piping systems, including evaluations of support integrity to detect degradation over time.^[56] The American Institute of Steel Construction (AISC) standards, particularly ANSI/AISC 360, apply to the structural steel elements of pipe supports, providing design criteria for buildings and other structures that incorporate these components.^[57] For international applications, Eurocode 8 (EN 1998-4) addresses seismic design of pipelines and associated supports, specifying resistance requirements for tanks, silos, and piping in earthquake-prone regions.^[58] The ASME B31 series originated from efforts initiated by the American Standards Association in 1926, with the first comprehensive code published in 1935; by the 1950s, it evolved into distinct sections like B31.1 and B31.3 through separation and specialization to address diverse piping needs, with ongoing updates such as the 2024 edition of B31.3 incorporating allowances for finite element analysis in support design.^[59] These standards collectively define the scope for pipe supports by establishing load allowables—such as stress limits under sustained, occasional, and thermal conditions—testing protocols including proof loads at 1.5 times the design load for hangers, and certification processes to verify compliance with safety and performance criteria.^[54]

Installation and Inspection Practices

Installation of pipe supports begins with pre-assembly checks to ensure components meet design specifications, including verification that variable spring supports are set to the cold position, where the installed load corresponds to the non-operating condition of the piping system.^[60] This involves adjusting the spring load indicator using turnbuckles to align with the calculated cold load, preventing excessive stress during thermal expansion.^[61] Bolting must be torqued to manufacturer-recommended values, such as approximately 75 ft-lbs for 1/2-inch diameter Grade 5 bolts in dry conditions, to secure connections without overstressing threads.^[62] Alignment is critical to avoid binding, with supports positioned to accommodate pipe movement while maintaining structural integrity.^[63] Tools and techniques for installation include spirit levels to confirm plumbness and vertical alignment of hanger rods, ensuring the support system remains stable under load. Laser alignment devices are employed for precise spacing between supports, typically adhering to project drawings to prevent pipe sagging or excessive deflection. Cold springing techniques pre-load the piping system by intentionally offsetting pipe lengths during installation, reducing reaction forces on supports by up to 50% during operation and minimizing thermal stresses.^[64] Inspection protocols for pipe supports encompass visual examinations for signs of corrosion, distortion, or loose components, conducted externally as part of routine piping assessments. Load testing verifies support capacity, often through hydrostatic testing of the connected piping at 1.5 times the operating pressure to confirm no excessive deflections occur. Periodic non-destructive testing (NDT), such as ultrasonic thickness measurements or guided wave testing for corrosion under supports, is required per API 570 guidelines, with intervals typically every 3 to 5 years depending on service class and risk level—for instance, every 5 years for Class 1 systems in lower-hazard conditions.^[65]^[66] Maintenance practices involve adjustments for foundation settlement, where supports are realigned and shimmed to restore proper elevation and prevent pipe stress concentrations. Worn springs in variable supports should be replaced if load variability exceeds 10% of the design value or after approximately 10 years of service, with inspections confirming coil integrity and housing condition. All activities must be documented, including as-found and as-left measurements, to track performance and comply with regulatory requirements.^[67]^[68] Best practices emphasize qualified field welding for attachments, performed by welders certified to standards like API 1104 to ensure weld quality and avoid defects that could compromise support strength. Safety measures include fall protection systems, such as full-body harnesses anchored to secure points, for overhead installations to mitigate risks during assembly or inspection at heights exceeding 6 feet.^[69]^[70]

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May 27, 2014 · The general friction factors for steel to steel are for static friction are around 0.72 to 0.74 and for sliding friction the values are quoted as 0.57.Pipe Support Design for Frictionfriction factor used for shoe slidesMore results from www.eng-tips.com
[33]
Brief History of FEA | ESRD | Engineering Software Research and ...
Learn about the history of FEA from the beginnings in 1956 to the present commercialization of standardized Sim Apps and the Simulation Governance movement.
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[PDF] Basics of Piping System Thermal Expansion for Process Engineers
ASME B31. 3 offers a simplified formula for determining if a pipe section requires stress analysis; by analysis is meant a total pipe stress analysis such as ...
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[PDF] ASME B31.3 Process Piping - AquaEnergy Expo Knowledge Hub
Displacement Stress Range section of this chapter. The allowable stress range is presented in B31.3 by two equations: Equation (1a):. SA = f (1.25 Sc + 0.25 Sh).
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[PDF] Effectiveness of seismic supports in piping
A basis for design of piping systems with energy-absorbing seismic supports has been proposed. Vibration control of each non-interacting segment is separately ...
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Cold Springing (Cold Pull) In Piping Systems
Why Cold Spring? · Reduce the hot stresses to mitigate the creep damage. · Reduce the hot reaction forces on connecting equipment. · Control the movement space.
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Selection of pipe supports: Parameters considered
Feb 9, 2013 · The basic parameters considered during the selection of supports are mentioned below: 1) Process design conditions 2) Pipe material of construction 3) Piping ...
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[PDF] NPHCatalog.pdf - National Pipe Hanger Corporation
accommodating thermal expansion on roller hangers and supports. MATERIAL: Carbon Steel (A36) or Stainless Steel (A240) Types 304 and 316. MAX TEMP: 650°F for ...<|separator|>
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ASTM A36 Steel Plate - Completely Specifications You Should Know
Yield Strength and Tensile Strength. Its mechanical properties include tensile Strength ksi of 58-80 (400-550 Mpa) and minimum Yield strength 36 ksi (250 Mpa).
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304 vs 316 Stainless Steel: What You Need to Know - Unified Alloys
While 316 comes in second in terms of quantities sold, it offers vastly superior corrosion resistance to chlorides and acids. ... Pipe Supports, Hangers & ...
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How to Choose the Right Pipe Support - Oatey
Consider location, pipe type, material, and spacing. Different pipe materials and sizes require specific supports. Plumbing codes mandate proper support.Missing: affecting | Show results with:affecting
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Steels for High-Temperature Piping
Low alloy steels for high-temperature piping: C-Mo alloy steels, Cr-Mo alloy steels, and Mn-Mo or Mn-Mo-Ni alloy steels are regarded as steel for high- ...
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Pipe Supports - Material Issue - Eng-Tips
Feb 5, 2007 · 1. Make the pipe shoe of 304H and rest it directly on the existing galvanized steel? 2. Make the pipe show out of another material that will ...
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Pipe Support Selection for Bare Pipe - Stress and Integrity
The supports are supplied in various plastic or composite grades. The standard plastic material used is very hard, to reduce deformation. It can incorporate a ...Metallic Wear Pad On Pipe · Full Encirclement Frp Wrap · Half-Round Thermo-Plastic On...<|control11|><|separator|>
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5 Ways to Isolate Dissimilar Metals - Pipe Supports
A common example is when you pair carbon steel with stainless steel. When these two common metals are combined and an electrolyte is introduced, electrons ...
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Piping Support Design Explained - Buckaroos
They are typically designed to support pipework in environments where temperature fluctuations and vibrations are prevalent, such as power plants and processing ...
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FRP's Role in Pipe Supports and Corrosion Protection - RedLineIPS
Jun 17, 2024 · FRP provides corrosion protection in pipe supports, preventing CUPS by creating a barrier and using liners to minimize friction.
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Corrosion Protection | Piping Technology & Products, Inc.
This technical bulletin will consider four methods of protecting carbon steel pipe supports components from corrosion; painting, zinc coatings, hot dip ...
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Cathodic Protection for Underground Piping - MATCOR
Feb 12, 2025 · This post describes 3 methods of pipe cathodic protection for underground piping in new plant construction, including deep and shallow ...
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[PDF] Fireproofing For Hydrocarbon Fire Exposures - AXA XL
• Design fireproofing for pipe rack supports as follows: ° Fireproof both the vertical and horizontal members of the first level of a pipe rack located.<|control11|><|separator|>
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Strategies for Corrosion Under Pipe Supports Prevention - Inspenet
Sep 3, 2024 · Routine maintenance and cleaning: Regular maintenance is vital to prevent the buildup of moisture, dirt, and corrosive substances that ...
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Customised 3D printed pipe supports with Roboze Carbon PA
Find out how to optimize the production of multi-purpose pipe supports with Roboze 3D printing solutions and Carbon PA composite material.Missing: prototypes R&D 2020
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MSS SP-58 - Manufacturers Standardization Society
MSS SP-58-2025 establishes standards for the materials, design, manufacture, selection, application, and installation of pipe hangers and supports. It is ...
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https://webstore.ansi.org/standards/mss/ansimsssp692003
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API Standard 570, 5th Edition - API.org
The American Petroleum Institute (API) has published the 5th edition of API 570, Piping Inspection Code: In-service Inspection, Rating, Repair, and Alteration ...
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ANSI/AISC 360 | American Institute of Steel Construction
30-day returnsThe AISC Specification provides the generally applicable requirements for the design and construction of structural steel buildings and other structures.
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Eurocode 8: Design of structures for earthquake resistance
EN 1998 Eurocode 8 applies to the design and construction of buildings and other civil engineering works in seismic regions.Missing: pipe supports
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Overview of ASME B31 Pressure Piping - Wermac
The ASME B31 committee was originally formed in 1926. The code has a long history beginning as early as 1935. Some sections have been absorbed into others ...
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FAQ: Engineered Spring Supports | Piping Technology & Products, Inc.
The “cold” setting of a variable spring support refers to the installed position and the associated load being carried by the support at that time.Missing: verification | Show results with:verification
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Constant Spring Supports - Installation & Maintenance Guide
Constant Spring Supports · 1. Support the pipe at the desired elevation. · 2. Attach load rods to the structural support. · 3. Attach the constant to the load rods ...
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Bolt Torque Chart - AFT Fasteners
Suggested Starting Torque Values ; 1-1/2", 6, 148,000, 178,000, 1,850 - 2,225 ...
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How to Properly Install Pipe Supports to Avoid Common Mistakes
### Step-by-Step Installation Guide for Pipe Supports
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Cold Springing: Exploring the Benefits, Techniques ... - Blog EPCland
Aug 22, 2023 · Cold spring is a technique employed to intentionally induce stress and elastic deformation in the piping configuration during the construction ...
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API 570 Requirements: Key Guidelines for Piping Inspection
Overview of API 570 requirements: Inspection, repair, alteration standards for in-service piping systems to ensure safety.What Is API 570? · What are the API 570... · What Are The Requirements...
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[PDF] Inspection of Corrosion under Pipe Supports | TWI Global
The presence of pipe supports usually makes the areas prone to corrosion and inaccessible to standard NDT techniques, which significantly limits the ...
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Piping System Spring Can Maintenance - Industrial Access
After the installation of piping systems, spring cans are adjusted to a particular position for the pipe's “cold” (non-operating) condition. Technicians work ...
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Spring Hanger Maintenance - News
Sep 18, 2025 · Load Adjustment: Change the spring pre-compression by adjusting the nut to ensure that the load variation during pipe displacement is within ±5% ...
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[PDF] API 1104: Standard for Welding Pipelines and Related Facilities
This standard also covers the procedures for radiographic, magnetic particle, liquid penetrant, and ultrasonic testing as well as the acceptance standards ...
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https://www.osha.gov/laws-regs/regulations/standardnumber/1926/1926.501