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Distorted thread locknut
Distorted thread locknut
Distorted thread locknut
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from Wikipedia

A distorted thread locknut,[1] is a type of locknut that uses a deformed section of thread to keep the nut from loosening due to vibrations, or rotation of the clamped item. There are four types: elliptical offset nuts, centerlock nuts, toplock nuts and partially depitched (Philidas) nuts.

High temperature use

[edit]

Because these nuts are solid metal, they remain effective at high temperatures, unlike nyloc nuts. High-grade nuts can withstand temperatures up to 1,400 °F (760 °C).

Safety factors

[edit]

High-strength distorted thread nuts cannot be used with low-strength fasteners because the hard nut will act like a die and destroy the threads on the fastener.[2]

Elliptical offset nuts

[edit]

Elliptical offset nuts is a catch-all category that encompasses designs known as oval locknuts[1] or non-slotted hex locknuts,.[3] The salient feature is that the thread has been deformed at one end so that the threads are no longer perfectly circular. The deformed end is usually shaped into an ellipse or obround triangle. These are known as one-way nuts as the nut may be easily started on the male fastener from the bottom non-deformed portion but is practically impossible to start from the deformed end. As the male fastener reaches the deformed section it stretches the threads of the nut elastically back into a circle. This action increases the friction between the nut and the fastener greatly and creates the locking action. Due to the elastic nature of the deformation the nuts can be reused indefinitely.[2]

Centerlock nuts

[edit]

Center lock nuts are similar to elliptical offset nuts, except that they are distorted in the middle of the nut. This allows the nut to be started from either side.[1]

Toplock nuts

[edit]

Toplock nuts are also similar to elliptical offset nuts, except that the whole thread on one end is not distorted. Instead only three small sections of the thread are deformed on one end.[1]

Partially depitched nuts

[edit]

Partially depitched nuts are commonly called Philidas nuts,[4] after their originator and current manufacturer, and differ from the above three nut types insofar as a portion of the thread is displaced axially, this being facilitated by one or more slots perpendicular to the axis.

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Distorted thread locknut

View on Grokipedia
from Grokipedia
A distorted thread , also known as a deformed-thread locknut, is a type of prevailing torque designed to resist loosening from vibrations and dynamic loads by intentionally deforming one or more sections of its internal threads to create frictional interference with the mating bolt. This all-metal construction provides a reliable locking mechanism without relying on additional components like adhesives or inserts, making it suitable for high-vibration environments. Distorted thread locknuts operate by compressing the deformed threads against the bolt's threads during installation, generating a prevailing torque that maintains clamp load even under repeated stress cycles. Common variants include the top lock (or Stover-style) nut, where deformation occurs at the top threads for one-directional locking, and the center lock (or two-way reversible) nut, featuring indentations in the middle threads that allow secure fastening from either end. These nuts are typically manufactured from materials such as low-carbon steel, alloy steel, or 18-8 stainless steel, with thread sizes ranging from 1/4" to 1" in imperial measurements or M6 to M20 in metric, and they conform to standards like ASME B18.16.6. The primary advantages of distorted thread locknuts include their ability to be formed in a single operation, broad tolerance limited by the base material and any plating or coating—for example, up to 500°F (260°C) for zinc-plated and 1,000°F (540°C) for 18-8 variants—and reusability for approximately 10 cycles before the locking effectiveness diminishes due to thread . However, they may reduce the fatigue life of the assembly slightly compared to standard nuts and are less suitable for high-precision applications requiring minimal thread damage. Widely used in , automotive assemblies, and industrial machinery, these locknuts excel in scenarios demanding vibration resistance without the need for lock washers or elements.

Introduction

Definition and Purpose

A distorted thread locknut is a type of prevailing torque locknut that achieves its locking function by intentionally deforming a section of its internal threads, creating an and increased friction against the mating bolt threads to resist self-loosening caused by vibrations or dynamic loads. This deformation, often achieved through crimping or pressing, alters the thread profile in specific areas without compromising the overall thread engagement. The primary purpose of a distorted thread locknut is to provide reliable fastening in environments subject to , impact, or cycling, where standard fasteners might lose preload and loosen over time. Its all-metal construction ensures durability in high-temperature, corrosive, or harsh conditions, eliminating the need for supplementary locking elements such as adhesives, spring washers, or secondary nuts. By generating prevailing during installation and maintaining it through , these locknuts help sustain joint integrity and prevent component failure in applications like automotive assemblies, machinery, and structural connections. Basic components of a distorted thread locknut include a hexagonal body for wrench engagement, internal threads with standard pitch that are selectively deformed—typically through 2-3 indentations or offsets in the upper section—and a bearing surface for load distribution. This design contrasts with standard hex nuts, which feature uniform, undistorted threads that allow free rotation and are prone to loosening under transverse loads or vibrations, often requiring additional measures to maintain clamp load. In distorted thread locknuts, the deformation ensures consistent resistance to rotation in both directions, promoting sustained preload without the need for retightening.

Historical Development

Locknuts first emerged in as an innovative solution to reduce assembly costs in machinery by integrating locking functionality directly into the nut, thereby eliminating the need for separate lock washers that were previously required to prevent loosening from . This development addressed a common issue in industrial applications where vibrations could cause standard nuts to back off, leading to failures in bolted joints. Early examples, such as the Elastic Stop Nut perfected around the same period, demonstrated the feasibility of self-locking designs and gained traction in . Distorted thread variants of locknuts, which achieve locking through intentional deformation of the internal threads, were specifically developed in the mid-20th century to provide durable, all-metal prevailing torque mechanisms suitable for demanding environments. A seminal advancement occurred with the Stover (Toplock) design, patented in 1949 (filed 1945) by Jordan H. Stover, involving compression of the nut's top portion to induce an elliptical distortion in the threads, creating friction that resists loosening under vibration. This technique was particularly valued in automotive and military applications during and after World War II, where reliable fastening amid shock and vibration was essential. Subsequent patents, such as one in 1965 by Jordan H. Stover III, refined the compression method to ensure consistent torque performance across a range of sizes. The post-World War II era saw broader adoption and evolution of distorted thread locknuts, including elliptical offset and centerlock configurations, driven by needs in and for high-temperature and high-vibration resistance. These designs built on wartime innovations in reliability, with limited early documentation reflecting their rapid integration into specialized sectors. By the late , standardization efforts, such as those outlined in ASME B18.16.6 (first published in 2008), codified performance requirements for prevailing locknuts, ensuring consistency in thread and values for modern applications.

Locking Mechanism

Principles of Thread Distortion

Thread distortion in locknuts operates by intentionally deforming the internal threads of the nut to create an with the mating bolt threads, generating radial and axial friction that resists rotational loosening. This deformation typically involves indenting, offsetting, or squeezing the threads in targeted areas, which reduces the effective thread locally and causes the nut's threads to bind unevenly against the bolt's flanks. As a result, the distorted sections wedge into the bolt threads, converting applied rotational force into frictional resistance that maintains the joint's integrity under dynamic loads such as . The deformation process balances elastic and behaviors to ensure both effective locking and practical reusability. Elastic deformation predominates in the nut's thread during assembly and disassembly, allowing the threads to recover partially and enabling multiple uses—often up to 10 or more cycles—before significant wear occurs. However, a controlled set is introduced in high-stress areas during , such as through permanent indentations, to sustain the over time without excessive thread damage. This combination prevents complete thread flattening while providing consistent grip. When engaged with a mating fastener, the distorted threads interact by gripping the bolt's thread flanks asymmetrically, which distributes pressure unevenly and amplifies frictional forces without promoting galling, provided the materials are compatible (e.g., similar hardness levels). The locking action arises from this uneven contact, where the deformed areas "dig" into the bolt threads, creating higher localized friction that opposes both tightening and loosening torques. Visually, the distortion often manifests as three indentations spaced approximately 120° apart around the nut's circumference or as an elliptical reshaping of the thread profile, altering the otherwise circular thread path—as seen in toplock and centerlock variants, respectively.

Prevailing Torque Characteristics

Prevailing torque refers to the minimum required to rotate a on a threaded , independent of any clamping , and is measured as on-torque during installation and off-torque during removal. In distorted thread locknuts, this is generated by the interference between the deformed internal threads and the bolt threads, providing resistance to before preload is applied. For standard sizes, on-torque typically ranges from 5% to 20% of the overall tightening , depending on thread diameter and nut material, as specified in performance standards for prevailing torque nuts. Off-torque, measured after initial assembly, generally maintains a substantial portion of the initial on-torque value following vibration testing, retaining residual preload despite partial loosening. Several factors influence prevailing torque levels, including thread size (larger diameters yielding higher ), material hardness (softer materials allowing greater deformation), and the depth of thread distortion (deeper deformation increasing interference). Prevailing torque in these locknuts arises from frictional models under zero-preload conditions due to the locking features. Testing protocols for prevailing torque and loosening resistance include the Junker vibration test, which simulates transverse vibrations at accelerations up to 10g and aligns with standards like DIN 65151 or ISO 16130. In this test, distorted thread locknuts typically exhibit initial self-loosening but demonstrate reliable performance by retaining preload over multiple cycles (e.g., 30,000) without complete detachment.

Types of Distorted Thread Locknuts

Elliptical Offset Nuts

Elliptical offset nuts feature a design in which the end of the nut is deformed into an elliptical or obround shape via offset stamping, distorting approximately one-third to one-half of the threads to create prevailing torque. This deformation occurs primarily at the top portion of the nut, where opposite sides are compressed inward, resulting in a minor axis reduction and an elliptical cross-section while the bottom remains circular for easy initial engagement. The locking mechanism is unidirectional, necessitating that the nut be installed starting from the undistorted end to ensure proper thread interaction and grip. The manufacturing process entails inserting a into the threaded nut blank to control deformation depth, followed by pressing the nut against a die or employing squeeze rolls to elliptically distort the of the upper section. This controlled deformation, typically to a depth of 1/4 to 1/2 the nominal , permanently alters the threads to provide spring-like elasticity without compromising the nut's overall integrity. The resulting structure maintains a flat bottom bearing surface and chamfered corners for compatibility with standard hex wrenching. A key advantage of elliptical offset nuts is their high elastic recovery, which enables multiple reuses without significant loss of locking performance, unlike deformation-based locks that may permanently alter after initial use. They are particularly suitable for threads, where precise control and resistance are essential. These nuts excel in environments demanding repeated assembly and disassembly, offering reliable self-locking through thread distortion rather than inserts or additives. Typical specifications include availability in grades 2 through 8, with metric sizes from M3 to M20 and imperial sizes from 1/4" to 3/4", often in zinc-plated steel for corrosion resistance. A common variant aligns with DIN 980 standards for prevailing torque performance, ensuring dimensional consistency and thread tolerance across applications.

Centerlock Nuts

Centerlock nuts feature a bidirectional design achieved through deformation in the middle third of the internal threads, created by two or three radial indents that slightly distort the thread profile. This central deformation allows the nut to engage and lock effectively from either end, making it reversible and suitable for automated assembly processes where orientation is unpredictable. The indents are typically rectangular or round and positioned at equal spacing—180° apart for two indents or 120° apart for three—ensuring uniform thread distortion across the nut's midpoint. In operation, the distorted threads in centerlock nuts provide a controlled prevailing torque that grips the mating bolt symmetrically from both directions, minimizing uneven stress during installation. This centralized deformation results in a balanced locking mechanism that engages without requiring full thread run-down, enhancing efficiency in high-volume applications. The design draws on elastic deformation principles to maintain locking integrity while permitting limited reusability, as the threads can partially recover after removal. Manufacturing of centerlock nuts involves applying pressure via opposed punches to the flat sides of a standard hex nut, creating the indentations that deform the internal threads. These all-metal nuts are typically produced from low-carbon and conform to standards such as ISO 7042 for prevailing hexagon nuts. Common specifications include Grade A or Grade 5 strength ratings, with sizes ranging up to 1 inch in , and they are often finished with plating to provide resistance in general industrial environments.

Toplock Nuts

Toplock nuts are one-piece all-metal prevailing torque hex nuts characterized by three small, chamfered indentations on the top end that distort the internal threads over a short length. This design features a conical top and a flat bottom bearing surface with chamfered corners, enabling the nut to provide locking action through thread deformation primarily at the upper portion. The indentations are typically spaced at 120° intervals around the top face, creating irregular thread shapes that engage the bolt for friction-based resistance. A key unique feature of toplock nuts is their minimal thread , which allows for easy finger-starting during installation as the lower threads remain largely unaffected and run smoothly onto the bolt until reaching the deformed section. This configuration delivers consistent prevailing suitable for low to medium vibration environments, where the top generates reliable clamping force without excessive resistance throughout the full engagement. The mechanism resists loosening from dynamic loads by increasing friction at the top threads, offering reusability for multiple installations while maintaining performance. These nuts are manufactured by applying controlled pressure through or processes to form the indentations on the top face of a standard hex nut blank, deforming the internal threads in a localized manner. The process ensures precise distortion without compromising the overall structural integrity, often conforming to standards like DIN 980V for metric variants. Typical specifications for toplock nuts include Grade C with coarse threads, available in sizes ranging from 1/4" to 1" in imperial measurements, and commonly finished with plating for resistance. variants are also prevalent, incorporating an integrated washer-like bearing surface to distribute loads effectively in assemblies requiring enhanced stability.

Partially Depitched Nuts

Partially depitched nuts, also known as Philidas nuts, feature a where narrow axial slots are cut into the collar or body of the nut, allowing sections of the internal threads to be displaced axially by approximately 0.5 to 1 pitch. This displacement creates overlapping thread profiles that interfere with the mating bolt threads, generating for locking without relying on radial compression. The original was patented by Philidas Ltd. in , establishing it as a pioneering all-metal self-locking mechanism. This axial depitching provides high prevailing torque while maintaining thread integrity, making these nuts suitable for high-precision applications where consistent locking performance is required under . Unlike designs that deform threads radially, the slotted axial shift ensures the locking element flexes elastically during assembly, gripping the bolt flanks fully without excessive on the primary threads. For the industrial variant, two slots are typically cut in the same plane within a collar above the hexagon, while the turret variant uses slots positioned one above the other for enhanced depitching of the bolt threads. Manufacturing involves cold forming or the nut body, followed by precise slotting—often via stamping or milling—and reforming the threads to achieve the pitch offset. This process is commonly applied to high-strength materials such as 8 or 10, with finishes like zinc plating for corrosion resistance. variants (A2-70 or A4-80) are also produced for demanding environments. These nuts are less commonly specified outside European markets but adhere to standards like BS EN ISO 7042:2012 for prevailing performance. Typical sizes range from M6 to M12 in fine or coarse threads, though broader availability extends to M3 through M20 in metric and UNF/UNC imperial equivalents, prioritizing compact, high- applications.

Applications

High-Temperature Environments

Distorted thread locknuts, owing to their all-metal construction, are particularly well-suited for high-temperature environments where non-metallic locking mechanisms would degrade. These locknuts can operate effectively up to °F (760°C), a capability determined solely by the properties of the and any protective , far surpassing the limits of nylon-insert locknuts that typically fail above 250°F (121°C) due to material softening. In applications involving thermal cycling, such as exhaust systems, internal combustion engines, gas , and components, distorted thread locknuts provide reliable fastening by accommodating material expansion and contraction without compromising joint integrity. For instance, they secure critical elements in automotive exhaust manifolds and turbochargers, as well as casings and mounts, where temperatures fluctuate dramatically and consistent preload is essential to prevent loosening. Performance in these settings is enhanced by the absence of degradable inserts, ensuring no loss of prevailing from oxidation or breakdown; tests and standards confirm that these locknuts retain their locking effectiveness under prolonged heat exposure, limited only by the base material's endurance. Austenitic stainless steels like 316 provide good oxidation resistance for intermittent service up to 870°C (1600°F), though continuous use is limited to about 425°C (800°F) to avoid , while superalloys such as provide superior protection in more extreme oxidative conditions up to 980°C (1800°F), maintaining joint clamp load with minimal relaxation even after extended exposure.

Vibration-Prone Assemblies

Distorted thread locknuts are essential in vibration-prone assemblies, where mechanical shock and cyclic loading threaten integrity. Key applications include automotive suspension systems, which endure constant dynamic forces from road irregularities, and machinery mounts that stabilize equipment under operational vibrations. Rail systems also rely on these locknuts to secure tracks and components against train-induced shocks, while assemblies in rugged environments, such as those in or industrial devices, use them to withstand cyclic loading exceeding . These uses leverage the locknuts' ability to maintain secure joints without additional locking elements. Performance evaluations highlight their anti-loosening efficacy through standardized tests like the Junker vibration test (DIN 65151), which simulates transverse s. All-metal distorted thread locknuts typically pass these tests with minimal clamp load loss, enduring thousands of cycles at typical conditions (e.g., 40 Hz frequency and 0.3 mm ) while retaining a significant residual preload—often preventing complete loosening even after initial partial rotation. Under sinusoidal profiles common in real-world scenarios, prevailing from thread distortion ensures sustained clamping force, with studies showing retention of preload levels sufficient for continued functionality in high-stress conditions. Selection for these assemblies considers the severity of , with higher thread deformation preferred for extreme cases like off-road to amplify and resistance. Representative examples include mounts in , where they secure components against engine pulsations; conveyor belts in , countering repetitive impacts; and power tools, protecting against handheld vibrations during operation. This targeted application underscores their role in enhancing reliability without compromising assembly efficiency.

Design and Performance Considerations

Safety Factors and Material Compatibility

When using distorted thread locknuts, a primary safety risk arises from mismatched material strengths between the nut and bolt. High-strength locknuts, such as Grade 8 equivalents, installed on lower-strength bolts like Grade 5 can cause thread stripping, as the harder deformed threads of the nut act like a cutting die on the softer bolt threads. To mitigate this, it is essential to match the nut grade to the bolt grade, for example, using a Grade 5 locknut with a Grade 5 bolt to ensure compatibility and prevent failure. Design factors for safe application include limiting the clamp load to 75% of the bolt's proof strength to avoid overstressing the assembly. This conservative limit accounts for the additional from the prevailing generated by the distorted threads, ensuring the maintains integrity under load without risking bolt yield or . In shear-critical joints, distorted thread locknuts should be paired with washers to distribute bearing loads and prevent localized or embedding at the nut face. Material compatibility is limited to standard Unified thread forms, specifically UNC and UNF, as the distortion is engineered for these profiles to achieve reliable locking without compromising thread engagement. They are not suitable for tapered threads or ACME threads, which have differing geometries that would interfere with the deformation mechanism and lead to improper seating or . Installation guidelines emphasize controlling thread deformation to minimize risks, particularly in variants where high exacerbates adhesion between mating surfaces. Manufacturers recommend using lubricants on threads and avoiding excessive to prevent , with deformation kept minimal to maintain bolt integrity during assembly. Per ASME B18.2.2 standards for inch-series nuts, all-metal locknuts like distorted thread types must conform to specified material grades (e.g., ASTM A563) to ensure overall compatibility and performance.

Reusability and Installation Guidelines

Distorted thread locknuts are installed using standard specifications appropriate for the size, material grade, and application conditions. For one-way designs, such as toplock nuts, installation must begin from the deformed thread end to ensure proper engagement of the locking feature. is recommended for nuts with Grade 5 or higher strength to reduce and prevent during assembly, typically using dry film lubricants like that comply with relevant specifications. Reusability of distorted thread locknuts is generally limited to 10-15 cycles before the prevailing decreases by approximately 20%, at which point the locking effectiveness diminishes due to thread wear or loss of deformation. Inspection after each cycle should check for visible thread deformation, , or reduced resistance during hand-tightening; nuts exhibiting these signs must be discarded to maintain reliability. In applications, all-metal deformed thread locknuts like MS21043 or NAS1291 types have demonstrated average reuse lives of 11-15 cycles at preloads of 66-85% yield strength, with initial drops of 20-50% between the first and second cycles. Removal of distorted thread locknuts employs standard tools, such as wrenches or sockets, with reverse rotation; however, the prevailing torque mechanism may necessitate up to 20% additional torque compared to non-locking nuts to overcome the friction lock. Breakaway removal torque typically ranges from 10-17 in-lbs for common sizes after initial cycles, decreasing progressively with reuse. Compliance with standards like NASM25027 is essential for aerospace-grade distorted thread locknuts, which mandates testing for 15 unseated cycles with prevailing maintained between 3.5 and 30 in-lbs. Nuts should be discarded if the prevailing falls below 50% of the initial value during testing, ensuring consistent and .

Advantages and Limitations

Key Benefits

Distorted thread locknuts offer superior vibration resistance compared to standard plain nuts, providing reliable locking through thread deformation that maintains preload under dynamic loads. These locknuts exhibit exceptional temperature tolerance, retaining full locking efficacy up to 1400°F, which significantly outperforms nylon-insert locknuts limited to approximately 250°F due to material degradation. In terms of cost-effectiveness, distorted thread locknuts are generally more economical than specialized deformed flange or wedge-locking alternatives, while their reusability—up to 10 cycles provided prevailing remains within specifications—helps minimize needs and long-term replacement costs. Their all-metal ensures simplicity in design and installation, requiring no supplementary components or inserts, making them particularly suitable for harsh environments involving chemical exposure or marine conditions where non-metallic elements would corrode or fail.

Potential Drawbacks

Distorted thread locknuts exhibit higher prevailing compared to standard nuts due to the intentional deformation of their threads, which can complicate hand assembly by requiring greater effort or tools to overcome the initial resistance. The locking effectiveness of these nuts degrades with repeated use, typically allowing for approximately 10 cycles before the prevailing diminishes sufficiently to warrant replacement, in contrast to jam nuts that offer indefinite reusability without such limitations. There is a risk of thread damage, including , particularly when using distorted thread locknuts on soft bolts or in applications, where the deformed threads increase and between mating surfaces, making them unsuitable for frequent adjustments. While available under standards like DIN 980V, distorted thread locknuts offer fewer options for metric fine threads compared to other all-metal prevailing types, limiting their versatility in precision applications requiring finer pitches. In scenarios involving factors, compatibility issues may arise if pairings exacerbate these drawbacks, such as accelerated on softer components.

References

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