Split pin
A split pin, also known as a cotter pin, is a simple yet effective mechanical fastener formed from a single piece of malleable wire bent into an open U-shape with two parallel prongs or tines, designed to be inserted through aligned holes in assembled components and then spread apart to create a secure lock that prevents unintended disassembly.[1][2] These fasteners provide a positive, vibration-resistant retention mechanism, allowing for quick installation and removal without specialized tools, and are widely employed in applications requiring reliable securing of bolts, shafts, clevis pins, and castle nuts against loosening or axial movement.[2][3] Split pins are standardized internationally under ISO 1234, which defines their characteristics, including nominal diameters ranging from 0.6 mm to 20 mm, with recommended hole tolerances such as H13 for smaller sizes and H14 for larger ones to ensure proper fit and performance.[4] Typically manufactured from low-carbon steel for general use—often with zinc plating to enhance corrosion resistance—or from stainless steel (such as grade 1.4310) for environments demanding higher durability and resistance to rust, split pins can also be produced in brass or other softer metals for less demanding or electrical applications.[5][3] Their design emphasizes malleability, enabling the tines to be bent back upon themselves without fracturing, as per ISO 1234, though this process renders them single-use in most cases due to material fatigue.[1][6] Common in industries like automotive engineering, general machinery, and aerospace, split pins excel in scenarios where shear strength is secondary to ease of assembly and reliable retention under dynamic loads.[3]Background
Definition and Purpose
A split pin is a wire-formed metal fastener characterized by two parallel tines or legs extending from a looped head, designed to be inserted through aligned holes in mechanical components and then bent outward at the ends to secure them in place.[2] It is typically manufactured from thick wire with a half-circular cross-section, which results in flat inner surfaces that, when the tines are brought together during insertion, form a split cylindrical shape for a snug fit in the hole.[2] This design allows the pin to act as a simple locking device, preventing unintended rotation or axial movement between parts.[7] The primary purpose of a split pin is to secure bolts, pins, or nuts against loosening caused by vibration, torque, or dynamic loads in mechanical assemblies.[8] For instance, it is commonly used to lock clevis pins in linkages or castellated nuts on bolts, ensuring reliable retention in environments subject to repetitive motion.[8] By bending the tines after insertion, the pin provides a positive mechanical stop that resists disassembly without additional tools.[1] In terminology, the split pin is also referred to as a cotter pin in the United States, while in the United Kingdom, "cotter pin" typically denotes a distinct non-split tapered wedge, such as the crank cotter used to secure bicycle pedals to the crank arm.[9] To avoid confusion, the term "split cotter" is sometimes employed internationally for the split-pin variant.[9] Its general advantages include simplicity in design, low manufacturing cost, and ease of installation, making it suitable for low- to medium-load applications where quick assembly is prioritized.[10] Invented in 1912 by Ira J. Young, it remains a foundational fastener in engineering.[11]Historical Development
The split pin, a two-tine wire fastener, was invented by Ira J. Young of the Wire Manufacturing Company in St. Louis, Missouri, in 1912.[12] Young filed key patents for machines enabling its production, including US Patent 1,119,211, submitted on June 15, 1912, and issued on December 1, 1914, which detailed a rotary mechanism for feeding, severing, and bending wire into split pins with a central eye and parallel legs.[11] An earlier related patent, US 1,151,645, filed on June 27, 1910, and issued on August 31, 1915, described automatic machinery using half-round wire to form pins with equal-length legs and a round eye, synchronized via gears for efficient operation. Following the patents, split pins saw early adoption in mechanical assemblies, particularly machinery and vehicles during the early 20th century, building on simpler wire-based fasteners used in industrial settings like railroads.[12] The mechanized production processes outlined in Young's inventions facilitated a shift from labor-intensive hand-forming to mass manufacturing, allowing widespread integration into emerging automotive and equipment designs.[11] Since their introduction, split pins have undergone limited design changes, with emphasis placed on standardization in the mid-20th century to ensure consistency across industries; the International Organization for Standardization issued Recommendation R 1234 in 1971, specifying metric series dimensions for split pins.[13] This standardization supported their reliable use in global mechanical applications without altering the core wire-forming principles established by Young.[12]Design and Construction
Materials
Split pins are commonly manufactured from mild steel, valued for its cost-effectiveness and adequate tensile strength, typically around 440 MPa, which provides sufficient shear resistance for general mechanical fastening without bearing high axial loads. However, mild steel is susceptible to corrosion in humid or exposed environments, often requiring zinc plating to enhance durability and prevent rust formation. Stainless steel, such as AISI 304 or 316 grades, serves as a primary alternative, offering excellent corrosion resistance and longevity in harsh conditions like marine or chemical exposures, with similar tensile properties but superior environmental stability. Softer materials like brass, bronze, and aluminum are used for non-structural applications where malleability and lighter weight are prioritized over high strength, such as in electrical or decorative assemblies. The material's half-circular wire cross-section is key to performance, enabling the prongs to flex during bending for secure installation while resisting shear forces through the solid profile. This design balances flexibility for easy deformation with enough rigidity to lock components effectively, though the materials are generally soft to facilitate manual bending without specialized tools. Steel variants provide robust shear resistance suitable for vibrations, but all materials exhibit limitations in high-tension scenarios, emphasizing their role as secondary locking devices rather than primary load-bearers. In production, split pins are formed by straightening and cutting half-round wire to precise lengths, followed by looping one end to create the head and tapering or pointing the prongs; steel pins are frequently zinc-plated post-forming to improve corrosion resistance. This wire-forming process ensures uniformity and allows for high-volume manufacturing while preserving the material's ductility for bending. Selection of materials depends on environmental factors and load requirements; for example, stainless steel is essential in corrosive settings like marine hardware to avoid degradation, whereas softer options like aluminum or brass are unsuitable for applications involving significant shear forces due to their lower strength.Types
Split pins, also known as cotter pins in some regions, are categorized by their prong configurations and end finishes, which determine their structural integrity and adaptability to various assembly requirements. The standard type features two equal-length tines formed from semi-circular wire, with square-cut ends that allow the prongs to be spread and bent symmetrically after insertion for basic securing functions.[14] This design provides a straightforward, versatile structure suitable for general mechanical assemblies where uniform prong deformation is preferred.[15] Extended prong types incorporate structural modifications to one or both tines for enhanced handling and retention. In these variants, one prong is elongated relative to the other, facilitating easier separation during preparation, while the overall parallel, narrow prong geometry supports wrapping around adjacent components for added stability.[16] Sub-variations include square-cut ends with straight terminations for precise alignment, curved ends that promote smoother bending without sharp angles, and beveled ends featuring an angled taper to accommodate specific clearance needs in confined spaces.[14] These differences in end geometry allow extended prong split pins to adapt to diverse structural demands, such as improved insertion in tight tolerances.[17] Other variations focus on specialized end treatments to optimize fit and security. Mitre end split pins have an angled cut at the prong tips, typically at 45 degrees, enabling a flush integration with surrounding surfaces for aesthetic or space-constrained scenarios.[14] Bevel end designs, similarly angled but with a more gradual slope, are structured for compatibility with tapered or irregular hole profiles, ensuring a secure seat without excessive material deformation.[14] Hammer lock types differ by incorporating a curved termination on the longer prong that bends inward toward the shorter one, creating a tapered profile; this allows the prongs to spread upon impact to the head, providing robust locking in high-vibration environments.[17][18] Specialized split pins include humped and clinch variants, which incorporate ridges or protrusions for superior retention. Humped split pins feature a raised hump or shoulder on one prong, enhancing grip through increased surface friction and resistance to slippage in dynamic conditions, though they remain less prevalent than standard forms.[19] Clinch types are distinguished by a self-locking ridge or clinch mechanism on the prongs, where the formed wire structure springs apart post-insertion to create an automatic hold, offering improved anti-rotation properties compared to basic designs.[20] These specialized forms prioritize enhanced mechanical interlocking over simplicity. Split pins, with their bifurcated tines designed for bending, differ fundamentally from non-split cotters, which rely on wedge-shaped insertion without prong deformation for locking.[19]Specifications
Sizes
Split pins are available in standardized metric sizes with nominal diameters ranging from 0.6 mm to 20 mm according to ISO 1234:1997 (DIN 94 superseded), with common sizes including 0.6, 0.8, 1, 1.2, 1.6, 2, 2.5, 3.2, 4, 5, 6.3, 8, 10, 13, 16, and 20 mm.[21][22] These diameters correspond to wire diameters slightly smaller for insertion into drilled holes, typically with a tolerance that allows the pin to fit snugly without excessive play. Lengths are selected based on the thickness of the assembly, generally approximately twice the depth of the hole to ensure the prongs can be bent securely around the component. For example, a 1.6 mm diameter split pin is suitable for securing a 6 mm bolt, requiring a corresponding hole size of about 1.7 mm.[23] The following table summarizes key dimensions for common metric split pin sizes under ISO 1234:1997 (dimensions in mm):| Nominal Diameter (mm) | Wire Diameter Min/Max (mm) | Eye Width ≈ (mm) | Short Prong (mm) | Long Prong (mm) | Typical Lengths (mm) |
|---|---|---|---|---|---|
| 1 | 0.9/1.0 | 3 | 1.6 | 2.5 | 6–40 |
| 1.6 | 1.4/1.5 | 3.2 | 2.6 | 4 | 10–50 |
| 2 | 1.8/1.9 | 4 | 3.2 | 5 | 12–60 |
| 3.2 | 2.9/3.0 | 6.4 | 5.6 | 8 | 16–80 |
| 4 | 3.6/3.8 | 8 | 7 | 10 | 20–100 |
| 5 | 4.5/4.8 | 10 | 9 | 13 | 25–120 |
| 6.3 | 5.7/6.0 | 12.6 | 11 | 16 | 30–140 |
| 8 | 7.2/7.5 | 16 | 14 | 20 | 40–160 |
| Nominal Diameter (in) | Shank Diameter Min/Max (in) | Hole Diameter (in) | Typical Lengths (in) |
|---|---|---|---|
| 1/32 | 0.028/0.032 | 0.047 | 1/4–3 |
| 1/16 | 0.056/0.060 | 0.078 | 1/4–3 |
| 1/8 | 0.116/0.120 | 0.141 | 1/2–3 |
| 1/4 | 0.220/0.225 | 0.266 | 1–4 |
| 3/8 | 0.329/0.335 | 0.375 | 1–4 |
| 1/2 | 0.467/0.473 | 0.500 | 2–5 |
| 3/4 | 0.715/0.723 | 0.750 | 3–6 |