Clevis Pin Guide: Types, Sizes, Materials, and Retention Methods

A clevis pin is an unthreaded cylindrical fastener that passes through a clevis bracket and a mating component to form a pivoting joint. Unlike a bolt, a clevis pin is retained at the open end by a split pin, R-clip or nut rather than by threading — making the joint quick to assemble, disassemble and adjust while allowing free rotation between the connected parts.

Clevis pins are found throughout Australian industry: tractor three-point linkages, hydraulic ram ends, conveyor pivot arms, wire rope turnbuckle jaws, rigging assemblies, trailer couplings and agricultural implement connections all rely on them. This guide covers types, DIN 1444 metric sizes, materials, retention methods and how to identify a replacement when you no longer have the original specification.

What Is a Clevis Pin?

The name comes from the clevis — a U-shaped or forked bracket with aligned holes through both ears. The clevis pin slides through one ear, then through the mating part (a rod eye, chain link, shackle or bracket), then out through the other ear. A retaining device through the cross-hole at the exposed end prevents the pin from backing out.

Clevis pin retention via cotter pin is one method — for the castellated-nut-plus-cotter-pin alternative used on rotating shafts and wheel hubs, see the AIMS castle nut guide.

Because the pin is unthreaded and free to rotate within the hole, it creates a true pivot joint: the connected components can rotate relative to one another around the pin axis without generating thread fatigue or loosening torque. This is why clevis pins are preferred over bolts wherever cyclical rotation, oscillation or angular movement occurs under load.

The three-part assembly — clevis bracket, clevis pin, retaining device — is one of the oldest and most reliable mechanical joints in engineering. In the Australian agricultural and industrial context, you will see it referred to variously as a hitch pin, drawbar pin, linch pin (though that is technically a different fastener) or simply a clevis. Whatever the local name, the geometry and function are identical.

A clevis pin is a shear-loaded fastener. In double-shear (the standard clevis arrangement where both ears of the bracket are engaged), the pin carries the applied load across two shear planes simultaneously. This is more efficient than a bolt in the same arrangement, and is why clevis pins of modest diameter can handle surprisingly high loads when the material and geometry are correctly matched to the application.

Types of Clevis Pins

Standard Clevis Pin (DIN 1444 Form B)

The most common type. Has a domed or flat head at one end and a cross-hole drilled through the shank near the other end for a split pin or R-clip. Available in metric diameters M5 through M30 and a range of grip lengths. This is the pin you will find in most general industrial, agricultural and lifting applications in Australia. The Form B designation confirms the cross-hole is present — Form A (no cross-hole) is less common and used only where an alternative retention method is designed into the assembly.

Headless / Shoulder Clevis Pin

Used where the pin must pass through from one side only, or where head clearance above the clevis ear is restricted. Common in hydraulic cylinder rod-end and base-end connections and precision pivot assemblies on production machinery. The shoulder (a step-down diameter) provides the retention face at one end; the cross-hole or snap-ring groove retains the other end. On hydraulic cylinders, the shoulder pin is often retained by a snap ring (circlip) seated in a groove machined into the clevis ear rather than by an external split pin.

Multi-Hole Clevis Pin

Has multiple cross-holes drilled along the shank at regular intervals, allowing the effective grip length to be adjusted without removing the pin from the clevis assembly. Used extensively in three-point linkage systems, cultivator frames, toolbar connections and implement height adjusters, where the operator needs to set depth or position increments in the field without a toolkit. The Champion CPMH01 range stocked by AIMS is a typical example: two or more holes let the operator select the engagement point by repositioning the R-clip.

Threaded-End Clevis Pin

Has a standard domed head at one end and a threaded shank at the other, retained by a nyloc nut and washer. Used in applications where positive, non-backing-out retention is required and tool access at the retention end is available. Less common in field-service applications than the split-pin type but preferred in fixed machinery where vibration is high and the joint is not designed for frequent adjustment. The nut should be tightened to a snug fit — not hard torqued — to preserve free rotation of the pin in the clevis.

DIN 1444 — The Standard That Applies in Australia

Australian industry uses metric clevis pins manufactured to DIN 1444 (German standard, widely adopted internationally), which defines two forms:

• Form A — head only, no cross-hole. Used where the pin is retained by another method (circlip groove, grub screw, press fit) or where the assembly is not intended for field disassembly.
• Form B — head plus cross-hole drilled through the shank near the retention end. The standard workshop and field-service pin. This is what AIMS stocks and what you will find in most hardware and industrial supply catalogues in Australia.

The DIN 1444 standard specifies nominal diameter, tolerance class (typically h11 — a slightly loose fit to allow rotation), cross-hole diameter and position, and head dimensions. The h11 tolerance means a 10mm DIN 1444 clevis pin will have an actual diameter of 9.94–10.00mm. The mating clevis holes are typically drilled to 10.5mm (normal fit) for easy assembly and to allow the joint to rotate freely without binding.

The standard also specifies the cross-hole diameter relative to pin diameter, so split pins and R-clips sized to the pin will fit correctly without play. A 10mm DIN 1444 pin has a 3.2mm cross-hole; a 12mm pin has a 4.0mm cross-hole; a 16mm pin has a 5.0mm cross-hole. This relationship is what allows you to select the correct split pin simply by knowing the clevis pin diameter.

Imperial clevis pins made to ANSI/ASME standards are still in use in Australia, primarily on older US-manufactured agricultural equipment, some British-origin machinery and North American-sourced trailers and attachments. These use inch-fraction diameters and their cross-holes are sized to inch-fraction split pins and R-clips. Where you have a mix of metric clevis hardware and imperial-specification pins on the same machine, do not interchange them without checking the hole sizes match — the dimensional tolerance system differs between DIN and ANSI.

Clevis Pin Sizes — Metric Reference Table (DIN 1444)

The table below covers the most common DIN 1444 Form B metric clevis pin sizes stocked in the Australian market. Lengths shown are standard stock lengths; non-standard lengths are available to order for volume requirements.

A note on grip length: The grip length is the usable shank length between the underside of the head and the centre of the cross-hole. When ordering, confirm that the grip length matches the combined thickness of the clevis ears and the mating part. The cross-hole should clear the outer clevis ear face by at least 3–5mm to allow the split pin legs to be spread or the R-clip to seat fully.

Tolerance and fit: DIN 1444 Form B pins are manufactured to h11 tolerance. The mating hole in the clevis bracket should be drilled to H12 tolerance for a normal running fit, or H11 for a close fit. For standard off-the-shelf clevis hardware (turnbuckles, connecting links, hydraulic cylinder rod ends), the clearance fit is designed into the product — simply match the pin diameter to the specified pin size for that fitting.

Imperial Clevis Pin Sizes

For workshops maintaining older US-origin or British-origin equipment, the following imperial sizes are the most commonly encountered in Australia. Imperial sizes are typically specified in fractional inches for the diameter and whole or fractional inches for the length.

The Metric/Imperial Crossover Problem in Australian Agriculture

This is a real practical issue. Many tractors and implements sold in Australia from the mid-2000s onwards — particularly Chinese-manufactured machines sold under Australian brand names — use clevis geometry that sits between the metric and imperial systems. A nominally 10mm metric clevis hole may accept a 3/8" (9.53mm) imperial pin with slightly looser clearance, and vice versa. This occurs because the Chinese manufacturing supply chain has historically mixed metric and imperial tooling, and the dimensional differences at these sizes are small enough that the pin physically fits even though it is not the correct specification.

The practical guidance: if you are replacing a worn pin on Asian-origin equipment and cannot find the original specification, measure the clevis hole diameter in millimetres. If the measurement is exactly a metric value (10.0mm, 12.0mm, 16.0mm), specify a DIN 1444 metric pin. If the measurement corresponds to an imperial fraction (9.5mm ≈ 3/8", 12.7mm = 1/2"), specify an imperial pin. If in doubt, specify the metric size that is closest to the measurement and check the fit before committing to a batch. A metric DIN 1444 pin is usually the safer choice in Australia as it is more widely stocked and its tolerance system is better documented.

Clevis Pin Materials

Mild Steel, Zinc-Plated (Grade 4.6 Equivalent)

The standard material for general industrial and agricultural use. Zinc electroplating (typically 5–8 microns) provides moderate corrosion resistance suitable for sheltered environments, workshop use and most field conditions where the pin will be periodically replaced as a wear item. The steel substrate is mild steel with a minimum tensile strength of around 400 MPa, adequate for the shear loads in standard DIN 1444 applications.

Hot-dip galvanised clevis pins are also available for outdoor agricultural applications where corrosion resistance must outlast a regular maintenance cycle. The thicker zinc layer (85 microns minimum to AS/NZS 4680) provides significantly better protection at the cost of slightly reduced dimensional precision.

Zinc-plated mild steel is not suitable for permanently wet, coastal, food-processing or chemical environments. In those applications, specify stainless steel.

Grade 316 Stainless Steel

The correct choice for marine, coastal, food-processing and chemical-processing environments. Grade 316 contains 2–3% molybdenum, which provides significantly better pitting and crevice corrosion resistance than Grade 304 in the presence of chlorides — including seawater, salt-laden coastal air and chlorinated cleaning solutions. If a clevis pin is used in rigging on a boat, near a harbour, in carwash equipment, in seafood processing, in coastal outdoor applications or in any chemical plant with halide exposure, Grade 316 is the minimum acceptable specification.

Tensile strength of 316 stainless is typically 515–690 MPa depending on temper and form — comparable to Grade 4.6 mild steel for most clevis pin applications. The significant benefit is corrosion resistance, not strength.

Do not substitute Grade 304 for Grade 316 in saltwater or chloride environments. Crevice corrosion and pitting failure in Grade 304 clevis pins used in marine rigging is a documented failure mode that can lead to pin seizure, fracture or the inability to disassemble the joint.

Grade 304 Stainless Steel

Suitable for general corrosion resistance in non-marine, non-chloride environments. Commonly used in food-preparation areas where cleaning agents are mild (no chlorine-based sanitisers), in refrigeration equipment, in light outdoor applications not subject to salt exposure, and in chemical environments where chlorides are absent. Grade 304 is significantly cheaper than Grade 316 and is adequate for many industrial applications, but its chloride corrosion resistance limit must be respected.

High-Tensile Steel (Grade 8.8 Equivalent and Above)

Used where a clevis pin is load-rated and the shear strength of a standard DIN 1444 Grade 4.6 equivalent pin is insufficient for the application. Lifting shackle pins, clevis shortening hooks, crane rigging hardware and rated agricultural drawbar connections use high-tensile or alloy steel pins with defined Working Load Limits (WLL). These are not general-purpose DIN 1444 pins — they will have a WLL, grade marking and/or traceability number stamped on them. They must be used within their rated limits and must not be substituted with standard commercial clevis pins.

AIMS stocks rated clevis lifting hardware (Grade 80 and Grade 100 clevis hooks and master links) as separate products from the standard DIN 1444 pin range. If you are selecting a pin for a safety-critical or load-rated lifting application, contact AIMS to confirm the correct rated product.

Retention Methods

Split Pin (Cotter Pin)

The most common retention method for DIN 1444 Form B clevis pins. A split pin — also called a cotter pin in American usage — is inserted through the cross-hole and the two legs are spread outward (typically at 90° to each other, with one leg bent back) to resist withdrawal. The split pin provides positive, visible retention: if the split pin is missing, the joint is immediately identifiable as unretained.

Split pins are one-use items — once bent, they must be replaced on reassembly. Attempting to re-use a bent split pin risks fatigue fracture of the leg during or after installation. Always carry spare split pins of the correct diameter when working on agricultural or industrial equipment in the field. See the Split Pin & Cotter Pin Guide for full sizing, types and installation guidance. Size the split pin to the cross-hole diameter in the DIN 1444 specification for the pin diameter.

R-Clip (Hairpin Cotter / Lynch Pin)

A spring-steel wire formed into an R or hairpin profile that clips through the cross-hole and springs outward to resist withdrawal. Tool-free installation and removal — the key advantage over split pins in applications where the joint is frequently adjusted: agricultural implement depth settings, drawbar length adjusters and toolbar connection points. R-clips are reusable through many cycles.

R-clips must be inspected regularly and replaced when fatigued. A correctly tensioned new R-clip provides substantial retention force from the spring action; a worn, flattened or permanently deformed R-clip may fall out of the cross-hole under vibration. R-clips are the correct choice for frequently adjusted connections, but are not the right choice where positive, tamper-evident retention is required and the joint is rarely disassembled.

Wire Lock Pin (Safety Pin)

A solid pin body with an integrated spring-wire lock. The wire passes through the cross-hole and locks automatically. Provides secure, vibration-resistant retention while remaining tool-free for removal. Used on lifting equipment, safety-critical pivot connections and applications where an R-clip may vibrate loose under sustained cyclic loading. The wire lock must be fully seated in the cross-hole to be effective — inspect before use.

Nut and Washer (Threaded-End Pins)

For threaded-end clevis pins, a standard or nyloc nut with a flat washer provides the retention. The nut should be tightened to a snug fit that eliminates axial float — not torqued hard, as over-tightening binds the joint and generates lateral side loads on the pin. Use a nyloc nut wherever vibration is present to prevent self-loosening. In high-vibration applications, a castle nut with a split pin through a drilled shank may be the most reliable option.

Roll pins serve a different retention function — they lock a component to a shaft by interference fit rather than retaining a pin against withdrawal. For gear, sprocket, and lever retention on rotating shafts using a spring steel roll pin, see the Roll Pin (Spring Pin) Guide.

Agricultural and Heavy Equipment Applications

Clevis pins are among the most frequently replaced consumable fasteners in Australian agricultural and construction equipment. The high-cycle loading of three-point linkage connections, hydraulic top link attachments and drawbar links causes progressive wear in both the pin and the clevis ears, typically appearing as a loose, rattling joint before connection failure.

Three-Point Linkage (3PL) Pins

Australian tractor manufacturers generally follow the ASAE/ISO Category system for three-point linkage pin dimensions. These are commonly referred to as Cat 1, Cat 2 or Cat 3 pins in Australian rural supplies:

• Category 1: Lower link pin 22.4mm diameter, top link pin 19.3mm diameter. Suits compact and mid-range tractors.
• Category 2: Lower link pin 28.7mm diameter, top link pin 25.5mm diameter. Suits medium to large farm tractors.
• Category 3: Lower link pin 37.4mm diameter, top link pin 31.8mm diameter. Suits large four-wheel drive tractors and high-horsepower implements.

Standard Australian rural supply outlets stock pins to these specifications in mild steel (zinc or galvanised), Grade 316 stainless, and hardened steel for high-wear applications. Category pins are retained by R-clips or lynch pins in almost all field applications for ease of implement changeover.

Hydraulic Cylinder Connections

Hydraulic cylinder rod-end and base-end clevis connections use shoulder or headless pins in most designs. The pin diameter is specified in the cylinder's engineering data and must be matched exactly — an undersized pin will wear rapidly under the side-loading from cylinder force vectors. On excavators, loaders and agricultural hydraulic systems, these pins are designed as replaceable wear items with defined service intervals. Hardened or case-hardened pins are preferred in high-cycle applications to extend service life.

Drawbar and Towing Connections

Drawbar clevis connections on trailers and agricultural equipment use larger-diameter pins (typically 16–32mm) and must be selected to carry the drawbar tongue weight and dynamic tow loads. In transport applications subject to Australian Road Rules requirements, the pin and clevis assembly must meet the coupling rating (typically expressed as a D-value or tow rating in the vehicle or equipment certification). Do not substitute a lighter pin for a rated tow coupling pin.

Marine and Rigging Applications

Clevis pins in marine rigging are a specialised application with requirements distinct from general industrial use. Wire rope terminations (swaged fittings, Sta-Lok, Norseman), turnbuckle jaw ends and chainplates all rely on clevis pins that must meet a different standard:

• Material without exception: Grade 316 stainless steel in all saltwater environments. Grade 304 is not acceptable.
• Retention: In standing rigging, clevis pins are typically retained with a stainless split ring (cotter ring) rather than a split pin, to prevent sharp bent-leg ends from snagging sails, lines or crew. Some class rules and manufacturers specify a specific retention method — check the rig specification before changing pin or retention type.
• Dimensional match: Marine clevis fittings are designed to a specific pin diameter and the WLL is rated for that exact diameter. Do not mix pin diameters across a fitting family.
• Inspection interval: Standing rigging clevis pins should be inspected at each annual rig inspection and whenever the rig is unstepped. Look for pitting, crevice corrosion at the pin-to-fitting interface, surface blistering and any visible bending of the pin shank.

Clevis pins in load-rated rigging hardware — bow shackles, dee shackles, clevis shortening hooks, master links — are purpose-designed components with defined WLLs and are not interchangeable with standard DIN 1444 pins. See the Bow Shackle Guide for load-rated rigging hardware. For turnbuckles with jaw (clevis) ends, see the Turnbuckle Guide.

Clevis Pin Inspection and Maintenance

Clevis pins are wear items. In high-cycle or abrasive applications, periodic inspection and timely replacement prevents joint failure and the associated downtime and safety risk.

What to Inspect

• Pin diameter wear: Measure the pin at the primary shear plane (midpoint between the clevis ears, where loading is concentrated). More than 5% reduction from nominal diameter is cause for replacement. For a 12mm pin, that is 11.4mm — visible with a vernier caliper.
• Flats and grooving: A pin that has been prevented from rotating (by a too-tight fit or a seized cross-hole) will develop wear flats on one side. A grooved or flatted pin should be replaced even if the diameter reduction is less than 5%, as the remaining section at the wear flat may be below the load-bearing minimum.
• Cross-hole condition: Check that the cross-hole is clear, the edges are not mushroomed, and a new split pin or R-clip will seat correctly. A mushroomed cross-hole mouth prevents proper split pin installation and is a sign of previous incorrect assembly (oversized split pin forced through).
• Clevis ear condition: Inspect the clevis bracket holes as well as the pin. An oval hole (worn from round) accelerates further pin wear and may allow the pin to shift laterally under load. A mildly oval hole can sometimes be reamed to the next standard size up with a matching larger pin; a severely worn or cracked clevis ear requires bracket replacement.
• Corrosion: Surface rust on zinc-plated pins is cosmetic; pitting that has reduced the shank cross-section is cause for replacement. In stainless pins, look for crevice corrosion (dark discolouration at the pin-to-fitting interface) and pitting in the shank. Do not abrade or polish away pitting — replace the pin.

Lubrication

Clevis pins in rotating or oscillating applications benefit from periodic lubrication. A light application of general-purpose grease at assembly reduces friction-induced wear and helps prevent fretting corrosion at the shear plane. In agricultural equipment, a grease nipple in the clevis ear body is common practice on high-wear connections. In marine applications, anti-seize compound (not grease) on stainless pins prevents galling during assembly and reduces crevice corrosion risk at the pin-fitting interface.

How to Choose the Right Clevis Pin

Follow these steps to select the correct clevis pin for any application:

Step 1 — Determine the required diameter

Measure the hole diameter in the clevis ears with a vernier caliper. The pin diameter should be a close sliding fit — for a DIN 1444 h11 tolerance pin in a standard H12 clevis hole, there will be approximately 0.1–0.3mm clearance. If the clevis hole has worn oval, ream it to the next standard size up and fit a correspondingly larger pin.

Step 2 — Determine the required grip length

Measure the combined thickness of both clevis ears and the mating component at the pin centreline. The grip length of the pin (from head underside to cross-hole centre) should equal this combined thickness, plus 3–5mm to allow the split pin or R-clip to be fitted clear of the outer ear face. If the mating component has a boss or bearing surface that floats axially on the pin, account for the full float range when calculating the required grip length.

Step 3 — Select the pin form

For most agricultural, industrial and maintenance applications: DIN 1444 Form B (drilled cross-hole) with split pin or R-clip. For frequently adjusted connections (implement depth settings, drawbar adjusters): Form B with R-clip. For hydraulic cylinder rod and base-end connections: shoulder/headless type to match the cylinder specification. For adjustable implement toolbar connections: multi-hole type.

Step 4 — Select the material

General industrial or agricultural in sheltered conditions: mild steel zinc-plated. Exposed outdoor agricultural in wet conditions: hot-dip galvanised. Coastal, marine, food-processing or chemical environments: Grade 316 stainless. Load-rated lifting or structural: rated clevis pin to WLL specification — not a DIN 1444 commercial pin.

Step 5 — Select the retention method

Infrequent assembly, safety-critical: split pin (positive, one-use, cheap). Frequent field adjustment: R-clip (reusable, tool-free). High-vibration with infrequent adjustment: wire lock pin or castle nut + split pin. Size the split pin or R-clip to the cross-hole diameter in the DIN 1444 specification for the selected pin diameter — these are directly correlated and documented in the standard.

How to Identify a Replacement Clevis Pin

When the original pin has been lost, worn beyond recognition or the equipment documentation is unavailable, use this procedure:

1. Measure the clevis hole diameter with a vernier caliper — measure at two points 90° apart to check for oval wear. If the hole is oval, the measurement at the minor axis (smallest diameter) is your target pin size. Record in millimetres.
2. Measure the clevis ear thickness on each ear individually, and the thickness of the mating component. Add these three measurements together for the required grip length (plus the 3–5mm cross-hole clearance allowance).
3. Check the cross-hole position on any remaining section of the old pin — the distance from the tip of the shank to the cross-hole centre tells you whether the grip length calculation is correct.
4. Determine metric or imperial — if the clevis hole measures exactly 9.5mm, 12.7mm, 15.9mm or another imperial inch-fraction equivalent, you are dealing with an imperial-specification fitting. Cross-reference with the imperial size table above.
5. Identify the correct material from the operating environment — marine, coastal or food-processing environment specifies Grade 316 stainless. General industrial or agricultural specifies zinc-plated mild steel unless extended corrosion resistance is needed.
6. Check the retention end geometry — confirm whether the original pin had a drilled cross-hole (DIN 1444 Form B), a threaded end, a snap-ring groove or a different retention feature. Do not fit a Form B pin into an assembly designed for a threaded-end pin without understanding why the design specified threaded retention.

If you are unsure after measuring, bring the worn pin (or the clevis ear assembly if it can be removed) to the AIMS counter. Our team can cross-reference to the correct stocked size and confirm material specification.

Clevis Pins at AIMS Industrial

AIMS stocks a comprehensive range of clevis pins for general industrial, agricultural and maintenance applications across Australia:

• DIN 1444 Form B metric clevis pins in mild steel zinc-plated — M5 through M30, standard length range
• Grade 316 stainless steel clevis pins — metric sizes M6 through M20
• Imperial clevis pins — 3/16" through 3/4" diameter for maintenance of older US and British-origin equipment
• Champion CPMH01 multi-hole clevis pins for adjustable implement connections
• Matching R-clips (hairpin cotters / lynch pins), split pins and wire lock pins

View the full clevis pin range at AIMS Industrial →

For volume orders, agricultural fleet pin kits, non-standard lengths or help identifying a replacement, contact the AIMS team on (02) 9773 0122 or via the contact page — we carry the reference material to match most applications.

Frequently Asked Questions

What is a clevis pin?

A clevis pin is an unthreaded cylindrical fastener that passes through a U-shaped clevis bracket and a mating component to create a pivoting joint. It is retained at one end by a split pin, R-clip or nut. Unlike a bolt, a clevis pin allows free rotation between the connected parts, making it the correct choice for joints that experience cyclic movement, oscillation or angular displacement under load.

What is the difference between a clevis pin and a cotter pin?

A clevis pin is the main cylindrical fastener that passes through the joint and carries the load. A cotter pin (split pin) is the retaining device inserted through the cross-hole at the end of the clevis pin to prevent it backing out. They work as a pair — the clevis pin carries the shear load; the cotter pin holds it in place. See the Split Pin & Cotter Pin Guide for full cotter pin sizing and selection.

What is another name for a clevis pin?

Clevis pins are called hitch pins, drawbar pins, pivot pins or implement pins in Australian agricultural usage. The retaining device may be called a split pin, cotter pin, R-clip, lynch pin or hairpin cotter depending on type and region. In marine rigging the clevis pin may simply be called a rigging pin.

Is a clevis pin stronger than a bolt?

Strength depends on diameter, material and grade — there is no universal answer. A standard DIN 1444 mild steel clevis pin (Grade 4.6 equivalent) is weaker in shear than a Grade 8.8 bolt of the same diameter. However, clevis pins are designed to operate in double shear and perform well in that loading mode. The correct question is whether the selected clevis pin is appropriately rated for the shear load in the joint — size, material and form matter more than a bolt comparison.

What size clevis pin do I need for a Category 1 three-point linkage?

Category 1 (ISO 730 / ASAE S217) lower link pins are 22.4mm diameter; the top link pin is 19.3mm diameter. For Category 2 (larger tractors), lower link pins are 28.7mm and top link is 25.5mm. Category 3 uses 37.4mm lower link pins. These are sold as 'Cat 1', 'Cat 2' and 'Cat 3' pins in Australian rural supplies and farm machinery outlets.

What is the difference between an R-clip and a split pin for a clevis pin?

A split pin (cotter pin) is a single-use, positively retained fastener that is bent through the cross-hole — secure, tamper-evident, but requires tools and must be replaced every time the pin is removed. An R-clip (lynch pin) is a reusable spring-steel wire clip that inserts and removes tool-free, ideal for connections adjusted regularly in the field. For safety-critical or infrequently serviced joints, use a split pin. Inspect R-clips regularly for fatigue and replace if flattened or deformed.

What does DIN 1444 mean on a clevis pin?

DIN 1444 is a German dimensional standard (widely adopted internationally) that specifies the nominal diameter, tolerance class (h11), cross-hole diameter and position, and head dimensions for clevis pins. Form A has no cross-hole; Form B has a drilled cross-hole for a split pin or R-clip. Purchasing to DIN 1444 ensures dimensional interchangeability with DIN 1444-compliant clevis hardware regardless of manufacturer.

Can I use a Grade 304 stainless clevis pin in a marine environment?

No — Grade 304 stainless is not suitable for direct saltwater or coastal marine use. It lacks the molybdenum content of Grade 316 and is susceptible to pitting and crevice corrosion in chloride environments. Grade 316 stainless is the correct specification for marine, coastal, offshore and food-processing applications where chlorides are present. In fresh water or sheltered inland environments with no chloride exposure, Grade 304 is acceptable.

What is a multi-hole clevis pin used for?

A multi-hole clevis pin has several cross-holes along the shank at fixed intervals, allowing the effective engagement depth to be adjusted without removing the pin. Widely used on agricultural implement depth wheels, height adjusters and toolbar connection points where the operator needs quick incremental adjustment in the field without a toolkit. The Champion CPMH01 is a commonly stocked example in Australia.

How do I measure a clevis pin?

Measure the shank diameter with a vernier caliper at the midpoint of the shank (away from head and cross-hole). Measure overall length from head underside to shank tip. For grip length, measure from head underside to the centreline of the cross-hole. When sizing a replacement, always measure the clevis hole diameter (not the worn pin) — worn pins understate the required size. Measure the hole at two points 90° apart to check for oval wear.

Where are clevis pins used?

Common Australian applications include tractor three-point linkages and drawbars, hydraulic cylinder rod-end and base-end connections, conveyor and production machinery pivot arms, trailer coupling connections, agricultural implement depth and position adjusters, rigging and lifting hardware (rated versions), marine wire rope fittings, turnbuckle jaw ends, and structural tie-rod connections.

What is a headless (shoulder) clevis pin used for?

A headless clevis pin is used where there is no clearance for a conventional domed head on the entry side of the joint, or where the pin must insert from either direction. Hydraulic cylinder rod-end pins are the most common application — the pin is retained by a snap ring (circlip) in a groove in the clevis ear rather than by a head. Also used in precision machinery pivots where head clearance above the clevis ear is restricted by an adjacent component.