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Product Engineering Reference

Threaded Inserts

A comprehensive engineering reference for mechanical design engineers, OEM manufacturers, aerospace and automotive teams — covering threaded insert types, installation methods, pull-out and torque-out capacity, substrate compatibility, dimensional standards and full project documentation for helical wire inserts, solid bushings, press-in inserts, heat-set and moulded-in variants.

Heli-Coil / STI / Keensert M2 – M36 / #2 – 1-1/2" Al · Steel · CFRP · Plastic · Wood SS 304/316 · Brass · Bronze · Ti Press · Heat-Set · Heli-Coil · Moulded EN 10204 3.1 MTC
Threaded Inserts by RR Hydraulics
800+
SKUs in Stock
M2–M36
Thread Range
8+
Insert Types
8+
Substrate Types
10+
Material Grades
48 hr
Express Dispatch
Part 01

Threaded Insert Types,
Installation Methods & Holding Mechanics

Threaded insert types and installation methods
Part 01 — Types, Installation Methods & Holding Mechanics
Helical Wire · Solid Bushing · Press-In · Heat-Set · Moulded-In
Aluminium · Plastic · CFRP · Timber · Sheet Metal
Threaded Insert · Heli-Coil · STI Insert · Keensert · E-Z Lok · Press-In Insert · Heat-Set Insert · Ultrasonic Insert · Moulded-In Insert · Self-Tapping Insert · Thread Repair · Pull-Out Capacity · 

Definition and Engineering Function

A threaded insert is a fastener installed into a parent material to provide a strong, durable internal thread that is superior to a thread cut directly in the parent material. Threaded inserts serve three primary engineering purposes: (1) Thread reinforcement — providing a high-strength thread in a soft or weak parent material (aluminium, magnesium, plastics, timber) that cannot develop adequate thread strength by direct tapping; (2) Thread repair — restoring stripped or damaged threads in a parent material to full or greater-than-original strength without replacing the parent component; and (3) Thread conversion — enabling a different thread standard (e.g. metric in an inch-threaded housing, or a coarser thread from a finer original) to be used in an existing tapped hole.

The critical engineering advantage of a threaded insert is that it transfers the bolt load from the weak parent material thread-engagement zone to a larger bearing area on the insert body, which then distributes that load over a greater contact area in the parent material. A well-specified helical wire insert in aluminium, for example, develops the full proof load of a standard Grade 8.8 bolt — a load that would strip the soft aluminium thread by a wide margin if the bolt were threaded directly.

Engineering Principle — Thread Strip vs Insert Pull-Out

There are two independent failure modes for an inserted thread connection that must both be checked: (1) Thread strip — the internal thread of the insert strips under bolt torque load; and (2) Pull-out / torque-out — the insert body is pulled or rotated out of the parent material. The insert material and thread form control mode (1); the insert's external geometry, engagement length and parent material properties control mode (2). A well-designed insert system ensures that the bolt shank fractures (ductile steel failure) before either mode (1) or mode (2) occurs — this is the design objective for safety-critical threaded insert joints in aerospace and automotive applications.

Request a Formal Quotation — Threaded Inserts, All Types & Substrates
Helical / Solid / Press-In / Heat-Set · M2–M36 · SS / Brass / Bronze / Ti · EN 10204 MTC

Threaded Insert Types — Engineering Descriptions

Helical Wire Insert (Heli-Coil)
AS8879 · MIL-I-8846 · STI tapped hole
A coil of diamond-section stainless steel wire wound into a helix that screws into a special STI (Screw Thread Insert) tapped hole slightly larger than the nominal thread. The coil diameter is slightly larger than the tapped hole, so it contracts radially when installed, gripping the parent thread. The inner surface of the coil forms the standard thread profile. Provides full bolt-load strength in aluminium, magnesium, titanium and soft materials. Locking variants include a tang that is broken off after installation. Standard for aerospace, defence, automotive and general engineering thread repair.
Solid Bushing Insert (Keensert)
Keensert · Ensat · E-Z Lok
A solid cylindrical insert with an internal thread and an externally threaded or knurled body. Installed into a tapped or drilled/reamed hole. Locking Keenserts have hardened serrated keys on the flange that are driven into the parent material after installation, providing high torque-out resistance without adhesive. Provides the highest pull-out strength of all insert types. Suitable for high-load structural applications in aluminium alloys, steel, stainless and titanium substrates. Preferred for aerospace structural connections.
Press-In / Knurled Insert
DIN 16903 · Brass / SS
A cylindrical insert with an internal thread and a knurled or ribbed external body. Pressed into an undersize hole in the parent material — the knurls displace parent material into the ribs or grooves as the insert is pressed home, providing pull-out and torque-out resistance. Used in aluminium castings, sintered metals and thermoplastics (cold-pressed). Available in brass, stainless steel and aluminium. Simple installation requiring only a press or arbor; no heat, tap or adhesive.
Heat-Set / Ultrasonic Insert
DIN 16903 · Brass · thermoplastics
A brass (or SS) insert with knurled or ribbed external profile installed into a moulded or drilled hole in a thermoplastic substrate using a heated tip (heat-set) or ultrasonic horn (ultrasonic). The thermal or ultrasonic energy locally melts the plastic around the insert body; as it cools and re-solidifies, the plastic flows into the external knurling, creating an extremely strong mechanical interlock. Produces the highest pull-out strength possible in thermoplastic substrates. Standard for injection-moulded electronics enclosures, automotive interior panels, consumer products and medical devices.
Moulded-In Insert
Injection moulding · overmoulding
Insert placed in the injection mould tool before the plastic shot is injected. The plastic flows around and keys into the insert's external features (grooves, knurls, flanges) as the part is moulded. Produces the highest possible retention strength in a moulded plastic part because the plastic is mechanically interlocked with the insert on all surfaces simultaneously. No secondary operation required. Used in high-volume production where insert installation cycle time must be eliminated. Insert design must account for mould temperature and pressure.
Self-Tapping Insert
Ensat · aluminium / steel / wood
An insert with an aggressive external thread that cuts or forms its own thread in the parent material as it is driven in with a hex driver or Allen key. No pre-tapping of the hole required — only a drilled hole of the specified diameter. Used in aluminium castings, steel fabrications, timber and engineered wood, and dense plastics. Available with straight-drive or hammer-drive installation. Produces higher pull-out strength than a directly tapped thread in the same material due to the cold work and displaced material compaction around the external thread flanks.

Substrate Compatibility by Insert Type

Aluminium / Magnesium
Helical wire (best strength-to-weight); solid bushing (Keensert for structural); press-in knurled; self-tapping. Heat-set not applicable (metal substrate).
Thermoplastics (ABS, PA, PC, PP)
Heat-set or ultrasonic (highest strength); press-in cold (moderate); moulded-in (highest, production only). Self-tapping for soft or thick sections.
CFRP / GFRP Composites
Helical wire (preferred — no stress concentration); solid bushing with adhesive; press-in (with care — risk of delamination). Self-tapping not recommended.
Timber / Engineered Wood
Self-tapping thread inserts (hammer or hex drive); barrel nut inserts (furniture construction); helical wire for dense hardwoods; press-in with adhesive for soft woods.
Part 02

Dimensions, Engagement Length
& Pull-Out and Torque-Out Capacity

Threaded insert dimensional data and load capacity
Part 02 — Dimensions, Engagement Length & Load Capacity
Helical Wire · Solid Bushing · Press-In · STI Drill & Tap
Pull-Out · Torque-Out · 1.0D · 1.5D · 2.0D
STI Tap Size · Insert OD · Insert Length · Engagement 1.0D · 1.5D · 2.0D · Pull-Out Force · Torque-Out · Aluminium 6061 · Steel 1020 · PA66 · Locking Tang · 
Sourcing Threaded Inserts for an OEM or Repair Application?
All types · M2–M36 · SS / Brass / Bronze · Aerospace / automotive / plastic grades

Helical Wire Insert — STI Tap Sizes & Engagement Lengths

Table 1 — Helical Wire Insert Key Dimensions: Thread Size, STI Tap Drill & Insert OD
Internal ThreadSTI Tap Size (mm)STI Drill Dia. (mm)Insert OD (mm)1.0D Length (mm)1.5D Length (mm)2.0D Length (mm)
M33.63.43.63.04.56.0
M44.74.54.74.06.08.0
M55.95.65.95.07.510.0
M67.06.77.06.09.012.0
M89.39.09.38.012.016.0
M1011.511.211.510.015.020.0
M1213.913.513.912.018.024.0
M1618.417.918.416.024.032.0
M2022.822.322.820.030.040.0

Dimensions per NAS1130 / AS8879 / Heli-Coil standard. STI Tap size is the major diameter of the special Screw Thread Insert tap required — do NOT use a standard metric tap for helical wire insert installation holes. The STI tap creates a thread slightly larger than nominal to accommodate the insert body diameter. Insert length is expressed as a multiple of the nominal thread diameter (1.0D, 1.5D, 2.0D). 1.5D is the most common — providing full bolt proof load in aluminium and most soft metals. 2.0D recommended for high-load cyclic applications and materials weaker than Al 6061-T6.

Table 2 — Indicative Pull-Out Capacity: Helical Wire Insert (M8, 1.5D = 12 mm) in Various Substrates
Substrate MaterialTensile Strength (MPa)Pull-Out Force (kN)Torque-Out (N·m)Bolt Grade for Full Load
Al 6061-T631012.528Grade 8.8 achievable
Al 5052-H322289.220Grade 8.8 marginal — use 2.0D
Al 380 Die Cast32413.030Grade 8.8 achievable
Low Carbon Steel40028.055Grade 10.9 achievable
Nylon PA66 (30% GF)1804.58Grade 4.6 only
ABS (unreinforced)451.22Low load only
CFRP UD Laminate600+ (0°)18.0**interlaminar shear governs

Indicative values for SS 304 helical wire insert, 1.5D engagement, adhesive-free installation. Actual pull-out capacity depends on insert length, substrate alloy and heat treatment, installation quality (correctly torqued STI tap, clean hole), and whether locking adhesive (Loctite 638) was applied. For CFRP composites, interlaminar shear strength governs — not tensile strength — and specific testing on the actual laminate is required. All values are characteristic (without safety factor) — apply design safety factor of 2.0 minimum for safety-critical joints.

Minimum Insert Engagement Length for Full Bolt Proof Load L_min = F_proof / (π × d × τ_substrate) // Min engagement length [mm]; F_proof = bolt proof load [N]
τ_substrate 0.577 × σ_y_substrate // Von Mises shear yield of substrate material [MPa]

// WORKED EXAMPLE: M8 Grade 8.8 bolt (F_proof = 22,100 N), Al 6061-T6 (σ_y = 276 MPa)
τ = 0.577 × 276 = 159 MPa
L_min = 22,100 / (π × 8 × 159) = 5.53 mm = 0.69D // Minimum for shear — specify 1.5D (12 mm) for margin
Part 03

Material Grades, Substrate Compatibility
& Corrosion Considerations

Threaded insert material grades and substrates
Part 03 — Materials, Substrates & Corrosion
SS 304 · SS 316 · Phosphor Bronze · Brass · Titanium
Aluminium · Steel · CFRP · Thermoplastic · Timber
SS 304 · SS 316 · Phosphor Bronze · Brass CuZn · Beryllium Copper · Titanium Gr.5 · Carbon Steel · Aluminium · Steel · CFRP · ABS · PA66 · Timber · Galvanic Corrosion · 
Table 3 — Material Grades for Threaded Inserts
MaterialStandardHardnessCorrosionGalvanic Risk in Al?Best Application
SS 302/304 (1.4300)ASTM A313 / AS8879~35 HRC (spring)HighModerateStandard helical wire; most industrial applications
SS 316 (A4)EN 10151~30 HRCVery HighModerateCoastal, offshore, chemical, food-grade inserts
Phosphor Bronze (CuSn6)BS 2873 PB101~25 HRCGoodLowMarine Al structures; electronics; non-magnetic
Brass CuZn37DIN 17660~15 HRCGoodLowHeat-set in plastics; press-in; non-sparking
Beryllium Copper (CuBe2)ASTM B197~40 HRCVery HighLowATEX/non-sparking; aerospace; high strength
Titanium Gr.5 (Ti-6Al-4V)ASTM F1472~36 HRCExtremeVery LowAerospace structural; CFRP; weight-critical
Carbon Steel (hardened)ISO 898-142–50 HRCLowHighSteel substrates only; not for aluminium or marine
Aluminium 6061-T6ASTM B209~55 HRBGoodZero (matched)Weight-saving self-tapping inserts in Al castings
Galvanic Corrosion Warning — Insert Material vs Substrate

When a threaded insert is installed in aluminium or magnesium, the galvanic potential difference between the insert material and the substrate must be evaluated. Standard SS 304 helical wire inserts in aluminium have a moderate galvanic potential difference but the very small contact area of the wire coil (which limits corrosion current) and the protection of the enclosed installation environment make this combination acceptable for most applications with appropriate surface treatment. Carbon steel inserts in aluminium must never be used in any wet or outdoor environment — the galvanic couple accelerates corrosion of the aluminium at the insert boundary. For maximum galvanic compatibility in aluminium, specify aluminium inserts (self-tapping type) or phosphor bronze helical wire inserts. For CFRP substrates — which are electrically conductive and highly cathodic — titanium inserts are the only fully galvanically compatible metallic insert.

Part 04

Selection Guide, Applications
& Quality Control and Documentation

Threaded insert selection guide and applications
Part 04 — Selection Guide, Applications & QC Documentation
Aerospace · Automotive · Electronics · Medical · Thread Repair
Selection Matrix · Installation · QC · Documentation
Aerospace Al Structure · Automotive Powertrain · Electronics Housing · Medical Device · Thread Repair · CFRP Structure · Furniture · Consumer Products · 

Insert Selection Reference

Table 4 — Threaded Insert Selection Decision Matrix
SubstrateLoad RequirementInstallation MethodRecommended Insert TypeMaterial
Aluminium (structural)Full Grade 8.8+ bolt loadMachine shop — drill + STI tapHelical wire 1.5–2.0DSS 304 or Phosphor Bronze
Aluminium (structural)Very high / cyclicMachine shopSolid bushing (Keensert)SS 304 or Ti Gr.5
Aluminium (production)ModeratePress (production line)Press-in knurledSS 304 or Aluminium
MagnesiumFull bolt loadDrill + STI tapHelical wire 2.0DPhosphor Bronze (galvanic compat.)
SteelThread repairDrill + STI tapHelical wire 1.0–1.5DSS 304
CFRP / GFRPStructural bolt loadDrill + STI tap + adhesiveHelical wire 2.0DTitanium Gr.5
Thermoplastic (ABS/PA/PC)Moderate (production)Heat-set / ultrasonicHeat-set knurled insertBrass
Thermoplastic (high volume)Moderate (moulded)In-mould (no secondary op.)Moulded-in insertBrass or SS
Timber / MDF / PlywoodLight–moderateHex driver or hammerSelf-tapping or barrel nutZinc alloy or SS
Sheet metal (<3 mm)Pull-through retentionPress from rearPEM / thinwall press-inSS 304 or CS

Applications by Industry

Aerospace and Defence — Primary Application

Helical wire inserts per AS8879 (formerly MIL-I-8846) are the standard thread reinforcement method throughout aerospace aluminium and magnesium structures, engine accessory gearboxes, avionics racks, fuel system brackets and landing gear components. Every tapped hole in an aerospace aluminium structural component that will accept a Grade 8.8 equivalent (NAS/AN bolt) fastener is typically STI tapped and fitted with a helical wire insert as standard design practice. The insert prevents thread strip, provides corrosion-resistant threads in bare aluminium, and allows the thread to be replaced (by removing and re-installing a new coil) if damaged during maintenance — without scrapping the parent component. Solid bushing inserts (Keensert, Kato) are used for the highest-load structural applications where helical wire pull-out strength is insufficient.

Automotive Powertrain and Engine Components

Helical wire inserts in cast aluminium engine blocks, cylinder heads, gearbox cases and differential housings allow assembly with standard steel bolts and studs at full torque without risk of thread strip. Magnesium engine components (used extensively for weight reduction in high-performance vehicles) require phosphor bronze or nickel alloy inserts to minimise galvanic corrosion — standard stainless inserts are marginally acceptable in dry protected locations but phosphor bronze is preferred for any component exposed to coolant, oil or road salt. Self-tapping inserts (Ensat type) are used in aluminium die-castings during the casting post-machining stage, offering fast installation without a separate tapping operation.

Electronics and Consumer Products

Heat-set brass inserts in ABS, PC/ABS, nylon PA66 and polypropylene enclosures are the standard method for providing re-usable bolt connections in injection-moulded electronic housings, instrument enclosures, control panel bezels, laptop and tablet cases, medical device housings and consumer appliances. The heat-set insert allows the enclosure to be opened and re-closed multiple times with the same bolt without degrading the thread — a direct thread in plastic would strip after 2–5 insertion cycles. The design rule for heat-set inserts is to specify the insert boss OD (moulded outer cylinder holding the insert) as minimum 2.0× the insert OD to prevent boss cracking under installation heat and bolt preload.

CFRP / Composite Structures

Carbon fibre reinforced polymer (CFRP) composites require special care for threaded connections because the fibres are easily damaged by direct tapping (which severs the fibres) and by conventional press-in inserts (which can cause delamination). Helical wire inserts installed with structural adhesive (Loctite 638 or equivalent) in STI-tapped composite holes provide the most reliable connection — the adhesive supplements the mechanical engagement and seals the hole against moisture ingress into the laminate. Titanium inserts are mandatory for structural CFRP applications where the galvanic potential of stainless steel combined with the highly cathodic CFRP surface would cause accelerated corrosion of any adjacent aluminium structure. Oversizing the hole by the STI tap amount slightly redistributes the stress concentration around the tapped hole in the laminate, reducing interlaminar shear stress at the hole edge.

Thread Repair and Maintenance

Thread repair is the most economically critical application of helical wire inserts — a stripped threaded hole in an expensive casting, housing or structural member can be repaired to full or greater-than-original strength by drilling to the STI drill size, tapping with the STI tap, and installing the appropriate helical wire insert. The repair restores the original thread size and pitch, is invisible after installation, and does not require replacement of the parent component. The cost of a helical wire insert repair kit (drill, tap, inserts, installation tool) is a small fraction of the cost of a replacement casting or machined housing. Automotive workshops, aircraft MRO facilities, industrial maintenance teams and field service engineers routinely carry helical wire repair kits for M3–M16 and imperial equivalents.

Quality Control and Documentation

Threaded insert QC covers: (1) Dimensional inspection — wire diameter, coil OD (free state), internal thread gauge (Go/No-Go per ISO 1502), and insert length; (2) Material verification — PMI for stainless, phosphor bronze, titanium and exotic inserts; (3) Pull-out test — representative samples tested to failure in the specified substrate material with the specified engagement length — failure mode (pull-out vs thread strip vs bolt fracture) and failure load are recorded; (4) Torque-out test — resistance to rotation of the insert in the substrate under applied torque, critical for locking-type inserts (Keensert keys, locking coils); (5) Installation verification — for aerospace applications, STI tap inspection (tap wear, tap size gauge), correct installation tool and torque/position verification per the assembly procedure.

Export Packaging and Preservation

  • Threaded inserts packed in polypropylene bags by type, thread size, length and material, labelled with standard reference, internal thread, insert length, material grade and batch/lot number
  • Helical wire inserts particularly sensitive to tangles — do not pack loose in bulk bags; pack in individual counted trays or tube dispensers for production use
  • Brass heat-set inserts and press-in inserts packed in component trays for automated assembly line use — orientation as specified by the customer tooling
  • SS inserts in clean sealed bags; brass inserts wrapped or bagged to prevent tarnishing; carbon steel inserts with VCI for sea freight
  • MTC (EN 10204 3.1), dimensional inspection report, thread gauge certificate, pull-out and torque-out test report (where required), PMI report for SS/Ti/BeCu, and all project documents in waterproof envelope with each shipment
EPC & OEM Project Documentation Package — Threaded Inserts (9 Documents)
#DocumentStandard / ReferenceMinimum Requirement
01Material Test Certificate (MTC)EN 10204 3.13.1 for OEM / industrial; AS9100D for aerospace
02Dimensional Inspection ReportAS8879 / NAS1130 / DIN 16903Wire OD, free-state coil OD, insert length as mandatory chars
03Thread Gauge Certificate ISO 1502 / ASME B1.2Go/No-Go internal thread per lot; tolerance 4H6H confirmed
04Pull-Out Test ReportAS8879 / MIL-I-8846 / project spec.Failure load and mode in specified substrate material; required for structural
05Torque-Out Test ReportAS8879 / project spec.Required for locking inserts (Keensert, locking coil); torque-out value confirmed
06PMI Report (XRF / OES)Project specification100% of SS, phosphor bronze, Ti, BeCu and exotic material inserts
07Hardness Test ReportISO 6507 / ASTM E92Hardness range confirmed per material grade; required for spring-property inserts
08ISO 9001 / AS9100D CertificateISO 9001:2015 / AS9100DISO 9001 for industrial; AS9100D required for aerospace supply
09ISPM-15 Phytosanitary CertificateIPPC / FAOAll wood packing for international export
Manufacturer Capability — RR Hydraulics

RR Hydraulics manufactures and exports threaded inserts in all types — helical wire (AS8879 / NAS1130), solid bushing (Keensert / Ensat), press-in knurled, heat-set, self-tapping and barrel nut — in stainless steel SS 302/304 and SS 316, brass CuZn37, phosphor bronze, beryllium copper, titanium Grade 5, and aluminium. Thread sizes M2–M36 metric and #2–1-1/2" inch UNC/UNF. EN 10204 3.1 MTC, thread gauge certificates, pull-out and torque-out test reports, PMI reports, AS9100D supply capability for aerospace. 48-hour express dispatch on standard in-stock sizes.

Ready to Source Threaded Inserts for Your Application?
Submit a formal R.F.Q. · All types & substrates · sales@rrhydraulics.com · 24-hour response