Henkel® LOCTITE® 3D IND406

Hair-Dryer-Attatchment-IND406 Loctite

Henkel® LOCTITE® 3D

IND406 HDT100

Exceptional performance in high-temperature resistance industrial applications

LOCTITE® 3D IND406 is a photopolymer 3D printing resin designed for DLP 3D printers. It offers an all-around strength, impact resistance, heat-resistance, and elongation making it an ideal candidate for parts that may be made with traditional injection molding polymers like ABS and polypropylene.

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3D print injection molded quality parts  

LOCTITE® IND406 is a rigid resin designed for interior applications in automotive, tooling and molds due to its high surface quality, dimensional accuracy and temperature resistance. The unique set of performance attributes makes it comparable to ABS. 3D printed parts can be machined, tapped or polished.

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Radio faceplate cover_ind406

Why choose LOCTITE® IND406?

 

  • Basic compatibility is achievable (ISO 10993 -5/-23 passed)
  • High heat deflection temperature, HDT >100°C
  • Tough and durable
  • Good surface finish
  • LOCTITE® IND406 formula can be made in additional pigment colours other than white & clear.

Automotive Shroud_Loctite IND406

Applications & Industries

Proto3000_Icon_Transportation_Truck

Automotive

Interior applications & components

Proto3000_Icon_Jigs Fixtures

Industrial & Manufacturing

Tooling & Molds

Proto3000_Icon_Consumer Product

Consumer Goods

Radio faceplate cover_ind406

Radio Faceplate Cover

Material: LOCTITE® IND406

This radio faceplate cover is used to cover a car radio.

Technology/Process
  • Digital Light Processing, DLP

Hair-Dryer-Attatchment-IND406 Loctite

Hair Dryer Attachment

Material: LOCTITE® 3D IND406

This is a hairdryer attachment used to concentrate hot airflow.

Technology/Process
  • Digital Light Processing, DLP

inner fan-piece IND406_LOCTITE

Inner Fan Piece

Material: LOCTITE® 3D IND406

The inner fan pieces are used to control the air flow in the automotive vent.

Technology/Process
  • Digital Light Processing, DLP

Material Properties

Proto3000_Icons_Tensile Strength

TENSILE STRESS AT BREAK

55 MPa

Proto3000_Icons_Tensile Modulus

YOUNG’S MODULUS

1610 MPa

Proto3000_Icons_Elongation at Break

ELONGATION AT BREAK

25%

Proto3000_Icons_Hardness

SHORE HARDNESS

Shore D, 79

Performance Scale

Heat Deflection
Toughness
Surface Finish

Colours

hex Black
hex White
hex Clear
hex Custom Pigment

Additive Manufacturing with Light

Discover the speed, throughput, and material capabilities of the
Digital Light Processing (DLP) 3D printing process

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Related Resources

Technical Specifications 

Tensile Stress at Break, ASTM D638
Tensile Stress at Break, ASTM D638
Green: 18.5 ± 1.9 MPa
Post-processed: 51.5 ± 0.8 MPa
Young's Modulus, ASTM D 638
Young's Modulus, ASTM D 638
Green: 449 ± 38 MPa
Post-processed: 1658 ± 89 MPa
Elongation at Break, ASTM D638
Elongation at Break, ASTM D638
Green: 42.4 ± 4.5 %
Post-processed: 24.3 ± 2.2 %
Notched Impact (Izod), ASTM D256
Notched Impact (Izod), ASTM D256
Green: 75.0 ± 4.0 J/m
Post-processed: 35 ± 8 J/m
Heat Deflection Temperature, HDT @ 0.455 MPa, ASTM D648
Heat Deflection Temperature, HDT @ 0.455 MPa, ASTM D648
Green: N/A
Post-processed: 108.2 ± 0.4°C
Shore Hardness D, ASTM D2240
Shore Hardness D, ASTM D2240
Green: 56.9 ± 0.8
Post-processed: 79.2 ± 0.8
Viscosity @ 25°C (77°F), ASTM D7867
Viscosity @ 25°C (77°F), ASTM D7867
Post-processed: 1063 cP

*Material properties may vary depending on the DLP printer and post-curing unit.