HMC Electronics 45404 Loctite 454 Prism Instant Adhesive, Surface Insensitive, Porous Surfaces User Manual
Loctite
Technical Data Sheet
LOCTITE
®
454™
March
-
2010
PRODUCT DESCRIPTION
LOCTITE
®
454™
provides
the
following
product
characteristics:
Technology
Cyanoacrylate
Chemical Type
Ethyl cyanoacrylate
Appearance (uncured)
Clear to slightly cloudy gel
LMS
Components
One part - requires no mixing
Viscosity
High, thixotropic
Cure
Humidity
Application
Bonding
Key Substrates
Metals, Plastics and Elastomers
LOCTITE
®
454™ is designed for the assembly of difficult-
to-bond materials which require uniform stress distribution and
strong tension and/or shear strength. The product provides
rapid bonding of a wide range of materials, including metals,
plastics and elastomers. The gel consistency prevents
adhesive flow even on vertical surfaces. LOCTITE
®
454™ is
also suited for bonding porous materials such as wood, paper,
leather and fabric.
NSF International
Registered to NSF Category P1 for use as a sealant where
there is no possibilty of food contact in and around food
processing areas. Note: This is a regional approval. Please
contact your local Technical Service Center for more
information and clarification.
TYPICAL PROPERTIES OF UNCURED MATERIAL
Specific Gravity @ 25 °C
1.1
Flash Point - See MSDS
Casson Viscosity, 25 °C, mPa·s (cP):
Cone and plate rheometer
150 to 450
LMS
Viscosity, Brookfield - RVT, 25 °C, mPa·s (cP):
Spindle TC, speed 2.5 rpm, Helipath
*100,000 to 300,000
LMS
Spindle TC, speed 20 rpm, Helipath
*18,000 to 40,000
LMS
* Applies to material made in N. America
TYPICAL CURING PERFORMANCE
Under normal conditions, the atmospheric moisture initiates the
curing process. Although full functional strength is developed
in a relatively short time, curing continues for at least 24 hours
before full chemical/solvent resistance is developed.
Cure Speed vs. Substrate
The rate of cure will depend on the substrate used. The table
below shows the fixture time achieved on different materials
at 22 °C / 50 % relative humidity. This is defined as the time to
develop a shear strength of 0.1 N/mm².
Fixture Time, seconds:
Steel
60 to 210
Aluminum
3 to 10
Zinc dichromate
5 to 20
Neoprene
15 to 20
Rubber, nitrile
5 to 15
ABS
3 to 10
PVC
5 to 10
Polycarbonate
5 to 10
Phenolic
5 to 30
Wood (balsa)
<3
Wood (oak)
30 to 45
Wood (pine)
45 to 60
Chipboard
5 to 15
Fabric
15 to 30
Leather
105 to 150
Paper
7 to 15
Cure Speed vs. Bond Gap
The rate of cure will depend on the bondline gap. Thin bond
lines result in high cure speeds, increasing the bond gap will
decrease the rate of cure.
Cure Speed vs. Humidity
The rate of cure will depend on the ambient relative
humidity. The best results are achieved when the relative
humidity in the working environment is 40% to 60% at 22°C.
Lower humidity leads to slower cure. Higher humidity
accelerates it, but may impair the final strength of the bond.
Cure Speed vs. Activator
Where cure speed is unacceptably long due to large gaps,
applying activator to the surface will improve cure speed.
However, this can reduce ultimate strength of the bond and
therefore testing is recommended to confirm effect.
TYPICAL PROPERTIES OF CURED MATERIAL
Cured for 1 week @ 22 °C
Physical Properties:
Coefficient of Thermal Expansion,
ISO 11359-2, K
-1
145×10
-6
Coefficient of Thermal Conductivity, ISO 8302,
W/(m·K)
0.3
Glass Transition Temperature ISO 11359-2, °C
137
Electrical Properties:
Volume Resistivity, IEC 60093, Ω·cm
1.6×10
15
Surface Resistivity, IEC 60093, Ω
57×10
15
Dielectric Breakdown Strength,
IEC 60243-1, kV/mm
25
Dielectric Constant / Dissipation Factor, IEC 60250:
1
-
kHz
3.6 / 0.04
1
-
MHz
3.0 / 0.11
10
-
MHz
2.5 / 0.36
Documentation Provided By HMC Electronics
33 Springdale Ave. Canton, MA 02021
(800) 482-4440