KP-FSD3 Panduit Corp, KP-FSD3 Datasheet - Page 133

KIT FERRULE INS DIN AWG12-6

KP-FSD3

Manufacturer Part Number
KP-FSD3
Description
KIT FERRULE INS DIN AWG12-6
Manufacturer
Panduit Corp
Series
Pan-Term®r
Type
Ferrule Kitr
Datasheet
1.KP-FSD1.pdf (1040 pages)

Specifications of KP-FSD3

Kit Type
Ferrule - Wire End
Values
100 pcs - Assorted Insulated 12 ~ 6 AWG Ferrules
Kit Contents
50 Pieces Of FSD81-10, 20 Pieces Each Of FSD82-12 And FSD83-12, 10 Pieces Of FSD84-12
Mounting Method
Crimp
Where Used
To terminate stranded wire for insertion into terminal blocks
Lead Free Status / Rohs Status
Lead free / RoHS Compliant
Radiation/Moisture/Temperature/Tensile Strength
Radiation
Installed cable ties of various materials have been exposed to different amounts of radiation to determine the
maximum acceptable limit. These tests were conducted by Panduit to determine the acceptability for use in vari-
ous areas of nuclear power plants (for radiation exposure accumulated over a 40 year life). See Cable Tie
Selection Chart (pages B1.2 and B1.3) for radiation resistance rating.
Moisture
Many plastics when exposed to high relative humidity absorb water and, as such, the tensile strength of the
material can change dramatically. Nylon 6.6 when exposed to 100% relative humidity, will absorb as much
as 8.5% water which will reduce tensile strength by 50% when compared to a dry cable tie. Polypropylene,
HALAR
the effect of water is minimal. See Cable Tie Selection Chart (pages B1.2 and B1.3) for moisture absorption.
Proper Storage
Nylon 6.6 is a hygroscopic material (affected by atmospheric moisture variations). The optimum storage
requirement for Nylon 6.6 cable ties is 73°F (± 15°F) and 50% RH (relative humidity) in sealed containers.
Improper storage, especially in cold/dry conditions can result in moisture loss, which impedes cable tie
performance. Panduit packaging provides Nylon 6.6 cable ties conditioned to 2.5% moisture added
by weight in heavy-wall, polyethylene heat-sealed bags.
Temperature
Plastic materials normally undergo property loss due to oxidation caused by exposure to high temperatures.
The maximum continuous use temperature for cable tie materials depends upon the time at the elevated
temperature as well as other environmental conditions. Initially, plastics become more flexible and weaker
when exposed to high temperatures. After a period of time, oxidation may occur which will cause embrittlement,
making plastic cable ties more susceptible to failure from impact and vibration.
The maximum continuous use temperature, is based on the UL Relative Thermal Index (mechanical
without impact) as determined by UL per UL 746B. It is one indicator of a material’s ability to retain a particular
physical property when exposed to elevated temperatures over an extended period of time. It is based on the
assumption that there is no loading, no chemical attack, and impact-free condition. The maximum continuous
use temperatures for cable tie materials are listed in the Cable Tie Selection Chart (pages B1.2 and B1.3).
Low temperature exposure will also make most plastics more brittle during the exposure, but little property loss
occurs when the material is returned to room temperatures. The minimum application use temperatures for cable
tie materials are listed in the Cable Tie Selection Chart (pages B1.2 and B1.3).
Tensile Strength
Most cable ties are selected based on material, length, and minimum loop tensile strength. Minimum loop
tensile strength was established under SAE Aerospace Standard AS23190. Each cable tie cross section
(SM = Subminiature, M = Miniature, I = Intermediate, S = Standard, HS = Heavy-Standard, LH = Light-Heavy,
H = Heavy and EH = Extra-Heavy) has a different loop tensile strength when tested per AS23190.
The cable tie is first conditioned at 49°C (120°F), 20% relative humidity for 24 hours, then the cable tie is
installed on a split mandrel and the halves of the mandrel separated at a rate of 1 inch (25.4mm) per minute.
The separating force required to unlock or break the cable tie is the loop tensile strength. Loop tensile strength
is dependent both on the locking design and the tensile strength (psi) of the material. As an example, the tensile
strength of polypropylene material is approximately 1/2 to 1/3 of Nylon 6.6; thus the loop tensile strength of a
given cross section tie made of polypropylene would be much less than a tie made of Nylon 6.6. This is another
property to be considered when selecting a cable tie. The various representative loop tensile strengths are listed
in the Cable Tie Selection Chart (pages B1.2 and B1.3).
Halogen-Free
All Panduit cable ties (with the exception of TEFZEL
IEC Specification 61249-2-21.
HALAR is a registered trademark of Ausimont USA, Inc.
TEFZEL is a registered trademark of E.I. du Pont de Nemours and Company.
, Type 12 Nylon, TEFZEL
, Acetal and PEEK are low water absorbing materials and, as such,
For technical assistance in the U.S., call 866-405-6654 (outside the U.S., see inside back cover for directory)
ELECTRICAL SOLUTIONS
and HALAR
) are halogen-free per
B1.103
Management
Identification
Accessories
Connectors
Connectors
Grounding
Pre-Printed
& Write-On
Protection
Permanent
Solutions
Cable Ties
Terminals
Lockout/
Overview
Steel Ties
& Safety
Stainless
Raceway
Abrasion
Labeling
Systems
Surface
Markers
Tagout
System
Wiring
Labels
Power
Cable
Cable
Index
Duct
E5.
B1.
B2.
B3.
D1.
D2.
D3.
C1.
C2.
C3.
C4.
E1.
E2.
E3.
E4.
A.
F.