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'MINIATURE'
FASTENERS PLAY BIG ROLE IN SMALL PACKAGES
As design engineers
strive to create smaller and lighter packages composed of thinner materials,
hardware can get in the way. Compact designs inherently shrink the "real
estate" available to place and install hardware, while thinner materials
can reduce the ability for hardware to gain purchase and provide secure
attachment over time. Then there is the matter of choosing the best
method for a job.
Traditional "permanent"
fastening methods, such as adhesives or welding, will fail to allow
for product disassembly, which is so crucial in today's high-tech product
world. Welding results in undesirable fumes and burn-outs and often
requires complicated electrodes and pilots that can stall production.
Even some types of conventional mechanical fasteners have drawbacks
in performance, including sheet-metal screws that can fall short in
the areas of reusability and holding power.
These emerging issues
have given rise to a whole new generation of self-clinching "miniature"
threaded fasteners, which offer performance and service advantages that
conventional fastening and joining methods cannot. They install quickly
and permanently, minimize the need for additional hardware, and promote
access and serviceability.
A variety of miniature
types and styles fit especially well in the increasingly restrictive
design envelopes encountered in industries ranging from electronics
to aerospace. All will provide strong, permanent, and reusable threads
in very thin (sometimes "ultra-thin") metal sheets. Usually, only a
mating screw or nut is required to complete the attachment process.
These types of fasteners
require fewer assembly operations, deliver more holding power than sheet-metal
screws, and can offer benefits especially advantageous for small-component
assemblies. Some types, for example, will promote installation closer
to edges to maximize use of space, while others will solve problems
encountered when working with thin materials.
FASTENER PROFILES
Now designers have
the opportunity to think big when deciding how to assemble small packages.
Among the "miniature" threaded self-clinching fastener solutions for
those working in the shrinking world of component assembly:
•Self-Clinching
Locking and Non-Locking Threaded Nuts.
This specialized family of miniature locking and non-locking fasteners
is characterized by extremely small thread sizes (as low as #0-80 and
M2) and the tiniest of footprints. They can be permanently installed
in aluminum or steel sheets as thin as .019"/0.76mm.
The tops of the
locking types are elliptically squeezed (instead of round) to add tightening
action around the mating screw and meet locking torque requirements
of NASM25027.
Both locking and
non-locking types feature knurled collars, which embed completely in
a metal sheet upon fastener installation to guarantee against rotation.
(The spin resistance of the knurl exceeds the torque that can be exerted.)
Pushout resistances in values up to 420 lbs./1868N can be achieved,
due to the displaced sheet material filling the undercut cavity beneath
the collar. These fasteners usually come supplied with a dry-film lubricant
to provide smooth, non-galling prevailing torque performance. Torque-out
values of up to 110 lbs./12.43 Nom can be realized, depending on thread
size and sheet material.
•Self-Clinching
Threaded Nuts for Ultra-Thin Sheets.
Compared with standard clinch nuts, these types exhibit a lower profile
and can be mounted up to 50% closer to the edge of ultra-thin steel
sheets. The nuts' diameters (.220"/5.6mm) and height (.065"/1.4mm) contribute
to the low profile and maximized use of space in an assembly.
Once installed (in
sheets as thin as .025"/0.64mm), these nuts will provide permanent threads
in sizes as small as #2-56 and M2.
•Self-Clinching
Threaded Studs with Low-Displacement Heads.
These types also can live "close to the edge." Depending on thread size
(as small as #2-56 and M2), they can be installed 25% to 50% closer
than standard self-clinching studs without causing that edge of the
metal sheet to bulge. (Both the head and overall design are contributing
factors.)
When installed in
aluminum or steel sheets as thin as .040"/1mm, a flush-head assembly
is created and the stud locks securely in place.
•Self-Clinching
Threaded Studs for Thinner Sheets.
Non-flush stud types (thread sizes as small as #2-56 and M2) can be
installed in aluminum or steel sheets as thin as .020"/0.51mm. As with
the low-displacement head studs, these fasteners will similarly lock
with ample torque-out and pushout resistances. Although their heads
will not be flush in the assembly, these fasteners will enable "close
to edge" installation in metal sheets half as thick as the thickness
of materials required for installation of flush-head studs.
•Self-Clinching
Threaded Standoffs for Ultra-Thin Sheets. The primary function of
these types of fasteners is to enable components made from the thinnest
metal sheets to be stacked or spaced securely. They can be utilized
in aluminum or steel sheets as thin as .025"/0.63mm and can be specified
in various lengths and in the small thread sizes (#2-56 and M2).
FASTENER INSTALLATION
Users specify miniature
self-clinching fasteners where good pullout and torque loads are required
in sheet metal that is too thin to provide secure fastening by any other
method. They perform reliably in sheets too thin to tap and will serve
as superior threaded alternatives to extruded/tapped or stamped threads.
(In general, miniature self-clinching fasteners should be selected whenever
a component must be replaced readily and where "loose" nuts and hardware
would be inaccessible.)
The fasteners are
installed by pressing them into place in properly sized drilled or punched
holes using a parallel acting press adjusted to predetermined forces.
The pressing or squeezing process causes displaced panel material to
cold-flow into a specially designed annular recess in the shank or pilot
of the fastener, locking the fastener in place. Depending on fastener
type, a serrated clinching ring, knurl, ribs, or hex head prevents the
fastener from rotating in the metal when tightening torque is applied
to the mating screw or nut.
The outcome is that
miniature self-clinching fasteners become a permanent and integral part
of the panel, chassis, bracket, or other component in which they are
installed.
For high-volume
installations, an automated press (instead of manual models) can be
considered. Some automated presses are specifically designed to feed
self-clinching fasteners automatically into punched or drilled holes
in sheet metal, seating them correctly with a parallel squeezing force.
Feeding rates are up to six times faster than manual insertions, and
squeezing action is adjustable to compensate for variations in thickness
and hardness of the sheet and the height of the fasteners.
Installers also
have a newfound option to take advantage of significant advances in
in-die fastener-feeding equipment. Systems have been developed to work
in tandem with stamping presses (and properly tooled die) to feed and
install fasteners, which eliminates secondary operations typically required
for fastener insertions. This provides a capability to perform two operations
(stamping and fastener installation) simultaneously in the die.
FASTENER RELIABILITY
Once a miniature
self-clinching fastener has been installed, its reliability in service
will depend on many factors, beginning with a properly sized hole, the
thickness and hardness of the host sheet, proper installation procedure,
and the design and quality of the fastener itself.
There are three
tests applicable to a self-clinching fastener to determine its reliability
in service. The first is torque out, which determines the fastener's
ability to resist rotation within the sheet. This test often is made
at the head of the fastener often with values exceeding the ultimate
torsional strength of the mating screw or nut.
A second reliability
measure is pushout. Pushout values indicate the axial resistance
of a fastener in the opposite direction from which it was installed,
and should be roughly 5% to 10% of the force used to install the fastener.
A final test is
torque-through, which is the resistance of a fastener to pulling
through the metal sheet when a champing torque is applied.
As is generally
true in the manufacturing marketplace, differences will exist among
fastener suppliers and, in turn, among their products in the areas of
reliability, quality, and installed cost.
Production of quality
fasteners begins with good engineering research, design, development,
and testing. Precision is necessary in all facets of fastener production,
especially relating to miniature types. Dimensional accuracy and consistency
are crucial and, if these are lacking the result will be rejected panels,
chassis, or boards upon fastener installation. Even minute size variations
among parts can cause automated equipment to jam, increasing downtime
and production time.
A good rule of thumb
is that product designers take the time to take advantage of a supplier's
support before a package or component is designed and use the
resources of the supplier in the early stages of design to develop the
best fastener for the application.
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