Background
[0001] The present invention is directed to a means of sealing the interfaces in energetic
devices with anaerobic sealants. Anaerobic seals for interfaces between like-to-like
materials or dissimilar-to-dissimilar materials in assembled devices such as squibs,
detonators, mechanical actuators, initiators, and primers are found easier to produce
commercially and equivalent in service to present seals.
[0002] The present technology is aware that interfacial seals between like materials and
interfacial seals between dissimilar materials remains a problem in the energetic
devices art. Welding and soldering techniques are considered the benchmark technology
which is known to this art and provide substantial means for sealing the troubled
interfaces that concern the present invention. These techniques, however, do not easily
lend themselves to the rigors of commercial production. Chemical sealant techniques
have been used to seal interfaces, for example in U.S. patent 3,971,320, incorporated
herein by reference in its entirety, potting materials such as epoxy resins are disclosed
to seal the interfaces of squibs to insure environmentally tight seals.
[0003] Energetic devices comprise a generic group of assembled structures that require a
chamber which provides a common reaction forum thus enabling explosive compositions
to react. For reliable reactions, the chamber and its companion structural interfaces
must be sealed against the ingress of moisture and other contaminants often found
in the hostile environments in which these devices must function. Anaerobic sealing
techniques are generally known to those skilled in the explosive ordnance art such
as that used with percussion primers.
[0004] The present invention is directed to the use of anaerobic sealing techniques for
interfaces in energetic devices. Such use is heretofore unknown for these devices
and give significant manufacturing advantages, such as ease of sealing these surfaces
in a fast and economic manner, thus reducing production costs. Additionally, means
may be added to the anaerobic sealing technique to facilitate quality assurance, an
important aspect of any energetic device manufacturing process. As those skilled in
this art appreciate, once manufactured it is difficult to determine sealant presence
at the interfaces, the present invention lends itself to such a determination.
[0005] The present invention is useful for all manner of sealing interfaces in energetic
devices, this is especially useful in the automotive airbag business in the production
of initiators.
SUMMARY OF THE INVENTION
[0006] A single or plurality of interfaces between components in energetic devices comprising
an anaerobic sealing means wherein said means communicates therebetween and therefrom
metal-to-metal first surfaces, metal-to-nonmetal second surfaces, and/or nonmetal-to-nonmetal
third surfaces wherein said first, second, and/or third surfaces are optionally a
part thereof and therein of said energetic devices. The single or plurality of interfaces
can be any of the surfaces brought together of the assembled pieces or components
for the manufacture of energetic devices. In particular and by way of example, the
interfaces between metal sleeves either first or second side said first side juxtaposed
to a plug assembly, said plug assembly a closure means which enables a signal transmission
such as light, by way of example a laser, electrical or mechanical stimulation for
said signalling purposes, a metal cup or chamber means that fit juxtaposed to a housing
and/or to said first side of said sleeve, the insulator materials that fit juxtaposed
or within said second side of said sleeve or chamber means, component electrical structures
embedded within said insulators, and the dissimilar interfaces of the body used to
cap the top portion of an energetic device such as a squib. The three different interfaces
are optional in the sense that not all three are required in any one device, although,
of course, at least one of the options must be in the device.
[0007] The energetic devices of particular benefit to the present invention are squibs,
initiators, mechanical actuators, detonators, primers, pyrotechnic devices, explosive
devices, combinations thereof and therebetween. Preferably squibs, initiators, and
mechanical actuators, most preferably squibs and initiators are the beneficiaries
of the present invention.
[0008] The metal-to-metal interfaces commonly used in energetic devices may be selected
from the first, second or third transition series, alloys thereof and combinations
thereof from the Periodic Chart. Preferably, aluminum, copper, carbon steel, stainless
steel, iron, zinc, nickel, tin, titanium, alloys and combinations thereof, most preferably
aluminum, copper, stainless steel, alloys, combinations thereof and therebetween.
The metal-to-metal interfaces may be combinations of either the same metal interfaces
or dissimilar metal interfaces.
[0009] The metal-to-nonmetal interfaces include all of the metals recited hereinabove, and
nonmetal materials comprising, glasses, ceramics, glass-ceramics, insulators such
as thermoplastic and thermosetting materials and blends thereof. Examples of glasses
are soda-lime silicate, borosilicate, quartz, aluminosilicate, mixtures of alkali
and alkaline earth silicates, ferrosilicates. Ceramic materials such as borates, zirconates,
aluminates, lanthanates, titanates, and combinations thereof are used as insulators.
Thermoplastics such as the nylons, (Nylon 66 and 6, for example), polypropylenes,
polystyrenes, ABS, polyesters, polyethersufones (PES), polyetherethersulfones (PEES),
polyetheretherketones (PEEK), polyetherketones (PEK), polyetherimides (PEI), polycarbonates,
polyvinyls, polyacetates, acetals, polyethylenes, and combinations thereof. Thermosetting
materials such as epoxies, methacrylates, acrylics, cyanates, isocyanates, phenolics,
phthalates, and combinations thereof. The above recited nonmetals may be sealed with
other nonmetals as recited above in any combination using the same sealant techniques
disclosed herein.
[0010] Communication may be defined as its ordinary meaning indicating that through and
as a result of the anaerobic sealant means, the interfaces are brought together forming
a combined unitary functional assembly that is environmentally stable to, by way of
example, moisture, solvents, electrical charges, pressure and temperature variations.
The anaerobic sealant means has been found to withstand the same environmental stresses
as the welding and soldering techniques resulting in equivalent interfacial seal integrity.
[0011] The anaerobic sealant, such as Loctite 290 (obtained from the Loctite Corporation,
Newington, Connecticut) the preferred sealant, for sealing metal-to-metal interfaces,
applies through a wicking action after the assembly has been combined. Of course,
application may be applied prior to assembly, however, it is preferred for purposes
of commercial production, to wick the sealant to, through, between, and/or on the
interfaces after assembly. Due to its lower viscosity (as compared to the soldering
and welding techniques), the anaerobic sealant runs into and thereafter remains on
and between the interfaces. It is believed that the interfacial surface energies may
be relaxed by sealant presence thereon and therebetween said interfaces, thereby enabling
the above-referenced communication.
[0012] An important consideration in this sealant technique is the methodology of its application,
touched on hereinabove. The production method most familiar to those in this art are
the solder and/or welding techniques. These techniques employ before-assembly and/or
after-assembly methods which decrease the economies available to mass production assembly
that after-assembly methods using anaerobic sealants promote. Due to the wicking and
solvent characteristics of these anaerobic sealants an ultraviolet reflecting or absorbing
means may be mixed with the sealant. Thereafter, an ultraviolet detection means may
be employed on-line in a production line to quality check and thus assure that the
sealant found its way to the interface, in fact. The solder and welding techniques
do not lend themselves to such a sophisticated detection means, requiring an operator
assisted observation. The economies therefrom of the present invention reduce labor
intensity, increase speed of assembly, increase reliability of product quality and
assurance thereof, and the economies that flow therefrom.
[0013] For sealing metal-to-nonmetal interfaces Flexseal XT, (obtained from the Loctite
Corporation, Newington, Connecticut) is the preferred sealant. This sealant is applied
in a dry vacuum environment whereby the assembly is introduced into a vacuum chamber
with sealant, the partial pressure of air above the sealant removed, then the sealant
is impregnated into the assembly under pressure. Similar equivalency in sealed interfaces
with ease of manufacture is experienced with this sealant, as well. It has also been
conveniently found that wet vacuum and/or pressure techniques may be utilized for
operational species, as well, dependent upon manufacturing requirements.
[0014] Other anaerobic sealants contemplated as operable hereunder are derived from the
family of anaerobic sealants which may include thermosetting sealants and the generic
acrylates which are not necessarily completely anaerobic in their curing properties
and may include thermally and/or ultraviolet (UV) initiated polymerized sealants.
[0015] Anaerobicity, even if only partial, is an important part of this sealant mechanism
since oxygen curing of the sealant may be an impractical and therefore not preferred,
although operable, means of curing within the interfaces.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0016] By way of example of how the above recited invention may be practiced, the following
description is offered, not intending to limit the scope thereof.
[0017] Three hundred squid energetic devices were prepared wherein 100 of each squib were
prepared whereby the chamber means was inserted into the housing means and mechanically
crimped by a 360 degrees perimeter crimp. Said crimp was positioned such that the
housing means and chamber means were crimped simultaneously and therefore together.
A similar sample subset was crimped and sealed with solder, and a third subset was
crimped and sealed with the anaerobic sealant, Loctite 290. The samples were then
subjected to an accelerated environmental test where for a thirty-six week time period
the squibs from each subset were subjected to a humidity chamber at 25 to 60 degrees
centigrade cycling over a 24 hour period. Each squib assembly was placed in a pressure/time
test bomb. The squib is initiated and the time from application of firing current
to peak output pressure was measured. This test provides a measure of moisture contamination.
The more moisture ingress into the sample the longer the test times. This test is
known by those skilled in the art as MIL-STD-810C, Method 507.1. The squib assembly
which is the subject of the present invention, is the same assembly as disclosed in
U.S. patent 3,971,320, the structure and description of which are incorporated herein
by reference in its entirety.
[0018] The crimped only subset exhibited multiple failure modes whereas the solder and anaerobic
sealant subsets performed equally well with no failures for either method and no substantial
degradation.
1. A single or plurality of interfaces between components in energetic devices comprising
an anaerobic sealing means wherein said means enables communication therebetween and
therefrom metal-to-metal first surfaces, metal-to-nonmetal second surfaces, and/or
nonmetal-to-nonmetal third surfaces wherein said first, second, and/or third surfaces
are optionally a part thereof and therein of said energetic devices.
2. The interfaces of claim 1 wherein said interface between components comprise a sleeve
and a plug assembly .
3. The interfaces of claim 1 wherein said interface between components comprise a chamber
and a housing.
4. The interfaces of claim 1 wherein said interface between components comprise insulator
materials and sleeve.
5. The interfaces of claim 1 wherein said interface between components comprise electrical
structures and insulators.
6. The interfaces of claim 1 wherein said interface between components are combined to
form a squib.
7. The interfaces of claim 1 wherein said interface between components are combined to
form an initiator.
8. The interfaces of claim 1 wherein said interface between components comprise metals
selected from the group consisting of aluminum, copper, stainless steels, alloys thereof,
and combinations thereof and therebetween.
9. The interfaces of claim 1 wherein said interface between components comprise nonmetals
selected from the group consisting of glasses, ceramics, glass-ceramics, thermoplastics,
thermosets, and combinations thereof and therebetween.
10. The interfaces of claim 1 wherein said communication provides a unitary assembly.
11. The interfaces of claim 1 wherein said anaerobic sealant is Loctite 290.
12. The interfaces of claim 1 wherein said anaerobic sealant is Flexseal XT.
13. The interfaces of claim 1 wherein said anaerobic sealant is a wicking sealant.
14. The interfaces of claim 1 wherein said anaerobic sealant is combined with a detection
means to provide on-line quality assurance.
15. The interfaces of claim 1 wherein said sealant consists of an acrylate.
16. The interfaces of claim 1 wherein said sealant is thermosetting.
17. The anaerobic sealant of claim 1 wherein said sealant is partially anaerobic.