[0001] This invention relates to an inflatable expansible structure, that is a structure
made from flexible sheet material and including at least one gas-tight chamber, the
structure being initially packed in a deflated condition to form a dense compact package
for storage and upon need, is deployed and inflated to form a buoyant functional article
such as: a liferaft; an escape chute; a raft; a jetty; an inflatable vessel; and inflatable
sail; or a boom or marker.
[0002] Heretofore, inflatable expansible structures have been made from composite flexible
material consisting of rubber or plastics material reinforced with textile material.
Typically, a sheet of woven or non-woven textile material has been impregnated with
a fluid plastics or rubber material which is caused to fill the interstices of the
fabric and create a flexible, gas-impermeable sheet. It has also been known to produce
items from sheets of unreinforced rubber or plastics materials. Specifically cheap
air beds and light use articles.have been so made. However, the resistance to tearing
offerred by unreinforced plastics or rubber sheeting is very low and such articles
are very susceptible to damage. Accordingly their use is restricted to situations
where failure is unimportant.
[0003] In a composite air-impermeable material the reinforcement is often an intrinsically
strong textile material; such as canvas, having a very high resistance to tearing
and cutting damage. We have found, however, that there is a marked difference between
the tear resistance of a reinforcing fabric before and after impregnation with rubber
or plastics material. Surprisingly, the resistance of an impregnated composite fabric
can often only amount to from 25% to 50% of the tear resistance of the basic fabric.
[0004] In a specific example, the tensile strength of the warp of a 41/4 oz fabric of high
tenacity nylon, the fabric being unproofed except for a light anti-fray coating, was
reduced by 20% on proofing, the tensile strength of the weft being reduced by 22%.
The corresponding figures for tear strength were approximately 36% for the warp and
40% for the weft.
[0005] We do not know with certainty why this is the case, but research has suggested that
when an edge moves into contact with the fabric in a tear-forming way, it first contacts
one thread of the fabric and, because the thread has a degree of freedom in the fabric,
moves that first thread aside into contact with an adjacent thread. The two threads
are then moved together until a small "bundle" of threads are resisting edge movement.
Only when the resistance of such a bundle has reached a sufficiently high value is
the edge forced to cut to continue its movement. It is now compelled to cut the bundle
of threads together and a quite high force is required, resulting in a high tear strength.
It must be appreciated that the degree of movement of the threads in a closely formed
fabric will be small, and that the edge will not make any appreciable penetration
through the fabric by pushing the threads aside.
[0006] Conversely, in a composite material, wherein the fabric interstices are filled with
rubber or plastics compound, the individual threads are held in a spaced- apart condition
and cannot form such a "bundle". When an edge contacts the composite material it meets
a single thread and tensions it to a cutting level individually as it cannot move
sideways. Thus the edge cuts the threads successively and individually which clearly
requires much less force than is needed to cut a bundle of threads formed as a "bow
wave" in advance of the edge.
[0007] The consequences of the lowered tear-strength are that an inflatable structure made
from composite material is of lower tear-resistance than would be assumed from consideration
of the tear strength of the basic fabric. If a particular tear strength is specified
for a composite material, a basic fabric of considerably higher basic tear strength
must be chosen, with a consequent cost penalty.
[0008] It is an object of the present invention therefore, to provide an inflatable expansible
structure wherein the aforesaid disadvantage of a composite air-impermeable material
is reduced or eliminated.
[0009] Accordingly the invention provides an inflatable expansible structure having at least
one chamber comprising a bladder of air-impermeable material enclosed within an envelope
of textile material.
[0010] The bladder can be formed or moulded from unreinforced flexible rubber and/or plastics
sheet material. A degree of reinforcement can be incorporated in the bladder to improve
its strength during storing and handling, but is not essential. If the bladder is
formed from sheet material by cutting, forming and glueing, the adhesive used can
be relatively weak, as it needs only to create an airtight joint with only small mechanical
strength. Constraint against excessive expansion under the influence of inflation
gas is provided by the surrounding envelope and need not be incorporated in the bladder.
[0011] Because the envelope is not itself gas-tight, it can be formed from sheet material
and secured in shape by sewing or by adhesive. Adhesive must be used with composite
material, because sewing produces perforations which need to be subsequently sealed
by coating or taping at some expense. However, sewing is a preferred method of uniting
textile material as it can produce a very strong joint simply and easily without the
use of chemicals and solvents and without the need for a dwell after adhesion to allow
setting or curing. Thus the dual nature of the new structure does necessitate two
forming and joining operations, but each is easier in itself, thus there is not a
doubling of the work and expenditure involved.
[0012] The invention will be described further, by way of example, with reference to the
accompanying drawings, wherein:-
Fig. 1 is a perspective view of a liferaft conforming to the invention;
Fig. 2 is a fragmentary cross-sectional view on line II-II of Fig. 1; and
Fig. 3 is a further enlarged fragmentary cross-sectional view of the part ringed III
in Fig. 2.
[0013] A preferred inflatable expansible structure conforming to the invention is a liferaft
10 of generally conventional overall form comprising a floor 11 of fluid- impermeable
sheet material and a pair of superposed annular buoyancy chambers 12. Each chamber
12 is of dual construction having an annular outer envelope 13 of a strong woven textile
material such, as for example, cotton duck or canvas, which is unproofed, except for
a light anti-fray coating, and which retains the whole or substantially the whole
of its strength and flexibility. The envelopes 13 are formed by cutting and sewing
together one or more sheets of fabric. Sewing provides a mechanically very strong
bond at minimal cost, rapidly and with little complication. The two annular-envelopes
13 can be sewn together and to the floor 11 to form a mechanically strong structure.
[0014] Within each envelope 13 is an annular bladder 14 moulded, for example, from polyurethane
or other flexible rubber or plastics material without (or with minimal) reinforcement.
If made by cutting, forming and glueing sheet material, the adhesive can be a cheaper
sealing adhesive rather than a mechanically strong adhesive.
[0015] The bladders 14 are each connected to a gas source such as a cylinder 15 by conventional
pipes 16. Non-return valves (not shown) can be incorporated to maintain the chambers
separate, so that failure of one cannot allow deflation of the other.
[0016] In a typical construction, the bladder comprises a 0.3mm unsupported liner material,
whilst the envelope is a 41/4oz. fabric woven from high tenacity nylon.
[0017] Fig. 3 illustrates an additional advantage of the dual construction. It is well known
that the juntion between an inflation tube and the body of an inflatable item is a
weak point at which failure often occurs. In an inflatable made from composite material
such junction must be both mechanically strong and completely gas impermeable. In
the present dual construction these two properties are separated. Strength and protection
can be afforded by reinforcing the material of the envelope 14 by an annular patch
17. sewn and/or adhered to the envelope 14 without attention being paid to sealing.
The moulding-in or adhesion of a flanged pipe-to-body junction can be effected with
reference only so the need for gas impermeability, mechanical strength and protection
being essentially disregarded as such properties are primarily provided by the envelope.
[0018] The structure of the invention has resistance to damage by tearing and impact which
is concomitant with the tear resistance of the envelope material and a much more rugged
and robust structure is provided than using a composite material of comparable basic
strength.
[0019] Of course, the dual, bladder/envelope construction has been previously applied to
such items as gameballs ( a rubber bladder within a leather sheath) and a vehicle
tyre structure (inner tube within a reinforced casing). However, in neither of these
cases was the envelope solely of a textile material whose tear strength determined
the ruggedness of the structure. Further, neither of these structures was an expansible
structure, normally collapsed in a dense, compact package for storage and transport,
and subsequently inflated for use from a gas source.
[0020] The invention can be applied to escape chutes, buoys, jetties, boats and similar
inflatable expansible structures.
1. An inflatable expansible structure including a chamber comprising a bladder (14)
of an air-impermeable material enclosed within an envelope (13) of textile material.
2. An inflatable expansible structure as claimed in claim 1, wherein the envelope
(13) comprises a woven textile material.
3. An inflatable expansible structure as claimed in claim 1 or 2, wherein the envelope
(13) comprises a textile material having a protective coating applied thereto of a
form and in an amount not materially to reduce the tear strength thereof.
4. An inflatable expansible structure as claimed in claim 3, wherein the protective
coating comprises a light anti-fray coating.
5. An inflatable expansible structure as claimed in any one of the preceding claims,
wherein the envelope (13) is secured in shape by sewing.
6. An inflatable expansible structure as claimed in any one of the preceding claims,
wherein the bladder (14) includes light reinforcement.
7. An inflatable expansible structure as claimed in any one of the preceding claims,
wherein the envelope (13) includes an aperture therein in register with and to provide
passage for an inflation tube (16) extending from the bladder (14).
8. An inflatable expansible structure as claimed in claim 7, further including reinforcement
of the envelope about the periphery of the aperture therein.
9. An inflatable expansible structure as claimed in claim 8, wherein the reinforcement
comprises an annular patch (17) applied to the envelope (13) in register with the
aperture therein.
10. A liferaft comprising an inflatable expansible structure as claimed in any one
of the preceding claims.