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Description  |
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FIELD OF THE INVENTION
This invention relates to improved high molecular weight polyethylene tape,
ribbon or line products with continuous and coherent structures having
high modulus and tensile strength properties and particularly adaptable
for use as dental floss, fishing line and other line products. The
invention also relates to a novel method for processing ultra-high
molecular weight polyethylene (UHMWPE) morphologies and other polymers for
producing such products having high modulus and tensile strength
properties.
BACKGROUND OF THE INVENTION
Ultra-high molecular weight polyethylene (UHMWPE) is a unique polymer with
outstanding properties. It can be compression molded to obtain products
which have high abrasion, wear, and fatigue resistance and strength. Also,
it can be processed by solution techniques and drawn to form ultra-high
modulus and strength multifilament fibers. Specially prepared single
crystal morphologies of this polymer can be extruded and drawn to produce
fibers with a modulus approaching theoretically predicted values. UHMWPE
is intractable by conventional melt processing techniques such as
extrusion and injection molding because of its extremely high molecular
weight and melt viscosity, and is processed by powder sintering techniques
used for ceramics and metals, and by ram extrusion.
Information in the prior art is available separately on the swelling
behavior of crosslinked systems in the presence of a solvent, the
dissolution of polymers, and the diffusion of solvents into amorphous
polymers. However, there is only limited information in the literature on
simultaneous kinetics of swelling and dissolution in polymers. Ultra-high
molecular weight polymers are unique in the respect that significant
swelling can occur without dissolution, even though the polymers are
uncrosslinked and are crystalline in nature. This phenomenon occurs
because of the long reptation and relaxation times of the molecular chains
and the high molecular chain entanglement concentrations in these systems.
There has been extensive investigation on producing high modulus and high
strength products from flexible and linear commodity polymers. In
Zachariades U.S. Pat. Nos. 5,030,402 and 4,820,466 solid-state deformation
processes are disclosed for achieving high modulus products. Smith et al
(P. Smith and P. Lemstra, J. Mater. Sci., 1980, Vol. 15, 505 and P. Smith
and P. Lemstra British Polymer Journal, 1980, 212) among others reported
the gel processing route for the manufacture of high stiffness and
strength ultra-high molecular weight polyethylene fibers. This process
required the polymer to be dissolved in a solvent, extruded, quenched,
freed of the solvent and then subsequently hot drawn. In U.S. Pat. No.
4,413,110, Kavesh et al also described gel spinning from a solution to
make ultra-high modulus and strength polyethylenes using 2-5% UHMWPE in
paraffin oil. Such a process uses too much solvent making processing
difficult. Tapes made from melt crystallizing UHMWPE exhibit draw ratios
of only about 8, resulting in final properties of Young's modulus about
1-2 GPa and tensile strength of 0.1-0.3 GPa.
Zachariades in his earlier patent, U.S. Pat. No. 4,655,769, differentiated
between pseudo-gels and true gels used by other researchers, and described
a process for making ultra-high polyethylene tubular products employing
pseudo-gel states covering the following salient step points:
Dissolving a starting material of UHMWPE powder in non-volatile solvent at
140.degree.-170.degree. C. to produce a solution; cooling the solution to
123.degree. C. to prepare a pseudo-gel in sheet form; extracting
non-volatile solvent by a volatile solvent; compressing the pseudo-gel at
123.degree. C. to form a thin gel-like film which is wrapped around a
mandrel; evaporating the volatile solvent while the pseudo-gel film is
wrapped on the mandrel; and then drawing the tubular product at around
5.times. at 135.degree. C.
Also, others have attempted to develop polymer products with high strength
characteristics. In Sano et al U.S. Pat. Nos. 4,879,076, 5,026,511,
4,996,011, 4,760,120 and 5,002,714, a selected polyethylene obtained using
a specific catalyst was drawn at temperatures lower than the polymer
melting point, in order to make high modulus and high strength fibers or
films. In some cases this specific polyethylene was compression molded,
immersed in solvent, solid-phase extruded or rolled, and finally drawn.
Their process is similar to an earlier process, (See 1. M.P.C. Watts, A.
E. Zachariades and R. S. Porter, "New Methods of Production of Highly
Oriented Polymers" in "Contemporary Topics in Polymer Science", Ed: M.
Shen, Plenum Press, 1979, p. 297-318 and A. E. Zachariades U.S. Pat. No.
4,820,466). Kobayashi et al in their U.S. Pat. Nos. 5,106,555 and
5,200,129 describe a process for continuous production of polyolefin
material by feeding the powder between a pair of belts under compression
rolling and stretching the compression-molded olefin.
Mackley and Solbai in their published paper (Mackley, Malcolm R., and
Solbai, Somad, "Swell Drawing: A new method of manufacturing high
performance polyethylene structures", in Polymer J., 1987, Vol. 28,
1115-1120) present a process of swell drawing to manufacture high modulus
and high strength ultra-high molecular weight polyethylene (UHMWPE) tapes.
Their process includes the following steps:
1. Preparing a precursor UHMWPE material stock (Hoechst Celanese GUR 415)
without orientation using sintering by ram extrusion. Preparation of tapes
of thickness 0.010 inch by skiving the UHMWPE stock.
2. Swelling the skived tape in decalin or xylene at 100.degree.-130.degree.
C. for 1 to 10 minutes to an extent that the weight of the solvent to
weight of the polymer Ws/Wp, was up to 20.
3. Cooling the swollen tape down to room temperature under uncontrolled
conditions to crystallize the swollen UHMWPE.
4. Evaporating the volatile solvent from the polymer at 80.degree. C.
5. Drawing the dried tape under isothermal conditions at 4 inch/min (100
mm/min) in the temperature range of 90.degree.-120.degree. C.
SUMMARY OF THE INVENTION
The present invention is different from the aforesaid prior art including
Mackley and Solbai's process and produces a different and improved result
because it uses different precursor morphologies to form a pseudo-gel,
different swelling conditions, different polymers, and different
processing steps.
The present process includes the formation of a pseudo gel state in the
form of a swollen tape (or ribbon), using a non-volatile solvent, the
compression of the swollen tape, the extraction of non-volatile solvent
with a volatile solvent from the pseudo-gel state, the evaporation of the
volatile solvent from the pseudo-gel state to form a dried tape,
compression deformation of the dried tape between rollers, and then high
temperature drawing or stretching to obtain high modulus and high strength
products. The present process does not deal with dissolution of the
polymer or fluid processing, as has been described by earlier authors and
patents, but deals with the controlled swelling of a thermoplastic polymer
as it forms a pseudo-gel with a crystalline structure while the solvent is
incorporated in the polymer, then removing the solvent to produce a more
crystalline morphology, then compressing this crystalline morphology
between compression rolls, and finally solid state deforming (e.g. by
stretching) the crystalline morphology from the pseudo-gel precursor to
obtain products with high modulus and strength properties. The starting
material in the present process can be in the form of skived tape from a
melt crystallized material stock, melt crystallized tape as produced by
melt extrusion, compacted powder morphology or sintered powder morphology.
Depending on their width, we observe that tapes obtained by skiving of
melt crystallized stock often exhibit surface defects along the length of
the tape which can be detrimental in the subsequent drawing (stretching)
step of the process.
The amount of swelling during the formation of the pseudo-gels can also be
controlled by the degree of crystallinity of the starting polymer profile.
A lower crystallinity, associating with a higher amorphous region, allows
more swelling. A major advantage of the present process is that use of
solvents for the formation of the pseudo-gel state by swelling a polymer
is limited to small amounts and does not require so-called "solution
processing" of the polymer. Upon swelling of a polymer in a solvent around
the crystalline melting temperature of the polymer, the density of the
molecular chain entanglements is reduced, thus making it easier to extend
the molecular chains on stretching the polymer to a high draw ratio after
the removal of the solvent from it and producing e.g. tapes and ribbons
with high modulus and strength. To attain high modulus and strength
performance with a draw ratio, upon stretching in the solid state, it is
important that the molecular chains between adjoining crystal be
intertwined together just enough to enable efficient drawing and extension
of the molecular chains to take place without the chains slipping on one
hand or without the molecular entanglements preventing their draw. In an
analogy to cooked spaghetti which is mixed up with sauce, under the
condition of the limited amounts of solvent and short times allowed for
solvent treatment in our process, the molecular chains become "lubricated"
and disentangle to an extent which is controlled by the degree of
crystallinity of the pseudo-gel state. The "solvent-lubrication" process
is reversible in that it does not occur when the solvent is removed from
the polymer.
In summary, the present invention provides high modulus and high strength
tape, ribbon or line products from thermoplastic linear polymers capable
of being swollen in a suitable solvent to form a pseudo-gel state and,
upon removal of the solvent by extraction or evaporation, of being solid
state deformed by compression (e.g. extrusion or rolling), and then by
tension (stretching). Not all thermoplastic polymers are capable of being
swollen with a solvent and forming a pseudo-gel state, namely a state with
time dependent elastic properties, and in addition of being solid state
deformed into high modulus and strength fibrous products. Polymers which
meet these requirements must be linear and have a very high molecular
weight or polar groups in the chain backbone such as the polyamides. By
polymers having a very high molecular weight, it is meant, a polymer resin
having a molecular weight (as measured by viscometric techniques) of at
least 300,000 and up to 5-6 million. Polymers which can be used under the
scope of this invention include polymers such as polyethylenes including
the UHMWPE meeting the specification of ASTM D4020-81, polypropylene,
poly(L-lactide), poly(vinyl alcohol), polyacrylonitrile, poly-4-methyl-
1-pentene, poly(ethylene terphthalate), polyamides and polysaccharides,
and others of the above mentioned type of polymers being copolymers,
linear/branched, and compounded compositions of the above with or without
additives e.g. for adhesion, surface modification or fire retardation. In
the present invention, the polymer is used in the form of a suitable
precursor profile such as a tape or ribbon. The terms tape or ribbon are
used herein to describe a unitary filament preferably in the form of a
narrow strip of material with continuous coherent structure unlike the
multifilament fibers obtained by e.g. solution spinning. For some
applications, the precursor profile can be a monofilament, sheet or tube.
For all embodiments, the precursor material is placed in a non-volatile
solvent at high temperatures, near the polymer crystalline melting point
for 1-5 minutes to form a pseudo-gel. Then cooling the pseudo-gel e.g.
tape profile under controlled conditions to ambient temperature, lightly
compressing the tape between rolls to remove the non-volatile solvent by
squeezing action, removing the residual solvent from the tape by
extraction with a volatile solvent and then by evaporation or vacuum, and
then compressing the profile between rolls to remove defects on the tape,
balance its porosity, increase its crystallinity, by up to 10%, improve
its coherence and continuity, and then increase its tensile properties by
predrawing to a draw ratio of 3-6 and eliminate necking. The processed
tape precursor is then stretched to a certain draw ratio at temperatures
below the crystalline melting point of the polymer in order to obtain
certain desired mechanical properties. Resulting products could then be
used in single filament form or be braided, knitted, or woven, and also
incorporated into composite products.
The final fiber products of our process can be used as dental floss,
fishing line, sail cloth, ropes, threads, bondable tapes, porous
membranes, structural and reinforcing material, in catheters and balloon
materials, etc. They can also be used in composite materials with glass,
carbon, mica, aromatic polyamide fibers, steel, silicon, boron nitride,
and other inorganic and ceramic fibers for impact resistance and as
bullet-proof or ballistic resistant materials.
Other objects, advantages and features of the invention will become
apparent from the following detailed description including examples of
product development according to the invention.
DETAILED DESCRIPTION OF EMBODIMENTS
In accordance with the present invention the precursor material is a
thermoplastic polymer meeting certain requirements i.e. the polymer must
be linear with molecular weight greater than 300,000 to 6 million and be
capable of being: a) solid state deformed into high modulus and strength
fibrous products, and b) swollen with a solvent and forming a pseudo-gel
state. Polymers suitable for precursor material include polyethylenes,
polypropylenes, polyamides, polyesters, polymethyl pentene, polyvinyl
alcohol, poly acrylonitrile, polysaccharides, and variation of such
polymers, including copolymers, linear/branched, compounded compositions
with or without additives. In one form, the precursor material may be
prepared by melt crystallization using compression molding and skiving or
direct melt extrusion into tapes and ribbons. Here, a continuous solid
piece of material is formed from either of these approaches.
The precursor material could also be prepared by powder compaction under
selected temperature and pressure conditions. For polyethylene, suitable
temperatures are in the range of 80.degree. C. to 240.degree. C. and
pressures from 1000 psi to 60,000 psi. Our process can use either an
ultra-high molecular weight polyethylene powder or mixtures of powders
which can be fed through a converging conical die, or between extrusion
rolling dies or rolls, to produce continuous and coherent structures. For
example, UHMWPE HiFax 1900; Mw=3-4.times.10.sup.6, reactor powder was
compacted under a pressure of around 2,000 psi at 110.degree. C. into 1 mm
thick and 10 mm wide tapes. The so prepared tapes were then drawn to a
draw ratio 6 by compression at 124.degree. C. through a pair of rollers.
The precursor material originally provided as described can be processed
directly into a tape, ribbon, sheet, rod, monofilament, tube, and any
other geometrical profile by skiving or by ram or melt extrusion.
After forming the original precursor material, it may be drawn into an
oriented ribbon/tape/sheet/rod/monofilament of a desired size and cross
section as was described briefly above.
Now, the tape/ribbon/sheet of the previous step is fed into a solvent
(volatile or non-volatile) unoriented or after orientation by stretching
or compression drawing through rollers to form a swollen pseudo gel
structure. The solvent could be paraffin oil, mineral or vegetable oils,
decalin, xylene, and kerosene. Preferably the tape/sheet is swollen at
130.degree.-160.degree. C. in paraffin oil to provide a change in weight
Ws/Wp (weight of solvent to weight of polymer) of about 3 to 5, and not
exceeding 10 when swollen for longer times. For example, swelling of a
precursor polyethylene tape with paraffin oil at 130.degree. C. for 5
minutes, provided a change in weight of 170%, a change in length of 50%, a
change in width of 15%, and change in thickness of 20%. Depending on the
thickness, the solvent can go across the thickness of the
tape/ribbon/sheet, or only at the surface. Thus, the process does not
involve formation of a solution. Under the employed swelling conditions,
the molecular chain mobility is restricted by molecular entanglements and
crystals (the swollen polymer has a residual crystallinity of up to 18%),
resulting in a semicrystalline state which has a reduced molecular
entanglement density. The amount of swelling to make pseudo-gels can also
be controlled by the starting crystallinity of the polymer profile. A
lower crystallinity, resulting in a higher amorphous region, allows more
swelling. It has been observed that when the precursor tape/ribbon/sheet
is frozen using liquid nitrogen, and then exposed to a solvent, say at
room temperature, it swells faster to form a pseudo-gel structure
described above.
The swollen tape/ribbon/sheet in its pseudo-gel state is then cooled down
below 70.degree. C. by quenching or slow cooling to recrystallize on
present crystals and crystal nuclei.
Subsequently, the swollen pseudo-gel material is lightly compressed to
remove the non-volatile solvent by mechanical means such as rolling the
tape/ribbon/sheet between soft rolls. For example, after swelling at
130.degree. C. for 5 minutes, almost 90% of the paraffin oil will be
removed by this light compression step.
Thereafter, the tape/ribbon/sheet of the previous step is fed in a volatile
solvent, e.g. hexane. For example, after the swollen tape has been in
paraffin oil at 130.degree. C. for 5 minutes, and is then compressed, it
is fed in a hexane bath at room temperature for up to 10 minutes to remove
any residual paraffin oil. Higher temperatures can be used for faster
removal of this oil, if desired.
In the next step, any residual volatile solvent is removed by evaporation
or vacuum to provide a dried tape.
Now, the dried tape is compressed between rolls at suitable temperature
(room temperature to 130.degree. C.) and pressure (100 to 50,000 psi)
conditions without or with stretching it to a deformation ratio of about 6
to produce a uniaxially oriented tape before its final hot stretching.
Compression-rolling the dried tape before final stretching gives the
following desired characteristics: removal of defects in the tape,
provides balance porosity and better homogenization and increases
crystallinity (by about 1-10%) which is known to result in better
mechanical properties. Also, pre-drawing the tape to a draw ratio up to 6
gives the precursor tape better strength and mechanical stability before
its final drawing, and results in a fibrous tape product with better
mechanical properties. Compression-rolling also makes a more coherent and
continuous structure. In addition, predrawing makes the precursor tape
more coherent and provides a continuous structure. It also eliminates
necking thus enabling one to better draw and obtain higher final
properties.
Thereafter, the compressed tape/ribbon/sheet may be stretched at
80.degree.-130.degree. C. at different draw rates from 0.5 to over 100 of
feet/min using single or multiple stages in conventional drawing
apparatus. The compression and drawing steps of the processed material
accomplishes the orientation, unfolding and extension of the molecular
chains and provides a unitary filament end product with exceptional
strength and high modulus characteristics.
The single filament products resulting from the previous method steps may
also be braided, knitted, or woven, as commercial materials, and also
incorporated to form composite products.
The filament products provided by the aforesaid process steps can be used
as dental floss, fishing line, sail cloth, ropes, threads, bondable tapes,
porous membranes, structural and reinforcing materials, catheters and
balloon materials, etc.
Braided, knitted or woven products made from combinations of single
filaments can be used as composite materials in combination with glass,
carbon, mica, (Kelvar.RTM.), steel, silicon, boron nitride, and other
inorganic and ceramic fibers for impact resistance and as bullet-proof or
ballistic resistant materials.
The following examples illustrate various implementations of the method
according to the present invention including examples of products
resulting from different application of the method.
EXAMPLE 1--Dental Floss
A new dental floss product with a unique combination of properties, was
made of a very high molecular weight (MW) polyethylene, preferably with MW
greater than 300,000 and even better with MW greater than 1,000,000. It
was discovered that such polyethylenes, particularly those with molecular
weights greater than 1 million have self-lubricating properties and can be
drawn into highly oriented and extended tape products suitable as dental
floss. Such products are fibrillar, but unlike the conventionally
available products, are not multifilament and they exhibit remarkable
resistance to shredding. The properties of such fibrillar products vary
depending on the degree of chain extension as effected by the draw ratio,
and on other processing conditions according to the method.
Healthy gums and bone anchor teeth firmly in place. Gingivitis occurs when
toxins from bacteria-laden plaque irritate the gums, causing them to be
red and tender and to bleed. Periodontitis is the more advanced stage.
Toxins destroy more tissue, gums become detached from the teeth, roots and
bone are exposed, leading to tooth loss. Plaque is constantly forming on
tooth surfaces. If not removed daily, plaque can cause cavities and gum
disease. Toothbrushing alone cannot remove plaque from all tooth surfaces.
Flossing helps remove plaque between teeth and below the gums.
Dental floss products heretofore developed and available in the market have
well known problems and disadvantages such as: shredding of the floss on
use into separate filaments resulting in ineffective flossing and
breakage; slippage of the fiber between teeth making it hard to use and
making flossing ineffective. Most of the prior art floss products are made
from nylon, polyamides, or teflon and suffer disadvantages in mechanical
properties compared to newer materials.
In order to hold the fibers from shredding, many prior art floss products
were coated with wax. More recently a polytetraflouroethylene type of
material was produced with slipping characteristics. This material did not
shred readily, but, it had a very low tensile strength in comparison to
other floss materials.
As indicated, the present invention provides a new dental floss tape
product with a unique combination of properties. The dental floss is made
of a very high molecular weight (MW) polyethylene, preferably with MW
greater than 300,000 or preferably with a MW greater than 1,000,000. Such
polyethylenes, particularly those with molecular weights greater than 1
million have self-lubricating properties and can be drawn into highly
oriented and extended tape products. Such products are fibrillar. However,
they exhibit remarkable resistance to shredding. The properties of such
products may vary somewhat depending on the degree of chain extension as
effected by the draw ratio, and also on the processing conditions.
The new dental floss tape product of this example was made in accordance
with the method steps of the present invention using a polyethylene
capable of being swollen into a gel-like state in volatile or non-volatile
solvents and having an average molecular weight of 0.8 to 3 million. In
accordance with the invention, useable polyethylenes can be of a
homopolymer nature, copolymer, or mixture of different molecular weight
characteristics, e.g., a mixture of a resin of MW 800,000 and MW 3
million. Here, the dental floss product was prepared from a melt
crystallized precursor tape of such a polyethylene which was first swollen
into a gel-like state with paraffin oil at 130.degree. C. for 1 minute,
then was compressed (squeezed) lightly to remove the paraffin oil. It was
then immersed in hexane for 5 minutes to dry the tape and remove all
residual paraffin oil. Thereafter, the tape was heated to around
70.degree. C. to remove all residual hexane to produce a porous tape
product with higher porosity than the original melt crystallized tape.
Next, the porous tape was compressed under 100-10,000 psi using die
rollers to balance the material physical properties, e.g., percent
crystallinity, and pores uniformity. After compression, the tape was
stretched with conventional drawing apparatus at a temperature of
80.degree.-130.degree. C. to obtain a drawn product with desired
mechanical properties for dental floss.
As stated, swelling the polyethylene prior to drawing makes it porous. This
porosity can be controlled by the applied swelling conditions and by the
compression conditions between the die rollers before stretching the
polyethylene. By making the polyethylene porous, one can incorporate
different additives such as flavor enhancers or medicinal materials either
while it is being swollen by placing the additive in the paraffin oil or
subsequently after the solvent has been removed.
The product of this invention is a tape acting like a monofilament in sharp
contrast to the multifilament dental floss products heretofore available.
Thus, the product is easier and more convenient to use, has a higher
resistance to tearing, does not fibrillate into smaller filaments, thereby
making flossing more convenient and effective.
In summary, a product formed from high molecular weight polyethylene
material according to the invention, provides several advantages:
1. Since our floss product is in the form of a ribbon/tape, as opposed to a
fiber, it makes flossing much easier. The product will not shred into
filaments on prolonged use between teeth.
2. An extended range of Young's modulus and tensile strengths are
available, e.g. the floss can be made precisely with Young's modulus in
the range of 0.5 GPa to 10 GPa, and tensile strengths of 0.1 GPa to 1.2
GPa, thereby allowing a wide window for specific floss properties.
3. The floss can be made in any desirable range of widths, e.g. from 0.01
inches to 0.25 inches and more.
4. The floss can be made in any desirable range of thickness, e.g. from
0.001 inches to 0.005 inches and more.
5. The floss can be made in a range of flavors such as neutral, mint,
chocolate, strawberry, almond, orange, lemon, banana, maple, etc.
6. The floss can be treated or permeated with medicinal materials such as
peroxide which disinfects the material and makes it safer for use in the
mouth, and/or attack the residual bacteria between the gums and thus
prevent plaque formation.
7. The resulting porosity of the dental floss tape can be used to
incorporate additives, flavors, anti-bacterial agents, anti-tartar agents,
and drugs for periodontal diseases.
8. Another advantageous property of the dental tape or floss made in
accordance with the invention is that it is not coated with a waxy solid
but is self lubricating and is highly effective in use.
EXAMPLE 2--FISHING LINE
A new fishing line with a unique combination of properties, was made of a
very high molecular weight (MW) polyethylene having a MW of about 1.45
million. The starting profile was a rod of diameter 0.020" and was swollen
in paraffin oil for 2 minutes at 130.degree. C., then lightly compressed
to remove the paraffin oil, then dried in hexane to remove any remaining
paraffin oil, and finally drawn at 130.degree. C. to a desired diameter by
drawing to different extents.
The fishing lines used currently are made of nylon or dacron. For the same
diameter of line, the fishing line made in accordance with the present
invention is stronger and has lower elongation at failure.
In particular the fishing line made in accordance with the present
invention provides several important advantages and features. It provides
a line with a small diameter yet high strength, light weight, and having a
low stretch factor. The line can be easily knotted, will float, and casts
well. It does not absorb water or swell on the reel, is self-lubricating,
and does not fray. Following are comparative strength versus size
comparisons with samples made from nylon.
______________________________________
Strength versus Size
Diameter Nylon Present Invention
______________________________________
0.009 inch 8 lbs 25 lbs
0.012 inch 10 lbs 40 lbs
0.017 inch 15 lbs 70 lbs
______________________________________
Elongation
Nylon 25-35% elongation at failure
Present Invention 5-10% elongation at failure
EXAMPLE 2a--FISHING LINE
A highly oriented tape of a very high molecular weight polyethylene
(Mw.about.1.45 million) was obtained by the process described in Example
1. However, the stretching step involved drawing the tape to different
extents. The drawn tape was twinned and braided into a line incorporating
four filaments. For the purpose of this example, the tape was twinned
first by twisting slowly the tape on a lathe and then by braiding the
twisted tapes into a four component structure.
EXAMPLE 3--HIGH MOLECULAR WEIGHT POLYETHYLENE
A precursor powder material having a MW of 1.45 million was used. This
powder was compressed at 200.degree. C. and 10,000 psi to make a
cylindrical billet. Tapes of width 0.25 inches and thickness 0.010 inch
were skived from this block. The tape was swollen in paraffin oil for 1
minute at 130.degree. C., lightly compressed to remove paraffin oil, dried
in hexane to remove remaining paraffin oil. The dried tape was compressed
under 20,000 psi, and then stretched at 130.degree. C. The stretched tape
had a draw ratio of 42, and the final material properties included a
Young's modulus of at least 55 GPa and tensile strength of at least 1.2
GPa.
EXAMPLE 4--POWDER COMPACTED POLYETHYLENE
Precursor material in the form of a UHMWPE Hoechst Celanese GUR 412 powder
was compacted into a tape under 3,000 psi at 120.degree. C. The tape was
swollen in paraffin oil at 130.degree. C. for 2 minutes. The change in
weight was 190% increase in length 13%, in width 8%, and thickness 30% on
swelling. The tape was then lightly compressed to remove paraffin oil, the
remaining paraffin oil was extracted by hexane, and the tape was stretched
at 130.degree. C. to a draw ratio of 18, resulting in final properties of
Young's modulus of 12 GPa, tensile strength of 0.5 GPa, and percent
elongation at break of 5%.
EXAMPLE 5--POWDER COMPACTED POLYETHYLENE (SOLID-STATE ROLLING FOLLOWED BY
HOT STRETCHING)
Precursor material in the form of a UHMWPE HiFax (Himont 1906; Mw.about.3-4
million) reactor powder was compression molded at 2,000 psi at 110.degree.
C. into 1 mm thick and 10 mm wide tapes. The so prepared tapes were
compression deformed at 124.degree. C. to a draw ratio 6 by rolling
through a pair of rollers rotating at a speed e.g. 30 cm/min. The so
prepared pre-drawn tapes by rolling, were then stretched uniaxially at
130.degree. C. to a final fibrous tape product with a Young's modulus of
at least 68 GPa and tensile strength of at least 1.3 GPa. The Table below
lists the properties of the precursor compacted powder before and at
different stages of draw by compression rolling and stretching.
TABLE
______________________________________
Physical and Mechanical Properties of Himont 1900
UHMWPE precursor compacted powder before and during
different stages of draw by compression rolling and
stretching.
Crystal- Melting
linity Temp. Y.M.# T.S.##
Item/step Draw % (.degree.C.)
(GPa) (GPa)
______________________________________
1. Compacted 1 73.4 142.4 * *
powder
2. Hot 6 67.9 141.8 2.8 0.38
rolled
3. After hot 73 81.7 145.1 68 1.3
stretching
______________________________________
*Too fragile to measure
#Young's modulus
##Tensile strength
EXAMPLE 6--POLYPROPYLENE TAPE
An ultra-high molecular weight polypropylene tape was skived from a block
made by melt crystallization during compression molding. The untreated
tape had a melting temperature of 163.degree. C. This 0.005 inch thick
tape was swollen in paraffin oil at 160.degree. C. for 2 minutes to form a
pseudo-gel and the paraffin oil was then extracted by hexane. During
swelling, the change in weight of the tape was 166%, increase in length
12%, increase in width 8%, and thickness 33%. The dried tape was stretched
at 130.degree. C. to a draw ratio of 7, resulting in final tape properties
of Young's modulus of at least 3 GPa and tensile strength of at least 0.3
GPa.
EXAMPLE 7--HIGH DENSITY POLYETHYLENE
A precursor material with a 800,000 molecular weight polyethylene powder,
was compressed at 200.degree. C. and 10,000 psi to make a cylindrical
billet. Tapes of width 0.25 inches and thickness 0.010 inch were skived
from this block. The tape was swollen in paraffin oil for 1 minute at
125.degree. C., lightly compressed to remove paraffin oil, dried in hexane
to remove remaining paraffin oil, compressed under 20,000 psi to even the
material, and stretched at 125.degree. C. The stretched tape had a draw
ratio of 38, and the final material properties included a Young's modulus
of at least 32 GPa and tensile strength of at least 0.8 GPa.
EXAMPLE 7(a)--(a) HIGH DENSITY POLYETHYLENE
The same procedure as in Example 7 was used with a precursor material of
500,000 molecular weight polyethylene herein are purely illustrative and
are not intended to be in any sense limiting.
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