巴西专利BR112012003040A2 process for the production of a polyethylene tape article, laminated polyethylene tape article, and

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专利摘要:
PROCESS FOR THE PRODUCTION OF AN ARTICLE OF TYPE OF POLYETHYLENE TAPE, ARTICLE OF POLYETHYLENE TAPE, LAMINATED, AND IMPACT AND PENETRATION RESISTANT ASSEMBLY.Processes for the production of articles of the type of high-strength polyethylene tape, produced from ultra-high molecular weight and high-strength multifilament yarns, and articles such as tapes, fabrics, laminates and impact-resistant materials produced from them .
公开号:BR112012003040A2
申请号:R112012003040-0
申请日:2010-07-29
公开日:2020-08-11
发明作者:Thomas Tam；Mark Benjamim Boone；Steven Correale；Ashok Bhatnagar
申请人:Honeywell International Inc.；
IPC主号:

专利说明:

PROCESS FOR THE PRODUCTION OF AN ARTICLE OF TYPE OF POLYETHYLENE TAPE, ARTICLE OF POLYETHYLENE TAPE, LAMINATED, AND
IMPACT-RESISTANT ASSEMBLY AND PENETRATION Fundamentals of the Invention 5 1. Field of the Invention The invention relates to processes for the production of articles of the type of high resistance polyethylene tape, produced from ultra-high and high molecular weight yarns resistance, and articles such as tapes, fabrics, laminates and impact resistant materials produced therefrom.
2. Description of the Related Art Impact-resistant and penetration-resistant materials find use in many applications, such as sports equipment, safety clothing, and most crucially, in personal body armor. Building armor for personal protection is an ancient art, but not archaic. Metal armor already well known to the Egyptians around 1500 BC persisted in use until about the 17th century. In the modern era, body armor has again become practical through the discovery of new strong fibers, such as ararnides, molecular weight polyethylene ultra-high (UHMW PE), and polybenzazoles.
Several fiber-reinforced constructions are known for use in impact resistant articles, resistant to ballistic projectiles and resistant to penetration; such as helmets, panels, and vests. These articles exhibit varying degrees of resistance to penetration by impact of projectiles or knives, and have varying degrees of effectiveness per unit weight. A measure of the effectiveness of ballistic resistance is the energy removed from a projectile per unit of density of the target area. This is known as specific energy absorption (Specific Energy Absorption, abbreviated as "SEA"), which has units of Joules per kg / m 2 or J-m 2 / kg.
The SEA of a fibrous construction is generally known to increase with increasing strength, tensile modulus and the breaking energy of the constituent fibers. However, other factors, such as the shape of the fibrous reinforcement, may come into play. U.S. Patent No. 4,623,574, presents a comparison between the ballistic efficacy of a composite constructed with a strip-like reinforcement, compared to one using a multifilament yarn: both from UHMW PE. The fiber had a higher toughness than the strip: 30 grams / denier (abbreviated g / d) versus 23.6 g / d.
However, the SEA of the composite constructed with the strip was somewhat greater than the SEA of the composite constructed with the wires. U.S. Patent No. 4,623,574 teaches that elastomer-coated tapes or strips can be more effective than filament-coated yarn in producing ballistic-resistant composites.
The preparation of UHMW PE articles having flat cross sections by a process commonly known as "gel spinning" is described in U.S. Patent No. 5,413,110. A strip prepared by the method described in U.S. Patent No.
4,413,110 is described in U.S. Patent No.
4,623,574. It had a width of 0.64 cm, a denier of 1240, and a toughness of 23.9 g / d (corresponding to a tensile strength of 2.04 GPa).
Other processes for preparing UHMW PE tape articles are described in U.S. Patent Nos. 4,996,011; 5,002,714; 5,091,133;
5,106,555 and 5,200,129; 5,578,373; 5,628,946; 6,017,834;
6,328,923 81; 6,458,72781; 7,279,441 82; US patents 6,951,685 81; US
7,470,459 81; U.S. Patent Publications
We. 2008/0251960 Al; 2008/0318016 Al and international patent WO 2009/056286 Al.
In a group of these patents, the polyethylene filaments were subjected to a contact pressure under high temperature to selectively melt a portion of the fibers in order to bond the filaments together, followed by compression of the attached fibers. A UHMW PE SPECTRA ® yarn subjected to this process in U.S. Patent No. 5,628,946 has lost 69% of its longitudinal modulus.
In another type of these patents, polyethylene powder was compressed at high temperatures to join the particles in the form of a continuous sheet which was then compressed and stretched. U.S. Patent No. 5,091,133 describes a fiber made by means of that last mentioned process, having a tensile strength of 3.4 GPa.
Polyethylene tapes thus produced are commercially available under the trademark TENSYLON ®. The highest toughness reported on the TENSYLON ® website is 19.5 g / d (tensile strength of 1.67 GPa) Research publications that describe the preparation of polyethylene tapes and / or flattening of UHMW PE fibers include the following: RJ Van et al., "The Hot Compaction of SPECTRA Gel-Spun Polyethylene Fiber", J. Matl.
Sci., 32, 4821-4831 (1997) A. Kaito et al. "Hot Rolling and Quench Rolling of Ultrahigh Molecular Weight Polyethylene", J. Appl. Poly Sci., 29, 1207-1220 (1983); "Preparation of High Modulus Polyethylene Sheet by the Roller Drawing Method", J. Appl. Poly. SCL, 30, 4591-4608 (1985) The highest breaking strength reported in these publications was approximately 0.65 GPa corresponding to a toughness of about 7.6 g / d. In the publication by Van et al. mentioned above, the UHMW PE longitudinal module was reduced by 27 to 74%.
Each of the patents and publications mentioned above represents an improvement in the state of the art. However, none describes the specific process of the present invention and none meets all the needs covered by this invention. There is a continuing need for materials 5 that provide superior resistance to penetration by ballistic projectiles. As noted above, the SEA of a fibrous construction is known to generally increase with increasing strength, tensile modulus and breaking energy of the constituent fibers. Highly oriented UHMW PE multi-strand yarns having strengths much greater than those of the tape articles of the existing technique are commercially available. The conversion of such high strength filaments into ribbon-like articles with substantial strength maintenance could be very useful. It would also be useful to provide woven and non-woven fabrics, and articles resistant to penetration and ballistic projectiles comprising such ribbon articles.
Summary of the Invention For the purposes of the invention, a polyethylene tape-type article is defined as a polyethylene article having a length greater than its width, less than about 0.5 millimeters in thickness, and having an aspect ratio of the average cross section greater than about 10: 1.
In one embodiment, the invention is a process for producing a polyethylene tape article of indefinite length comprising: a) selecting at least one multifilament polyethylene yarn, said yarn having an e-axis orientation function at least 0.9.6, an intrinsic viscosity 5 measured in decalin at 135 ° and by ASTM 01601-99 of about 7 dl / g to 40 dl / g, and said yarn having a toughness of from about 15 g / d up to about 100 g / d, measured by ASTM 02256-02 at a measurement length of 25.4 cm (10 inches) and a stretch rate of 100% / min; b) placing said wire under a longitudinal tensile force and subjecting said wire to at least one transverse compression step to flatten, consolidate and compress said wire at a temperature of from about 25 ° C to about 137 ° C, thus forming a tape article having an average cross-sectional aspect ratio of at least about 10: 1, each said compression step having a beginning and an end, wherein the magnitude of the force of said longitudinal tensile force on each of said strands or tape article at the outlet of each of said compression steps is substantially equal to the magnitude of the longitudinal tensile strength on the wire or on the tape article at the conclusion of that same compression step, and is at least about 0.25 kilogram-force (2.45 Newtons).
e) stretching said tape article at least once, at a temperature in the range of about 130 ° C to about 160 ° and at a rate of stretching from about 0.001 min-1 to about 1 min-1; d) optionally repeat step b) one or more 5 times at a temperature of about 100 ° C to about 160 ° C; e) optionally repeat step e) one or more times; f) optionally relaxing the longitudinal tensile strength between any of steps b) to e); g) optionally increasing the longitudinal tensile strength between any of steps b) to e); and h) cooling said tape article to a temperature below about 70 ° C, under tension.
In a second embodiment, the invention is a process for the production of an article of the polyethylene tape type of indefinite length comprising: a) selecting at least one multifilament polyethylene yarn, said yarns having an axis-orientation function and of at least 0, 96, an intrinsic viscosity measured in decalin at 135 ° and by ASTM 01601-99 of about 7 dl / g to 40 dl / g, said yarn having a toughness of from about 15 g / d about 100 g / d as measured by ASTM 02256-02 at a standard length of 25.4 cm (10 inches) and with a 100% / min stretch rate;
b) pass said wires through one or more zones heated to temperatures between about 100 º and up to about 160 C, under tension;
c) stretching said heated wire
5 at least once at a stretch rate of about
0.01 min-1 to about 5 min-1;
d) placing said yarn under a longitudinal tensile force and subjecting said yarns to at least one transverse compression step to flatten, consolidate and compress said yarns at a temperature of from about 100 ºC to about 160 C , thus forming a tape article having an average cross-sectional aspect ratio of at least about 10: 1, each said compression step having a beginning and an end,
wherein the magnitude of the longitudinal tensile force on each of said strands or tape article at the beginning of each said compression step is substantially equal to the magnitude of the longitudinal tensile force on the strand or on the tape article at the conclusion of that same compression step. compression, and is at least about 0.25 kilogram-
force (2.45 Newtons);
e) stretching said tape article at least once, at a temperature of from about 130 ° and about 160 ° and at a stretch rate of about 0.001 min-1 to about 1 min - 1 ;
f) optionally repeat step d) one or more times; g) optionally repeat step e) one or more times; h) optionally relaxing the longitudinal tensile force 5 between any of the steps c) to g); i) optionally increase the longitudinal tensile strength between any of steps c) to g); and j) cooling said tape article to a temperature below about 70 ° C under tension.
In a third embodiment, the invention. is a polyethylene tape type article of indefinite length and an average cross-sectional aspect ratio of at least 10: 1, said polyethylene having an intrinsic viscosity measured in decalin at 135 C by ASTM 01601-99 from about 7 dl / g to about 40 dl / g, and, when measured by ASTM 0882 at a standard length of 25.4 cm (10 inches) and at a stretch rate of 100% / min, said tape article has a tensile strength of at least about 3.6 GPa.
In a fourth embodiment, the invention is a fabric comprising the ribbon articles of the invention, said fabric being selected from the group comprising weave, weft and fabric of a three-dimensional character.
In a fifth embodiment, the invention is a laminate comprising two or more unidirectional layers of the tape articles of the invention with the direction of the tape in the adjacent layers being mutually rotated relative to each other by about 15 to about 90 degrees.
In a sixth embodiment, the invention is an impact and penetration resistant composite comprising at least one member selected from the group consisting of a fabric of the present invention, a laminate of the invention, and the combination thereof.
Brief Description of the Drawings Figure 1 illustrates a first equipment to implement a process of the invention.
Figure 2 illustrates a second equipment for implementing a process of the invention.
Figure 3 illustrates a third piece of equipment for implementing a process of the invention.
Figure 4 illustrates an equipment for implementing a fourth process of the invention.
Figure 5 illustrates an equipment for implementing a fifth process of the invention.
Figure 6 illustrates an equipment for implementing a sixth process of the invention.
Figure 7 illustrates a seventh device for implementing a process of the invention.
In each figure only one end of the wire is shown for clarity. It will be understood that the various ends of the yarn can be simultaneously treated in parallel through a process of the invention to produce several articles of ribbon in parallel, or a single article of wide ribbon.
Detailed Description of the Invention A process is provided for converting high strength UHMW 5 PE yarns into ribbon articles with substantial resistance retention. The inventive method provides substantially equal longitudinal tensile forces over a compression step. It is believed that the method of the invention is superior to the methods of the existing technique that maintain equal tensile stress (g / d) throughout a compression step with the consequent unbalanced tensile forces.
For the purposes of the invention, a polyethylene tape-type article is defined as a polyethylene article having a length greater than its width, less than about 0.5 millimeters in thickness, and having an aspect ratio of the cross section average greater than about 10: 1. Preferably, a tape article of the invention has a width of less than about 100 cm, more preferably less than about 50 cm, even more preferably less than about 25 cm, and more preferably, less than about 15.2 cm.
Preferably, a tape article of the invention has a thickness of less than about 0.25 millimeters, more preferably, a thickness of less than about 0.1 millimeters and, more preferably, a thickness of less than 0.05 millimeters. The thickness is measured in the thickest region of the cross section.
The aspect ratio of the average cross section is the average ratio between the largest dimension to the smallest dimension of the cross section over the length of the tape article. Preferably, a tape article of the invention has an average cross-sectional aspect ratio of at least about 20: 1, more preferably at least about 50: 1, even more preferably at least about 100: 1, even more preferably at least about 250: 1 and most preferably at least about 400: 1.
The cross section of a tape article of the invention can be rectangular, oval, polygonal, irregular, or any shape that meets the requirements for width, thickness and aspect ratio. Preferably a tape article of the invention has an essentially rectangular cross section.
The UHMW PE yarn selected as a feed for a process of the present invention can be prepared by any convenient method. Preferably, the selected UHMW PE yarn is prepared by "spinning gel".
UHMW PE yarns produced by "gel spinning" are commercially available from Honeywell International under the trade name® SPECTRA, from DSM NV and Toyobo Co. Ltd., under the trade name DYNEEMA ®, from Shanghai Pegaus Materials Co.,
Ltd., Hangzhou High Strength Fiber Material Inc. and others.
The UHMW PE yarn selected as a feed for a process of the present invention has an intrinsic viscosity 5 measured in decalin at 135 and ASTM 01601-99 from about 7 dl / g to about 40 dl / g, preferably about from 10 dl / g to about 40 dl / g, more preferably from about 12 dl / g to about 40 dl / g, and most preferably, from about 14 dl / g to 35 dl / g.
The UHMW PE yarn selected as a feed for a process of the present invention is highly oriented. A highly oriented UHMW PE yarn in the context of the invention is defined as having an e-axis orientation function of at least about 0.96, preferably at least about 0.97, more preferably at least about 0, 98 and more preferably at least about 0.99. The e-axis orientation function is a description of the degree of alignment of the direction of the molecular chain, with the direction of the fiber and is calculated from the equation reported by RS Stein, J. Poly Sei., 31, 327 (1958) .
2 ~ - {3 <coso> -1). 1 t "e; :: = 2 where 8 is the angle between the axis- and the polyethylene crystal (the direction of the molecular chain) and the direction of the fibers and the <> signs indicate the average of the interspersed quantity.
The average cosine of the angle between the crystal axis "c" and the direction of the fiber is measured using well-known X-ray diffraction methods. A polyethylene fiber in which the direction of the molecular chain is perfectly aligned with the fiber axis would have an fc = 1.
The UHMW PE yarn selected as a feed for a process of the present invention has a toughness of about 15 g / d of about 100 g / d, preferably of about 25 g / d of about 100 g / d, more preferably from about 30 g / d to about 100 g / d, even more preferably from about 35 g / d to about 100 g / d, even more preferably from about 40 g / d to about 100 g / d, and more preferably, about 45 g / d about 100 g / d.
The UHMW PE yarn selected as a feed for a process of the present invention can be, without twisting, or can be twisted. Preferably, the yarn is less than about 10 twist turns per inch in length. The UHMW PE wire selected as a feed can be thermoset using a process described in U.S. Patent No. 4,819,458 incorporated herein by reference, insofar as it does not conflict with that described.
The UHMW PE yarn selected as a feed for a process of the present invention can consist of unbound filaments, or the filaments can be at least partially joined by melting or gluing. The melting of the filaments of the UHMW PE yarn can be achieved by several means. Convenient means include the use of heat and stress, or by applying a solvent or plasticizing material prior to exposure to heat and stress, as described in U.S. Pat.
5,540,990, 5,749,214, 6,148,597 incorporated herein by reference, insofar as it does not conflict with the described. Bonding can be achieved by at least partially coating the filaments with a material having adhesive properties, such as KRATON® 01107.
In a first embodiment, the invention is a process for the production of an article of the polyethylene tape type of indefinite length comprising: a) selecting at least one multifilament polyethylene yarn, said yarn having an axis-orientation function and at least 0.96, an intrinsic viscosity measured in decalin at 135 C by ASTM 01601-99 of about 7 dl / g to 40 dl / g, and said yarn having a toughness of from about 15 g / d up to about 100 g / d, measured by ASTM 02256-02 at a measurement length of 25.4 cm (10 inches) and a stretching rate of 100% / min; b) placing said wire under a longitudinal tensile force and subjecting said wire to at least one transverse compression step to plan, consolidate and compress said wire at a temperature of from about 25 C to about 137 and, thus forming a tape article having an average cross-sectional aspect ratio of at least about 10: 1, each said compression step having a beginning and an end, in which the magnitude of the force of said longitudinal tensile force on each one of said strands or tape article at the outlet of each of said compression steps is substantially equal to the magnitude of the longitudinal tensile force on the wire or on the tape article at the conclusion of that same compression step, and is at least about 0.25 kilogram-force (2.45 Newtons).
c) stretching said tape article at least once, at a temperature in the range of about 130 C to about 160 C at a stretch rate of about 0.1 O 1 min -1 to about 1 min -1 ; d) optionally repeat step b) one or more times at a temperature of about 100 ° C to about 160 ° C; e) optionally repeat step c) one or more times; f) optionally relaxing the longitudinal tensile strength between any of steps b) to e); g) optionally increasing the longitudinal tensile strength between any of steps b) to e); and h) cooling said tape article to a temperature below about 70 ° C, under tension.
Preferably, steps b) through h) are carried out continuously.
In a second embodiment, the invention is a process for the continuous production of a polyethylene tape type article of indefinite length comprising: a) selecting at least one multifilament polyethylene yarn, said yarns having an axis orientation function -and at least 0.96, an intrinsic viscosity measured in decalin at 135 C by ASTM 01601-99 of about 7 dl / g to 40 dl / g, said yarn having a toughness of from about 15 g / d of about 100 g / d as measured by the ASTM D2256-02 standard at a standard length of 25.4 cm (10 inches) and with a stretch rate of 100% / min; b) passing said wires through one or more zones heated to temperatures between about 100 º and up to about 160 C, under tension; e) drawing said heated yarn at least once at a drawing rate of about 0.01 min-1 to about 5 min-1; d) placing said yarn under a longitudinal tensile force and subjecting said yarns to at least one transverse compression step to flatten, consolidate and compress said yarns at a temperature of from about 100 ºC to about 160 and, thus forming a tape article having an average cross-sectional aspect ratio of at least about 10: 1, each said compression step having a start and end, in which the magnitude of the longitudinal tensile force in each 5 of said strands or tape article at the beginning of each said compression step is substantially equal to the magnitude of the longitudinal tensile force on the wire or on the tape article at the conclusion of that same compression step, and is at least about O .25 kilogram-force (2.45 Newtons); e) stretching said tape article at least once, at a temperature of from about 130 ° to about 160 ° and at a stretch rate of about 0.01 mm to about 1 mm - 1 ; f) optionally repeat step d) one or more times; g) optionally repeat step e) one or more times; h) optionally relaxing the longitudinal tensile force between any one of steps c) to g); i) optionally increase the longitudinal tensile strength between any one of steps c) to g); and j) cooling said tape article to a temperature below about 70 ° C under tension.
Preferably, steps b) through j) are carried out continuously.
A continuous process of the first embodiment is illustrated schematically in Figures 1, 2 and 7. A continuous process of the second embodiment is illustrated schematically in Figures 3-6. The figures illustrating a particular embodiment differ in the number and placement of process equipment, but illustrate the same steps.
In each of Figures 1 to 7, a selected UHMW PE multifilament yarn (10-16, respectively) is unwound from a bundle or bundle (not shown) and passed over and under the various restraining rollers (20). The restriction rollers are at a temperature of about 25 ° C to about 137 ° C. In Figures 1, 2 and 7, the wire that leaves the restraining rollers (80, 81, 86, respectively) is passed under tension directly to one or more means (30, 33, 39) to compress, consolidate and flatten the wire , thereby forming a ribbon-like article. The tape article is subsequently heated and stretched at least once.
In Figures 3 to 6, the wire that leaves the restriction rollers (82-85, respectively) is heated and stretched before reaching a medium for its compression. The heating of a wire can be through any means, such as by infrared radiation, contact with a heated surface, or contact with a heated fluid. Preferably, the wire is heated and stretched in a forced air convection oven (50-59, 510 in Figures 1-7), with multiple temperature zones. The yarn is drawn at least once at temperatures between about 100 ° C to about 160 ° and at a stretch rate of about 0.01 min-1 to 5 about 5 min-1 • The stretch rate is defined as the difference between the speed at which a material leaves a stretch zone (V 2) and the speed at which it enters a stretch zone (V 1), divided by the length of the stretch zone (L), that is , Stretch ratio (V2-Vl) / L, min- 1 Preferably, the yarn is stretched to a stretch ratio of from about 1.01: 1 to about 20: 1 at a temperature of about 135 ºe until about 155 e. Preferably, the stretching rate is the maximum possible without breaking the thread.
In both of the above embodiments, each strand or article of tape is under a longitudinal tensile force at both the start and finish of compression in each medium for compression (30-40). Longitudinal traction force is regulated by regulating the speeds of the successive operating means.
The magnitude of the longitudinal tensile force on the wire or on the tape article at the beginning of each compression step is substantially equal to the magnitude of the longitudinal tensile force on the wire or on the tape article at the conclusion of the same compression step. In the context of the invention, the term "substantially equal" means that the ratio of a lower tensile strength to a greater tensile strength over a compression step is at least 5, 0.5: 1, preferably at least 0.8 O: 1, more preferably at least 0.85: 1, even more preferably at least 0.90: 1 and most preferably at least 0.95: 1. Such substantially equal longitudinal tensile strength at the beginning and completion of a compression step is a fundamental feature of the creative process. Equal tensile forces throughout a compression step ensure zero stress at the midpoint of the compression.
It is believed that the inventive method is superior to the methods of the existing technique that maintain tensile efforts (g / d) through a compression medium with the consequent unbalanced tensile forces as the denier is reduced. The inventive method allows for higher temperatures and pressures in a compression step without breaking the wire or tape article, or slipping in a compression medium. It is believed that this allows for higher speeds and productive capacities to achieve higher strengths.
The longitudinal tensile strength is at least 0.25 kg-force (abbreviated Kgf, equal to 2.45 Newtons, abbreviated N) on the wire or on the tape article at the beginning and at the end of a compression step. Preferably, the tensile strength is at least 0.5 Kgf (4.9 N) 'more preferably at least 1 Kgf (9.8 N), even more preferably at least 2 Kgf (19. 6. 2 N), and another 5 preferably at least 4 Kgf (39.2 N) at the beginning and completion of a compression step. More preferably, the longitudinal tensile strength is as high as possible without breaking the thread and without causing the thread or tape article to slip in a compression medium.
For clarity without the intention of limiting the scope of the invention, the illustrated compression means (30-40 °) in each of Figures 1-7 are opposing rollers, in counter-rotation (pinch rollers): each pinch roll of a unit preferably has the same surface speed, and exerts pressure on the wire or the tape article.
Other suitable and well-known means of compression include sequences of pressure rollers consisting of three or more rollers in a single unit providing two or more pairs of compression straps which press on opposite sides against the rolls of wire or tape article where the wire or the tape article makes a 180º turn under high tension or the like. The pressure applied by the clamping rollers and the moving straps can be interacted by hydraulic cylinders, or the pressure can result from the fixing of an opening between the rollers in a dimension less than the thickness of the inlet material. Still other means of compression are possible and are contemplated.
The means for compression can be vibrated.
Considering the tape article as an almost two-dimensional object with negligible composition and width but negligible thickness, the vibration may be in a direction normal to the plane of the tape article, or in the plane of the tape article or in an inclined direction in relation to both planes .
The vibration can be of low frequency, or of sonic or ultrasonic frequencies. Vibration can be used as an aid in consolidation by transmitting additional pressure or shear pulses. It can also be used to produce periodic variations in the thickness or width of the compressed article useful for bonding in composite applications.
The pressure exerted in a compression step in each modality is about 0.14 to about 69 MPa (from about 20 to about 10,000 psi), preferably about 0.34 to about 34 MPa ( from about 50 to about 5000 psi), and more preferably from about 0.69 to about 17 MPa (from about 50 to about 2500 psi) The pressure is preferably increased in successive stages of compression.
The compression means are at a temperature of from about 25 ° C to about 160 ° C, preferably from about 50 ° to about 155 ° C, and more preferably from about 100 ° to about 150 ° C. .
After passing through at least one compression medium, for example, (30) in Figure 1, a newly formed tape article (100) is heated and stretched at least once. Heating of the tape article can be done by any means; such as by infrared radiation, contact with a heated surface, or contact with a heated fluid. Preferably, the tape article is heated and stretched in a forced air convection oven (50, 51) having multiple temperature zones marked by the dashed lines in the figures. Heaters and blowers are not shown in the Figures to heat and circulate the air through the oven.
The stretching of the tape article is at a temperature of from about 100 ° to about 160 ° or 0 ° C, and preferably about 135 ° and about 15 °. The tape article is stretched at a stretch rate of about 0.001 min-1 to about 1 min-1 • Preferably, the tape article is stretched at a stretch rate of about 0.001 min-1 to about 0 , 1 min-1 • Preferably, the tape article is stretched at a stretch ratio of from about 1.01: 1 to 20: 1.
The drawing force can be applied by any convenient means, such as passing the yarn over and under a sufficient number of drive rollers (60), as shown in Figures 2, 3, 4 and 6; by compression means (31, 32, 40), as illustrated in Figures 1 and 7; by both compression means (36 '37.40) and drive rollers (60, 61) as in Figures 5 and 7, or by wrapping the article tape several times around a pair of godet and tensioner type rollers ( (not shown) The drive rollers that apply the stretch force can be internal to the oven or external to the oven.
The longitudinal tensile strength does not need to be the same throughout a continuous operation.
Optionally, a strand or tape article can be relaxed to a lower longitudinal tensile strength or left to retract less than about 5% between successive compressions or stretches by means of tension isolation.
Alternatively, the tension can be increased between successive compressions or stretches by means of tension isolation. In Figure 7, the rollers (61) act as a means of insulating tension. The tensile force on the tape article (114) can be greater or less than on the tape article (113), depending on the speed of the pinch rollers (39) and (40) and the temperatures in the two furnaces. In both cases, the speed of the restriction rollers (20) and drive rollers (60) are adjusted to maintain a constant tensile force between the compression means (39 and 40).
The tape article is cooled under tension before being transported to a winder. The length of the tape article will decrease slightly due to thermal contraction, but the tension must be sufficiently high during cooling to prevent shrinkage beyond thermal contraction. Preferably, the tape article is cooled in rolls (60) and the rolls are cooled by natural convection, forced air circulation, or are internally water-cooled. The final stretched tape article (70-76), cooled under tension to a temperature of less than about 70 ° C, is wound under tension (winder not shown) as a bundle or in a bundle.
As noted above, the amount and positioning of the compression and stretching means can be varied within a particular embodiment, as illustrated schematically in the figures.
Figure 1, which illustrates the first modality, shows a sequence of compression-stretching-compression-stretching-compression.
Figure 2 illustrates the first modality showing a sequence of compression-compression-stretching.
Figures 3-6 illustrate the second embodiment of the invention. Figure 3 shows a stretch-compression-stretch sequence.
Figure 4 shows a stretch sequence-three consecutive compressions-stretch.
Figure 5 shows a stretch-compression-stretch-compression-stretch sequence in a six-zone oven (57).
Figure 6 shows a stretch-two consecutive compression-stretch sequence in a four-zone oven (58) Figure 7, which illustrates the first embodiment, shows a compression-stretch-stretch sequence 5 at increased tensile-compression strength.
Many other processing sequences consistent with either the first or the second of the embodiments of the invention are possible, and are contemplated.
Preferably, a process of the invention produces a tape article with a tensile strength of at least about 2.2 GPa, more preferably of at least about 2.6 GPa, even more preferably of at least about 3.0 GPa , and more preferably at least about 3.6 GPa.
Preferably, a process of the invention produces a tape article with a tensile strength of at least 75% of the strength of the yarn from which it is made. More preferably, a process of the invention produces a tape with a tensile strength greater than that of the yarn from which it is made.
A third embodiment of the invention is a polyethylene tape-like article of indefinite length and an average cross-sectional aspect ratio of at least 10: 1, said polyethylene having an intrinsic viscosity measured in decalin at 135 C by ASTM
D1601-99 from about 7 dl / g to about 40 dl / g, and when measured by ASTM D882 at a measurement composition 25.4 cm (10 inches) at a 100% / min stretch rate, said tape article having a tensile strength of at least about 3.6 GP a.
In a fourth embodiment, the invention is a fabric comprising the tape articles of the invention, said fabric to be selected from the group consisting of weave, weft and fabric of a three-dimensional character. Preferably, a fabric of the present invention is composed of at least 50% by weight of the tape articles of the invention.
In a fifth embodiment, the invention is a laminate comprising two or more unidirectional layers of the tape articles of the invention with the direction of the tape in the adjacent layers being mutually rotated relative to each other by about 15 to about 90 degrees.
In a sixth embodiment, the invention is an impact and penetration resistant composite comprising at least one member selected from the group consisting of a fabric of the present invention, a laminate of the invention, and a combination thereof. Preferably, a compound of the invention is resistant to penetration by ballistic projectiles and by knives and other sharp or pointed tools.
The following examples are presented to provide a more complete understanding of the invention. The specific techniques, conditions, materials, proportions and reported data established to illustrate the principles of the invention are exemplary and should not be construed as limiting the scope of the invention.
Measurement Methods 5 Intrinsic viscosity Intrinsic viscosity measurements were made by ASTM 01501 -99 in 135 e decalin solution.
Yarn tenacity Yarn tenacity was measured by ASTM 02256-02 at a standard length of 25.4 cm (10 inches) at a 100% minimum stretch rate.
Tape tensile strength The tape tensile strength was measured by ASTM 0882-09 at a standard length of 25.4 cm (10 inches) and with a 100% stretch / min stretch rate.
Orientation function The e-axis (fc) orientation function was measured by the open-angle x-ray diffraction method described in Correale, ST and Murthy, Journal of Applied Polyrner Science, Vol. 101, 447-454 (2006) such as applied to polyethylene.
EXAMPLES Examples 1 to 2 provide testing of simplified systems.
EXAMPLE 1 (Comparative)
A 1200 denier multi-strand UHMW PE yarn • having an intrinsic viscosity of 12 dl / g, an e-axis orientation function of 0.99, and an initial toughness of 28 g / d, was twisted at 2.76 turns / cm (75 turns / inch). The tenacity of the twisted yarn was 15.5 g / d. The twisted wire was pulled and fused and then statically compressed in a press between plates at a temperature of 22 C and a pressure of about 55 MPa (about 8,000 psi). The tensile strength of the 10-tape article was 2.0 GPa corresponding to a toughness of 23.4 g / d. The tape article maintained 83.6% of the resistance of the initial yarn without twist.
EXAMPLE 2 (Comparative) A 4800 denier 15 multifilament UHMW PE yarn having an intrinsic viscosity of 14 dl / g, an e-axis orientation function of 0.99, and a toughness of 28 g / d was twisted about 0 .01 turns / cm (about 0.025 turns per inch). The yarn was stretched at a ratio of 2.5: 1 in a forced air convection oven at a temperature of 20 155.5 ºe and at a stretching rate of 1.07 min- 1 The yarn filaments were thus at least partially fused together. The toughness of the stretched and fused yarn was 20 g / d.
The stretched and fused wire having a diameter of about 25.0 cm was continuously drawn along a steel plate at a temperature of 152 C and then
through a fixed opening between the bottom heated steel plate • and an unheated top steel plate. The upper plate was inclined at an angle to the lower plate in such a way that its lower edge defined a line of contact with the wire. The tensile strength on the wire was 225 g in the opening and 400 g when leaving the opening.
the wire was continuously flattened, consolidated and compressed in the passage through the opening under tension, thereby forming a tape. The tape remained in contact with the heated plate beyond the compression opening and some stretching may have occurred.
The tape article thus produced had lateral dimensions of 0.012 cm (0.05 inch) thick by 15 0.254 cm (0.10 inch) wide, and a 20: 1 aspect ratio. The tape tensile strength was 1.62 GP a, corresponding to a toughness of 19 g / d, and 68% of the strength of the original yarn.
EXAMPLE 3 20 the following example shows the best method contemplated by the inventors for carrying out the first embodiment of the invention.
A 1200 denier spinning UHMW PE yarn produced by 1200 denier spinning gel about 0.01 turn / cm is selected having an intrinsic viscosity of 14 dl / g, an O-axis orientation function, 99, and a toughness of 47g / d. • As illustrated in Figure 1, the yarn (10) is unwound from a bundle in a warper (not shown) and passed over restraining rollers (20). The rollers are at a temperature of 130 e. The wire leaving the restraining rollers (80) is passed at a speed of 5 meters / min, directly to a first pair of pinch compression rollers (30). The tightening rollers apply a longitudinal tensile force of 2.5 Kgf (24.5 N) to the wires. The tightening rollers are at a temperature of 135 ° C. The wire is flattened, consolidated and compressed on the tightening rollers under a pressure of about 3.4 KPa (500 psi), forming a tape article (100). The tape article leaving the first pair of pinch rollers (30) is under a longitudinal tensile force 15 of 2.5 Kgf (24.5 N) applied by a second pair of pinch rollers (31).
The tape article (100) enters and passes through two zones of a forced air convection oven (50) in the passage between the pinch rollers (30) and (31). The temperatures in the oven are: Zone 1: 149 and Zone 2: 150 ºC. The tape article (100) is drawn at a stretch rate of 0.11 min-1 in the oven (50). The stretched tape article is compressed a second time in nip rolls (31, and is passed in a second oven (51). The temperatures in the second nip roll are 14 7 e. compressed and stretched once (101) is stretched at a stretch rate of 0.096 min-1 in the first and second zones of the second kiln (51) under the influence of a 2.5 kgf longitudinal tensile strength (29.4 N) applied by a third 5 pair of pinch rollers (32) The zone temperatures in the oven (51) are 151 and 152 and, respectively.
The tape article is then compressed a third time under a pressure of about 3.4 kPa (500 psi) at temperatures of the pinch roll of 150 and the third set of pinch rollers (32). The longitudinal tensile strength in the tape article is essentially constant at 2.5 Kgf (2 9, 4 N) at the inlet and outlet of the third set of pinch rollers. The longitudinal tensile force on the tape article at the outlet of the third set of pinch rollers (32) is applied by external rollers (60).
The tape is cooled under tension to a temperature of 50 C on the outer rollers (60). The final tape article (7 O) is wound under tension at a speed of 7.5 meters / min.
The new tape article produced has an essentially rectangular cross section with a thickness of 0.00697 cm, a width of 0.135 cm and an aspect ratio of the average cross section of 20: 1. The tensile strength of the tape article is 3,6 GPa corresponding to a toughness of 42 g / d. The tape article retains 89% of the strength of the yarn from which it is produced.
EXAMPLE 4 the following example shows the best method contemplated by the inventors for carrying out the second embodiment of the invention.
5 A multi-threaded UHMW PE yarn produced by a 4800 denier spinning gel, twisted at 0.01 turn / cm is selected having an intrinsic viscosity of 15 dl / g, an '98' e-axis orientation function and a toughness of 45 g / d.
As illustrated in Figure 3, the yarn (12) is unwound from a bundle in a warp (not shown) and is passed continuously along restraining rollers (20). o The rollers are at a temperature of 135 C. The wire that leaves the restriction rollers (82) is passed at a speed of 5 meters / min to a two-zone oven (53) under a longitudinal tensile force of 8 Kgf ( 78, 4 N). The longitudinal tensile force is regulated by the speed of the clamping rollers (34). The temperatures of the first and second zones of the second oven are 14 9 C and 150 C, respectively. The yarn is drawn at a stretch rate of 0.9 min-1 in the oven (53) before entering the tightening rollers. The stretched yarn is compressed into nip rolls (34), at a temperature of 152 ° C, forming a tape article.
The tape article is passed to a second oven (54) and stretched under a longitudinal tensile strength of 8 Kgf (78.4N). The longitudinal tensile strength is regulated by the speed of: external fools (60). The tape article is stretched at a stretch rate of 0.086 min-1 at a temperature of 152 ° C. The tape is cooled under tension to a temperature of 5 50 C on the outer rollers (60). The final tape article (72) is wound under tension at a speed of 7 meters / min.
The new tape article produced has an essentially rectangular cross section with a thickness of 0.00627 cm, a width of 0.627 cm and an average cross section aspect ratio of 100: 1. The tensile strength of the tape article is 3.6 GP a corresponding to a toughness of 42 g / d. The tape article maintains 93% of the strength of the yarn from which it is produced.
EXAMPLE 5 A ribbon article of the invention as described in Example 3 is woven in the form of a flat weave fabric having a warp and fill count of 7.2 per centimeter.
EXAMPLE 6 A ribbon article of the invention as described in Example 4 is woven in the form of a flat weave fabric having a warp and fill count of 1.5 per centimeter.
EXAMPLE 7 A tape article of the invention as described in
Example 3 or Example 4 is wrapped in a multiplicity of • packages and the packages are placed on a warp.
Multiple ends of the ribbon articles, unrolled from the warp, aligned in parallel in lateral contact, are placed on a transport web consisting of a 0.00035 cm thick high density polyethylene film (HDPE). The conveyor web and tape are passed through heated, pressure-tightened rollers to make the tape articles adhere to the conveyor web. The 10 conveying webs and the adherent parallel tape articles are wound on two rolls.
The two rolls are fed to a device for cross-overlapping, as described in U.S. Patent No. 5,173,138, in which the webs containing the 15 tape articles are overlapped and consolidated by means of heat and pressure. A four layer laminate is thus formed where the layers, in sequential order across the laminate are HDPE-tape articles-tape articles-HDPE, and the direction of the tapes in the adjacent layers are mutually perpendicular. This laminate of the invention is rolled up.
EXAMPLE 8 Fabrics of the invention as described in Example 5 or Example 6 are overlapped and loosely connected to form an assembly of the invention having an area density of 1.5 kg / m 2 • The assembly of the invention is expected to have a specific energy absorption of at least about 500 Jm 2 / Kg against a 9 x 19 mm Parabellum FMJ projectile, as measured by MIL.-STD. 662F.
EXAMPLE 9 Laminates of the invention as described in Example 5 7 are superimposed and consolidated to form an impact and penetration resistant composite article of the invention having an area density of 1.5 kg / m 2 • The composite article is expected of the invention has a specific energy absorption of at least about 500 Jm 2 / Kg against a 9 x 19 mm projectile of Parabellum FMJ, as measured by MIL.-STD. 662F.
Having thus described the invention in detail, it will be understood that such details need not be strictly observed, but that additional changes and modifications can be properly suggested by those usually skilled in the art, and falling within the scope of the invention, as defined by the attached claims. .

权利要求:
Claims (10)
[1]
1. PROCESS FOR THE PRODUCTION OF AN ARTICLE OF TYPE OF POLYETHYLENE TAPE, characterized by comprising: a) selecting at least one polyethylene yarn 5 multi-strands, said yarn having an e-axis orientation function of at least 0.96, an intrinsic viscosity measured in decalin at 135 ° C by ASTM D1601-99 of about 7 dl / g to 40 dl / g, and said yarn having a toughness of from about 15 g / d to about 100 10 g / d, measured by ASTM D2256-02 at a measurement length of 25.4 cm (10 inches) and a stretching rate of 100% / min; b) placing said yarn under a longitudinal tensile force and subjecting said yarn to at least one transverse compression step to flatten, consolidate and compress said yarn at a temperature of from about 25 C to about 137 C , thus forming a tape article having an average cross-sectional aspect ratio of at least about 10: 1, each said compression step having a beginning and an end, in which the magnitude of the force of said longitudinal tensile force on each of said strands or tape article at the outlet of each of said compression steps is substantially equal to the magnitude of the longitudinal tensile force on the wire or on the tape article at the conclusion of that same compression step, and is at least minus about 0.25 kilogram-force (2.45 Newtons). • c) stretch said tape article at least once, at a temperature in the range of about 130 C to about 160 º and at a stretch rate of about 0.001 min-1 to about 1 min-1 ; d) optionally repeating step b) one or more times at a temperature of about 100 ° C and up to about 160 ° C; e) optionally repeat step c) one or more 10 times; f) optionally relaxing the longitudinal tensile strength between any of steps b) to e); g) optionally increasing the longitudinal tensile strength between any of steps b) to e); and 15 h) cooling said tape article to a temperature below about 70 ° C, under tension.
[2]
2. Process according to claim 1, characterized in that steps b) through h) are carried out continuously.
[3]
3. Process according to claim 1, characterized in that the selected multifilament yarn is less than about 10 twist turns per 2.54 cm (1 inch) in length.
[4]
4. Process according to claim 1, characterized in that the filaments of the selected multifilament yarn are connected by means of a process selected from the group consisting of melting and gluing. •
[5]
Process according to claim 1, characterized in that the resistance of the tape article measured by ASTM D882-09 to a standard length of 25.4 cm (10 5 inches) and with a stretching rate of 100% / min , is at least 75% of the strength of the multifilament yarn from which it was produced.
[6]
6. Process according to claim 1, characterized in that when measured by ASTM D882-09 at a standard length of 25.4 cm (10 inches) and with a stretching rate of 100% / min, said article of tape has a tensile strength of at least about 2.2 GPa.
[7]
Process according to claim 1, characterized in that a means for compression is vibrated 15 in a direction with respect to the plane of a tape article selected from the group consisting of normal to said plane, in said plane and inclined with respect to both those plans. .
[8]
8. POLYETHYLENE TAPE ARTICLE, with an average cross-sectional aspect ratio of at least about 10: 1, said polyethylene characterized by having an intrinsic viscosity measured in decalin at 135 C by ASTM Dl601-99 of about of 7 dl / g to 40 dl / g, and when measured by ASTM D882-09 at a standard length of 25.4 cm (10 25 inches) and at a stretch rate of 100% / min, said tape article has a tensile strength of at least about 3.6 GPa. •
[9]
9. LAMINATE, comprising two or more unidirectional layers of tape articles, as described in claim 8, characterized in that the direction of the tape in the 5 adjacent layers are mutually rotated relative to each other, by about 15 to about 90 degrees.
[10]
10. IMPACT AND PENETRATION RESISTANT ASSEMBLY, characterized by comprising at least one member 10 selected from the group consisting of a fabric, according to claim 9.

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法律状态:
2020-08-25| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

2020-09-15| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

2021-01-05| B11B| Dismissal acc. art. 36, par 1 of ipl - no reply within 90 days to fullfil the necessary requirements|

2021-11-03| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

申请号 | 申请日 | 专利标题

US12/539,185|2009-08-11|

US12/539,185|US8236119B2|2009-08-11|2009-08-11|High strength ultra-high molecular weight polyethylene tape articles|

PCT/US2010/043634|WO2011019512A2|2009-08-11|2010-07-29|High strength ultra-high molecular weight polyethylene tape articles|

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