CA2132013C - Non-woven layer consisting substantially of short polyolefin fibers - Google Patents

Abstract

The invention relates to a non-woven layer that consists substantially of short polyolefin fibres the non-woven layer being a felt with in the plane of the layer substantially randomly oriented fibres with a length of 40-100 mm, a tensile strength of at least 1.2 GPa and a modulus of at least 40 GPa. The invention also relates to a method for the manufacture of this felt and to layered structures in which the felt is used. Layered structures comprising a non-woven layer according to the invention have improved specific energy absorption on impact of ballistic projectiles.

Description

1 ..
NON--WOVEN LA~.'Ek CONSISTING SUBSTANTTALLY
OF S~-iORT POLYOLEFIN FIBRES
The invention relates to a non-woven layer that consists substantially ;~f short pol.yolefin fibres. Such a non-woven layer is known from WO-A-89/01126. This known layer consists of polyolefin fibres, having a length of at most 20.3 cm, which are substantially unidi.rectionally oriented and are embedded in a polymeric matrix. This known layer is used in layered ballistic-resistant structures.
A drawback of this layer is that the specific energy absorption (SEA;, that is the energy absorbtion on ballistic impact divided by the cereal density (weight per m2) , is still Low. Because of this the ballistic-resist<~nt layer must have a high weight per m2 to offer sufficient protection against ball:iatic impacts. A further drawback is that the layer comprise; a matrix, as a result. oi: which it is less flexib::ie and dc:ee not breathe as well. Because of this, ballistic-resist«mt. clothing, such as fragment-resistant and bull.etprc:c f vests, ir: which this layer is incorporated i.s not ve~.:y comfortable tc wea r.
In one aspect, the inventicm provides a non-woven layer comprising short palyolefin fibers having a tensile strength of at: least 1.2 GPa and a madulus of at least 40 GPa, wherein the non-woven layer is a felt comprising at least 80~, by volume, of short polyolefin fibers which are substantially randomly oriented in the plane of the non-woven layer and have a length of 40-100 mm.
In a further aspect, the invention provides a non-woven layer comprising short polyo:lefin fibers having a - la -tensile strength of at least 1.2 GPa and a modulus of at least 40 GPa, wherein the non-woven layer is a felt consisting of the short. polyolefin fibers which are substantially randomly oriented in the plane of the non-woven layer anal which a.r~~ crimped, have a length of 40-100 mm and have a fineness of between 0.5 and 8 denier.
In a. still further aspect., the invention provides a method for the manufacture of a non-woven layer according to any one of claims 1 i~~~ 9, comprising: (a) carding a mass of loose short polyo:lefin fibres into a carded non-woven web, the loose short pca:Lyolefin fibres having a tensile strength of at least. 1.2 GPa, a modulus ;~f at least 40 GPa, a length of between 40 and 100 mm, and a substantially unidirectional orientic;n; (b) feeding the carded non-woven web obtained in step (a) to a discharge moving in a direction perpendicular t.o that in which the non-woven web is supplied, c>nto which the web is deposited in zigzag folds while being si.multaneomsly discharged, so that in the discharge directian a ~:t.Gcked layer: is formed that consists of a number of stacked layers of the supplied carded non-woven web that partly ;verlap one another widthwise;
(c) calendering the stacked layer obtained in step (b), in which the thickness of the layer is reduced, to obtain a calendered la~Ter; (d) :stretching the calendered layer obtained in step (c) irl the discharge direction of the calendered layer obtaitued in step (c); and (e) entangling the stretched layer obt:.ained in step (d) to form a felt layer.
In the invention the non-woven layer is a felt having in the plane of the layer s~abstartially randomly 1b -oriented short fibres wi_tln a length of 40-100 mm, a tensile strength of at least 1.2 ~Pa and a modulus of at least 40 GPa.
A felt is a layer wherein the individual fibre's are not assembled together to form a specific structure 7_ike obtained when yarns are knitted or woven and which layer does by definition not ~~omprise a matrix.

_ 2 _ Surprisingly. it has been found that this layer has an improved specific energy absorption (SEA) and is hence very suitable for use in a layered ballistic-s resistant structure, in particular for protection against (shell) fragments.
'Good ballistic-resistant properties' is hereinafter understood to be in particular a high SEA. In the field of layered ballistic-resistant structures 'high SEA' is generally unaerstood to be an SEA of more than 35 Jm2/kg. The SEA i~ aetermined according to test standard Stanag 2920 using a fragment-simulating projectile of 1.1 + 0.02 g. The SEA of the non-woven layer according to the invention is preferably more thar. 40 Jm'/kg and more preferably more ttlar: 50 Jm'/kg and most preferably more than 60 Jm~/kg.
The advantage of a high SEA is that fragments with a certain velocity can be arrested by a layer With substantially iowe: areal density. A low areal density 2G very impcrtant fc~ increasing the comfort in wearing, WhlCh, besioes CCCG ~':i.LECtiG~ra, 1~ ttiE ITiclri aim in developing nE~~ mar: ir.~s ire ballistic-resistant clothing.
A furthE~ mayor advantagE cf the use of the non-woven layer acce:c:inc tc the inveraticn r. ballistic-

2~ resistant clothinc i~ that it does not comprise a matrix and is hence more flexible and more easily adaptable to the shape of the body and can moreover breathe, so that perspiration vapour can easily be discharged.
An additional advantage is that the structure of 30 the invention can be produced via a simpler process that can be carried out using conventional and commercially available equipment.
Although the aforementioned advantages of the invention are pre--eminently advantageous in the afore-35 mentioned ballistic-resistant clothing such as fragment-resistant and bullet--proof vests, the use of the invention is not limited thereto. Other applications are in for example bomb blankets and panels.

'.'',~ 93t20271 . ~ ~ ~ ~ ~ ~ ~ ~ pt.'TlNL93/(~0078 . _ 3 WG-A-91j0~855 discloses a felt consisting of a mixture of 2 different types of short polyolefin fibres, one type of which is substantially shorter and of a polyolefin material having a lower melting temperature than the other type: The felt is converted to a ballistic-resistant article by sintering or melting of the short fibres which are formed into a matrix embedding the long fibres. The drawbacks of this article are that it is not very flexible because of the rigid bonding of the long fibres and that it has mediocre ballistic-resistant properties. Another important difference with respect to the present invention i;s that WO-A-91/04855 uses fibres with a length of at least 12.7 mm.

US-A-4623574 mentions the use of felt layers of non-woven polyolefin fibres in an ballistic-resistant application: However the use of shot fibres was not mentaored. Further it is stated here that a minimum conter. (of at least about 13 ~rt.~) of matrixmaterial is ZO reguired in the layer to obtain a layer with good ballistic-resistam properties, with all of the aforemientioned drawbacks relativb to the pfesent invention tha it entails:

The non-woven layer o the invention eonsists substantially of short polyolefin fibres. With "substantially" is meant here that the non-woven layer may comprise minor amounts of other GOnstituents, not including a matrix. These other constituents may f or example be short'lfibers of an ~ther material. It was found that other constituents negatively influence the good results achieved by the present invention. Preferably the amount of other constituent is less than 20 ~ more preferably less than 1U' ~ and even more preferably 1'ess than 5~ and most pzeferably U~ (~ by volume).

It ha;s been found that the ballistic-resistant p~ogerties. imgzove with the fineness of the fibres. The fineness of the fiber is the weight ger.unit length of fiber (in denier). Good resu~.ts are obtained if the W~ 93/24D271 ' ~ ~ ~ U ~ ~ _ 4 _ P~Cf/NL931~40".w fineness of the fibres is between 0.5 and 12 denier. Tt is difficult to process fibres that are finer than 0.5 denier , into a felt. Felts consisting substantially of fibres with a fineness of more than 12 denier have poorer ballistic- , resistant properties and a poorer compactness. Preferably, the fineness is between 0.5 and 8 denier, more preferably the fineness is between 0.5 and 5 denier and most prefe=ably the fineness is between 0.5 and 3 denier.
Preferably the fibers are crimped. A felt consisting substantially of crimped fibers has better mechanical and ballistic-resistant properties. Crimped short polyolefin fibres can be obtained from crimped polyolefin filaments with a tensile strength of at least I5 1.2 GPa and a modulus of at.least 40 GPa by reducing the latter according to methods known per se, for example by chopping or cutting: Crimped:filaments can be obtained in any manner known from the prior art; preferably however with the aid of a stuffier box. The f fibre's mechanical properties; for example its tensile strength and modulus, may not substantially deteriorate as a result of the crimping;
Particularly suitable polyolefins are polyethylene and polypzopylene homopolymers and - --25 cap~lymers: In addi ion, the p~olyolefins used-may contain small amounts of one or more other polymers. in particular other alkene-1-polymers.
Good results are obtained if linear polyethylene (PE) is chosen as the polyolefin. hinear polyethylene is 30 here understood to be polyethylene with fewer than 1 side chain per 100 C at~ms and preferably with fewer than I
side chain per 300 C atoms; which fan moreover contain up to 5 mol.~ one or mora copolymerisabla other alkenes such as propylene, butylene, pentane, 4-methylpentene and 35 octane..
Preferably, polyolefin fibres consisting of linear polyethylene with an intrinsic viscosity in Decalin at 135°C of at least 5 d1/g are used in the non-woven layer according to the invention.

.. ,.~ 93/20271 ~ ~, ~ ~ ~ ~ ~ PC.'f/1~1L93I0007~
_ 5 _ The length of the fibres must be between 40 and 100 mm. At a fibre length of less than 40 mm the cohesion, the strength and the SEA of the non-woven layer are too poor. At a fibre length of over 100 mm the SEA and compactness of the non-woven layer are substantially lower. The compactness is the areal density divided by the thickness of the layer. In general, a layer with a higher compactness has a lower blunt trauma effect. The blunt trauma effect is the detrimental effect of the bending of the ballistic-resistant structure as a result of the impact of a projectile: It is important that ballistic-resistant clothing has a low blunt trauma effect besides a high SEA.
1.5 It is further important that the fibres haue a high tensile strength, a high modulus of elasticity and a ha~gh energy absorption. In the non--woven layer of the invention use is: to be made of polyolefin fibres the monofilament of which has a strength of at least 1.2 GPa ZO and a modulus of at feast 40 GPa. When use is made'of fibres with a lower strength and modules good ballistic-resistant properties dannot be obtained.
The layer of the invention can contain fibres with variously shaped c~os~ sections, for example ro'und°
25 rectang~xlar (tapes) or ~val fibres: The shape of the cross section of the fibres Can for example also be adjusted by rolling the fibres flat. The shape of the cross section of the fibre is expressed'in the cross section°s aspect ratio, which is the ratio of the length and the width of 30 the cross section. The cross section°s aspect ratio is preferably between 2 and 24: more preferably between 4 and 20: Fibres with a higher aspect ratio show a higher degree of interaction in the non- woven layer, as a result of which they can-move less'easily relative to one another 35 in the case of a ballistic impact: Because of this an z.mproved SEA of the non-woven layer can be obtained.
The degree of interaction can also be modified by modifying the surface of the fibres. The surface of the r~ro ~maoam _ ~crow~.~mooo,-.,~..
fibre can be modified by incorporation of a filler in the fibres. The filler may be an inorganic material, such as gy~isum, or a polymer. The surface of the fibre may also be modified via a corona, plasma and/or chemical treatment.

The modificat~,on may be a roughening of the surface, owing to the presence of etching pits, an increase in the polarity of the surface and/or a chemical functionalisation of tie surface.

'.'the SEA and the blunt trauma effect of the npn-woven layer can be improvbd by increasing this the degree of interaction between the fibres. However if the degree of interaction is tao great the SEA rnay decrease again.

The optimum can be found by one skilled in the art by ~.5 routine experimentation.

Good ballistic-resistant properties are obtained according to the invention when the polyolefin fibres described above are substantially randomly oriented in the plane bf the non-woven layer: 'Substantially randomly" is understood to mean that tie fibers have no preferential orientati~ns leaainc~ to different mechanical properties in the plane of the layex: the mechanical properties in the plane of the layer are substantially isotr'opi~ally, that is, substantially he same' i.n da,fferent directions. 'The spread of mechanical pr~p~rties in different directions in the p~~ne of th~'non-woven Dyer may not exceed 20~, preferably not 10~. More preferably, the spread of the non-women layer is s~ that the spread of the layered structure that consists of one or more of the non-woven layers of the invention is less than 10~.

Preferably use is made of polyclefin fibres that are obtained from polyolefin filaments prepared by means of a gel-spinni~ig process ' as descr ibed in for example GD-A- 2042414 and GE-A~2051667. This process essentially consists in preparing a solution of a polyolefin with a high intrinsic viscosity, as determined in Decalin at I35'~, spinning the solution to filaments at a temperature above the dissolution temperature, cooling the filaments "...
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below the gelling temperature to cause gelling and removing the solvent bef ore, during or after the stretching of the filaments.
The shape of the cross section of the filaments can be chosen by chosing a corresponding shape of the spinning aperture.
The non-woven layer of the invention can be used in ballistic-resistant structures in cliff erent ways. The 1p non-woven layer of the invention can be used as such, as a single layer.
A particular application of the invention is in a layered structure consisting of at least two non-woven layers according to the invention which are entangled together. The advantage of this application is that this layered structure is more compact and easier to handle than a single non-woven layer:
Another particular application of the invention is in a 7.ayered structure consisting of one or mare non-~0 woven layers according to the invention and one or more woven fabrics which are entangled together. The woven layer preferably has also good ballistic-resistant propertiesa The w~ven layer' px~ferably consists of pc~lyolefin filaments having a tensile strength of at least 12 GPa and a modules ~f at least 40 GPa. The advantage of such a layerbd~structure is that it is very compact and has ~ low blunt trauma-effect besides an impr~ved SEA. The layers in the Zaye~ed structured described above may be eT.angled together by needling, hydroentanglement or 3p ,stitching.
A layered structure for ballistic-resistant use may comprise one of more of the non-woven layers or of the lay~red structures described ab~ve. The number of layers in the layered structure depends on the level of protection required. In. application in ballistic-resistant clothing the choice of the number of layers and thus the cereal densit~r of a layered'ballistic-resistant structure is a difficult trade- off of an the one hand the desired .,..... .c...,.._......... t.". , ,.....F.;'f ,v" ... .. ... .., ......x.. ..
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level of protection and on the other on the desired comfort in wear~,ng: The comfort in wearing is mainly determined by the weight and thus the are~l density of the ballistic resistant structure A particular advantage of the non-woven layer of,the present invention is that a progressively higher SEA is obtained at lower areal densities: Because of this,:the non-woven layer of the invention is particularly advantageous in application in ballistic°resistant structures for the lower and medium protection level range (V50 from 450-500 m/s) because of the very light weight flow areal density) and hence higher comfort to wear: The advantages of the non-woven layer of the present invention are in particular apparent in layered structures consisting of a stack of non-woven layers and having an areal density below 4 kg/m2, or more preferably below 3 kg/m2 or .most preferably below 2 kg/m2.
Layered structures w~.th a high areal density are preferably formed by lonely stacking a large number of layers having a ver~r small areal density.
The non-woven'f~lt layers ~r the layered structures can be combined with'layers of a different type that can contribute towards certain other specific ballistic-resin ant properties or'other properties: The ~5 drawback of the combing ion with layers of a different type is that the SEA and the comfort in wearing; among other properties, will deteriorate: Pref erablyP the entire structure theref ore consists of non-woven layers or the afr~rementioned layered structures: Ptef erably, such a layered structure has a'thickness of between 10 and 30 mm.
The non-werven layer can Ire manufactured by several techniques ~.ike for example by papez-making techniques such as passing 2~n aqueous slurry of the.fibers onto a wire screen and dewatering: Pref ezably however the non-woven layer is manufactured by a method comprising the carding , of a mass of loose short polyolefin fibres having a tensile strength of at least 1.2 GPa, a modulus of at least 40 GPa and a length of between 40 and 100 mm, the fibres being'substantially 21320.
"~~() 93/2p271 P~'/1'~L93/OOii7~
_ g _ unidirectionally oriented and being formed into a carded non-woven webs - the feeding of the carded non-woven web obtainied to a discharge device moving in a direction perpendicular to that in which the web is fed to it, onto which the web is deposited in zigzag folds, while being simultaneously discharged, so that in the discharge direction a stacked layer is formed that consists of a 20 number of stacked layers of the supplied carded non-woven web that partially overlap one another widthwise;
- the calendering of the stacked layer, in which the thickness of the layer is reduced;
- the stretching of the calendered layer obtained in the discharge direction;
- the entangl~.ng of the stretched layer obtained to form a felt layez .
This appears to result in a non-woven layer in the form of ~ felt having improved ballistic-resistant properties, ~n particular a specific energy absorption of more than 35 Jnn2/kg, in particular more than 40 J~h~/kg and more in particular morn than 50 Jm2/kg.
Preferably lrhe short polyolefin fibers are crimped.
The crimg~ed fibres can be obtained by subjecting polyolefan filaments having tta~ desired mechanical properties and fineness. which can be obtained using methods k~~wn per s~ and mentioned above. to treatments f or crimping known per se. An example of a known crimping method is treatment of the filaments in a stuff er box. The crimped fibres thus obtained must then be cut to the desired length, between 40 and 100 mm. In this cutting a compressed mass of fibres is often obtained, This mass must be d~.sen~tangled (opened) by f or example mechanical combing or blowing. In this process the composed fibres, which are obtained when use is made of multifilaments, are simultaneously disentangled to substantially single fibres. The advantage of using crimped fibres in the method described above is that crimped fibers are more 'VYO 93/2027 ~ ~ c7 ~ ~ ~ j - 10 - ~CT/1~IL93/00t~°.., easily disentangled (opened) after cutting and are more easy to card into a web: .

The carding can be done with the usual'carding machines. The thickness of the layer of fibres that is fed , to the carding device may be chosen within wide limits: it is substantially dependent on the desired areal density of the felt ultimately to be obtained. Tn particular, a~.lowance must be made for the stretching to be carried out at a later stage in the"process, in which the areal density will decrease dependent on the chosen draw ratio.

The carded non-woven web is stacked in zigzag folds onto a discharge device that mores in a direction perpendicular to that in which the.carded non-woven web is fed to it, This direct~;on is the discharge direction. The discharge device may be for example a conveyor belt, Whose transport speed is'chosen so relative to the supply rate of the carded non-woven web that a stacked layer comprising the desired number of partially cwe~lapping Z(~ ~;ayers' is' obtained:

The orientatcion of the fibres in the stacked layer depends on the ratio of the aforementioned supply rate and transport speed and the ratio of the width of the carded web and the width of the stacked layer. The-fa.b=es wild be oriented substantially,in two directions. which are determined'by the zigzag pattern.

The calendering of the etack'ed layer can be carried out using the known'devicesa Thethickness of-the layer decreases in the process arid the contact between the individual fibres becomes closer.

Then the calendered layex is stretched lengthwise, i:e. in the discharge direction. This causes the surface area to increase s~ that the thickness and hence the areal density of the stretched layer can decrease slightly: The draw ratio is preferably between 20 and ' 100 Tt has been found that the orientation of the fibzes in the plane of the'layer becomes substantially random in the stretching pr'ocess~' ..":
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n v r vs ra,..r .n-us~.y,t .w ~...,t . , , ."
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......,.f..., ....,..... n .."m ,....,. . ..

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The cohesion, the strength and the compactness of the stretched layer are increased by entangling this layer. This entangling can be done by needling the layer or by hydroentanglinge In the case of needling the felt is pierced with needles having fine barbs that draw fibres through the layers. The needle density may vary from 5 to 50 needles per ema. Preferably the needle density is between 10 and 20 needles per cmZ. In the case of hydroentangling the stretched layer is pierced with a plurality of fine high-pressure streams of water. The advantage of hydroentangling over needling is that the fibres are damaged less: hTeedling presents the advantage that it is a technically simpler process.
Further compacting of the felt can be carried out by subjecting the stretched layer and/or the felt to an additional needling or calendering step. The result of the additional needling or calenderin~ of the felt layer is that the felt becomes more compact, which presents the advantage that the blunt trauma effect is reduced without the aEA being unacdeptalaly lowered.
It has been fecund that the entangling also helps to increase the randomness of the orientation bf the fibres and the isotropy of mechanical properties in the plane of Z~ the layer.
The thickness of the felt layer is determined by the ar,~al densi y 8f the mass of loose short fibres fed to the carding dwice in 'relati~n to ~tY~e nurc~aer of stacked carded non--woven webs arad the decrease in thickness that occurs during the calendering, stretching and entangling.
Thick lagers of felt can be obtained by increasing the layer thickness at'the beginning of the process or by compacta,ng less in the aforAmen~as~ned process steps: A
thicker, compact felt can also be obtaaned by stacking several layers of felt and then entangling them together, f ~r example via needling: The advantage of a thicker compac felt is that besides having a high SEA, it has a lower blunt trauma effect and can be handled more easily than a single thick non-proven layer.
,.
. .. ... . . . . .. ,.. .~ .;;.,.. ,. .,.. ~ .. ..
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~V~ 93/24271 ~ ~ .~ ~ (~ ~ j Pf'd°/~IL,93/OQQ~°~''~

In a particularly advantageous embodiment the felt abtained is needled together with fabrics or other types of layers. These hybrid structures are much thinner and have a low blunt trauma effect besides a greatly improved fragment- resistance.
The non-woven layers thus obtained or their particular embodiments described above can be combined in a layered ballistic-resistant structure with layers of a different type that can contribute towards certain other specific ballistic°resistant properties or other properties in order to increase the specific energy absorption thereof::
The inveaation is fuzther elucidated with reference to the following examples without being limited thereto. The quantities mentioned an the examples are determined in the following,manners.
The tensile str~engt~h and the modulus are determined by'aneans of a tensile test carried out with the 2p aid of a Zwick 1484 texasile tester. The filaments ~ ire measured without twist. The filaments are clamped over a length of 200 mm in Ori~ntec (25U-kg) yarn clannps, with a clamping press~re,o~ 8 bar ~o pre~bnt slipping of the filaments 'ixa tlae clamps. Tne cre~sshead speed is 1~0--25- mm/z~tinThe 'modul,us ° is understood to 'be the initial modtalus. this is dete~rnnined at ~~ elongation. The fineness is determined by weighing a fibre with a known length.
The thicknesses (T) elf 'the felt layers were measured in compressed conditi~n, using a pressure of 5.5 34 KPa. the areal~density (AD) was determined by weighing a Part of a layer with an accurately deteranined area.
The specifis energy absorptioa~ (SEA) is determined according to the STANAS 2930 test, in which .22 calibze FSPs (Fragment-Simulatihg Projectiles), 35 hereizaafter referred to as ;fragments, of a non-deforming steel of specified shape. weight (I.1 g). hardness and dimensions (according to iJS MIL-P-46593), are shot at the balk stic-resistant structure in a defined manner. The energy absorption (EA} ~.s ca3:dulated Pram the kinetic ~~~~.~
"''(O 93!20271 PC1'lNL93/00078 energy of the bullet having the VSQ velocity. The V5a is the velocity at which the probability of the bullets penetrating the ballistic-resistant structure is'50~5. The specific energy absorption (SEA) is calculated by dividing the energy absorption (EA) by the area! densaty (AD) of the layer.
Example I
A polyethylene multifilament yarn (Dyneema SK60R) with a tensile strength of 2.65 GPa, an initial modulus of 90 GPa, a (fineness of 1 denier per monofilament and an aspect ratio of the fibre cross section of about 6 was crimped in a stuffer box. The crimped filaments were cut into 60-mm long fibres. The fibres obtained were supplied to a carding machine in a layer thickness of 12+3 g/m2: The carded non-woven web obtained was stacked in zigzag-f olds onto a conveyor belt, the ratio of the speed ofthe-belt and the supply rate of the carded non-woven '20 web fed t~ it at right angles being chosbn so that an approximately 2-m wide layer consisting of 10 stacked non-wo~ren webs was obtained. The stacked layer way calendered under:ligh~ pressure in a belt calende~-which resulted in a more compact'and thinner calendered layer. The y calendered layer was stretched 38~ lengthwise. The stretched layer was compacted by needling using 15 needles~'cm2. The area! density of the felt thus ~btained was 120 g/m2. 22 layers of this felt; hezeina~ter referred to as F~, were stacked to form a ballistic°resistant structure, Fl,'with an area! density of Z.6 kg/m2 and a thickness of 23 mm Example II .
Felt Fo,'as ~bta'ined according to example I, was subjected to additional needling wing 15 needles/cm2 to compact the felt. 22 layers of this felt were stacked to obtain a ballistic-°resistant structure, Fz, with an area!
density, of 2.7 kg/m2 and a layer thickness of 22 mm.

WO 93/20271 ~ ~ ~ ~ ~ ~ ~ PCf/1~1L93/000"'",' Example III
Felt Fo, as obtained according to example I, was subjected to additibnal calendering in order to Compact it further. Then a number of these layers were stacked to , obtain a ballistic-resistant structure (F3) with an areal density of 3.l kg/m2 and a layer thickness of 20 mm.
Example IV

An extra heavy and compact felt was manufactured by stacking 3 layers of felt Fo, as obtained according to example I~ and needling them together, using 15 needles per cm2'. Then a number of fhe layers thus obtained were stacked to obtain a ballistic-resistant structure (F,~) with an areal density of 2:9 kg/m2 and a layer thickness of 20 mm.

Examble V

A felt'wa manufadtured as described in example 24 I, only now the entangling was effected with the aid of high-pressure streams of water. Then a number of the layers thus obtained wire stacked to obtain a ballistic-resistant structure (FS) with an steal density of 2.6 kg/m2 and' a layer thickness of 20 mm:

Exam_pla VI

A number of layers of felt Ffl, as obtained according to example T, were needled together with a Dyneema 5048 fabric to obtain a ballistic-resistant 30 structure, F6,~wit~ an areal density of 2.6 kg/m2 and a layer thickness of 8 mm: Dyneema 5048 is a 1x1 plain woven fabric, supp2ied by 1~SM,, of 400 denier Dyneema ~K66R

yarn, having a warp and weft of 17 threads per centimetre anc~ an area:l density of 175 g/m2.

~;xamples VII and VIII

A felt was manufactured according to the method of example I, only now using fibres with a length of 90 mm 21~~fl~~
~''43 93!20271 PCf/NL93/00078 instead of 60 mm. A number of layers of the felt thus obtained were combined to obtain ballistic structures F~
and F8, having area! densities of 2.7 kg/m2 and 2'.6 kg/m2 and thicknesses of 3.2 and 4.8 cm, respectively. Structure F~ underwent an additional needling step and is therefore more compact and thinner than F8.
Example IX
A felt was manufactured according to the method of example Z except hat the smaller number of felt layers Fo were stacked to obtain a ballistic-resistant structure F9 with an area! den~i y of 1.5 kg/mZ and a layer thickness of l0 mm.
Comparative experiments 1 and 2 A number of layers. of the Dyn~ema 5048 fabric specified aboWe was stacked to obtain ballistic-resistant_ structures C~. and C2 having area! densities of 2.9 kg/m2 and 4~5 kg/m2. respectively:
Comparative experiments 3~7 Examgles 1-5 of Table 1 of the aforementioned patent apglica ion WO-A-89/01126 were taken as oomgarative examples C3 throughi C7: The vaauas given in this patent fc~r~the specific energyabsorption and the area! density ire based on the fibre weight only. In order to be able to compare these values with the examples of the present invention, the figures have been standardized to total area! density and total specific energy absorption by dividing and multiglying the AD and SEA values, zespecfiively, by the fibre mass free ion:
Specimens of 40 by 40 cm were cut from the bali.istic-~resistent structures Fl-FB and C1-C2 described above, which were then'tested to determine their ballistic-resistant properties by measuring the VSO, according to the STANAG 2920 test described above. The ballistic-resistant structures of comparative examples PCT/NL93/000°.
'~~ 93120271 2 ~ ~ ~ ~ ~ ,~ - 16 -C3-C7 of patent application WO-A-89001126 were tested according to the same standard. Table 1 shows the results.
Table 1 AD V 5 p SEA T

kg/ma m/s Jmz/kg mm F1 2.6 544 63 23 F2 2.7 526 59 22 F3 3. ~. 486 50 20 F4 2.9 490 51 20 F5 2.6 500 53 20 F6 2.6 445 42 8 F7 2.7 440 39 32 F8 2.6 474 48 48 Fg 1.5 478 86. 10 C1 2:9 450 39 8 C2 4.5 520 34 13 C3 6.1 621 35 C4 6.9 574 26 -C5 6a9 584 27 -C6 6.6 615 32 -C7 6~3 5?1 29 " Not specified in WI--A--X9/01:126 Comparison of the re sults shows that all of the ballistic-resistant layered ructures F1-F9 that comprise at least st one non-woven of the invention show a better layer specific energy absozption than the best ballistic-resistant structure of C1-C7 according to the state~of the art. The of felts F7 and Fg, which contain 90-SEA values mm fi.bzes, are ls~wer than those of felt structures FI-F5, which cont ain 60-mm fibres, but comparable with or better than and n most cases i much better than those of structures Cl-C7 so far known. F6 has a lower SEA because .,"'~O 93/x0271 ~ ~ 4~ - 1? - FCT/NL93/1100°~"
~1J2 of its specific structure and lower package Thickness. The

Claims (20)

CLAIMS:

1. A non-woven layer comprising short polyolefin fibers having a tensile strength of at least 1.2 GPa and a modulus of at least 40 GPa, wherein the non-woven layer is a felt comprising at least 80%, by volume, of short polyolefin fibers which are substantially randomly oriented in the plane of the non-woven layer and have a length of 40-100 mm.

2. The non-woven layer according to claim 1, wherein the non-woven layer consists of the short polyolefin fibers.

3. The non-woven layer according to claim 1 or 2, wherein the fibres have a fineness cf between 0.5 and 12 denier.

4. The non-woven layer according to any one of claims 1 to 3, wherein the fibres are crimped.

5. A non-woven layer comprising short polyolefin fibers having a tensile strength of at least 1.2 GPa and a modulus of at least 40 GPa, wherein the non-woven layer is a felt consisting of the short polyolefin fibers which are substantially randomly oriented in the plane of the non-woven layer and which are crimped, have a length of 40-100 mm and have a fineness of between 0.5 and 8 denier.

6. The non-woven layer according to any one of claims 1 to 5, wherein the non-woven layer has a specific energy absorption of at least 40 J.m2/kg.

7. The non-woven layer according to any one of claims 1 to 6, wherein the polyolefin fibres in the non-woven layer consist of linear polyethylene with an intrinsic viscosity in Decalin at 135° C of at least 5 dl/g.

8. The non-woven layer according to any one of claims 1 to 7, wherein the aspect ratio of the cross section of the fibres is between 2 and 20.

9. The non-woven layer according to any one of claims 1 to 8, wherein the surface of the fibres is modified by a method selected from them group consisting of corona treatment, plasma treatment, chemical functionalisation, and filling of the fibre.

10. A layered structure consisting of at least two non-woven layers according to any one of claims 1 to 9, which are entangled together.

11. A layered structure consisting of at least one non-woven layer according to any one of claims 1 to 9, and at least one woven layer, which are entangled together.

12. A layered structure comprising at least one non-woven layer according to any one of claims 1 to 9.

13. The layered structure according to claim 12, wherein the layered structure has a thickness of between 10 and 30 mm.

14. A method for the manufacture of a non-woven layer according to any one of claims 1 to 9, comprising:
(a) carding a mass of loose short polyolefin fibres into a carded non-woven web, the loose short polyolefin fibres having a tensile strength of at least 1.2 GPa, a modulus of at least 40 GPa, a length of between 40 and 100 mm, and a substantially unidirectional oriention;
(b) feeding tine carded non-woven web obtained in step (a) to a discharge moving in a direction perpendicular to that in which the non-woven web is supplied, onto which the web is deposited in zigzag folds while being simultaneously discharged, so that in the discharge direction a stacked layer is formed that consists of a number of stacked layers of the supplied carded non-woven web that partly overlap one another widthwise;
(c) calendering the stacked layer obtained in step (b), in which the thickness of the layer is reduced, to obtain a calendered layer;
(d) stretching the calendered layer obtained in step (c) in the discharge direction of the calendered layer obtained in step (c); and (e) entangling the stretched layer obtained in step (d) to form a felt layer.

15. The method according to claim 14, wherein the fibres are crimped fibres having a fineness of between 0.5 and 8 denier.

16. The method according to claim 14 or 15, wherein the entangling is effected through needling.

17. The method according to claim 14 or 15, wherein the entangling is effected through hydroentangling.

18. The method according to any one of claims 14 to 17, wherein at least the stretched layer of the felt layer is compacted.

19. Use of the non-woven layer according to any one of claims 1-9, in a ballistic-resistant structure.

20. Use of the layered structure according to any one of claims 10 to 13, in a ballistic-resistant structure.