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Publication numberUS3368934 A
Publication typeGrant
Publication dateFeb 13, 1968
Filing dateMay 13, 1964
Priority dateMay 13, 1964
Publication numberUS 3368934 A, US 3368934A, US-A-3368934, US3368934 A, US3368934A
InventorsVosburgh Sr William George
Original AssigneeDu Pont
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Nonwoven fabric of crimped continuous polyethylene terephthalate fibers
US 3368934 A
Abstract  available in
Previous page
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Claims  available in
Description  (OCR text may contain errors)

Feb. 13, 1968 w. c. VOSBURGH, SR 3,368,934



- ORNEY United States Patent Oflfice 3,368,934 Patented Feb. 13, 1968 3,368,934 NONWOVEN FABRIC OF CRIMPED CONTINUOUS POLYETHYLENE TEREPHTHALATE FIBERS William George Vosburgh, Sr., West Chester, Pa., as- Y signor to E. I. du Pont de Nemours and Company, Wilmington, Del., a corporation of Delaware Filed May 13, 1964, Ser. No. 367,002 3 Claims. (Cl. 161-150) ABSTRACT OF THE DISCLOSURE Nonwoven fabrics of crimped continuous synthetic organic filaments having (1) between 10 and 25% by weight of a specified synthetic organic binder distributed through the fabric and (2) at least 1500 discrete selfbond areas per square inch of fabric surface with the selfbond areas covering between about 2 and 15% of the surface area of the fabric, are useful as window shade material.

Detailed description the invention Nonwoven fabrics are well known and products having a broad spectrum of properties are now available in the market place. In most cases, however, the combination of properties obtainable in any one product is very limited. The requirements of window shade materials are numerous and include low edge curl, high fuzz-resistance, washability, resistance to edge tear, sufficient stiffness to give good hanging characteristics and high tensile strength. Heretofore, no single nonwoven fabric has had all of these properties to a sufiicient degree to qualify it for use as a window shade material. Another requirement for any nonwoven fabric to fit in the quality window shade market is that it be competitive from the cost standpoint with the woven cotton fabrics which are now used. For the new product to have the most impact on the market place, it should, however, also offer salable property advantages over competitive materials. Particularly desired properties in a window shade material are dimensional stability, ability of both coated and uncoated shade materials to accept decorative embossing, resistance to cracking and formation of pinholes, superior edge-tear resistance and resistance to degradation by sunlight.

It is an object of this invention to provide a nonwoven fabric with a combination of properties which specially adapts it for use as a window shade material.

Another object is to provide a window shade material which exhibits good dimensional stability.

A further object is a window shade material which will accept decorative embossing.

These and other objects of this invention are obtained by providing a nonwoven fabric of continuous synthetic organic fibers having at least 5 crimps per inch (2 crimps per centimeter) of unextended length, the fabric being bonded by a combination of (l) a synthetic organic binder distributed randomly throughout the fabric as granule bonds, which binder has an initial tensile modulus (Mi) of at least 5 g.p.d. and constitutes between and 25% by Weight of the fabric, and (2) at least 1500 discrete self-bond areas (defined below) per square inch (230 per square centimeter) of the fabric surface, said self-bond areas covering between 2 and of the surface area of the fabric.

The invention will be more readily understood by reference to the drawings in which:

FIGURE 1 is a schematic representation of an apparatus assembly which can be utilized to prepare continuous-filament nonwoven webs;

FIGURE 2 shows schematically in longitudinal section the nozzle portion of an aspirating jet which may be used with the apparatus of FIGURE 1;

FIGURE 3 is schematic representation of a bonding apparatus which is suitable for use with the nonwoven fabrics produced by the apparatus in FIGURE 1.

Continuous synthetic organic fibers are used in the nonwoven fabrics of this invention. The fabrics can be made economically in a process which integrates spinning, orientation of the fibers, and laydown of the filaments in the .form of a random nonwoven web which is essentially free from filament aggregates. Such a process, which involves electrostatic charging of the filaments and then permitting the filaments to separate due to the applied electrostatic charge, is described in British Patent 932,482 and illustrated schematically in FIGURE 1. This process when used to produce a nonwoven fabric of poly(hexamethylene adipamide) or other polyamide filaments can be so operated that it inherently gives fibers with the level of crimp required for the fabric to have minimum edge curl when used as a window shade material. In the case of poly(ethylene terephthalate) filaments, a heatrelaxation step according to Kitson and Reese, US. Patent 2,952,879 can be effected during or subsequent to the web-laydown process to provide fibers which are spontaneously elongatable. Subsequent heating of the filaments, for example, during the bonding operation, causes the fibers to elongate and form crimps.

The concept of filament crimp is well understood in the art. Crimps can be measured by direct observation using a microscope with a scaled eyepiece, or by projection. A procedure which can be utilized with the bonded nonwoven fabrics of this invention involves making a photomicrograph of the fabric surface. A magnification of about 65X will usually be suitable. Anoverlay of a transparent sheet material, e.g., cellophane, is then placed over the photomicrograph. Several filaments (e.g., 10)

are then traced on the transparent sheet. The total length where N=total number of crimps M=magnification of photomicrograph L=total length of traced filaments In this invention a filament crimp is one in which the amplitude of the departure from the filament contour line is less than 3 times the radius of curvature of the crimp, the latter always being less than 0.5 inch (1.3 cm.).

Since, as indicated above, poly(hexamethylene adipamide) and poly(ethylene terephthalate) filaments can be readily formed into a web with crimped fibers, and moreover, because these synthetic fibers yield nonwoven fabrics which can be readily given a decorative embossing pattern, they are preferred for use in this invention. The most preferred species is poly(ethylene terephthalate) particularly because of its resistance to degradation from sunlight. Other continuous synthetic filaments which can be formed into nonwoven webs having crimped fibers can also be used, however; and this invention is not limited to either the specific polymers above or to products made by the above-described web-laydown process. For example, crimp in continuous filaments can also be obtained by the use of two-component fibers as disclosed in Breen, US. Patent 2,931,091; and such side-by-side spun fibers 3 as poly(ethylene terephthalate) /poly(propylene terephthalate) and poly(ethylene terephthalate)/poly(hexamethylene adipamide) can be used in the nonwoven fabrics of this invention. Crimped filaments can also be prepared by the process of Kilian US. Patent 3,118,012.

A convenient and effective way to distribute the binder uniformly throughout the nonwoven fabrics is by cospinning it with the matrix fiber of the fabric. In order to be readily melt-spinnable, the initial tensile modulus of the binder should be 5 g.p.d. or higher. With this limitation on the modulus of the binder, it is necessary, in order to avoid excessive stiffness in the nonwoven fabric and the development of a papery feel and rattle, not to use more than about 25% binder in the fabric. The minimum level of binder is which is the amount necessary to obtain the strength required in window shade materials particularly when the fabric is used in the uncoated form.

The nonpapery character required and exhibited in the fabrics of this invention and referred to hereinabove is evidence by the lack of, or low level of noise generation in the frequency range of 2,000 cycles per second and above when the fabric is flexed or scrubbed against itself at a constant moderate speed. The level and fre quency of sound developed under such conditions can be measured with a sound level meter. Nonpapery character is also demonstrated by the ability of a fabric to conform to a curved, three-dimensional surface such as a sphere when stretched thereover, without the formation of sharp bends and breaks. It is characteristic of all stiff papers that, when they are forced to conform to a curved surface, a bend in one portion will intersect a bend in another portion with the occurrence of sharp breaks, abrupt changes in slope and sharp edges.

Another structural requirement in the nonwoven fabrics of this invention is the presence of at least 1500 discrete self-bond areas per square inch (230 per square centimeter) of the fabric surface. These self-bond areas cover between 2 and of the total surface area of the fabric. If the number and area covered are below these limits, the fabric is deficient from the standpoints of both fuzzand scrub-resistance. If the self-bond areas are not discrete or if an excessive area of the fabric is covered, the fabric becomes paperlike and is deficient as a window shade material. The upper limit on the number of discrete self-bond areas is determined not by property considerations but by mechanical limitations of the apparatus used to form the self-bond areas.

The self-bond areas can be formed by passing the nonwoven fabric between heated embossing rolls under pressure. Under these conditions the fibers in sections of fabric compressed between raised portions of the rolls are consolidated as discrete columns extending through the thickness of the fabric in a direction generally perpendicular to the plane of the fabric. The columns, which are arranged in a predetermined pattern, comprise matrix filaments that are adhered to each other and may additionally contain binder particles of the type randomly dispersed through the remainder of the bonded fabric of the invention. The terminals of the columns at the faces of the fabric constitute the self-bond areas.

The temperature and pressure required to produce selfbond areas through use of embossing rolls will depend on the nature of the matrix fibers in the nonwoven fabric. For instance, with fibers of poly(ethylene terephthalate) a pressure of 50 p.s.i. (3.5 kg./cm. and a temperature of 150 C. or greater are suitable. The embossing rolls which are used may have matching surface patterns with land areas corresponding to the desired number and size of the self-bond areas. It is, however, difficult with paired rolls of this type to obtain the exact and complete registry which is required to form distinct self-bond areas. It is especially difiicult because of the large number and small size of the self-bond areas. Thus the land areas on the embossing rolls must number at least 1500 per square inch (230 per square centimeter) and will have a size of 0.0001 square inch (0.00065 sq. cm.) or less. While it is possible to use the foregoing type of embossing rolls, it is preferred to use grooved rolls, one roll having parallel grooves running circumferentially around the roll and the other having parallel grooves running axially along the surface of the roll. As the fabric passes between these two rolls, it receives the maximum pressure between the rolls only at the locations where the land areas between the grooves on the two rolls cross, thus only at these locations will self-bond areas be formed. Typical rolls for use in making the non-woven fabrics of this invention will have 48 grooves per inch (19 per centimeter) with the lands between grooves being 0.004 inch (0.10 cm.) wide. Use of two such rolls gives 2,304- self-bond areas per square inch (360 per square centimeter) and the self-bond areas cover about 4% of the surface of the fabric.

The filament denier of the matrix fibers of the nonwoven fabric affects the maximum opacity which can be obtained by complete and random separation of the individual filaments in the fabric. Since opacity increases as filament denier decreases, it is generally preferred that the filaments in the nonwoven fabric have a denier of 9 or less. The binder fibers are normally spun at about the same denier as the matrix fibers to aid in obtaining uniform distribution throughout the nonwoven fabric. Opacity and covering power of the fabrics of this invention are also improved by the use of trilobal cross section fibers.

As indicated previously, the binders used in this invention are high-modulus materials. The binder should be chosen so that its melting point is at least 10 C., and preferably at least 25 (1., below the melting point of the matrix fiber. Preferred binders for use with poly(hexamethylene adipamide) include polycaproamide or copolymers thereof with poly(hexarrnethylene adipamide). Preferred binders for use with poly(ethylene terephthalate) include poly(ethylene terephthalate)/poly(ethylene isophthalate), poly( ethylene terephthalate) /poly(ethylene sebacate), and similar copolyesters. The heating operation in which the binder fibers are activated to form the granule bonds is usually carried out after the embossing operation which forms the self-bond areas. The temperature used is, of course, dependent on the nature of the .binder. Typical temperatures used when an /20 copolymer of poly(ethylene terephthalate)/poly(ethylene isophthalate) is used as binder are in the range of to 230 C. Higher temperatures favor improved fuzz resistance but reduce tear strength.

The nonwoven fabrics of this invention can be used as both coated and uncoated window shade materials. A substrate having a fabric weight of about 3 oz./yd. is suitable for vinyl-coated translucent shade cloth and offers the advantage over woven cottons that it does not have to be filled before top-coating. This reduces the number of coating passes required from 4-6 for cotton to 1-2 for the fabrics of this invention. The coated product also has greater flex resistance than cotton shade cloth.

Both coated and uncoated window shade materials of this invention are superior to cotton in edge durability, that is, in resistance to tearing and ravelling. Because of the thermoplastic nature of the synthetic organic filaments, both products are readily embossed with deep decorative patterns. Translucent shades prepared with the fabrics of this invention are apparently unique in that they are the only shades known which have a look-through textured appearance as well as good durability. Translucent cotton shade cloth cannot be embossed at all and opaque cotton shade cloth can only be embossed with shallow patterns and only when coated with a thick, and therefore, expensive coating. Inexpensive paper and vinyl film translucent shades are embossed but they are inferior to the fabrics of this invention in tear strength and dimensional stability.

The window shade materials of this invention also have excellent washability as evidenced by resistance to fuzzing when scrubbed with water and a detergent, ex-

hibit the low edge curl required for good appearance when the shade is in the down position, and are resistant to cracking, formation of pinholes and fuzzing during use.

The invention will be further illustrated by the following examples. The procedures used to evaluate the nonwoven fabrics in the examples for fuzz resistance, edge curl, flex resistance, tear resistance and pinholes are described below.

Fuzz resistance.--A rubber-covered box (4 in. x 4 in.) cm. X 10 cm.) weighing 1000, 1500 or 2000 grams is moved back and forth once across the fabric. The degree of fuzz is then visually inspected and rated 1 to 5 with 1 representing severe fuzzing and 5, no fuzzing. Both sides of the fabric are tested and the fuzz ratings are averaged.

Edge curl.--Window shades (3 ft. x 6 ft.) (0.914 m. X 1.83 m.) are rolled up overnight, then pulled down 3 feet 0.914 m.) and allowed to hang at least 30 minutes. The amount that the edge curls away and stands out from the plane of the shade halfway down the unrolled portion is then measured as follows: a light-weight but rigid 6- inch cm.) ruler is attached to the back of shade at 4 to 5 inches (10 to 13 cm.) from the edge, with the long dimension of the rule being perpendicular to the edge of the shade. A convenient way to attach the ruler is by means of two-sided, pressure-sensitive tape placed near one end of the ruler. The perpendicular distance from the ruler (the plane of the shade) to the edge of the shade is then measured. The measurement is repeated at the other edge of the shade and the two values are averaged.

Flex resistance.-A mechanical scrub test as described in Industrial and Engineering Chemistry 27, 1400-1403 (1935) is used. In this test, a 2 in. x 4 in. (5.1 cm. x 10.2 cm.) sample is cut with the long dimension in the machine direction of the fabric, and is then clamped between a pair of jaws which move in opposite but parallel directions. The sample is inserted with the jaws placed directly opposite each other. At the extremity of movement of the jaws, corresponding to a distance of 0.75 in. 1.9 cm.) from the position where the jaws are directly facing each other, a sample elongation of 23% is achieved along a diagonal. In operation, the jaws of the scrub machine move back and forth past each other at a rate of 178 cycles/min, a cycle being movement of the jaws to both extreme positions and return to the starting position. A hinged rider bearing a weight rests on top of the sample as it is scrubbed. Samples are inspected for breaks, fiaking and pinholes after varying numbers of flex cycles.

Tear ressitance.The Elmendorf tear test (ASTM D 1424-59) is used. Tear strength in both the machine direction (MD) and cross-machine direction (XD) is determined. The latter is the more important in window shade materials.

Pinh0les.The window shade material is illuminated from behind with a 100 watt light bulb and is examined for pinholes from a distance of 3 feet (0.914 im.).

Noise generation.Window shades (3 ft. x 6 ft.) (0.914 m. x 1.83 m.) are pulled down 3 feet (0.914 m.) and y then rattled by shaking the bottom of the shade back and forth at a rate of about 180 cycles per minute. The noise generated is picked up by a sound level meter (General Radio Co., Type 15513) which is connected to a sound and vibration analyzer (General Radio Type 1554A). The analyzer is set at the frequency range desired, and the level of sound in decibels generated at that frequency is read directly from the analyzer.

The nonwoven fabrics of this invention have the following combination of properties which especially adapts them for use as uncoated and coated window shade materials: An average tear strength of at least 200 g./ oz. yd. (5.9 g./g./m. an edge curl of 0.5 inch (1.3 cm.) or or less, and a minimum fuzz rating of g. for substrates to be used as uncoated window shade materials, and g. for substrates to be coated. In addition, the fabrics exhibit a low level of sound generation when flexed, good washability and superior flex resistance.

6 EXAMPLE 1 This example illustrates a method for the preparation of bonded nonwoven products of this invention which are useful as window shade materials. The apparatus assembly used in this example is shown schematically in FIG- URE 1, wherein the filaments pass directly, as indicated by the dotted lines, from the spinnerets 1 and 2 to the target bar of corona discharge device 3. Poly(ethylene terephthalate) (27 relative viscosity) is spun through spinneret 1 having 17 holes (0.009 in. diameter x 0.012 in. long) (0.023 cm. x 0.031 cm.) at a total throughput of 20.0 g./min. while an /20 copolymer of poly(ethylene terephthalate)/polyethylene isophthalate) (29 relative viscosity) is spun through spinneret 2 having 10 holes (0.009 in. diameter x 0.012 in. long) (0.023 cm. x 0.031 cm.) at a total throughput of 9.0 g./min. The spinneret temperatures are 285 C. and 258 C., respectively. Three of the copolyester filaments are used and the other 7 are spun to waste. The filaments are quenched in the ambient air at 27 C. before entrance into a draw jet 4 located about 65 inches (165 cm.) below the spinnerets. The 20 filaments from the two spinnerets are combined into a filament bundle at the target bar of corona discharge device 3 which is located about 6 inches (15 cm.) from the jet inlet.

The corona discharge device consists of a 4-point electrode positioned 0.63 inch (1.6 cm.) from a grounded, 1.25-inch (3.2 cm.) diameter, chrome-plated target bar rotating at 10 r.p.m. A negative voltage of 35 kv. (200 microamperes) is applied to the corona points. The filament bundle passes between the target bar and electrode and makes light contact with the target bar.

The yarn is drawn and forwarded toward the laydown belt 7 by aspirating jet 4 having a nozzle section as shown in FIGURE 2 and having the following dimensions:

Over-all jet length 24 in. (61 cm.). Filament inlet diameter (9) 0.062 in. (0.158 cm.). Filament passageway diameter (10) 0.100 in. (0.254 cm.). Metering annulus (11):

Inner diameter 0.0750 in. (0.190 cm.). Outer diameter 0.0930 in. (0.236 cm.). Length 0.020 in. (0.051 cm.). Filament inlet length (12) 0.55 in. (1.40 cm.).

Air at a pressure of 49.5 p.s.i.g. (3.5 kg./cm. is supplied to the jet through inlet 13. The jet under these conditions applies about 13.5 grams total tension to the filament bundle. Attached to the bottom of the jet is a relaxing chamber 6 (9.5 in. long; 0.375 in. inside diam- V eter) (24 cm.; 0.95 cm.) which is provided with an annular nozzle for supplying additional air to the relaxing chamber. Hot air (about 300 C.) is supplied to the relaxing chamber at a rate of 4.5 standard cu. ft./min. (127 liters/min), or sufficient to give an air temperature of 225 C. at the exit of the relaxing chamber. This raises the filament temperature to an estimated C. at the exit. Filaments spun without hot air in the relaxing chamber will have a linear shrinkage of 25% when treated in 75 C. water. Filaments processed with hot air in the relaxing chamber will show a linear shrinkage of less than 2% in 75 C. water, and will show spontaneous elongation (S.E.) as exhibited by a linear elongation of about 15% when heated relaxed in dry air at 200 C.

The jet-relaxing chamber unit is positioned at an angle of 82 with the plane of laydown belt and is moved by a traversing mechanism 5 so that it generates a portion of the surface of a cone, while the output from the relaxing chamber forms an are on the laydown belt 7 having a chord length of 36 inches (91 cm.). The traverse speed is 20 passes (10 cycles) per minute. The distance from the exit of the relaxing chamber to the laydown belt is approximately 30 inches (76 cm.). The laydown belt moves at a speed of 7.8 inches (20 cm.) per minute. Plate 7 8 located beneath the belt is charged at +35 kv. to pin the filaments to the laydown belt.

A typical unbonded web prepared by this procedure will have the following properties: unit weight 3.5 oz./ yd.'- (119 g./m. homopolymer, 3.8 d.p.f.; copolymer binder fiber, 3.7 d.p.f.; amount of copolymer binder fiber, 12% by weight.

A web prepared by the above process is next embossed in a hot-calendering operation. Embossing is carried out with a conventional calender stack equipped with two steel rolls each 16 in. (41 cm.) in diameter. The top roll of the pair is patterned with lands and grooves machined parallel to the axis of the roll, at a frequency of 48 lands/ in. (approximately 19/cm.). Each land is .003 to .004 in. (00076-00102 cm.) wide. The bottom roll has lands and grooves of the same size and frequency set perpendicular to the axis of the rolls. Web embossing is carried out at 4 yd./min. (3.7 m./min.) with both rolls heated to a temperature of 180 C., and under a pressure of 50 lbs./ linear in. (9 kg./cm.). The heating and compression of the web in the areas that the lands of the calender rolls cross results in self-bond sections. The self-bond areas so formed cover about 3% of the surface of the web.

Bonding of the embossed web at a temperature sufficient to melt the binder fibers throughout the web is accomplished by restraining the web between a belt and a metal drum while heating the web to the desired temperature. The bonding unit is shown schematically in FIGURE 3. This consists of a 20-in. (51 cm.) diameter steel drum 14 wrapped tightly with a woven wire screen having 30 x 28 wires per inch (11 X 12 per cm.). This 8 EXAMPLE 2 Continuous-filament nonwoven webs A and B 1.8 and 2.2 oz./yd. (61 and 75 g./m. containing 85% of round, 3.2 d.p.f., 6.6% SE. fibers of 2GT and 15% of an 80/20 2GT/2Gl copolyester as binder are embossed on a 66 in. (170 cm.) calender using rolls with 48 grooves per inch (19 per cm.) as in Example 1. The temperature and speed of embossing are 170 C. and 4 yd./min. (3.7 m./min.). The webs are then bonded on a rotary bonder with hot air being passed through the web. The temperature and speed of bonding are 200 C. and 5 yd./min. (4.6 m./min.). These nonwoven fabrics have 0 to 0.25 in. (0 to 0.6 cm.) edge curl compared with 1 to 1.25 in. (2.5 to 3.2 cm.) for nonwoven fabric having uncrimped fibers (no SE) but otherwise similarly prepared, embossed and bonded.

The above substrates are then coated with a typical vinyl coating formulation such as shown below.

Ingredients: Parts by weight Copolymer of vinyl chloride/vinyl acetate 15 Plasticizer (e.g., tricresyl phosphate) 3 Methyl isobutyl ketone Toluene 30 Propylene oxide 0.2 TiO or TiO /Sb O (9/1) 10 The coating is applied in two passes (one per side) to a total coating weight of 1.7 oz./yd. (58 -/m. and is then calendered to smooth the surfaces. Window shades fabricated from these materials are compared with vinylcoated cotton in Table I.

TABLE I T Uneoated Weight Coating Coated Weight Edge Curl Tear Strength (g.)

0z./yd. G./m. Passes Oz.lyd. (}./m. In. Cm. MD XD Nonwoven fabric.... 1. 8 61 2 3. 5 119 0 13 0 32 260 375 o 2.2 75 2 3.9 132 0 25 0 64 360 455 Woven Cotton 2. 6 88 4 5.1 173 0 94 2 4 350 255 drum is motor-driven and has provision for internal oil heating. An endless flexible wire screen 15 is held in contact with the drum by guiding over suitable rollers 16, to provide a drum-to-belt contact 31.4 in. (80 cm.), and tensioned sufficently to provide a unit pressure of about 0.4 0.5 lb./sq. in. (0.030.04 kg./cm. against the drum. The entire assembly is enclosed in an insulated box 17 which can be heated with hot air and is provided with entrance and exit slots for the web 18. The embossed web from above is bonded by a passing through this unit at 4 yd./ min. (3.7 m./ min.) with both the drum and air temperature inside the box being held at 200 C. Residence time in the box is about 28 seconds and residence time under restraint is about 13 seconds.

Typical properties of a sheet prepared by the above described process are as follows:

Strip tensile strength-6 lb./in.//oz. yd. (32 g./cm.//

Tongue tear-1.3 lb.//oz./yd. (17 g.//g./m.

Elmendorf tear--260-400 g.//oz./yd. (7.7-11.8 g.//

The nonwoven webs used in the Examples 2-9 are prepared by web laydown procedures either the same or closely related to that described in Example 1. The embossing and bonding conditions used in these remaining examples are given in each instance. For convenience, poly(ethylene terephthalate) and the copolyester of poly (ethylene terephthalate)/poly(ethylene isophthalate) will hereinafter be referred to as 2GT and 2GT/2G1, respectively.

The data in Table I show that the nonwoven fabrics of this invention are superior to woven cotton as substrates for window shades in edge curl and also in tear strength, especially in the important cross-machine (filling) direction.

EXAMPLE 3 A nonwoven fabric with a unit weight of 3 oz./yd. (102 g./m. and containing (1) trilobal 2GT fibers (2.4 d.p.f.; MR 2.0) (modification ratio, MR, of trilobal fibers is the ratio of the radius of the circumscribed circle to the radius of the inscribed circle) having 4.8% SE and (2) 15% copolyester binded /20 (2GT/2G1) is embossed and bonded by the procedures described in Example 2. The fuzz-resistance rating of this material is 3 at 1000 g. and the edge curl is 0.5 in. (1.3 cm.). When this fabric is coated by dipping in a vinyl solution, removing the excess solution by passing the coated material between non-rotating round bars, and then air-drying at room temperature, a material free from pinholes is obtained with a dry coating weight of only 1 oz./yd. (34 g./m.

EXAMPLE 4 This example demonstrates the effect of crimp level (percent SE) and embossing and bonding conditions on fuzz resistance of the nonwoven fabrics of this invention. The webs weigh 3 oz./yd. (102 g./m. and contain trilobal 2GT fibers (3.1-3.4 d.p.f.; MR 3.2) and 15% cospun binder fibers 80/20 (2GT/2G1). The webs are embossed with calender rolls having 48 lines/inch (19/cm.) as in Example 1, and then bonded with a fiow-through 9 bonder as in Example 2. The results are summarized in Table II below. All of the materials listed in the table exhibit an edge curl of to 0.25 inch (0 to 0.64 cm.). Al-

though tear strength decreases with increasing embossing and bonding temperatures, all of the materials have a tear strength of greater than 700 g. in the cross-machine direction.

The data in Table II show that fuzz resistance generally is raised by increasing the percent of SE, the embossing temperature or the bonding temperature. Preferred fabrics, for example, the material with SE embossed at 185 C. and bonded at 210 C., are observed to have a crimp level of greater than per inch (7.9 per cm.) and exhibit zero edge curl.

' An 8 in. x 18 in. (20 cm. x 46 cm.) sample of the fabric with 15% SE, embossed at 185 C. and bonded at 210 C., is coated with a commercial vinyl-coating solution by the procedure in Example 3. Drying at 135 C. for 3 minutes and then at 175 C. for one minute produces a product with the best flex resistance. This product, Sample A, is superior to a cotton shade cloth material coated with the same formulation in both tear strength and flex resistance. The results are summarized below:

Tear Strength (g.)

This example demonstrates further the effect of fiber crimp level (percent SE) and bonding temperature on fuzz resistance, edge curl and tear strength. Light-weight nonwoven fabrics (1.8 oz./yd. (61 g./m. are prepared with (1) round 2GT fibers (4 d.p.f.) having varying levels of SE and (2) 12% binder fibers 80/20 (2GT/2GI).The fabrics are embossed at 170 C. with calender rolls having 58 lines/inch (19/cm.) as in Example l and then bonded with a flow-through bonder as in Example 2. The results are summarized in Table III.

10 The results in Table III indicate that increasing the SE level increases fuzz resistance, decreases edge curl, but, in general, does not have a significant effect on tear strength. Fuzz resistance increases and the tear strength decreases as the bonding temperature is raised.

Application of a vinyl coating to a sample of the lightweight nonwoven fabric in Table III (having an SE level of 15% and bonded at 210 C.) by the procedure described in Example 4 provides a material, Sample B, which is superior to vinyl-coated cotton in both flex resistance and tear strength and which is decidedly superior to low-cost, machine-oil grade cotton shade cloth. The results are summarized below:

Shade Cloth Flex Resistance Tear Strength (g.)

Cycles to pinhole XD Sample B 200 395 Vinyl-coated cotton 350 Machine-oil cotton 1 325 Although the tear strength of the nonwoven fabric of this invention decreases when a vinyl coating is applied (from 955 to 395 g.), the coated product is superior to a similarly coated cotton substrate.

EXAMPLE 6 Weight Fuzz Rating Tear Strength (g.) Bonded Web (oz/yd?) at 2,000 g.

MD XD These materials are washable using a solution of a typical laundry detergent and either a sponge or cloth. The materials have the advantage of being embossable due to their inherent thermoplastic nature. Thus they are readily embossed with deep decorative patterns using commercial fabric embossing equipment having heated rolls.

EXAMPLE 7 A web weighing 5 oz./yd. g./m. is prepared with trilobal 2GT fibers (3.7 d.p.f.; MR 3.2; 15% SE) and 15% copolyester binder fibers 80/20 (2GT/2GI). It is embossed with 48 x 48 l.p.i. 19 x 19 lines per cm.) rolls at C. and then bonded with a rotary, flowthrough bonder at 200 C. This material has a fuzz rating of 4.5 at 2000 g., tear strength of 870 (MD) 1490 (XD), low edge curl 0.5 in.; 1.3' cm.) low light trans mission and good visual uniformity. It does not show any pinholes when viewed with a light behind it. This is a preferred window shade material.

TABLE III Percent Crimp Level per- Fuzz Rating Tear Strength (g.) Edge Curl Bond Temp. 0.) SE at 2,000 g.

Inch Cm. MD XD In. Gm.

1 1 EXAMPLE 8 This example demonstrates the effect of number of selfbond areas on fuzz resistance of the nonwoven fabrics of this invention. A web (3.3 oz./yd. 112 g./m. containing round 2GT fibers (11.4% SE) and 10% copolyester binder fibers 80/20 (2GT/2GI) is embossed and bonded in a single operation by being held Within a heated chamber between lined plates (lines in top plate perpendicular to lines in bottom plate) at 210 C. and a plate pressure 78 lb./in. (5.5 kg./cm. for 1 minute. A series of plates with different number of lines is used. The resulting embossed and bonded webs are evaluated for fuzz resistance with the following results:

coated paper window shade for noise generation. The results are summarized below:

Sound intensity (decibels) Sound Frequency Lined Plates Self-bond Areas Land Width Percent of Fuzz Rating Lines/in. Lines/cm. No./in. No./cm. Fabric at 2,000 g.

n. Cm. covered These results indicate that fuzz resistance increases as the number of self-bond areas increases. At more than 1500 self-bond areas per square inch (230 per square centimeter), the nonwoven fabric has a fuzz resistance above the desired 3 level. This minimum number of self-bond areas is also preferred in order to obtain good coating uniformity as judged by translucent appearance, and to obtain adequate stiffness for good hanging characteristics.

EXAMPLE 9 A nonwoven fabric with a unit weight of 3 oz./yd. (102 g./m. and containing (1) trilobal 2GT fibers (3 d.p.f.; MR 2) having 13.6% SE and (2) copolyester binder 80/20 (2GT/2GI) is embossed at 185 C. and 5 yd./min. (4.6 m./min.) and then bonded at 200 C. and 5 yd./min. (4.6 m./min.) with the embossing and bonding apparatus described in Example 1. The fabric is then coated with a typical vinyl latex coating formulation, such as shown below, to make a translucent shade cloth material.

Parts by weight Ingredients: (solids basis) Vinyl chloride/ vinyl acetate copolymer latex 100 Plasticizer:

Dioctyl phthalate Dioctyl adipate 15 Polymeric plasticizer l5 T10 Whiting 15 Aqueous thickener solution (as required for proper flow properties).

The coated fabric is compared with a translucent vinylcoated cotton shade cloth in the following table:

Coated Fabric Woven Cotton The coated fabric is next compared with a commercial, vinyl-coated, cotton window shade and a commercial, un-

These results illustrate the nonpapery character of the nonwoven fabrics of this invention, as evidenced by the relatively low level of noise generation, particularly at the higher frequency levels, when the material is flexed. It is significant that the nonwoven fabric of this invention evaluated above not only is far superior to a typical paper material in noise generation, but is actually superior in this respect to a Woven cotton material, which type of material is considered to have acceptable nonpapery character.

Calendering and/ or embossing of nonwoven webs containing crimped fibers or fibers with residual spontaneous elongatability tend to produce cockles, longitudinal wrinkles or puckers when carried out between heated rolls. This effect can be eliminated by preheating the web to calendering or embossing temperature and then passing it between cold rolls. Prevention of cockles is important not only in uncoated window shades made with the fabrics of this invention, but is also desirable in substrates which are to be coated in order to obtain a uniform coating. With both types of fabrics, the ability to be post-embossed with deep decorative patterns is an important styling advantage obtained through the use of the fabrics of this invention; but it is necessary, in order to obtain the full benefit of this advantage, that the embossing operation can be carried out without formation of cookies. The preheating-cold roll technique ensures that the embossing can be effected to obtain this desired result. Example 10 below illustrates this technique as applied to a nonwoven fabric of this invention.

EXAMPLE 10 A nonwoven fabric of this invention, prepared in accordance with Example 1 and having a unit weight of 5 oz./yd. (170 g./m. is preheated by passing over an infrared heating panel (12 in. x 50 in.) (30 cm. x 127 cm.) at 200 C. The fabric is then embossed on a cold 14 in. (36 cm.) calender between a smooth elastomercovered roll and a steel roll engraved with a burlap pattern. The calender nip is about 2 inches (5 cm.) from the heating panel. A distinct burlap pattern is obtained without cockling with a calender pressure of 476 pounds/ linear inch kg./cm.) and a speed of 3 to 5 yards/min. (2.7 to 4.6 meters/min). Post-embossing with hot rolls C. or higher) will often produce cockling. By coldcalendering with a smooth steel roll in place of the patterned roll the side of the fabric contacting the steel roll is given a smooth surface which is especially suitable for coating. With this arrangement, two passes are required to smooth both sides. Alternatively, two smooth steel rolls can be used to smooth both sides of the fabric in a single pass. Smooth calendering with hot rolls (75 C. or higher) will often produce cockles.

Cockles and wrinkles are sometimes observed after embossing the nonwoven fabrics to produce the discrete selfbond areas required in the products of this invention.

These Wrinkles can be avoided by developing some of the potential spontaneous elongation in the nonwoven web prior to the embossing step. A convenient way to accomplish this is to consolidate the nonwoven web between heated rolls at ll7S C. prior to the embossing operation.

What is claimed is:

1. A nonwoven fabric suitable for use as a window shade material comprising continuous poly(ethylene terephthalate) fibers having at least crimps per inch of unextended length, said fabric having randomly distributed therethrough as granule bonds, a synthetic organic binder which binder has an initial tensile modulus of at least 5 grams per denier and constitutes between about and 14 25% by weight of the fabric and at least 1500 discrete self-bond areas per square inch of the fabric surface, said self-bond areas covering between about 2 and 15% of the surface area of the fabric.

2. The fabric of claim 1 wherein the synthetic fibers have at least crimps per inch of unextended length.

3. The fabric of claim 1 wherein the synthetic organic binder is a copolymer of poly(ethylene terephthalate) and poly(ethylene isophthalate).

References Cited UNITED STATES PATENTS 3,081,517 3/1963 Driesch -2. 161-173 3,083,523 4/1963 Dahlstrom et a1 161-173 3,117,055 1/1964 Guandique ct a1 161170 FOREIGN PATENTS 574,562 4/ 1959 Canada.

MORRIS SUSSMAN, Primary Examiner.

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US3081517 *Apr 11, 1960Mar 19, 1963Glanzstoff AgFleece lining
US3083523 *Mar 9, 1960Apr 2, 1963Du PontTwistless, heat relaxed interlaced yarn
US3117055 *Dec 15, 1959Jan 7, 1964Du PontNon-woven fabrica
CA574562A *Apr 21, 1959Minnesota Mining And Manufacturing CompanyNonwoven polyester fabrics useful for electrical insulation
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3607543 *Mar 21, 1969Sep 21, 1971Stevenson Philip JProcess for forming lightweight nylon nonwoven web
US3793133 *Feb 22, 1972Feb 19, 1974Kimberly Clark CoHigh energy absorbing continuous filament web laminate
US3808088 *Jul 14, 1971Apr 30, 1974Goodrich Co B FSpot bonded laminates
US3855045 *Jan 21, 1972Dec 17, 1974Kimberly Clark CoSelf-sized patterned bonded continuous filament web
US3855046 *Sep 1, 1971Dec 17, 1974Kimberly Clark CoPattern bonded continuous filament web
US3870592 *Apr 27, 1972Mar 11, 1975Kimberly Clark CoLaminates containing outer plies of continuous filament webs
US3900632 *Apr 3, 1972Aug 19, 1975Kimberly Clark CoLaminate of tissue and random laid continuous filament web
US3937777 *Nov 27, 1972Feb 10, 1976Dynamit Nobel AgProcess for the production of sheets of foamed thermoplastics synthetic resins
US3975224 *Aug 16, 1973Aug 17, 1976Lutravil Spinnvlies Gmbh & Co.Dimensionally stable, high-tenacity non-woven webs and process
US4351683 *Oct 23, 1970Sep 28, 1982Minnesota Mining And Manufacturing CompanyMethod of forming web material
US4486485 *Aug 24, 1983Dec 4, 1984Burlington Industries, Inc.Nonwoven textile structures with reversible stretch
US5183708 *May 27, 1991Feb 2, 1993Teijin LimitedCushion structure and process for producing the same
US5314743 *Dec 17, 1990May 24, 1994Kimberly-Clark CorporationNonwoven web containing shaped fibers
US5342336 *Mar 16, 1992Aug 30, 1994Kimberly-Clark CorporationAbsorbent structure for masking and distributing a liquid
US5458963 *Nov 16, 1994Oct 17, 1995Kimberly-Clark CorporationNonwoven web containing shaped fibers
US6588080Mar 30, 2000Jul 8, 2003Kimberly-Clark Worldwide, Inc.Controlled loft and density nonwoven webs and method for producing
US6635136Apr 24, 2001Oct 21, 2003Kimberly-Clark Worldwide, Inc.Method for producing materials having z-direction fibers and folds
US6867156Mar 30, 2000Mar 15, 2005Kimberly-Clark Worldwide, Inc.Materials having z-direction fibers and folds and method for producing same
US6998164Jun 18, 2003Feb 14, 2006Kimberly-Clark Worldwide, Inc.Controlled loft and density nonwoven webs and method for producing same
US8920899Feb 16, 2010Dec 30, 2014Mitsubishi Electric CorporationVacuum heat insulating material and refrigerator
US9068683Feb 16, 2010Jun 30, 2015Mitsubishi Electric CorporationManufacturing apparatus of core material of vacuum heat insulating material, manufacturing method of vacuum heat insulating material, vacuum heat insulating material, and refrigerator
US9074716Jul 2, 2009Jul 7, 2015Mitsubishi Electric CorporationVacuum heat insulating material, heat insulating box using vacuum heat insulating material, refrigerator, refrigerating/air-conditioning apparatus, water heater, equipments, and manufacturing method of vacuum heat insulating material
US9074717Jun 15, 2011Jul 7, 2015Mitsubishi Electric CorporationVacuum heat insulating material, heat insulating box using vacuum heat insulating material, refrigerator, refrigerating/air-conditioning apparatus, water heater, equipments, and manufacturing method of vacuum heat insulating material
US9103482Feb 16, 2010Aug 11, 2015Mitsubishi Electric CorporationVacuum heat insulating material, heat insulating box, refrigerator, refrigerating/air-conditioning apparatus, water heater, appliance, and manufacturing method of vacuum heat insulating material
US20030213109 *Jun 18, 2003Nov 20, 2003Neely James RichardControlled loft and density nonwoven webs and method for producing same
US20120201997Feb 16, 2010Aug 9, 2012Mitsubishi Electric CorporationVacuum heat insulating material and refrigerator
US20120273111 *Jun 22, 2012Nov 1, 2012Mitsubishi Electric CorporationVacuum heat insulating material, heat insulating box using vacuum heat insulating material, refrigerator, refrigerating/air-conditioning apparatus, water heater, equipments, and manufacturing method of vacuum heat insulating material
EP0049563A2 *Aug 20, 1981Apr 14, 1982Crown Zellerbach CorporationFilament draw nozzle
EP0049563A3 *Aug 20, 1981May 19, 1982Crown Zellerbach CorporationFilament draw nozzle
EP0586924B2Aug 13, 1993Sep 8, 2004Kimberly-Clark Worldwide, Inc.Method for making a nonwoven multicomponent polymeric fabric
U.S. Classification428/195.1, 442/359, 442/417, 156/62.6, 428/369, 156/181, 442/409, 156/62.4
International ClassificationD01D5/22, D04H3/16, D01D5/00
Cooperative ClassificationD04H3/16, D01D5/22
European ClassificationD04H3/16, D01D5/22