US 3886942 A
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Description (OCR text may contain errors)
United stateS Patent 1 1 1111 3,886,942 Bernardin 1 June 3, 1975 1 SANITARY NAPKlN 3,336,923 8/1967 De Vaud 128/290 R 3.420235 1/1969 Harmon 128/290 R  Inventor Bernard, 3.545.442 12/1970 Wicker et a1. 128/296  Assignee: Kimberly-Clark Corporation,
N h, W eena ls Primary Examiner-Richard A. Gaudet  Filed: Apr. 29, 1974 Assistant ExaminerHenry S. Layton Appl. No.: 464,970
Related US. Application Data Attorney, Agent, or Firm-Wolfe, Hubbard. Leydig, Voit & Osann, Ltd.
6 Claims, 3 Drawing Figures SANITARY NAPKIN This is a continuation of application Ser. No. 15,164, filed Feb. 27, 1970, now abandoned.
DESCRIPTION OF THE INVENTION Sanitary napkins generally comprise an inner core of absorbent material and a fluid permeable outer cover. The cover should serve merely as an enclosing means for the absorbent material and have substantially no capacity for fluid absorption or retention itself.
Canadian Pat. No. 826,352 discloses a sanitary napkin which is said to possess optimum properties. The napkin therein disclosed consists of an inner core of absorbent material covered with a web of autogenously bonded synthetic fibers such as polyethylene, polypropylene, or polyesters. The web is disclosed as being prepared by carding, garnetting, or air laying.
While the Canadian patent states that fluids will readily pass through the outer cover and be retained in the inner core with no resultant clammy or wet feeling to the wearer of the sanitary napkin, and this is ture during periods of light flow; it has been found that as the amount of fluid retained by the inner core increases there is an increasing retention of fluid by the cover and this contributes to some discomfort. Thus, in actual use, the napkin surface does not remain as dry as would be expected; and, accordingly, there is still a need for improvement over the napkins disclosed in the Canadian patent.
Accordingly, it is a principal object of the present invention to provide an improved sanitary napkin which readily absorbs and retains fluid, and which maintains a substantially dry surface during use.
Another object is .to provide a sanitary napkin with an improved cover. It is a further object to provide a napkin as above-described with particularly desirable strength characteristics and which can be prepared economically.
Other objects and advantages will become apparent as the description proceeds and with reference to the drawings in which:
FIG. 1 is a perspective view illustrating a sanitary napkin of the present invention with a portion thereof cut away;
FIG. 2 is a plan view of a section of a web useful as a sanitary napkin cover.
FIG. 3 is an enlarged view of a section of a preferred web useful as a sanitary napkin cover.
While the invention is susceptible of various modifications and alternative constructions, there is shown in the drawings and will herein be described in detail the preferred embodiments. It is to be understood, however, that it is not intended to limit the invention to the specific forms disclosed. On the contrary, it is intended to cover all modifications and alternative constructions falling within the spirit and scope of the invention as expressed in the appended claims.
Briefly, the sanitary napkins f the present invention comprise an inner core of absorbent material and a cover consisting essentially of a porous web of unfinished thermoplastic fibers. As used herein, the term unfinished" refers to fibers whose surfaces do not contain lubricants, anti-static, or wetting agents. In this respect, it should be noted that the fibers customarily employed in preparing webs by techniques such as weaving, carding, air-laying or garnetting are finished, i.e., have their surfaces dressed with a combination of a lubricating, antistatic and wetting agent. In the absence of a surface finish, it is extremely difficult to handle the fibers during web preparation, and, accordingly, finished fibers are universally employed when webs are to be fabricated by such techniques. Typically, finished thermoplastic fibers have receding contact angles with water of less than Unfinished fibers, on the other hand, have somewhat higher contact angles with, unfinished polypropylene having a receding contact angle with water of greater than about 90, and generally in the range of about l00-l20.
Also, as used herein, the term consisting essentially of means that the porous web of unfinished thermoplastic fibers is an indispensibly necessary component of the cover, but that other cover components which do not detract from the desirable characteristics of the napkin can also be present. For example, those portions of the napkin cover which are not in contact with the body of the wearer need not be prepared from unfinished fibers.
Turning to the drawings, FIG. 1 depicts a sanitary napkin I0 comprised of an inner core of absorbent material l2 and a cover 14. The absorbent material 12 can be of conventional shape and size and can be any of those materials ordinarily used in sanitary napkin applications such as wood pulp fluff, cellulose wadding, cotton or rayon fibers, etc. Similarly, the manufacture of the sanitary napkin can be accomplished by generally known techniques which involve wrapping the core with the cover, and, thereafter, sealing the cover in order to enclose the absorbent material within, and provide means for securing the napkin to a belt or the like such as tabs.
With respect to the cover 14, it has been indicated that it consists essentially of a porous web of unfinished thermoplastic fibers. While webs of unfinished polypropylene fibers exhibit optimum characteristics, webs of other unfinished polyolefin fibers (e.g., polyethylene, polybutene, etc.) as well as polyester fibers can be advantageously used. F lG. 2 illustrates a preferred cover web 16 which, as shown, is made up of a plurality of substantially continuous, molecularly oriented, unfinished fiber filaments 18 arranged in a substantially random array.
Concerning the web 16, it is not essential that the fiber filaments therein be continuous, so long as they are unfinished. However, the fact that a continuous filament web can be directly obtained from unfinished fiber filaments renders such webs economically attractive. Moreover, as hereinafter discussed with respect to further aspects of the present invention, napkins prepared with covers as illustrated in FIG. 2 possess especially desirable strength characteristics. However, while continuous filament webs are preferred, other webs, such as those prepared by carding, wherein after preparation the surface fiber finish is removed, can also be used.
A variety of methods exist for preparing continuous filament webs of thermoplastic fibers. U.S. Pat. Nos. 3,34l,394 and 3,338,992 to Kinney disclose several presently known techniques. In general, web formation involves continuously extruding polymer through a spinneret, drawing the spun filaments, and thereafter depositing the drawn filaments on a continuously moving surface in a substantially random fashion. Drawing serves to give the polymer filaments tenacity, while substantially random deposition gives the web desirable isotropic strength characteristics.
In addition to presently known methods of initial web formation, a particularly useful technique is described in copending application Ser. No. 865,128. titled Continuous Filament Nonwoven Web and Process For Producing the Same, filed on Oct. 9, l969 and now U.S. Pat. No. 3,692,618. Use of the method therein disclosed permits especially high rates of web formation and, as hereinafter discussed, results in desirable product attributes. The disclosed method involves conventional spinning of continuous filaments of a synthetic polymer by, for example, extruding the polymer through a multiple number of downwardly directed spinning nozzles, preferably extending in a row or multiple number of rows. The filaments, as they are spun, are gathered into a straight row of side-by-side, evenly spaced apart, untwisted bundles each containing at least l5 and preferably from 50 to 150 filaments. These filament bundles are simultaneously drawn downwardly at a velocity of at least 3,000 meters per minute, and preferably from 3,500 to 8,000 meters per minute, in individually surrounding gas columns flowing at a supersonic velocity and directed to impinge on a substantially horizontal carrier. The gathering of the filaments into the bundles and their drawing and directing to impinge on the carrier is preferably effected by passing the bundles through air guns which surround the filaments with a column or jet of air which is directed downward at supersonic velocity. The air guns are arranged so as to extend in a straight row in a direction extending across the carrier at right angles to its direction of movement, so that the bundles confined in the gas columns as the same strike the moving carrier extend in a line or row at right angles across the carrier. In order to enhance intermingling of the bundles, the air guns can be made to oscillate, the plane of oscillation being transverse to the direction of carrier movement. The carrier can be a conventional carrier used in a nonwoven art, such as an endless carrier or belt screen or the upper portion of a drum, as for example a screen drum.
When prepared as described above, the filament bundles, containing a number of parallel filaments, are laid down on the carrier in a loop-like arrangement with primary loops extending back and forth across the width of a section defined by the impingement of the air column from one air gun on the carrier. Before and as the parallel filaments bundles impinge the carrier, they are broken up into sub-bundles containing a lesser number of parallel filaments and forming secondary smaller loops and swirls. The secondary loops and swirls overlap each other, and those of adjacent sections, to result in substantially complete intermingling with the overlapping portions of adjacent sections. Thus, the laid-down filament bundles form a continuous uniform nonwoven web.
A portion of a web prepared as described above is shown in FIG. 3. Several filament sub-bundles, such as those numbered 20, 22, and 24, are depicted. Due to the presence of filament bundles, rather than all single filaments as with other continuous filament webs, large inter bundle pores exist. It is felt that the existance of these pores helps promote fluid penetration into the inner core of a napkin when such a web is employed as the cover.
The web illustrated in FIG. 2 when used as a sanitary napkin cover can have a basis weight of about 0.25-] ozjydf, and preferably about 0.3-0.7 oz./yd.". The filaments thereof can have a denier of about 1-5 and, preferably, about l.2-2.
ln order to be useful as a sanitary napkin cover, the web of unfinished thermoplastic fibers must be bonded in a manner which imparts sufficient web strength, and yet does not adversely affect web softness or porosity of fluid transfer. In this respect, it has been found that those techniques which involve overall web bonding are generally unsatisfactory both with respect to porosity and sofness. Referring again to H65. 2 and 3, a preferred manner of web bonding is illustrated. As therein shown, the filaments of the webs are bonded together at a discrete number of spot bond areas 26 distributed intermittently throughout the web. A desirable combination of cover porosity and strength is present in a web wherein the total bonded area is about 550% of the web area and wherein the density of individual bond areas is about 50-3200 per inch the higher bond densities being employed with higher total bonded areas. Particularly preferred webs are those having a total bonded area of about 8-20% and a bond density of -500 per inch.
An especially suitable manner of preparing a bonded web such as illustrated in the figures is disclosed in copending Hansens et al. application Ser. No. 15,034 titled Pattern Bonded Continuous Filament Web, which application was abandoned in favor of application maturing into US Pat. No. 3,855,046. The bonding process illustrated therein comprises passing the unbonded continuous filament web through the pressure nip formed between a smooth hard roll and a heated embossing roll. By appropriately controlling the temperature of the rolls and the nip pressure, a web with a highly desirable type of bond, termed a release" bond, can be obtained. At web speeds of about 275-350 ft./min., such bonding can be achieved by maintaining the smooth roll at a temperature of less than about 270F., keeping the heated embossing roll at 300320C., and applying a nip pressure, on each raised embossing point, of 5,000-50,000 p.s.i.
The release bonds achieved by the process illustrated in Hansen et al. are characterized by the absence of a uniform degree of fiber bonding throughout an individual spot bond area which contain autogenously bonded filaments. When viewed under a microscope, the fibers bonded in the surface next to the embossing roll are seen to have substantially lost their filamentary character, while the fibers bonded in the other surface are cohesively secured together but retain their filament identity.
A significant advantage of the sanitary napkins described herein is their ability to absorb menstrual and other body fluids under the applied pressures of normal usage, and still provide a dry surface feel to the wearer. Such is believed to be due to the fact that the unfinished thermoplastic filaments in the cover are not only resistant to fluid absorption themselves, but additionally prevent fluid, when once absorbed within the inner core of the napkin, from coming back out to stain clothing or rewet the body. The superiority of a web of unfinished fibers for sanitary napkin covers is particularly unexpected in view of the fact that the webs illustrated herein do not exhibit such superior utility in related uses, such as diaper liners.
The above-mentioned desirable fluid behavior characteristics of the cover described herein are illustrated by comparatively evaluating the capillary transfer characteristics of a variety of covers. Such is accomplished uous filament webs illustrated herein make them especially desirable for sanitary napkin covers. Due to the randomness of filament orientation present in such webs, the tensile strength and stretch characteristics as follows: 5 are more isotropic than in existing webs. Such isotropic A standard capillary transfer cell (Textile Research characteristics are particularly important in sanitary J. 37, No. 5: 356-366)( May, 1967) is filled with water napkin applications since, in use, stresses are present in and 3 grams of filler from a conventional regular Kotex all directions. Moreover, by appropriate web bonding, feminine napkin is placed on one side of the cell. A sinas previously discussed, such isotropic strength can be gle layer of the web to be tested is placed on the other 10 obtained in combination with a desirable softness and side. Weights exerting about 0.l psi are used on both overall feel. Optimum mechanical characteristics, parsides of the cell to assure contact between the cell and ticularly with respect to the combination tensile the materials. After positioning, 7.5 ml. of water (or 10 strength and elongation, can be achieved with a web ml.) is added to the web sample side of the cell after containing release bonds as described in the previously which the cell valve is opened and water transfer to the referred to Hansen et al. application. When such a web filler permitted for l00 minutes. Thereafter, the web is used as a napkin cover, the web surface which was sample is weighed and the retained moisture therein in contact with the smooth roll during bonding should determined and reported asper cent moisture retention be placed adjacent to the inner core. By doing such, based on the weight of dry fiber. For sanitary napkin high abrasion resistance of the cover material can be covers, a low value of moisture retention is desirable. obtained. Moisture retention values obtained on several conven- Table 2 illustrates the mechanical and overall feel tionally available webs used as sanitary napkin covers characteristics of web covers prepared as described and on a web prepared as described herein are presherein compared with conventional webs used as saniented in Table l. tary napkin covers.
TABLE 1 Moisture Retention Web Basis Wt. g/yd. Initial 7.5 ml. initial l0 ml. Adhesively Bonded Carded Ra on Web 14 220 370 B. Ny on Scrim with Cotton Applique 7.8 100 260 Autogenously Bonded Carded Web of Finished Polypropylene Fibers 20.3 75 I08 D. Autogenously Bonded Carded Web of Unfinished Polypropylene Fibers" 20.3 2 l l E. Spot Bonded Web of Continuous Filaments of Unfinished Polypropylene Fibers" l5 2 3 Finish removed from immediately preceding finished fiber web by 3 step Soxhlet extraction with hexane. methanol. and water (4 hours each).
"Prepared as described in Scrial No. 865, l 28. with filament denier of 1.6 and fiber tenacity of 4.4 g/denier. Bonding accomplished as described in the above-mentioned Hansen nip under following conditions: Smooth roll temp. 24UF.; Embossed roll tern et al. application by passing web at 330 It/rnin. thro p. 300F.; Individual bond areas 0.0285" on h a smooth roll-embossing roll a side and spaced l0 per inch in both machine and cross-direction; 17% of total area bonded; Nip pressure on a raised point 28,000 psi.
Determined using a Thwing-Albert Instrument Company Handle-o Meter.
As can be appreciated from the results presented in Table l, sanitary napkin covers consisting essentially of unfinished fibers, particularly polypropylene, possess superior fluid behavior characteristics than do conventional webs of either rayon. nylon, or finished polypropylene fibers.
In addition to the above-discussed fluid behavior. the mechanical and aesthetic characteristics of the contin- Thus, it is apparent that there has been provided, according to the invention, an improved sanitary napkin whichfully satisfies the aims, objectives, and advantages as set forth above.
I claim as my invention:
1. A sanitary napkin comprising an inner core of absorbent material having a shape and size adaptable to absorb body menstrual fluids and a cover enclosing said inner core, said cover, in the body contacting area thereof, consisting of a nonwoven, porous and dry formed web having a basis weight of about 0.25 1 oz.- lyd. said web consisting of unfinished polyolefin or polyester fibers, said unfinished fibers being characterized by fiber surfaces which are devoid of lubricants, antistatic, or wetting agents, said web being intermittently autogenously bonded at discrete bond areas occupying about 5-50% of the web area and disposed in a density of about 50-3200/inch to permit the passage of menstrual fluid therethrough and into the absorbent core under the body pressures of normal usage to provide a substantially dry surface feel to the wearer.
2. The sanitary napkin of claim I wherein the web is an intermittently autogenously bonded porous nonwoven web of unfinished polypropylene fibers.
3. The sanitary napkin of claim 1 wherein the web is an intermittently autogenously bonded, porous web of substantially continuous and randomly deposited unfinished, molecularly oriented filaments of a polyolefin or a polyester.
4. The sanitary napkin of claim 3 wherein the continuous unfinished filaments are of polypropylene.
5. The sanitary napkin of claim 4 wherein the unfinished polypropylene filaments have a denier of about 1-5.
6. The sanitary napkin of claim 5 wherein the web has a basis weight of about 0.3-0.7 oz./yd. the unfinished polypropylene filaments have a denier of about 1.2-2 and wherein the autogenous bond areas occury about 820% of the web area and are disposed in a density of about -500/in."'.