IE51743B1 - Method of making a pattern densified fibrous web having spaced,binder impregnated high density zones - Google Patents

Abstract

The invention provides a soft, pattern densified fibrous web such as a paper sheet which web generally comprises a relatively low bond, high bulk, vaulted field and a patterned array of spaced zones of relatively high fibre density, at least a substantial proportion of which dense zones are at least partially impregnated with binder material. The degree of impregnating and bonding in the dense zones may be increased by applying mechanical compression to the impregnated zones subsequent to applying the binder material. A method of making such a web is also disclosed. The method generally entails forming a low bond, pattern densified fibrous web; supporting dense zones of the web on a patterned array of spaced supports; displacing the unsupported portions of the web into the spaces intermediate the spaced supports; and applying a binder material to dense supported zones of the web.

Description

This invention relates to a method of making a soft fibrous web such as paper for paper towels and tissue paper which is reinforced at least in part by binder material.

In general, the exemplary patents described below disclose soft, relatively high bulk webs such as paper, and concomitant processes, some of which include pattern applied binder materials such as elastomers for the purpose of strengthening the fibrous webs without making them inordinately inflexible or hard or harsh to feel.

US Patent No 2,039,312 which issued May 5, 1936 to J 11 Goldman discloses a Reinforced Carded Web which may be reinforced by a reticulated network of narrow lines of impregnation with a suitable binder which lines are preferably spaced slightly less than the average fibre length of the fibres constituting the web.

US Patents No 2,880,111 and No 3,009,822 which issued to A H Drelich et al on March 31, 1959 and November 21, 1961, respectively, disclose fibrous Textile-Like Nonwoven Fabrics wherein the fibres arc held together by an adhesive or bonding material disbributed amongst them in predetermined patterns of closely spaced discrete areas. The latter patent also discloses lined patterns of binder as well as a rotogravure method of making such fabrics which includes the step of wetting a fibrous web prior to rotagravure printing a predetermined pattern of spaced binder segments.

US Patent No 3,301,746 which issued January 31, 1967 to Lawrence H Sanford and James B Sisson covers a Process for Forming Absorbent Paper by Imprinting A Fabric Knuckle Pattern Thereon Prior To Drying And Process Thereof. Briefly, a high bulk fibrous web is wet formed and predried to a fibre consistency of from about 30 to about 80 percent by avoiding substantial mechanical compression until the web is predried) then a knuckle pattern of an imprinting fabric is imprinted in the predried web while the remainder remains substantially uncompacted. The web may also be somewhat molded to the surface of the imprinting fabric by differential fluid forces prior to the predrying. Upon being imprinted, the imprinted zones become compacted and relatively highly hydrogen bonded due to the imprinting pressure and the water remaining in the predried web prior to final drying. Thus, upon final drying, the resulting paper is pattern compacted and bonded in the image of the knuckle pattern of the imprinting fabric. It is believed that such a paper is soft and bulky because of not being compacted overall and because the fibres disposed in the uncompacted portions do not become highly hydrogen bonded as in theretofore conventional felt-pressing papermaking.

US Patent No 3,994,771 which issued November 30, 1976 to George Morgan Jr et al extended this technology to a Process for Forming A Layered Paper Web Having Improved Bulk, Tactile Impression And Absorbency And Paper Thereof.

US Patent No 4,158,594 which was filed Juno 24, 1971 and issued June 19, 1979 to Henry E Becker et al discloses Bonded, Differentially Creped, Fibrous Webs And Method of Making Same wherein crcping bonding material such a:; liitex ifi paitorn grnvure printed onto a dried, self-supporting fibrous web having relatively low interfibre bonding strength. The web is preferably creped prior to printing, and is printed while being forwarded onto a creping cylinder from which it is subsequentially differentially creped. This patent recites that it is particularly desirable to apply the bonding material in a reticular pattern so that the bonding material forms a net-like web of strength over the fibrous web. Indeed, all of the disclosed examples were printed with a reticular pattern although both discrete spot bonding and reticular pattern bonding are shown in the figures. This technology was apparently broadened somewhat by the following commonly assigned patents although all commonly show gravure printing of bonding material onto dried, self-supporting fibrous webs: US Patents No 3,879,257 which issued April 22, 1975; No 3,903,342 which issued September 2, 1975) and No 4,000,237 which issued December 28, 1976.

US Patent No 3,812,000 which issued May 21, 1974 to J L Salvucci et al discloses a Soft, Absorbent, Fibrous, Sheet Material Formed By Avoiding Mechanical Compression Of The Elastomer Containing Fiber Furnish Until The Sheet Is At Least 80% Dry. As disclosed, an elastomeric bonding material is included in the fibre furnish so that it is distributed throughout the finished sheet. Additionally, more such bonding material may be applied to the sheet in a predetermined pattern by a patterned gravure roll while the sheet is being forwarded through a papermachine on a foraminous drying fabric. The pattern is stated to preferably be a reticular hexagonal pattern. As compared to the Sanford-Sisson patent described above, Salvucci et al include elastomeric material in a low-bond furnish; predry to a greater extent; and may gravure print a pattern of additional binder material on the web with a patterned gravure roll. However, Salvucci et al expressly teach away from pattern knuckle comjxiction as taught by Sanford-Sisson because the pressures generated by the knuckle pattern of the woven wire are so high as to create hard portions of the web which give a feeling of harshness to the resulting product.

US Patent No 3,898,123 which issued August 5, 1975 to Charles H Phillips et al discloses a Method For Wet Print-Bonding Light-Weight Wet-Formed Fibrous Webs wherein a self-supporting, wet-formed web has an agueous resin binder applied by print-bonding rolls having etched or engraved printing surfaces, and which binder material is applied intermediate two open draw free spans of the web prior to drying the web.

US Patent No 4,127,637 which issued November 28, 1978 to Eugene J Pietreniak et al discloses a Method Of Manufacturing 'a Dry-Formed, Embossed Adhesively Bonded, Nonwoven Fibrous Sheet having spaced uncompacted fibrous zones on a compacted reticulated fibrous network wherein binder material is preferably disposed in the uncompacted zones and through the compacted network.

US Patent No 4,159,355 which issued June 26, 1979 to Kenneth Kaufman discloses Foam Bonding method and apparatus for applying a foamed binder in a uniform and controlled metered flow to a surface of a moving substrate such as a nonwoven web.

US Patent No. 3776807 which issued December 4th 1973 to C. E. Dunning et al discloses an air-laid adhesive bonded web in which the adhesive is printed in a preselected pattern to provide areas of densified fibres extending over 10 - 40% of the surface area of the web.

The unbonded areas of the web have a pillow shaped profile in cross section and are substantially free of binder material, the fibres being of an average length greater than the separation of the densified areas from each other.

Additionally, a paper entitled Forming of Low Density Nonwoven Fabrics: Technology and Direction was presented by G Λ M Butterworth on November IJ, 1979 at the International Air Laid and Low Density Forming Seminar at the Hyatt Regency Hotel in Atlanta, Georgia. This paper provides a consolidated discussion of patents pertaining to low density webs including webs which are at least partially impregnated with, for instance, binder material.

The problem addressed by the present invention is the provision of a bonded wet-laid densified web to which binder has been applied only in the discrete high fibre density zones wherein the high bulk low density portions of the web are substantially uncompacted.

According to the invention there is provided a method of making a pattern densifed partially impregnated fibous web, which method comprises wet forming without substantial mechanical compression, an embryonic web having insufficient structural integrity to be self supporting, dewatering said embryonic web, supporting the said embryonic web on an array of spaced supports on an imprinting fabric so that each of a predetermined subarray of discrete zones of the web and each of of a predetermined sub-array of said supports are juxtaposed and imprinting the fabric pattern on the web, to give a pattern densified web formed with an array of discrete zones of high fibre density, and completing the drying of said web, the method also comprising deflecting the spans of said embryonic web disposed intermediate said spaced supports into the spaces disposed intermediate said supports to form a multiplicity of arched spans, biasing the predetermined sub-array of said supports towards a contacting type impregnating means, with said sub-array of said zones disposed between said sub-array of said supports and said impregnating means, and at least partially impregnating at least a substantial proportion of the predetermined sub-array of said zones with a binder material, said arched spans of said web being deflected sufficiently to substantially obviate impregnation of said spans with said binder material.

In the method, the array of spaced supports may be the knuckles of an endless imprinting carrier fabric and the sub-array of such supports may be only the topsurface-plane knuckles of the fabric in fabrics having both top-surface-plane knuckles and sub-top-surface knuckles. In fabrics having no sub-top-surface knuckles the sub-array of supports would in fact be the array of supports. For maximum strength, all of the high density zones are impregnated with binder material whereas only some may only be partially impregnated in sheets wherein partial impregnation provides sufficient sheet strength for the intended use of the sheets. Impregnating means such as a full field gravure applicator may be used to impregnate the dense zones of the web biased against it whereas less-than-full-field gravure applicators may be used to only partially impregnate all or some of the dense zones of the web, or wholly impregnate only some of the dense zones. Moreover, the method may further comprise the step of subjecting the impregnated zones to further mechanical pressure/compaction after they are impregnated to increase the binder penetration and interfibre bonding therein.

The invention will now be described with reference to the accompanying drawings in which; 517 4 3 Figure 1 I:: an enlarged pliol «graphic sectional view of a fragmentary sheet of paper made in accordance wJih (he.method of present invention.

Figure 2 is a fragmentary plan view drawing of a 5 sheet of paper made in accordance with the method of the present invention which sheet ocnprises a predetermined pattern of spaced high density zones disposed on a relatively high bulk field.

Figure 3 is a fragmentary sectional view taken along line 10 3-3 of Figure 2, and which sectional view generally corresponds to the photographic sectional view of Figure 1.

Figure 4 is a fragmentary sectional view drawing of a sheet of paper which is substantially identical to that shown in Figure 3 except tho flat, high density zones of the Figure 4 sheet are not impregnated with binder material.

Figure 5 is a side elevational, somewhat schematic view of a papermaking machine for manufacturing a wet laid fibrous web such as paper in accordance with the method of the present invention.

Figure 6 is a fragmentary plan view of an exemplary imprinting carrier fabric such as may be used on the papermaking machine shown in Figure 5 and which imprints its top-surface-plane knuckle pattern into a web such as a sheet of paper to precipitate a pattern of compacted zones. , Figure 7 is a radially inwardly looking fragmentary view of the surface of a rotagravure cylinder having a full field of truncated pyramidal reservoirs formed therein, and having a partially peeled back opaque overlay disposed thereon which overlay is apertured in the knuckle pattern of the imprinting carrier fabric shown in Figure 6, Figures 8 through 12 are partially masked fragmentary rotagravure cylinders which are substantially identical t ο lli.il shown in Figure' 7 except t In1 cylinders of Figures 8 through 12 are less-thun-full-field micropatterned to provide reservoirs over only about 75, 50, 50, 50 and 25 percent, respectively, of their cylindrical surface areas.

Figure 13 is a somewhat .schematic side elevational view of a handsheet impregnating apparatus.

Figure 14 is an enlarged scale, fragmentary view of the roller-nip portion of the apparatus shown in Figure 13 and through which nip portion a handsheet disposed on an imprinting carrier fabric, and a flat gravure plate are being forwarded in juxtaposed relation.

Figure 15 is an enlarged scale, fragmentary view similar to Figure 14 except the handsheet of Figure 15 is not disposed on an imprinting carrier fabric as shown in Figure 14.

A fragmentary portion of a microtomed section of a paper sheet made in accordance with the method of the present invention is shewn in the photographic Figure 1 to comprise a fibrous web 20 comprising a multiplicity of fibres 21 which are disposed in relatively high density zones 22 and 23, and arcuate-shape relatively low density span portions 24, and in which web the high density zones 22 and 23 are impregnated with a latex fibre binder material 25.

Briefly, as described more fully hereinafter in conjunction with discussing web 20, Figures 2, 3 and 4, the method of the present invention provides a soft, pattern densified fibrous web such as a paper sheet which comprises a relatively low density fibrous field and a multiplicity of relatively high density fibrous zones disposed in a predetermined array, and in which web each of at least a substantial porportion of such dense zones are at to least partially impregnated with a binder material of a type which provides interfibre bond:; which are preferably substantially more flexible than ordinary interfibre hydrogen bonds which occur between cellul5 osic fibres in ordinary papermaking. The web comprises a principal web-strength fibre constituent comprising fibres of sufficient average length with respect to the spacing of the impregnated high density zones that a substantial fraction of the fibres will have spaced portions thereof disposed in adjacent impregnated dense zones and in overlapping bonded relation with portions of other fibres so that the bonded principal web-strength fibres constitute a strength-skeletalnetwork of the web. The low density field comprises arcuate-shape spans which are so disposed with respect to the dense zones that the web has a vaulted character. Preferably, the principal web-strength fibres have average lengths of about 2.0 mm or greater (e.g. softwood fibres)) but for the impregnated dense zones, the web is characterised by a relatively low degree of interfibre bonding which may be achieved by including debonders in the furnish, or through the use of low bond fibres) and the dense zones preferably are equal in number to the number of imprinting knuckles of an imprinting fabric having a mesh count of from 10-MD/10-CD to 60-MD/6Q-CD filaments per inch (from 4 by 4 to 24 by 24 machine direction filaments and cross machine direction filaments per centimetre, respectively) and more preferably from -MD/20-CD to 50-MD/50-CD filaments per inch (from 8 by 8 to 30 by 20 machine direction filaments and cross machine direction filaments per centimetre, respectively) Briefly, a web made in accordance with the present invention as described above is preferably made by forming a pattern densified web of fibres of appropriate lengths, flexibility, and bonding propensity) supporting high density zones of the web on an array of spaced supports tl which arc preferably generally coplanar) deflecting the webs low density span portions ouL of the plane of the supports; and impregnating at least a substantial proportion of the dense zones. The degree of impregnation and/or bonding may be increased by subjecting the high density zones to mechanical compression after the basic impregnation has been effected. For instance, a wet formed embryonic web may be so pattern densified and deflected by a differential fluid pressure while the embryonic web is disposed on an appropriate imprinting carrier fabric as described hereinafter in conjunction with discussing Figure 6) and the impregnating may be effected, for instance, by a pressure biased gravure apparatus as also described hereinafter. Preferably, the web is also creped, calendered and reeled after being impregnated and dried to further increase its stretch, bulk and softness, and to control its caliper.

Referring again to Figure 1, web 20 and the preferred process for making it in accordance with the present invention are described hereinafter as paper sheet 20 and papermaking processes, respectively, although it is not intended to thereby limit the present invention.

Figure 3 is a fragmentary sectional view drawing of a paper sheet 20 made in accordance with the present invention which view is taken along line 3-3 of Figure 2, and which sectional view drawing generally corresponds to the photographic sectional view of Figure 1. That is, paper sheet 20 is shown in Figure 3 to comprise arcuateshape low density span portions 24 which are alternately spaced by relatively long and short high density zones 22 and 23 respectively, which dense zones are generally planar and are impregnated with binder material 25.

As may be seen in Figure 2, a multiplicity of dense zones 22 and 23 are disposed in a predetermined pattern or array on a generally low density field of which portions 24, Figure 3, are representative.

Figure 4 is a fragmentary sectional view drawing of a pattern densified paper sheet 20a which generally corresponds with paper sheet- 20, Figure 3, except paper sheet 20a is not impregnated with binder material. That is, paper sheet 20a is a pattern densified web which has not had its high density zones, impregnated with binder material in accordance with the present invention. Also, the relative fibre density of zones 22a and 23a of unimpregnated sheet 20a is shown to be somewhat less than the fibre density of zones 22 and 23 of sheet 20 because zones 22a and 23a have not been subjected to the mechanical compaction experienced by zones 22 and 23 through the practice of the present invention as hereinbefore described.

Figure 5 is a fragmentary, somewhat schematic side elevations1 view of an exemplary papermaking machine 30 through the use of which paper sheet embodiments of the present invention can be made and the process of the present invention can be practised. Papermaking machine 30 is a fixed roof former type papermaking machine wherein a fibrous slurry is delivered from a headbox 32 onto a Fourdrinier wire 33 passing over a vacuum type breast roll 34. The Fourdrinier wire then passes over a forming board 35 and suction box 36 and is further looped about turning rolls 41 through 46. The slurry is partially dewatered by the vacuum and table roll action of the breast roll. Further dewatering is precipitated by forming board 35 and suction box 36 so that an embryonic fibrous web 20e is formed and forwarded on the Fourdrinier wire to a first transfer station generally designated 50 where it is transferred from Fourdrinier wire 33 to an endless intermediate carrier fabric 51 which partially wraps roll 42, passes over suction boxes 52 and 53, then over vacuum transfer · box 54, and then is looped about rolls 55, 56, 57 and 58. Dewatering is furthered as the embryonic web 20e is forwarded in sandwiched relation between Fourdrinier wire 33 and fabric 51 past suction boxes 52 and 53, and then over a portion of vacuum transfer box 54 after which the embryonic web 20e is disposed and forwarded on fabric 51 to an endless imprinting carrier fabric 59 at a second transfer station designated 60. At the second transfer station 60, embryonic web 20e is transferred by the action of vacuum transfer box 61 from the intermediate carrier fabric 51 to the imprinting carrier fabric 59 which is looped past/ about suction box 62, turning roll 63, blow through predryer 64, impregnating means 65, turning roll 66, pressure roll 67, turning roll 68, showers 69, suction box 70, and turning rolls 71 and 72. At this time, formation of the web continues due to the differential fluid pressure applied to the web to effect the second transfer and fibre mobility enabled by a sufficiently high water content (preferably a fibre consistency of 30 percent or less), the embryonic web becomes pattern densified with dense zones of fibres juxtaposed the knuckles of the imprinting carrier fabric 59. After being transferred to the imprinting carrier fabric 59, the embryonic web is further dewatered by. suction box 62 and blow through predryer 64; then partially impregnated with binder material 25 by pressure biased impregnating means 65 J and then transferred to Yankee dryer 75 by the action of pressure roll 67 which is biased towards the Yankee dryer by biasing means 76. ' Transfer of the web to the Yankee dryer and adherence thereto is enabled by creping adhesive applied through applicator 77. Finally, upon being fully dried on the Yankee dryer, the transformation of embryonic web 20e to paper sheet 20 is completed as the final drying thereof is effected and, preferably, it is creped from the Yankee dryer by the action of doctor blade 78. 4 Preferably, the paper sheet 20 is then calendered and reeled to control its ciiliper and enable its subsequent conversion from reels into paper products such as paper towels, toilet and facial tissue paper. Also, in the event the binder material requires curing, such curing may be effected at least in part after the paper dieet has been removed from the papermaking machine.

Figure 6 is a plan view of the top, outwardly facing surface of an exemplary imprinting carrier fabric 59 which may be used on a papermaking machine such as papermaking machine 30, Figure 5, to practise the present invention. Fabric 59 is a five-shed satin weave of polyester monofilaments which were woven using a 1, 4, 2, 5, 3 warp pick sequence and wherein the filaments 90-1 through 90-5 which extend in the machine direction, MD, alternatively pass over four and under one of the filaments 91-1 through 91-5 which extend in the cross machine direction, CD) and wherein the CD filaments alternately pass over one and under four MD filaments. Fabric 59 has been stressed, heat set, ahd sanded to provide coplanar sets of long MD imprinting knuckles 92, and relatively short 1-over CD imprinting knuckles 93. The outwardly facing surfaces of coplanar sets of knuckles 92 and 93 corporately define a top-surface-plane of fabric 59. Fabric 59 also has adjacent pairs of sub-top-surface filament crossovers designated 94 which, by virtue of the weave, stressing, and heat setting are recessed below the topsurface-plane of the fabric. Such a fabric is described more fully in Trokhan US Patent No 4,329,065 issued December 16, 1980. Also, such a fabric is particularly useful for making, soft and absorbent imprinted paper having uncompressed portions circumscribed by picketlike lineaments of alternately spaced areas of compacted fibres and non-compacted fibres which compacted fibre areas or zones are precipitated by imprinting the top51743 surface-plane knuckles of the fabric into a relatively uncompacted, low density, high bulk paper sheet.

This is more fully described in the commonly assigned Trokhan US Patent 4,191,609 issued March 4, 1980.

While the 5-shed fabric 59, Figure 5, has been described above as exemplary with respect to the present invention it is not intended to thereby limit the present invention to any particular fabric weave, or knuckle geometry or disposition.

Impregnating means 65, Figure 5, comprises rotagravure cylinder 81, backing roll 82, biasing means 83, and reservoir 85 which is adapted by means not shown to maintain a relatively constant predetermined level of liquid impregnating material 25 therein. This level insures that a downwardly facing arcuate portion of rotagravure cylinder 81 is immersed in the impregnating material. Doctor means, not shown, are provided for removing the excess impregnating ’material from the rotagravure cylinder as it rotates upwardly towards the travelling embryonic web. Synchronous drive means, not shown, may also be provided as needed to obviate deleterious drag on the embryonic web as it passes through Lhe nip between rotagravure cylinder 81 and backing roll 82. While as described, impregnating means 65 of papermaking machine 30 is a gravure type applicator, it is not intended to thereby limit the present invention to gravure applicators or impregnators. Rather, it is believed that other contacting type applicators such as, for instance, foanr applicators may be used to practise the present invention.

Figure 7 is an enlarged scale, radially inwardly looking view of a fragmentary portion of an exemplary rotagravure cylinder 81 which has its cylindrical surface covered by a partially peeled back, opaque mask 96 which is apertured in the top-surface-plane knuckle pattern of imprinting carrier fabric 59, Figure 6. That is, apertures 92a and 93a in mask 96 are sized and disposed in the image of the topsurf ace-plane knuckle pattern of fabric 59, Figure 6.

The entire gravure surface of rotagravure cylinder 81 is defined by a full field pattern of truncated pyramidal cavities or reservoirs 100. ' In use, as an embryonic web 20e is carried through the nip of impregnating means 65 of papermaking machine 30, Figure 4, only the dense zones of the web which are juxtaposed topsurface-plane knuckles 92 and 93 of fabric 59 are biased against the rotagravure cylinder 81. This substantially limits the pattern of impregnation to the pattern of the high density zones juxtaposed the top-surface-plane knuckles 92 and 93 of fabric 59.

Thus, the pattern of impregnation is determined by the imprinting carrier fabric rather than a pattern on the rotagravure cylinder. Also, the pattern of impregnation of the web is in registration with the pattern of dense zones of the web as illustrated in web 20, Figures 1 and 3. However, the area of the web which becomes impregnated may in fact be substantially larger than the sanded areas of knuckles 92 and 93 because the filaments of the woven fabric 59 gradually slope away from the sanded areas of the knuckles and thus cause web portions contiguous thereto to be impregnated along with the web portions immediately juxtaposed the sanded areas of the knuckles Furthermore, it is believed that the absence of bias30 ing of the unsupported span portions of the embryonic web substantially obviates transfer of binding material thereto from rotagravure cylinder 81. Moreover, displacement of the unsupported span portions into the interfilamentary spaces of the imprinting fabric may be effected to virtually totally obviate their being impregnated by rotagravure cylinder 81.

Figures 8 through 12 are similar to Figure 7 excepl ihe alternate embodiment rotagravure cylinders 81a through 81c of Figures 8 through 12, respectively, are provided with less-than-full-field checkerboard type patterns of reservoirs 100 which reservoirs cover 75, 50, 50, 50 and 25 percent, respectively, of the working surfaces of cylinders 8la, 8lb, 8lc, 81d and 81e. Thus, such less-rthan-full-field patterned rotagravure cylinders will coact with a patterned imprinting fabric to apply impregnating material to only the surface portions of an embryonic web which are in registered relation with top-surface-plane knuckles and adjacent reservoir portions of the rotagravure cylinder pattern. Such patterned cylinders are useful with respect to providing various degrees of web strength through binder impregnation while preserving various complementary degrees of binderfree surface areas. Thus, strength may be increased by impregnating larger percentages of web surface area. Furthermore, whereas the alternate embodiment, lessthan-full-field, rotagravure cylinders 81a through 81e have relatively small checkerboard-type patterns with respect to the knuckle pattern of fabric 59, Figure 6, less-than-full-field patterns (not shown) having larger open (non-printing/non-impregnating) areas may be used to assure not impregnating a substantial proportion of the dense zones as well as concurrently assuring that a Substantial proportion of the dense zones will be impregnated. This is useful when, for instance, creping of the finished web is desired and the binder substantially vitiates the intended function of a creping adhesive (e.g. polyvinyl alcohol applied by spray applicators 77, Figure 5). The proportion of binder impregnated zones is maintained great enough to provide adequate web strength while the proportion of non-binder-impregnated zones is made great enough to enable the creping adhesive to securely affix those zones to the Yankee dryer (creping cylinder) to control the web and the creping thereof in substantially the manner disclosed in the hereinbefore referenced Sanford-Sisson patent.

Figure 13 is a somewhat schematic side elevational 5 view of a handsheet impregnating apparatus 106 which comprises rotatably mounted, rubber covered rolls 107 and 108, a slanted feed plate 109, a horizontal feed plate 110, and a'receiving plate 111. Means not shown' are provided to pressure bias rolls 107 and 108 together, and to synchronously rotate rolls 107 and 108 in the directions indicated by the arrows drawn thereon.

Figure 14 is a fragmentary enlarged scale view of the nip portion of apparatus 106, Figure 13, which view shows fragmentary sections of rolls 107 and 108, a gravure plate 115, and a paper handsheet 116 disposed on the under side of an imprinting carrier fabric 117. Figure 15 is substantially identical.to Figure 14 except the handsheet 116 in Figure 15 is self-supported, i.e. not disposed on an imprinting carrier fabric.

In use, referring to handsheet impregnating apparatus 106, Figures 13 through 15, a gravure plate 115 is placed on plate 110 with its pattern side up and with its cells filled with binder material. Then, a hand25 sheet 116 is placed on plate 109. Handsheet 116 may be associated with an imprinting carrier fabric 117 as indicated in Figure 14, or not so associated as indicated by the absence of such a fabric 117 from Figure 15. Then, rolls 107 and 108 are biased together with a predetermined force and rotated sychronously while the handsheet 116 and the gravure plate 115 are simultaneously moved so that their leading edges enter the nip between the rolls. Thus, as the handsheet and gravure plate pass through the nip, the handsheet becomes impregnated. When the web is associated with a fabric during impregnation as shown in Figure 14, the pattern of web impregnation is the knuckle pattern of the fabric v/hen a full field gravure plate is used. Therefore, when the handsheet has been pattern densified by formation on an imprinting carrier fabric so that the dense zones of the handsheet are juxtaposed the knuckles of the imprinting carrier fabric, only the dense zones of the handsheet become impregnated by a full field gravure plate through the use of handsheet impregnating apparatus 106.

Briefly, referring back to Figure 5, an embryonic web 20e is preferably formed and forwarded without subjecting it to substantial mechanical compaction until it reaches the impregnating means 65. By including a principal web-strength fibre constituent in the furnish which constituent consists of fibres having a predetermined average length relation with respect to the knuckle pattern of the imprinting carrier fabric 59, and by.controlling dewatering a pattern densified embryonic web may be formed in which web relatively high fibre density zones are juxtaposed the outwardly facing knuckles of imprinting carrier fabric 59, and in which web the remaining portions which are unsupported and span the spaces between the knuckles have relatively low fibre density. Preferably, the unsupported spans are also acted on by sufficient differential fluid pressure while the web is at a sufficiently low fibre consistency to sufficiently displace the unsupported spans into the interfilamentary spaces between the knuckles of the imprinting carrier fabric to obviate their being impregnated by impregnating means 65 although it is ' not intended to thereby limit the present invention.

The embryonic web is preferably predried to from about 30 to about 95 percent fibre consistency and more preferably to from about 60 to about 90 percent fibre consistency prior to being impregnated. Also, preferably the drying is sufficiently asymmetrical to dry the unsupported portions of the web substantially more than the dense portions. This may be effected, for instance, by blow through predrying of the web while it is disposed on the imprinting carrier fabric of papermaking machine 30. This enhances the Zdirection penetration of the binder material through the thickness of the web and lessens the propensity of the binder material to migrate laterally in the X-Y directions into the low density portions of the web.

Such X-Y migration into the low density portions of the web from the high density zones is further inhibited due to their relative capillary structures: i.e. normally capillary flow is greater from low density to high density zones than from high density to low density zones. Moreover, with respect to latex type binder emulsions in particular, it is believed that the commencement of X-Y migration from relatively wet zones into dry areas acts to dewater such emulsions and cause them to coagulate rather than migrate very far into the dry areas.

In addition to the impregnation of the high density zones which is effected as the web is carried on the imprinting carrier fabric 59 through the pressure biased impregnating means 65/ Figure 5, the biasing also precipitates some compaction of and bonding within the high density zones of the web. Subsequently, as the high density zones of the web are again subjected to knuckle pressure between pressure roll 67 and Yankee dryer 75, the penetration of the binder is enhanced, and the degree of compaction and bonding within the high density zones is increased.

A number of handsheet examples as well as papermaking machine examples are described below. Briefly, the handsheet examples evidence the benefits of impreg35 nating only dense zones of a pattern densified paper sheet in accordance with the present invention) and the papermaking machine examples evidence the benefit of subjecting impregnated high density zones to further mechanical pressure after the impregnating, and the benefits which may be derived from the present invention through the use of different impregnating materials.

HANDSHEET EXAMPLE I A pattern densified, one foot square (30 cm square) handsheet having a basis weight of 16.5 pouhds per 3000 square feet (27 grams per square metre) was formed from a fibrous furnish on a foraminous polyester fabric of the 5-shed satin weave shown in Figure 6 and having a 36-MD/32-CD filaments per inch (14-MD by 12.6-CD filaments per centimetre) mesh count. The furnish comprised 60 percent by fibre weight of Tongacel ( trademark of Louisiana Pacific Corporation) K 32 4N, a relatively low bond, long fibre, post bleach cold caustic extracted dissolving grade Northern Softwood Sulfite which is available from Louisiana Pacific Corporation, and 40 percent by fibre weight of relatively long softwood fibres which were obtained from the Buckeye Cellulose Corporation under the designation Grand Prairie Prime, a Northern Softwood Kraft. After formation and draining, the handsheet was further dewatered by pulling the fabric with the handsheet disposed thereon over a vacuum slot having 10 inches (25.4 centimetres) of mercury vacuum applied thereto. The handsheet was then dried on a can type dryer while still disposed on the fabric and in its original relation thereto. The dried handsheet was then impregnated in its zones juxtaposed the topsurface-plane knuckles of the fabric by passing the fabric/sheet combination and a full-field gravure plate through the handsheet impregnating apparatus 106 as indicated in the enlarged scale Figure 14 and as hereinbefore described. The latex binder comprised a 25 percent solids, self-crosslinking acrylic latex emulsion which was obtained from Rohm and Haas Company, Philadelphia, Pennsylvania, and which was designated TR-520. The latex binder further comprised ammonium nitrate (NH^NO^), a latent acid catalyst, in the amount of 0.5 percent by weight of latex solids) Pluronic L-92 of 1.0 percent by weight of latex solids, which is a nonionic-surfactant sold by BASF Wyandotte Corporation, Parsippany, New Jersey, and which was added to serve as a finished product wetting agent) ammonium hydroxide (NH^OH) in sufficient amount to raise the pH of the binder solution to 5.0) Lithium Acetate (CH^CC^Li) in the amount of 200 ppm Lithium based on the weight of latex solids to serve as a tracer to facilitate analysis of samples to ascertain their latex content) and an anionic water soluble dye was added to allow visual inspection of the impregnati.on pattern. The gravure plate was etched to provide a full field of reservoirs which numbered 22,500 reservoirs per square inch (3500 reservoirs per square centimetre) and the corporate volume of the reservoirs was 1.2 microlitres per square centimetre of etched area.

HANDSHEET EXAMPLE 2 Handsheet Example 2 was a replicate of Handsheet Example 1 insofar as variables in the making thereof permitted.

HANDSHEET EXAMPLE 3 Handsheet Example 3 was prepared like Handsheet Examples 1 and 2 except for Number 3 the etched, full field gravure pattern comprised 40,000 reservoirs per square inch (6200 reservoirs per square centimetre), and the corporate volume of the reservoirs was 2.2 microlitres per square centimetre.

HANDSHEET EXAMPLE 4 Handsheet Example 4 was prepared like Handsheet Example 1 except that after it was dried on its forming fabric it was removed therefrom, rotated 90 degrees with respect thereto, and reassociated therewith with adhesive tape. Thus, the pattern of the zone densified handsheet was placed out of registration with the knuckle pattern of the fabric -prior to impregnation so that comparative data could be obtained with respect to out-of-registration impregnation (Handsheet Example 4) versus in-registration impregnation (Handsheet Examples 1, 2 and 3) of pattern densified fibrous webs.

HANDSHEET EXAMPLE 5 Handsheet Example 5 was prepared like Handsheet Example 4 except, prior to impregnation, the densified structure of the handsheet was placed out of registration with the knuckle pattern of the fabric by removing the handsheet from the fabric and turning the handsheet over prior to reassociating it with the fabric with adhesive tape. This handsheet provided further out-ofregistration-impregnation data which is tabulated along with the corresponding data from Handsheet Examples 1 through 4 in Table I.

HANDSHEET EXAMPLE 6 Whereas Handsheet Examples 1 through 5 were pattern densified during their formation on relatively coarse 36 x 32 mesh fabrics of the 5-shed satin weave shown in Figure 6, Handsheet Example 6 was formed with relatively uniform density on a relatively fine mesh fabric having 110 x 95, MD x CD filaments per inch (43 x 37, MD x CD filaments per centimetre), and woven with a 4-shed satin weave using a 1, 2, 3, 4 warp pick sequence. But for the different forming fabrics, Handsheet Example 6 was made and dried in the same manner and of the same furnish as Handsheet Example 1. However, because the relatively fine mesh 4-shed satin weave fabric described above is much smoother than the relatively coarse 5-shed fabric shown in Figure 6, and because the fibres of the furnish were very long with respect to the knuckle-to-knuckle span of the 110 x 95, 4-shed as compared to the coarser 36 x 32, 5-shed fabric, the handsheet formed on the 4-shed was relatively uniformly dense as compared to the pattern densified Handsheet Examples 1 through 5, inclusive. But, it is not intended to thereby imply that pattern densified sheets cannot be formed on fine mesh fabrics such as the 4-shed satin weave described above. After being dried, Handsheet Example 6 was removed from the 110 x 95 forming fabric and taped onto a 36 x 32 mesh, 5-shed fabric identical to those used for Handsheet Examples 1 through 5 prior to being impregnated.by passing it through handsheet impregnating apparatus 106 in the manner indicated in Figure 14. The gravure plate and the latex binder composition were also the same for Handsheet Example 6 as for Handsheet Examples 1, 2, 4 tnd 5. Thus, Handsheet Example 6 was a pattern impregnated sheet of relatively uniform density which yielded data which is also tabulated in Table I for conveniently comparing the pattern densified/pattern impregnated Handsheet Examples 1 through 3 embodying the present invention with the uniform density/pattern impregnated Handsheet Example 6.

Referring now to Table I, the Handsheet Examples 1 through 3 made in accordance with the present invention clearly have superior (lower) bending modulus (i.e. greater flexibility) as compared to the out-of-registration impregnated/pattern densified Handsheet Examples 4 and 5, and as compared to the pattern impregnated./uniform density Handsheet Example 6.

TftlhE I Hand- Sheet Example Humber Binder Area on Prod- Covered uct Per- Percent cent of Weight of Fibres Total Dry Tensile Strength g/cm Total Wet Tensile Strength g/cm Wet Total Tensile Percent of Dry Total Tensile Bending Modulus Kg/cra2 1 7.82 39.1 388 163 42.0 31.9 2 8.32 38.2 356 140 39.2 21.3 3 10.56 51.6 543 235 43.4 31.9 4 9.17 65.4 430 163 38.0 45.9 5 8.48 60.3 373 157 42.1 43.6 6 9.68 58.4 429 164 38.2 67.4 HANDSHEET EXAMPLES 7 AND 8 Two additional Handsheet Examples made in accordance with the present invention were prepared in the same manner and with the same furnish as Handsheet Examples 1 through 3 except the gravure plates were engraved to provide different levels of binder addition. Pertinent data from these two examples are tabulated in Table IX) in particular, comparative dry strength and wet strength data which evidences that embodiments of the present invention have greater strength derived from a given amount of binder than the nonpattern densified Handsheet Example 9 described next.

HANDSHEET EXAMPLE 9 This handsheet was of relatively uniform density and was formed, dewatered and dried substantially identically to Handsheet Example 6 using the same furnish as for Handsheet Examples 1 through 8. However, whereas Handsheet Example 6 was impregnated by a full-field gravure plate while backed by a χ 32 5-shed fabric in the manner shown in Figure 14, Handsheet Example 9 was impregnated in the manner shwon in Figure 15) that is, not backed by a fabric.

In this instance, the gravure plate 115 was prepared with a pattern identical in size and geometry to the top-surface-plane knuckles of a 36 x 32 5-shed fabric, Figure 6. The gravure pattern comprised 22,500 reservoirs per square .inch of reservoirs (3500 reservoirs per square centimetre of reservoirs) and waa derived from a 150 x 150 lines per inch (59 x 59 lines per centimetre) screen which, eas superimposed on a knuckle-pattern print made from the 36 x 32 5-shed fabric 59, Figure 6, to make a negative which was then used in producing an acid etched gravure plate.

Therefore, the uniform density Handsheet Example 9 was pattern impregnated in the same pattern as Handsheet Examples 7 and 8, However, whereas Handsheet Examples 7 and 8 were pattern densified prior to their being impreg20 nated in their dense zones, Handsheet Example 9 was of uniform density, i.e. having no dense zones.

TABLE II Hand- Basis Binder Total Dry Total Wet Wet Total sheet Weight Percent Tensile Tensile Tensile Example lb/3000 of Strength Strength Percent of sq ft Weight of Fibres gra/cm gra/cm Dry Total Tensile 7 16.2 4.64 277 102 36.7 8 16.0 5.40 328 125 38.0 9 15.4 5.02 213 69 32.4 Another benefit which may be derived from the present invention is precipitated by the application of pressure to the binder impregnated dense zones as, referring to Figure 5, the pattern densified embryonic web 20e 81743 (backed by fabric 59) passes through the pressure biased nip intermediate pressure roll 67 and Yankee dryer 75 prior to the final drying and creping of the web. The following example, Example 10, illustrates this.

EXAMPLE 10 Basically, a papermaking· machine of the general configuration as papermaking machine 30, Figure 5, was run to produce two families of samples during which run: the percent of latex solids in the binder emulsion in reservoir 85 was incremented from 10 to 25 and then to 40 percent) the after predryer (APD) fibre consistency was varied from about 68 percent to about 91 percent) and samples were taken from adjacent the doctor blade 78 which samples had about zero crepe, and from intermediate roll 66 and pressure roll 67. In the data tabulated in Table Ilia and Illb, the former samples are designated Pressed Samples, and the latter samples are designated Unpressed Samples) and pairs of samples are designated by pair numbers which pairs each comprise a Pressed Sample and an Unpressed Sample.

TABLE Ilia EXAMPLE 10 POST IMPREGNATION PRESSING OF DENSE ZONES PRESSED SAMPLES VS. UNPRESSED SAMPLES 5 Sample Pair No Percent Solids in Latex Binder APD Total V/et Fibre Tensile Strength Consistency % of Total Dry Percent Tensile Strength Pressed Unpressed Ratio Pressed to Unpressed fRatio of Column 4 to Column 5 10 1 10 76.0 28.0 28.3 0.99 2 10 88.9 27.6 26.1 1.06 3 25 67.6 39.7 32.4 1.23 4 25 88.7 40.2 27.9 1.44 5 40 67.6 39.0 31.4 1.24 15 6 40 90.9 31.4 21.5 1.46 TABLE Illb EXAMPLE 10 POST IMPREGNATION PRESSING OF DENSE ZONES PRESSED SAMPLES VS, UNPRESSED SAMPLES Pair ΐ/et Tensile Strength, g/cm No Pressed MD CD Total Unpressed MD CD Total 1 18.1 15.4 33.5 32.7 19.7 52.4 2 29.1 17.3 46.4 26.0 16.1 42.1 3 45.3 31.5 76.8 39.0 24.8 63.8 4 43.7 32.7 76.4 29.9 17.3 47.2 5 37.4 28.3 65.7 33.5 23.6 57.1 6 16.9 21.2 38.1 22.0 16.1 38.1 ?he samples of ExampL e 10 were made on a pape making machine of the general geometry of machine 30, Figure 5, using the 60 percent Tongacel/40 percent Grand Prairie Prime (low bond/kraft softwood fibres, respectively), long fibre furnish as used to make Handsheet Examples 1 through 9 described above. This furnish was chosen to produce, if not impregnated in accordance with the present invention, a weak weh with less than 59 grams per cm total tensile strength (the sum of the machine direction tensile strength plus the cross machine direction strength). A 0.12 percent fibre consistency pulp slurry of this furnish was distributed on a Fourdrinier wire 33 of a 4-shed satin weave havng a 78 x 60, MD x CD filament mesh count per inch (31 by 24 filaments per centimetre). Dewatering was progressively effected while the web was being forwarded on the 78 x 60 Fourdrinier wire, and then on intermediate carrier wire 51 of the same mesh, weave, and material as the Fourdrinier wire to increase the fibre consistency of the web to about 22 percent prior to being transferred to the imprinting carrier fabric 59 which was a 5-shed satin weave of the type shown in Figure 6 and having 31 x 25, MD x CD filaments per inch (12 x 10 filaments per centimetre). Further dewatering was precipitated by vacuum transfer box 61 and the triple vacuum box 62 to provide a fibre consistency of about 32 percent. The result of vacuum transferring from the 78 x 60 intermediate carrier fabric 51 to the 31 x 25 imprinting carrier fabric 59 and the vacuum dewatering thereon caused the web to become pattern densified thereby completing the formation of the pattern densified web: discrete spaced dense zones juxtaposed top-surface-plane knuckles of imprinting carrier fabric 59, and relatively low density spans or portions between those knuckles. These conditions also caused the unsupported portions of the web to be displaced by the vacuum induced differential fluid (air) pressure into the interfilamentary voids of fabric 59. The air was then predried by blow through predryer 64 to an APD fibre consistency in the range stated above: 68 percent to percent. The web, still disposed on fabric 59 then was forwarded thereon through a full-field pattern, pressure biased gravure impregnating means of the type described hereinbefore which caused the dense zones of the web to be pressed against the gravure cylinder 81 and thereby become impregnated) however, the low density span portions were not so impregnated by virtue of having been sufficiently displaced into the interfilamentary spaces of fabric 5-9 to substantially obviate their being impregnated by the impregnating means. Additionally, binder impregnation of the low density span portions was substantially obviated by not pressing them against the rotagravure cylinder 81. Rotagravure cylinder 81 was engraved with a full-field pattern of reservoirs (cells) numbering about 3500 per square centimetre and having a total volume of 1.4 microlitres per square centimetre.

The binder material used to impregnate the samples of Example 10 was the same latex emulsion as for the hereinbefore described handsheets except: the percent solids was incremented from 10 to 25 and then to 40 percent) and very low levels of commercial defoamers (Foammaster 160L and Colloid 694) were added to suppress foaming of the latex emulsion 25 in reservoir 85 as cylinder 81 rotated therethrough and the excess latex was doctored therefrom. Foammaster 160L was obtained from Diamond Shamrock Corporation, Cleveland, Ohio, and Colloid 694 was obtained from Colloids Inc, Newark, New Jersey.

Further with respect to Example 10, backing roll 82, Figure 5, was an 80 Shore A Durometer rubber covered roll) and pressure roll 67 was an 85 Shore A Durometer rubber covered roll. Roll 82 was biased towards cylinder 81 with a force of about 20 pounds 517 43 1 per lineal inch (3.5 kilograms per lineal centimetre)J and pressure roll 67 was biased towards Yankee cylinder 75 at 440 pounds per lineal inch (78 kilograms per lineal centimetre). The creping adhesive which was applied to Yankee dryer 75 via spray applicators 77 to enable creping was Gelvatol 20-90; a polyvinyl alcohol/acetate manufactured by Monsanto Co, St Louis, Missouri. After being creped from the Yankee dryer 75 by doctor blade 78, the paper web from which the pressed samples were taken was reeled at the same speed as the Yankee; thus the samples exhibited virtually zero residual crepe so that residual crepe would not be a substantial difference between the pressed samples and the unpressed samples which were obtained as follows. The unpressed samples of Example 10 were obtained by pressing a sheet width, adhesive coated, rotatably'mounted spool against the web on fabric 59 running from roll 66 towards pressure roll 67 to accumulate sufficient web on the spool to run samples thereof which were not adulterated by the adhesive on the spool. The samples were tested to obtain the Tables Ilia and IIIb data after being cured for 5 minutes at 300°F (150°C).

Generally, the data in Tables Ilia and IIIb indicate that post-impregnation pressing as described hereinbefore precipitates improved wet tensile strength; and greater wet tensile strength for a 25 percent level of solids in a latex binder emulsion than for either a 10 percent or 40 percent level of solids. Furthermore, post-impregnation pressing also generally improves the ratio of total wet strength to total dry strength of the paper which is generally regarded as a performance parameter for paper towels and the like.

Three more papermaking experiments which are designated and described below as Examples 11, 12 and were conducted to produce papers embodying Si 743 the present invention: that is, pattern densified papers having discrete, spaced, binder impregnated zones of high fibre density and otherwise being substantially low bond, high bulk, unimpregnated structures. Data from these examples are tabulated in Table IV. 3 TABLE IV EXAMPLE 11 2-piy Paper Towel EXAMPLE 12 2-Ply Paper Towel EXAMPLE 13 3-Layer Toilet Tissue Basis Weight: pounds per 3000 sq ft(grams per square metre) 34.2 (55.8) 39.2 (63.9) 16.8 (27.4) Caliper: mils (om) 33.1 (0.83) 30.0 (0.76) 10.7 (0.27) Dry MD Tensile Strength: grams/inch(grams/cm) 465 (183) 924 (364) 196 (77) Dry CD Tensile Strength: grams/inch(grams/cm) 346 (136) 559 (220) 144 (57) Wet CD Tensile Strength: grams/inch(grams/cm) 157 (62) 176 (69) Not measured Wet/Dry CD Tensile strength 47% 31% Wet Tear Strength: grams 56.0 53.0 Not measured Stretch MD 19% 35% 23% Stretch CD 11% 9% 7% Softness: Subjective Panel Score Units, Example Versus a Contemporary Paper Product of Comparable Basis Weight +1.7 +1.0 +1.7 Spill Wipe-Up: Subjective Panel Score Units, Example Versus a Contemporary Paper Product of Comparable Basis Weight -0.4 +0.9 Not measured Binder Content, Estimated as percent of fibre weight 6% 2% 2.4% Binder: Type Concentration Latex Emulsion 40% Solids Polymeric Solution 10% Solution Latex Emulsion 5% solids 4 Briefly, Examples 11 and 12 were made using low bond Tongacel, described hereinbefore, in the furnishes to provide low bond webs, and the process conditions were so controlled that the webs were pattern densified when fully formed, and then impregnated with binder material in their dense zones to enhance both their wet and dry strengths: a latex emulsion binder for Example 11 and a polymeric solution type binder for Example 12.

More specifically, Example 11 was made from the same 60% Tongacel/40% Northern Softwood Kraft and in the same manner as Example 10 except for a relatively constant APD fibre consistency of 78 percent) and except for the latex binder having 40 percent solids and containing no lithium tracer or dye. After the paper web was creped and doctored from the Yankee dryer, Example 11 was calendered by a rubber/steel calender roll pair at 58 pounds per square inch (400 kPa) and reeled at a speed of 75 percent of the Yankee to provide a relatively high degree of residual crepe. The reels of paper were then combined into 2-ply paper towels with the non-Yankee-contacting sides of both plies in face-to-face relation, and embossed and adhesively secured together as' taught by OS Patent No 3,414,459 which issued December 3, 1968 to E R Wells, and shown in sectional-view Figure 6 thereof. The combined product was cured at 350°F for 3 seconds, reeled, and then tested. The data are tabulated on Table IV. These paper towels exhibited high strength 30 and an extraordinary ratio of wet/dry CD tensile strength as compared to a variety of contemporary paper towels yet scored substantially higher in subjectively perceived softness. Also, the data evidences that the converting process removed a substantial 35 portion of the residual crepe in the paper.

Example 12 was also made on a papermaking machine of the same general geometry as machine 30, Figure 5, except, a three chamber divided headbox (not shown) was used to deliver two types of fibre slurries onto the Fourdrinier wiere 33 in superposed relation.

The first-down slurry juxtaposed the Fourdrinier wire was identical to the low bonding pulp slurry of Tongacel/Northern Softwood Kraft which was used to make Examples 10 and 11, and was issued from the bottom chamber of the headbox at a fibre consistency of 0.20 percent. Northern Softwood Kraft slurries were simultaneously issued from bothttie centre and top headbox chambers at a fibre consistency of 0.12 percent. The Fourdrinier wire 33, and intermediate carrier fabric 51 were the same 78 x 60 mesh and weave, respectively, as used for Examples 10 and 11. However, the imprinting carrier fabric 59 was the same 36 x 32, -shed mesh and weave as used for Handsheet Example 1. Fibre consistency was 13 percent prior to transfer to fabric 59) 29 percent before predryer (BPD)and 96 percent APD.

The binder used for Example 12 was a 10 percent solution of Parez 631 NC, a papermaking wet strength resin sold by American Cyanamid Company, Wayne, New Jersey. This is believed to be a reaction product of glyoxal with a copolymer of dialkyl dimethyl ammonium chloride and acrylamide.

The rotagravure cylinder used for Example 12 was the same as for Examples 10 and 11) and the web was finished, creped, calendered, reeled, converted to 2-ply paper towels, and tested to the same degree and in the same manner as Example 11 except both plies were oriented to place their low bond layers on the outside of the structure. The resulting data are tabulated in Table IV.

Example 13 was formed as a 3-layer structure using the 3-compartment headbox described above and in the same general manner in the same papermaking machine as Example 12. The three layers consisted of Champion Eucalyptus on the top and bottom and Grand Prairie Prime Northern Softwood Kraft in the middle. The Champion Eucalyptus was obtained from Champion International Corporation, Stamford, Connecticut. All pulps were at 0.13 percent consistency when distributed at three equal basis weights to produce a web on the machine of 17.7 pounds per 3000 square feet (28.9 grams per square metre) basis weight. The kraft layer was made from low bonding pulp furnish which had Quaker 2003 (a steary1 imidazoline made by Quaker Chemical Company, Conshohocken, Pennsylvania) added at a level of about 0.25 weight percent of the kraft. The web was initially formed on the same 78 x 60 Fourdrinier wire used for Examples 10, 11 and 12, and subsequently transferred and dewatered as generally described with respect to those Examples. The imprinting carrier fabric was a 3-shed semi-twill having a mesh count of 31 x 25, MD x CD filaments/inch (12 x 10, MD x CD filaments/cm) and was treated to provide imprinting knuckles as described in US Patent No 3,905,863 which issued September 16, 19.75 to P G Ayers. The net result of vacuum transferring from a 78 x 60 intermediate fabric to a 31 x 25 imprinting carrier fabric and subsequent dewatering was to produce a web on the 31 x 25 mesh imprinting carrier fabric of nonuniform density having low density portions juxtaposed the voids in the fabric, and high density zones juxtaposed the fabric knuckles.

The latex binder used was Airflex 402 which was obtained from Air Products and Chemicals Inc, Allentown, Pennsylvania) a dry strength vinyl-acetate ethylene emulsion. This was adjusted to have a 5% level of 7 solids, and applied by the same rotagravure cylinder of Example 10. The impregnated web, still disposed on and in register with the 31 x 25 imprinting carrier fabric, was then pressed at 440 p.l.i(78 kilograms per lineal centimetre) against the Yankee dryer, using a rubber covered pressure roll with a Shore A Durometer hardness of 85 loaded against the dryer to imprint the knuckle pattern of the fabric into the web and thereby compact the dense zones thereof.

Gelvatol 20-90 polyvinyl alcohol/acetate manufactured by Monsanto was applied to the Yankee dryer upstream from the pressure roll to adhere the web to the Yankee and allow creping at the doctor blade after the web was dried. The web was then run through a rubber roll/ steel roll papermaking calendering nip at a light load and wound up on a reel at 82% of the Yankee speed.

The reels of paper thus obtained were rewound and slit into standard toilet tissue rolls and tested.

The test data are tabulated in Table IV.

Claims (16)

CLAIMS :

1. A method of making a pattern densified partially impregnated fibrous web, which method comprises wet forming, without substantial mechanical compression, an embryonic web having in5 sufficient structural integrity to be self supporting, dewatering said embryonic web, supporting the said embryonic web on an array of spaced supports on an imprinting fabric so that each of a predetermined sub-array of discrete zones of the web and each of a predetermined sub-array of said supports are juxtaposed 10 and imprinting the fabric pattern on the web, to give a pattern densified web formed with an array of discrete zones of high fibre density and completing the drying of said web, the method also comprising deflecting the spans of said embryonic web disposed intermediate said spaced supports into the spaces disposed 15 intermediate said supports to form a multiplicity of arched spans, biasing the predetermined sub-array of said supports towards a contacting type impregnating means, with said sub-array of said zones disposed between said sub-array of said supports and said impregnating means, and at least partially impregnating at least 20 a substantial proportion of the predetermined sub-array of said zones with a binder material, said arched spans of said web being deflected sufficiently to substantially obviate impregnation of said spans with said binder material.

2. A method according to Claim 1, wherein said supports com25 prise outward facing knuckles of a loop of an imprinting carrier fabric, said fabric having meshes in the range of from 4-MD/4-CD to 24-MD/24-CD filaments per centimetre.

3. A method according to Claim 2, wherein said fabric has meshes in the range from 8-MD/8-CD to 2O-MD/2O-CD filaments per 30 centimetre.

4. A method according to any one of Claims 1 - 3, wherein said web comprises a principal web-strength fibre constituent of fibres of sufficient average length with respect to the spacing of said supports constituting said predetermined sub-array of said 35 supports that after said web is formed a substantial fraction of said fibres will have spaced portions thereof disposed on adjacent supports of said sub-array of said supports and in overlapping relation with portions of other fibres whereby said fibres constitute a strength-skeletal-network of said web with said overlapping portions of said fibres bonded together.

5. A method according to any one of Claims 1-4, wherein the aqueous fibrous slurry used to form the web comprises a fibrous furnish of sufficiently low inherent interfibre bonding propensity that said embryonic fibrous web would have insufficient structural integrity to be self supporting while being impregnated with said binder material.

6. A method according to any one of Claims 1-5, which comprises the step of drying said embryonic web in the absence of substantial mechanical compression to an average fibre consistency of from 30 to 95 percent prior to said impregnating.

7. A method according to Claim 6, wherein said embryonic web is dried to an average fibre consistency of from 60 to 90 percent prior to said impregnating.

8. A method according to Claim 6 or 7, wherein said drying is effected in such a manner that the unsupported spans of said embryonic web are dried substantially more than the supported zones of said embryonic web.

9. A method according to Claim 8, wherein said drying is effected by blow through drying means while said web is supported on said supports.

10. A method according to any one of Claims 1-9, wherein the deflection of the spans of said embryonic web is effected by applying a differential fluid pressure across said supported web. 4 0

11. Λ method according to any one of Claims 1 - 10, which comprises the further step of subjecting said supported zones to substantial mechanical compression after said impregnating has been effected. 5

12. A method according to any one of Claims 1-11, wherein said predetermined sub-array of said supports coacts with an impregnation pattern of said impregnating means so that said impregnating material is applied to only the portions of said zones disposed intermediate registered areas of said predeter10 mined sub-array of said supports and said impregnating pattern during said impregnating.

13. A method according to Claim 1 of making a pattern densified partially impregnated fibrous web, substantially as hereinbefore described with reference to the accompanying 15 drawings.

14. A method according to Claim 1 of making a pattern densified partially impregnated fibrous web, substantially as hereinbefore described and exemplified.

15. A pattern densified partially impregnated fibrous web

16. 20 whenever made by a method claimed in a preceding claim.