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PAPER TOWEL PRODUCTS AND METHODS OF MAKING THE SAME

20220380983 · 2022-12-01

    Inventors

    Cpc classification

    International classification

    Abstract

    A two-ply rolled Through Air Dried paper towel with high total absorption and absorption rate at a low basis weight. Further, the paper towel has a unique combination of properties including an Sdr value of greater than 30, and a Vvd value of greater than 4.

    Claims

    1. A paper towel product comprising a laminate of at least two plies, the paper towel product being through air dried, rolled, and disposable, wherein a GATS total absorption of the product is between 17.0 grams water/grams of towel and 21.3 grams water/grams of towel.

    2. The paper towel product of claim 1, wherein a basis weight of the product is between 39 and 45 grams/m.sup.2.

    3. A paper towel product comprising a laminate of at least two plies, the paper towel product being through air dried, rolled, and disposable, wherein a GATS absorption rate of the product is between 5.0 and 6.6 (l/sec.sup.0.5).

    4. The paper towel product of claim 3, wherein a basis weight of the product is between 39 and 45 grams/m.sup.2.

    5. A paper towel product comprising a laminate of at least two plies, the paper towel product being through air dried, rolled, and disposable, wherein CD stretch of the product is between 15.5% and 19.2%.

    6. The paper towel product of claim 5, wherein a basis weight of the product is between 39 and 45 grams/m.sup.2.

    7. A paper towel product comprising a laminate of at least two plies, the paper towel product being through air dried, rolled, and disposable, wherein the product has a measured Sdr value between 36 and 60 and a Vvd value between 5 and 14.

    8. The paper towel product of claim 7, wherein a GATS total absorption of the product is between 17.0 grams water/grams of towel and 21.3 grams water/grams of towel.

    9. The paper towel product of claim 7, wherein a GATS absorption rate of the product is between 5.0 and 6.6 (l/sec.sup.0.5).

    10. The paper towel product of claim 7, wherein CD stretch of the product is between 15.5% and 19.2%.

    11. The paper towel product of claim 7, wherein a TS750 value of the product is between 19 and 32 dB V.sup.2 rms.

    12. The paper towel product of claim 7, wherein a basis weight of the product is between 39 and 45 grams/m.sup.2.

    13. A paper towel product comprising a laminate of at least two plies, the paper towel product being through air dried, rolled, and disposable wherein a TS750 value of the product is between 19 and 32 dB V.sup.2 rms.

    14. The paper towel product of claim 13, wherein a basis weight of the product is between 39 and 45 grams/m.sup.2.

    Description

    BRIEF DESCRIPTION OF THE DRAWINGS

    [0047] The features and advantages of exemplary embodiments of the present invention will be more fully understood with reference to the following, detailed description when taken in conjunction with the accompanying figures, wherein:

    [0048] FIG. 1-4 are instrument settings associated with void volume and developed interfacial area measurements;

    [0049] FIGS. 5A and 5B show an extruded netting structure in accordance with an exemplary embodiment of the present invention;

    [0050] FIG. 6 is a loading weight associated with a test method;

    [0051] FIG. 7 is an exploded view of the attachment of a towel sample to an abrading table associated with a test method;

    [0052] FIG. 8 is an apparatus associated with a test method;

    [0053] FIG. 9 is a textured film associated with a test method;

    [0054] FIG. 10 is a steel emboss roll pattern in accordance with an exemplary embodiment of the present invention;

    [0055] FIGS. 11 and 12 are three-dimensional models of a fabric in accordance with exemplary embodiments of the present invention; and

    [0056] FIGS. 13 and 14 include Tables 1 and 2 which provide various properties of the paper towel products described in the Examples and Comparative Example, as well as that of competitor products.

    DETAILED DESCRIPTION

    [0057] A two ply rolled Through Air Dried (TAD) paper towel according to an exemplary embodiment of the present invention has exceptionally high total absorption and absorption rate at a low basis weight. The attributes of high absorption and absorption rate are important for a quality paper towel. Further, combining these attributes with low basis weight provides value to the end consumer in terms of performance, cost, and sustainability.

    [0058] For the purposes of the present disclosure, the term “disposable towel” may be taken to mean a towel without extruded polymers and that is a towel made to be used and discarded. Disposable towel is not a woven cloth or plastic fiber containing towel that is designed to be cleaned and reused.

    [0059] Paper towel in accordance with exemplary embodiments of the present invention has a unique combination of properties, including a Developed Interfacial Area (“Sdr”) value of greater than about 30, and a Void Volume (“Vvd”) value of greater than about 4. These properties enable the paper towel to deliver the highest absorbency and absorbency rate with the least amount of basis weight. The ability to have high Sdr with high surface smoothness (TS750) is also a unique combination of attributes that provide value to the end consumer as these attributes provide for an absorbent towel that is also smooth to the touch. Another unique property of the present invention is cross direction (“CD”) stretch from about 14% to about 19% or about 16% to about 20%, which increases the durability of the towel.

    [0060] Suitable ranges of properties for paper towels according to exemplary embodiments of the invention are: Developed Interfacial Area (“Sdr”) between about 30 and about 65 with Void Volume (“Vvd”) between about 4 and about 16 to create a towel with high absorbency and high caliper with relatively low basis weight. In exemplary embodiments, the Sdr may range between 32 to 50 and the Vvd may range between 5 to 11 or the Sdr may range from 35 to 45 and the Vvd may range between 6 to 10. Paper towel CD stretch may range between 14% to 19 or 16% to 20%. Paper towel caliper may range between 650 to 1200 microns or 750 to 950 microns, and basis weight may range between 35 gsm to 50 gsm or 35 gsm to 45 gsm or 38 gsm to 50 gsm or 38 gsm to 49 gsm or 38 gsm to 48 gsm or 38 gsm to 47 gsm or 38 gsm to 46 gsm or 38 gsm to 45 gsm or 38 gsm to 44 gsm or 38 gsm to 43 gsm or 38 gsm to 42 gsm or 38 gsm to 41 gsm or 38 gsm to 40 gsm. Gravimetric Absorption Testing System (“GATS”) absorbency may range from about 14 g/g to about 17 g/g or 15 g/g to 16 g/g or 13.5 g/g to 16.5 g/g. The GATS absorption rate may range between about 5 to about 7 or 4.5 to 6 l/sec.sup.0.5. Softness/smoothness TS750 may range between about 19 to about 40 or 20 to 30 or 19 to 50 or 25 to 45 dB V.sup.2 rms.

    [0061] Without being bound by theory, the unique properties of low basis weight, high absorbency, smooth surface, large void volume as measured by Vvd, high absorbency, good durability with low fiber content and high caliper is made possible by the soft nip transfer of the overlaid TAD structuring belt used in accordance with exemplary embodiments of the present invention. It is believed that the compression of the top layer of the TAD belt and the paper in the pressure roll nip creates a unique paper due to flexing of the sheet and delamination of the fibers during transfer from the TAD fabric to the Yankee and further delamination of the sheet during creping. The delamination of the sheet is not random in this process because the strength of the final product is still high. The unique structure of the fiber distribution provides the paper properties stated above. The combination of paper properties are unique and desired by the end consumer. In exemplary embodiments, the present invention arises from a structure that enables improved quality properties with lower basis weight.

    [0062] In an exemplary embodiment, the paper towel product is made on a papermaking machine in accordance with a through air dried process using a structured fabric made up of a web contacting layer and a support layer.

    [0063] In exemplary embodiment, the web contacting layer of the structured fabric may have the following attributes:

    [0064] Number of MD elements: 12 to 24 per inch, preferably 14 to 20 per inch, most preferably 14 to 18 per inch;

    [0065] Number of CD elements: 6 to 20 per inch, preferably 10 to 18 per inch, most preferably 12 to 16 per inch;

    [0066] Width of MD elements: 0.35 mm to 0.65 m, preferably 0.40 mm to 0.60 mm, most preferably 0.45 mm to 0.55 mm;

    [0067] Width of CD elements: 0.35 mm to 0.65 mm, preferably 0.40 mm to 0.60 mm, most preferably 0.45 mm to 0.55 mm;

    [0068] Mesh: 12 to 24, preferably 14 to 20, most preferably 14 to 18;

    [0069] Count: 6 to 20, preferably 10 to 18, most preferably 12 to 16;

    [0070] Contact Area (static—not under load): 20% to 38%, preferably 25% to 35%, most preferably 28% to 38%;

    [0071] Contact Area (under load): 40% to 60%, preferably 42% to 56%, most preferably 44% to 50%;

    [0072] Distance between MD elements: 1.20 mm to 1.70 mm, preferably 1.30 mm to 1.60 mm, most preferably 1.40 mm to 1.50 mm;

    [0073] Distance between CD elements: 1.40 mm to 1.90 mm, preferably 1.50 mm to 1.80 mm, most preferably 1.60 mm to 1.70 mm;

    [0074] Overall Pocket Depth: 0.50 mm to 0.80 m, preferably 0.55 mm to 0.70 mm, most preferably 0.58 mm to 0.65 mm;

    [0075] Pocket Depth from top surface of netting to CD mid rib: 0.25 mm to 0.60 m, preferably 0.32 mm to 0.58 mm, most preferably 0.36 mm to 0.46 mm;

    [0076] Permeability: 300 cfm to 700 cfm, preferably 350 cfm to 600 cfm, most preferably 400 cfm to 550 cfm;

    [0077] Caliper: 1.10 mm to 1.60 mm, preferably 1.22 mm to 1.50 mm, most preferably 1.30 mm to 1.45 mm;

    [0078] Peel force (from supporting layer): 1400 gf/in to 2800 gf/in, preferably 1600 gf/in to 2600 gf/in, most preferably 1800 gf/in to 2400 gf/in;

    [0079] Embedment Distance (into supporting layer): 0.12 mm to 0.30 mm, preferably 0.16 mm to 0.27 mm, most preferably 0.19 mm to 0.25 mm; and

    [0080] Tension applied during lamination with supporting layer: 0.25 pli to 0.75 pli, preferably 0.32 pli to 0.65 pli, most preferably 0.40 pli to 0.55 pli.

    [0081] In exemplary embodiments, the supporting layer of the structured fabric may have the following attributes:

    [0082] Cross section of rectangular MD yarn: 0.15 mm×0.12 mm to 0.42 mm×0.37 mm, preferably 0.18 mm×0.15 mm to 0.39 mm×0.34 mm, most preferably 0.21 mm×0.18 mm to 0.36 mm×0.31 mm;

    [0083] Yarns/Inch of MD yarn: 40 to 70, preferably 45 to 65, most preferably 50 to 60;

    [0084] Thickness of CD yarn: 0.25 mm to 0.55 mm, preferably 0.28 mm to 0.50 mm, most preferably 0.30 mm to 0.45 mm;

    [0085] Yarns/Inch of CD yarn: 25 to 65, preferably 30 to 55, most preferably 35 to 50;

    [0086] Weave Pattern: 5 shed weave with 3 MD yarns over 2 CD yarns; preferably 5 shed weave with 2 MD yarns over 3 CD yarns; most preferably 5 shed weave with 1 MD yarn over 4 CD yarns;

    [0087] Air Permeability: 500 cfm to 900 cfm, preferably 575 cfm to 800 cfm, most preferably 625 cfm to 725 cfm;

    [0088] Percent carbon black in the MD warp yarns: 8% to 28%, preferably 10% to 22%, most preferably 12% to 16%; and

    [0089] Percent carbon black in the CD weft yarns: 25% to 55%, preferably 30% to 50%, most preferably 35% to 45%.

    [0090] In exemplary embodiments, the parameters of the laser used to laminate the web contacting layer with the supporting layer may be as follows:

    [0091] Power Level: 120 watts to 200 watts, preferably 135 watts to 185 watts, most preferably 150 watts to 170 watts;

    [0092] Weld Speed: 20 mm/sec to 80 mm/sec, preferably 30 mm/sec to 70 mm/sec, most preferably 40 mm/sec to 60 mm/sec;

    [0093] Line Width: 0.20 mm to 0.50 mm, preferably 0.25 mm to 0.45 mm, most preferably 0.30 mm to 0.40 mm; and

    [0094] Overlap Width: 0.25 mm to 2.25 mm, preferably 0.50 mm to 1.75 mm, most preferably 0.75 mm to 1.25 mm.

    [0095] In exemplary embodiments, the furnish supplied to the headbox of the papermaking machine may have the following characteristics:

    [0096] Percent of fiber types in each layer: Each layer can be from 20-60% hardwood and 40-80% softwood;

    [0097] Rates of conical refiner: On hardwood refiner—0 to 60 kwh/ton, on softwood refiner—20-120 kwh/ton;

    [0098] Amount of Kymene added to each layer: 0-12 kg/ton, or more preferably 3-9 kg/ton, or most preferably 6-9.5 kg/ton;

    [0099] Amount of Luredur 555 added to each layer: 0-12 kg/ton, or more preferably 3-9 kg/ton, or most preferably 3-6 kg/ton

    [0100] Amount of Hercobond 2800 added to each layer: 0-8 kg/ton, or more preferably 3-8 kg/ton, or most preferably 4-7 kg/ton; and

    [0101] Amount of Hercobond 6950 added to each layer: 0-3 kg/ton, or more preferably 1-2 kg/ton.

    [0102] To impart wet strength to the absorbent structure in the wet laid process, typically a cationic strength component such as Kymene 5377 is added to the furnish during stock preparation. The cationic strength component can include any polyethyleneimine, polyethylenimine, polyaminoamide-epihalohydrin (preferably epichlorohydrin), polyamine-epichlorohydrin, polyamide, polyvinylamine, or polyvinylamide wet strength resin. Useful cationic thermosetting polyaminoamide-epihalohydrin (“PAE”) and polyamine-epichlorohydrin resins are disclosed in U.S. Pat. Nos. 5,239,047, 2,926,154, 3,049,469, 3,058,873, 3,066,066, 3,125,552, 3,186,900, 3,197,427, 3,224,986, 3,224,990, 3,227,615, 3,240,664, 3,813,362, 3,778,339, 3,733,290, 3,227,671, 3,239,491, 3,240,761, 3,248,280, 3,250,664, 3,311,594, 3,329,657, 3,332,834, 3,332,901, 3,352,833, 3,248,280, 3,442,754, 3,459,697, 3,483,077, 3,609,126, 4,714,736, 3,058,873, 2,926,154, 3,877,510, 4,515,657, 4,537,657, 4,501,862, 4,147,586, 4,129,528, 3,855,158, 5,017,642, 6,908,983, 5,171,795, and 5,714,552, the contents of which are incorporated herein by reference in their entirety. Cationic thermosetting PAE resins are the most widely used wet strength resins in wet laid absorbent structures such as paper towel, napkin and facial tissue due to the chemistries ability to generate a high amount of wet strength at an affordable dosage.

    [0103] As discussed, to impart wet strength to the absorbent structure in a wet laid process, a cationic strength component may be added to the furnish during stock preparation. To impart capacity for the cationic strength resins it is well known in the art to add water soluble carboxyl containing polymers to the furnish in conjunction with the cationic resin. Suitable carboxyl containing polymers include carboxymethylcellulose (“CMC”) as disclosed in U.S. Pat. Nos. 3,058,873, 3,049,469 and 3,998,690, the contents of which are incorporated herein by reference in their entirety.

    [0104] In accordance with exemplary embodiments, the method involves the use of ultra-high molecular weight (“UHMW”) glyoxalated polyvinylamide adducts (“GPVM”) and/or high molecular weight (“HMW”), glyoxalated polyacrylamide and/or high cationic charge glyoxalated polyacrylamide (“GPAM”) copolymers such as Luredur 555 and high molecular weight (“HMW”) anionic polyacrylamide (“APAM”) such as Hercobond 2800, which are mixed with the furnish during stock preparation of a wet laid papermaking process. HMW APAM is defined as having a molecular weight greater than 500,000 Daltons and can be an inverse emulsion product or a solution product, with a solution product being preferred. Methods to produce UHMW GPVM are documented in U.S. Pat. No. 7,875,676 B2 and U.S. Pat. No. 9,879,381 B2, the contents of which are incorporated herein by reference in their entirety. These patents also characterize the polymer and the prepolymers including the molecular weight. Methods to produce high cationic charge UMW GPAM copolymers are documented in U.S. Pat. No. 9,644,320, the contents of which are incorporated herein by reference in their entirety. This patent also characterizes the polymers and the prepolymers including the molecular weight. The standard viscosity of the APAM copolymer (measured from 0.1 weight-% polymer solution in 1 M NaCl at 25° C. using a Brookfield viscometer with a UL adapter at 60 rpm) may be less than 1.5 or less than 1.6 or less than 1.7 or less than 1.8. The combination of these two or three or more chemistries (referred herein as wet strength agents) provides wet tensile strength of at least 15%, for example 20% or 25% or 30% or 40% or 50% or 60% of the value of the dry tensile strength of the absorbent product measured either in a cross direction or machine direction of the absorbent product. In embodiments, polyvinylamine (PVAM) chemistries such as Hercobond 6950 can also greatly enhance the effectiveness of the wet strength system, as well.

    Test Methods

    [0105] All paper testing is conducted on prepared samples (cut to proper size) that have been conditioned for a minimum of 2 hours in a conditioned room at a temperature of 23+−1.0 deg Celsius, and 50.0%+−2.0% Relative Humidity. The exception is softness testing which requires 24 hours of conditioning at 23+−1.0 deg Celsius, and 50.0%+−2.0% Relative Humidity.

    Ball Burst Testing

    [0106] The Ball Burst of a 2-ply tissue or towel web was determined using a Tissue Softness Analyzer (TSA), available from emtec Electronic GmbH of Leipzig, Germany using a ball burst head and holder. The instrument is calibrated every year by an outside vendor according to the instrument manual. The balance on the TSA was verified and/or calibrated before burst analysis. The balance was zeroed once the burst adapter and testing ball (16 mm diameter) were attached to the TSA. The testing distance from the testing ball to the sample was calibrated. A 112.8 mm diameter circular punch was used to cut out five round samples from the web. One of the samples was loaded into the TSA, with the embossed surface facing up, over the holder and held into place using the ring. The ball burst algorithm “Berst Resistance” was selected from the list of available softness testing algorithms displayed by the TSA. The ball burst head was then pushed by the TSA through the sample until the web ruptured and calculated the force in Newtons required for the rupture to occur. The test process was repeated for the remaining samples and the results for all the samples were averaged then converted to grams force.

    [0107] For more detailed description for operating the TSA, measuring ball burst, and calibration instructions refer to the “Leaflet Collection” or “Operating Instructions” manuals provided by emtec.

    Wet Ball Burst Testing

    [0108] The Wet Ball Burst of a 2-ply tissue or towel web was determined using a Tissue Softness Analyzer (TSA), available from emtec Electronic GmbH of Leipzig, Germany using a ball burst head and holder. The instrument is calibrated every year by an outside vendor according to the instrument manual. The balance on the TSA was verified and/or calibrated before burst analysis. The balance was zeroed once the burst adapter and testing ball (16 mm diameter) were attached to the TSA. The testing distance from the testing ball to the sample was calibrated. A 112.8 mm diameter circular punch was used to cut out five round samples from the web. One of the samples was loaded into the TSA, with the embossed surface facing up, over the holder and held into place using the ring. The ball burst algorithm “Berst Resistance” was selected from the list of available softness testing algorithms displayed by the TSA. One milliliter of water was placed onto the center of the sample using a pipette and 30 seconds was allowed to pass before beginning the measurement. The ball burst head was then pushed by the TSA through the sample until the web ruptured and calculated the force in Newtons required for the rupture to occur. The test process was repeated for the remaining samples and the results for all the samples were averaged then converted to grams force.

    [0109] For more detailed description for operating the TSA, measuring ball burst, and calibration instructions refer to the “Leaflet Collection” or “Operating Instructions” manuals provided by emtec

    Stretch & MD, CD, and WET CD Tensile Strength Testing

    [0110] A Thwing-Albert EJA series tensile tester, manufactured by Thwing Albert of West Berlin, N.J., an Instron 3343 tensile tester, manufactured by Instron of Norwood, Mass., or other suitable vertical elongation tensile testers, which may be configured in various ways, typically using 1 inch or 3 inch wide strips of tissue or towel can be utilized. The instrument is calibrated every year by an outside vendor according to the instrument manual. Jaw separation speed and distance between jaws (clamps) is verified prior to use, and the balance “zero'ed”. A pretension or slack correction of 5 N/m must be met before beginning of elongation measurement. After calibration, 6 strips of 2-ply product are cut using a 25.4 mm×120 mm die. When testing MD (Machine Direction) tensile strength, the strips were cut in the MD direction. When testing CD (Cross Machine Direction) tensile strength, the strips were cut in the CD direction. One of the sample strips was placed in between the upper jaw faces and clamped before carefully straightening (without straining the sample) and clamping the sample (hanging feely from the upper jaw) between the lower jaw faces with a gap or initial test span of 5.08 cm (2 inches). Using a jaw separation speed of 2 in/min, a test was run on the sample strip to obtain tensile strength and peak stretch (as defined by TAPPI T-581 om-17). The test procedure was repeated until all the samples were tested. The values obtained for the six sample strips were averaged to determine the tensile strength and peak stretch in the MD and CD direction. When testing CD wet tensile, the strips were placed in an oven at 105 degrees Celsius for 5 minutes and saturated with 75 microliters of deionized water at the center of the strip across the entire cross direction immediately prior to pulling the sample.

    Basis Weight

    [0111] Using a dye and press, six 76.2 mm by 76.2 mm square samples were cut from a 2-ply product being careful to avoid any web perforations. The samples were placed in an oven at 105 deg C. for a minimum of 3 minutes before being immediately weighed on an analytical balance to the fourth decimal point. The weight of the sample in grams was multiplied by 172.223 to determine the basis weight in grams/m.sup.2. The samples were tested individually, and the results were averaged. The balance should be verified before use and calibrated every year by an outside vendor according to the instrument manual.

    Caliper Testing

    [0112] A Thwing-Albert ProGage 100 Thickness Tester Model 89-2012, manufactured by Thwing Albert of West Berlin, N.J. was used for the caliper test. The instrument is verified before use and calibrated every year by an outside vendor according the instrument manual. The Thickness Tester was used with a 2 inch diameter pressure foot with a preset loading of 95 grams/square inch, a 0.030 inch/sec measuring speed, a dwell time of 3 seconds, and a dead weight of 298.45 g. Six 100 mm×100 mm square samples were cut from a 2-ply product with the emboss pattern facing up. The samples were then tested individually, and the results were averaged to obtain a caliper result in microns.

    Wet Caliper

    [0113] A Thwing-Albert ProGage 100 Thickness Tester Model 89-2012, manufactured by Thwing Albert of West Berlin, N.J. was used for the caliper test. The instrument is verified before use and calibrated every year by an outside vendor according the instrument manual. The Thickness Tester was used with a 2 inch diameter pressure foot with a preset loading of 95 grams/square inch, a 0.030 inch/sec measuring speed, a dwell time of 3 seconds, and a dead weight of 298.45 g. Six 100 mm×100 mm square samples were cut from a 2-ply product with the emboss pattern facing up. Each sample was placed in a container that had been filled to a three inch level with deionized water. The container was large enough where the sample could be placed on top of the water without having to fold the sample. The sample sat in the water in the container for 30 seconds, before being removed and then tested for caliper using the ProGage. The samples were tested individually, and the results were averaged to obtain a wet caliper result in microns.

    Softness Testing

    [0114] Softness of a 2-ply tissue or towel web was determined using a Tissue Softness Analyzer (TSA), available from emtec Electronic GmbH of Leipzig, Germany. The TSA comprises a rotor with vertical blades which rotate on the test piece to apply a defined contact pressure. Contact between the vertical blades and the test piece creates vibrations which are sensed by a vibration sensor. The sensor then transmits a signal to a PC for processing and display. The frequency analysis in the range of approximately 200 to 1000 Hz represents the surface smoothness or texture of the test piece and is referred to as the TS750 value. A further peak in the frequency range between 6 and 7 kHz represents the bulk softness of the test piece and is referred to as the TS7 value. Both TS7 and TS750 values are expressed as dB V.sup.2 rms. The stiffness of the sample is also calculated as the device measures deformation of the sample under a defined load. The stiffness value (D) is expressed as mm/N. The device also calculates a Hand Feel (HF) number with the value corresponding to a softness as perceived when someone touches a sample by hand (the higher the HF number, the higher the softness). The HF number is a combination of the TS750, TS7, and stiffness of the sample measured by the TSA and calculated using an algorithm which also requires the caliper and basis weight of the sample. Different algorithms can be selected for different facial, toilet, and towel paper products. Before testing, a calibration check should be performed using “TSA Leaflet Collection No. 9” available from emtec. If the calibration check demonstrates a calibration is necessary, “TSA Leaflet Collection No. 10” is followed.

    [0115] A 112.8 mm diameter round punch was used to cut out five samples from the web. One of the samples was loaded into the TSA, clamped into place (outward facing or embossed ply facing upward), and the TPII algorithm was selected from the list of available softness testing algorithms displayed by the TSA when testing bath tissue and the Facial II algorithm was selected when testing towel. After inputting parameters for the sample (including caliper and basis weight), the TSA measurement program was run. The test process was repeated for the remaining samples and the results for all the samples were averaged and the average HF number recorded.

    [0116] For more detailed description for operating the TSA, measuring softness, and calibrations refer to the “Leaflet Collection” or “Operating Instructions” manuals provided by emtec.

    Absorbency Testing

    [0117] An M/K GATS (Gravimetric Absorption Testing System), manufactured by M/K Systems, Inc., of Peabody, Mass., USA was used to test absorbency using MK Systems GATS Manual from Jun. 29, 2020. The instrument is calibrated annually by an outside vendor according to the manual. Absorbency is reported as grams of water absorbed per gram of absorbent product. The following steps were followed during the absorbency testing procedure:

    [0118] Turn on the computer and the GATS machine. The main power switch for the GATS is located on the left side of the front of the machine and a red light will be illuminated when power is on. Ensure the balance is on. A balance should not be used to measure masses for a least 15 minutes from the time it is turned on. Open the computer program by clicking on the “MK GATS” icon and click “Connect” once the program has loaded. If there are connectivity issues, make sure that the ports for the GATS and balance are correct. These can be seen in Full Operational Mode. The upper reservoir of the GATS needs to be filled with Deionized water. The Velmex slide level for the wetting stage was set at 6.5 cm. If the slide is not at the proper level, movement of it can only be accomplished in Full Operational Mode. Click the “Direct Mode” check box located in the top left of the screen to take the system out of Direct Mode and put into Full Operational Mode. The level of the wetting stage is adjusted in the third window down on the left side of the software screen. To move the slide up or down 1 cm at a time, the button for “1 cm up” and “1 cm down” can be used. If a millimeter adjustment is needed, press and hold the shift key while toggling the “1 cm up” or “1 cm down” icons. This will move the wetting stage 1 mm at a time. Click the “Test Options” Icon and ensure the following set-points are inputted: “Dip Start” selected with 10.0 mm inputted under “Absorption”, “Total Weight change (g)” selected with 0.1 inputted under “Start At”, Rate (g) selected with 0.05 inputted per (sec) 5 under “End At” on the left hand side of the screen, “Number of Raises” 1 inputted and regular raises (mm) 10 inputted under “Desorption”, Rate (g) selected with −0.03 inputted per 5 sec under “End At” on the right hand side of the screen. The water level in the primary reservoir needs to be filled to the operational level before any series of testing. This involves the reservoir and water contained in it to be set to 580 grams total mass. Click on the “Setup” icon in the box located in the top left of the screen. The reservoir will need to be lifted to allow the balance to tare or zero itself. The feed and draw tubes for the system are located on the side and extend into the reservoir. Prior to lifting the reservoir, ensure that the top hatch on the balance is open to keep from damaging the top of the balance or the elevated platform that the sample is weighed on. Open the side door of the balance to lift the reservoir. Once the balance reading is stable a message will appear to place the reservoir again. Ensure that the reservoir doesn't make contact with the walls of the balance. Close the side door of the balance. The reservoir will need to be filled to obtain the mass of 580 g. Once the reservoir is full, the system will be ready for testing. Obtain a minimum number of four 112.8 mm diameter circular samples. Three will be tested with one extra available. Enter the pertinent sample information in the “Enter Material ID.” section of the software. The software will automatically date and number the samples as completed with any used entered data in the center of the file name. Click the “Run Test” icon. The balance will automatically zero itself. Place the pre-cut sample on the elevated platform, making sure the sample isn't in contact with the balance lid. Once the balance load is stabilized, click “Weigh”. Move the sample to the aluminum test plate on the wetting stage, centered with the emboss facing down. Ensure the sample doesn't touch the sides and place the cover on the sample. Click “Wet the Sample”. The wetting stage will drop the preset distance to initiate absorption (10 mm). The absorption will end when the rate of absorption is less than 0.05 grams/5 seconds. When absorption stops, the wetting stage will rise to conduct desorption. Data for desorption isn't recorded for tested sample. Remove the saturated sample and dry the wetting stage prior to the next test. Once the test is complete, the system will automatically refill the reservoir. Record the data generated for this sample. The data that is traced for each sample is the dry weight of the sample (in grams), the normalized total absorption of the sample reflected in grams of water/gram of product and the normalized absorption rate in grams of water per second. The GATS absorption rate is defined as the speed at which the towel sample absorbs the water as defined by the best fit plot on the GATS absorption curve. This is a standard value plotted and reported by the GATS software in units of 1/sec.sup.05. The higher this value is, the faster the water is being absorbed by the towel sample. Repeat procedure for the three samples and report the average total absorbency.

    Wet Scrub

    [0119] A wet scrubbing test was used to measure the durability of a wet towel. The test involved scrubbing a sample wet towel with an abrasion tester and recording the number of revolutions of the tester it takes to break the sample. Multiple samples of the same product were tested and an average durability for that product was determined. The measured durability was then compared with similar durability measurements for other wet towel samples.

    [0120] An abrasion tester was used for the wet scrubbing test. The particular abrasion tester that was used was an M235 Martindale Abrasion and Pilling Tester (“M235 tester”) from SDL Atlas Textile Testing Solutions. The M235 tester provides multiple abrading tables on which the samples are abrasion tested and specimen holders that abrade the towel samples to enable multiple towel samples to be simultaneously tested. A motion plate is positioned above the abrading tables and moves the specimen holders proximate the abrasion tables to make the abrasions.

    [0121] In preparation for the test, eight (8) towel samples, approximately 140 mm (about 5.51 inches) in diameter, were cut. Additionally, four (4) pieces, also approximately 140 mm (approximately 5.51 inches) in diameter, were cut from an approximately 82±1 μm thick non-textured polymer film. The non-textured side of a Ziploc® Vacuum Sealer bag from SC Johnson was used as the non-textured polymer film. However, any non-textured polymer film, such as high density polyethylene (HDPE), low density polyethylene (LDPE), polypropylene (PP), or polyester, to name a few, could be used. Additionally, four (4) 38 mm diameter circular pieces were cut from a textured polymer film with protruding passages on the surface to provide roughness. The textured polymer film that is used for this test is the textured side of a Ziploc® Vacuum Sealer bag from SC Johnson. The textured film has a square-shaped pattern (FIG. 9). The thickness of the protruding passages of the textured polymer film that are used are approximately 213±5 μm and the thickness of the film in the valley region of the textured film between the protruding passages are approximately 131±5 The samples were cut using respective 140 mm diameter and 38 mm cutting dies and a clicker press.

    [0122] An example of an abrading table used in conjunction with the M235 tester is shown in FIG. 7. Specifically, FIG. 7 presents an exploded view of the attachment of a towel sample to an abrading table 202. To insert each sample to be tested in an abrading table, the motion plate 204 of an abrading table was removed from the tester, a clamp ring 214 was unscrewed, a piece of smooth polymer film 210 was placed on the abrading table 202, and a towel sample 212 was then placed on top of the smooth polymer film 210. A loading weight 215, shown in FIG. 6, was temporarily placed on top of the sample 212 on the abrading table 202 to hold everything in place while the clamp ring 214 was reattached to abrading table 202 to hold the towel sample 212 in place.

    [0123] Referring to FIG. 8, for each abrading table 202 in the M235 tester, there is a corresponding specimen holder 206 to perform the abrasion testing. The specimen holder 206 was assembled by inserting a piece of the textured polymer film 216 within a specimen holder insert 218 that is placed beneath and held in place under a specimen holder body 220 with a specimen holder nut (not shown). A spindle 222 was mounted to the top center of the specimen holder body 206. A top view of the textured polymer film 216 of FIG. 8 is shown in FIG. 9.

    [0124] The M235 tester was then turned on and set for a cycle time of 200 revolutions. 0.5 mL of water was placed on each towel sample. After a 30 second wait, the scrubbing test was initiated, thereby causing the specimen holder 206 to rotate 200 revolutions. The number of revolutions that it took to break each sample on the respective abrading table 202 (the “web scrubbing resistance” of the sample) was recorded. The results for the samples of each product were averaged and the products were then rated based on the averages.

    Void Volume (Vvd) and Developed Interfacial Area (Sdr)

    [0125] Void Volume relative to a specified depth (Vvd) is the volume-per-unit-area of all surface features below a user-defined depth threshold. The depth threshold was set to be 250 micrometers below the mean plane of the filtered surface data. Vvd is reported as “cubic micrometers per square micrometer” which reduces to simple micrometers.

    [0126] A depth threshold of 250 micrometers is selected for Vvd. Prior to the calculation of Vvd, the surface data is levelled with a least squared plane and filtered to suppress wavelengths shorter than 0.08 mm and also suppress wavelengths longer than 8.0 mm. This filtering process results in a band-limited surface and provides the Z=0.0 reference for thresholding.

    [0127] The developed interfacial area (Sdr) can be further understood by referencing ISO 25178-2, the contents of which are incorporated herein by reference in their entirety. Sdr is reported as a percent increase in surface area due to roughness.

    [0128] Surface images used to calculate the Vvd and Sdr were acquired using a Keyence Model VR-3200 G2 3D Macroscope equipped with motorized XY stage, VR-3000K controller, VR-H2VE version 2.2.0.89 Viewer software, and VR-H2AE Analyzer software. After following calibration procedures, as outlined by the Keyence equipment manual from 2016, the instrument was configured for 25× magnification with display units as mm. The following was selected on the viewer software: “Expert mode” for viewer capture method, and “normal” capture image type for Camera settings. For Measurement settings: “Glare removal” mode was selected with “both sides” measurement direction, Adjust brightness for measurement set to “Auto,” and Display missing and saturated data turned “ON.” This results in an “optical surface data set” which is approximately 12.1 mm (X direction) by 9.1 mm (Y direction) with a pixel size of approximately 7.9 microns.

    [0129] On paper towels, the top surface of the top ply is the surface of interest, avoiding any and all emboss points if possible. Embossments are not representative of the majority of the surface and should be avoided during the “optical surface data set” acquisition. A representative paper towel sheet was torn from the center of a roll and held in place using weights. This test was performed under ambient office temperature and humidity. When tearing the sheet from the roll, care was taken to not alter the topographic features of the sample. The machine direction (MD) of the sample was placed in the Y axis (front to back on the stage as seen from operator perspective in front of the system) while the cross direction (CD) was placed in the X axis (left to right on the stage as seen from operator perspective in front of the system). Care was taken to ensure no creases or folds were present in the sample and the sample was not under any MD or CD directional stress. The image was autofocused prior to capturing the “optical surface data set”. Three of these “optical surface data sets” were collected for each sample and the average Sdr and the average Vvd parameters are reported for the three datasets. The average values are reported as the measured values for each sheet.

    [0130] “Optical surface data sets” were exported from the analyzer software with image type “Height” and the “No Skip” option selected. These “optical surface data sets” were analyzed with OmniSurf3D (v1.03.060) software, available from Digital Metrology Solutions, Inc. of Columbus, Ind., USA for parameter calculations.

    [0131] The OmniSurf3D settings were set as follows:

    [0132] Preprocessing:

    TABLE-US-00001 Alignment: Auto-trim to Valid, No Rotation Edge Discarding: Use all data Outlier Removal: None Missing Data Filling: BiCubic Fill Data Inversion: None Transform: Rotate = 0

    [0133] Geometry:

    TABLE-US-00002 Reference Geometry: Plane (Tilt) Residuals: Vertical

    [0134] Filtering:

    [0135] Short Wavelength Limitation: Gaussian/0.0800 mm/Sync X&Y

    [0136] Long Wavelength Limitation: 2.sup.nd Order Gaussian/8.0000 mm/Sync X&Y

    [0137] Post-Filter Edge Discarding: None

    [0138] The Pre-processing settings are shown in FIG. 1. The Geometry Settings are shown in FIG. 2. The Filtering settings are shown in FIG. 3.

    [0139] The settings described above were chosen to remove underlying curvatures and to suppress short wavelength noise in the samples—thereby providing a well controlled spatial wavelength regime.

    [0140] In the “Parameters” tab of the “analysis settings,” the parameters “Sdr” and “Vvd” were chosen. The Vvd threshold is set to −250 micrometers relative to the surface mean as shown in FIG. 4.

    Peel Force Test

    [0141] An Instron Tensile Tester with two clamps was used to perform the peel force test. Narrow strips were cut from the belt in the machine direction (MD) or cross-machine direction (CD), each 4 in. long (100 mm). Initially, a small portion of the belt was peeled apart by hand, and then a strip from the papermaking top fabric and the woven bottom fabric was each placed in opposite clamps. The setting was set from 10 mm-90 mm of movement from the original length (10% to 90%) and a speed setting of 300 mm/min, and the Instron was started to peel the two strips from each other, while measuring the peel force result in N. The result was then converted to gf by multiplying by 102 unit conversion.

    Embedment Distance

    [0142] To calculate embedment distance, a series of measurements was performed using an AMES model AQD-2110 (1644 Concord Street in Framingham Mass. 01701, Tel #781 893-0095) caliper measurement device. The web contacting layer was manually peeled away and detached from the woven supporting layer, until a large, flat area (devoid of any wrinkles or creases) was produced, suitably sized for taking multiple measurements at different points. Using the AMES device, at least five (5) caliper readings were taken at different points on the exposed woven supporting layer. Those measurements were averaged together and recorded. The plunger was not allowed to strike the material being measured, as this would artificially reduce the caliper. The plunger was allowed to gently contact the material. Next, the same series of five (5) caliper readings was performed on the web contacting layer which was peeled away from the woven supporting layer. Those measurements were averaged together and recorded. Finally, the total thickness of the composite/laminated belt was measured. Five (5) caliper readings were taken, widely spaced, from a piece of composite/laminated belt which still had the web contacting layer embedded into the woven supporting layer and which had not been peeled or disturbed. Those measurements were averaged together and recorded.

    [0143] Theoretically, a fabric which has achieved no embedment of the web contacting layer into the woven supporting layer will have a total thickness equal to the web contacting layer thickness plus the woven supporting layer thickness. Using the data collected previously in this procedure, the zero-embedment value was calculated by adding the average web contacting layer thickness to the average woven supporting layer thickness, and recording this number.

    [0144] To calculate the total embedment, the total measured thickness value was subtracted from the zero-embedment thickness value. The difference between those two numbers is the distance to which the web contacting layer had become embedded in the woven supporting layer.

    Shear Number

    [0145] To calculate shear number, samples were prepared by the following method. First, cut two samples from the composite belt or fabric, one at a 45 degree angle to the weft line, the second at a 135 degree angle to the weft line. These samples are to be 2.0±0.1 inches wide by a minimum of 9 inches long.

    [0146] Next, mount the sample in the clamps of a Constant Rate Extension (CRE) testing machine such as an Instron 3343 tensile tester, manufactured by Instron of Norwood, Mass. The CRE machine is to be set at a 6.0 inch gauge length, a crosshead speed of 1 inch/minute, and a load range of 3.0 lbs, with a 100 lb load cell recommended. Cycle the CRE machine from 0 to 2 lbs/inch, then back to 0. Shear number is determined by measuring the fabric elongation between 0.5 to 2 lbs/inch of loading. The average shear number will be determined as the average of the 45 degree and 135 degree sample values. A higher Shear Number equates to a fabric that is generally more stable, less flexible, and demonstrates a higher resistance to shear forces or movement, while the converse or lower Shear Number, equates to a fabric that is less stable, more flexible, and demonstrates a lower resistance to shear forces or movement.

    [0147] Shear number may be calculated according to formula (1) as follows:


    Shear Number=(Load Range×Gauge Length)/(Fabric Elongation×Sample Width).  (1)

    [0148] Applying formula (1) in this case results in the following calculation:


    Shear Number=(3 lbs×6 in.)/(Fabric Elongation×2 in.)

    [0149] This simplifies to Shear Number=9 (lbs)× Fabric Elongation (inches)

    The fabric elongation is a measured output of the test. For this example, the fabric elongation was measured at 0.195 inches, then Shear Number=9 lbs/0.0.195 in.=46 lbs/in.

    Permeability

    [0150] Permeability was tested by following the manual instructions of the TEXTEST FX 3300 LabAir IV available from TEXTEST AG, CH-8603 Schwerzenbach, Switzerland. The instrument works in accordance with ASTM D 737 test method, Standard Test Method for Air Permeability of Textile Fabrics. For the ASTM D 737 test method, test area of 38 cm.sup.2, test pressure of 125 Pa, and ft.sup.3/ft.sup.2/min for unit of measure were selected. The unit was reset to zero. The sample was loaded and the test was started by pressing down the clamping arm. The test sample was clamped to the test head and the vacuum pump automatically started. The orifice plate within the unit automatically adjusted to select the proper orifice size and opening for the air flow and permeability range of the sample. The reading was saved once the air flow reached a constant level. Five (5) different samples were tested and each test was recorded on the print out.

    Wound Caliper

    [0151] The wound caliper in microns is the calculated caliper of the paper towel in the rolled form before being removed from the roll. Wound caliper can be calculated in accordance with formula (2) as follows:


    WOUND CALIPER=(((Π*ROLL DIAMETER/2*ROLL DIAMETER/2)−(Π*CORE DIAMETER/2*CORE DIAMETER/2))/(SHEET COUNT*SHEET LENGTH))*1000.  (2)

    [0152] (Roll Diameter, Core Diameter, Sheet Length in Mm).

    [0153] The following Examples and Comparative Examples illustrate advantages of the present invention. Process parameters, fabric properties and towel product properties described in the Examples are not intended to be limiting to the present invention. Various properties of the paper towel products described in the Examples and Comparative Example, as well as that of competitor products, are provided in Tables 1 and 2 (FIGS. 13 and 14).

    Example 1

    [0154] A laminated composite fabric with a web contacting layer made up of an extruded netting of thermoplastic polyurethane (TPU) 16×14 (16 machine direction elements per inch by 14 cross-direction elements per inch in the top web contacting layer) was provided. FIG. 5A shows a top planar view and FIG. 5B shows a cross-sectional view of the extruded netting 1. The extruded netting had the following characteristics and geometries: machine direction (MD) elements having a width W3 of 0.52 mm and cross direction (CD) elements having a width W2 of 0.53 mm, with a mesh of 16 MD strands per inch and a count of 14 CD strands per inch, contact area of 30% (with the paper web) with solely MD elements in plane in static measurement and 48% contact area (with the paper web) under load (50 kN/m) as the structure compressed and the CD elements moved up into the same plane as the MD elements, due to use of the thermoplastic polyurethane (TPU) elastomeric material. The TPU material is a softer material and measured in the range of 65 to 75 Shore A Hardness while the woven supporting layer comprised of harder PET measured 95 to 105 Shore A Hardness using a portable Mitutoyo Hardmatic HH-300 series, ASTD Shore A Durometer test device calibrated per ASTM D 2240. The distance W1 between MD elements in the web contacting layer was 1.47 mm, and the distance L1 between the CD elements was 1.64 mm. The overall pocket depth T1 was 0.61 mm. The pocket depth E1 from the top surface of the netting to the CD mid-rib element was 0.40 mm. The TPU netting had a natural color, the permeability of the TPU laminated belt was 428 CFM with a caliper of 1.37 mm. The peel force required to remove the web contacting layer from the woven supporting layer was 2074 gf/in, and the embedment distance of the web contacting layer into the woven supporting layer was 0.23 mm. The supporting layer had a 0.27×0.22 mm cross-section rectangular MD yarn (or filament) at 56 yarns/inch, and a 0.35 mm thickness CD yarn at 41 yarns/inch. The weave pattern of the base layer was a 5-shed, 1 MD yarn over 4 CD yarns, then under 1 CD yarn, then repeated. The material of the base fabric yarns was 100% PET. The fabric was unsanded, with an air permeability of 675 CFM. The weft yarns received 0.40% carbon black content by weight in the CD, and 0.14% carbon black content by weight in the MD. A 20 percent by weight carbon black master batch was let down into neat polyethylene terephthalate to generate the desired concentration (from 0.4 to 0.14 weight percent) of carbon black in the yarn. The carbon black was evenly mixed by addition of the carbon black to the polymer pellets in a hopper prior to molten extrusion. The TPU netting was placed under 0.50 PLI (pounds per linear inch) of tension as it was being laminated to the supporting layer. The welding laser was purchased from Leister Technologes (1275 Hamilton Parkway Itasca, Ill. 60143). The welding laser was a NOVOLAS Basic AT with fiber-coupled (line-coupled) roll optics with nominal 300 W, 940 nm laser set to 40% power level (161 watts), at a welding head speed of 50 mm/sec and an optical line width of 34 mm with a 1 mm overlap between laser passes (line energy output 3200 J/m).

    [0155] The composite belt was used on a TAD machine with a three layer headbox. The towel web was multilayered with the three layers from top to bottom labeled as air, core, and dry. The air layer is the outer layer that is transferred to the TAD fabric from the inner forming fabric. The dry layer is the outer layer that is closest to the surface of the Yankee dryer and the core is the center layer of the towel web. Each of the three layers were prepared using 50% eucalyptus (Euc) fiber purchased from Cenibra (Avenida Afonso Pena, 1964 Andar 7 Belo Oriente, MB 30130005 Brazil, phone 55-31-3235-4041), refined in a conical refiner at 30 kwh/metric ton, and 50% Northern Bleached Softwood Kraft (NBSK) fiber purchased from the Grand Prairie mill owned by International Paper (6400 Poplar Ave, Memphis, Tenn. 38197, phone 901-419-9000), refined in a conical refiner at 100 kwh/metric ton. Kymene 5377 (a polyamide-epichlorohydrin resin) at 9.0 kg (dry basis)/metric ton and Luredur 555 (a glyoxylated polyacrylamide) at 4.0 kg (dry basis)/metric ton were added to the NBSK fiber stream after the refiner. After blending the NBSK and EUC fiber, Hercobond 2800 (an anionic polyacrylamide) at 5.0 kg (dry basis)/metric ton was added to the fiber stream. Additionally, 1.5 kg (dry basis)/metric ton of Hercobond 6950 (a polyvinyl amine) was added to each layer to aid in fiber retention prior to the fan pumps. These chemistries can all be purchased from Solenis (3 Beaver Valley Rd ste 500 Wilmington, Del. 19803 phone 506-233-0042).

    [0156] The furnish (mixture of fiber and chemicals) was diluted to a solids of approximately 0.5% consistency and fed to separate fan pumps which delivered the slurry to a triple layered headbox. The headbox pH was controlled to approximately 7.5 pH by addition of sodium bicarbonate to the stock prior to the fan pumps. The headbox delivered the furnish slurry to a gap former twin wire C-wrap with an outer wire (T-star Max 453, from Asten Johnson 4399 Corporate Rd, Charleston, S.C. 29405, phone #843-747-7800) and inner wire (T-star Max 451, from Asten Johnson). When the fabrics separated, the nascent web followed the inner wire and was dried to approximately 23% moisture using a series of vacuum boxes and steambox.

    [0157] The web was then transferred using vacuum to the laminated composite TAD fabric described previously with the inner wire running at 1005 m/min and TAD fabric running at approximately 1000 m/min. The vacuum at transfer was −50 kpa using a single slotted vacuum box followed by another vacuum box with 2 slots, the first at −33 kpa, and the second slot a −45 kpa, to help facilitate fiber penetration into the TAD fabric and provide caliper to the nascent web. The web was pre-dried using two through air dried drums, the first drum with a supply air temperature of 175 deg C., and the second drum with a supply air temperature of 140 deg C. The web was then transferred to a Yankee dryer at approximately 85% solids. The Yankee dryer had a chemical package to aid in sticking the web to the dryer and provide adhesion for creping at the crepe blade. The chemical package was the following: 65 total mg/m.sup.2 comprised of 52% Rezosol 8207 PVOH (from Solenis), 42% 3222 Adhesive (from Solenis), 4% Rezosol 5150 oil (from Solenis), and 2% monoammonium phosphate. The web was dried to approximately 97.5% solids using the Yankee dryer and installed hot air impingement hoods prior to being creped at a speed differential of 10% using a 65 deg steel blade with a blade holder angle of 25 deg. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 152 sheets, a sheet length (perforation to perforation) of 152.4 mm, a sheet width (cut to cut) of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 1 in Tables 1 and 2.

    Example 2

    [0158] A 2 ply TAD rolled towel was produced in the same manner as Example 1 but the roll was made with a sheet count of 104 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 2 in Tables 1 and 2.

    Example 3

    [0159] The composite belt of Example 1 was used on a TAD machine with a three layer headbox. The towel web was multilayered with the three layers from top to bottom labeled as air, core, and dry. The air layer is the outer layer that is transferred to the TAD fabric from the inner forming fabric. The dry layer is the outer layer that is closest to the surface of the Yankee dryer and the core is the center layer of the towel web. Each of the three layers were prepared using 30% eucalyptus (Euc) fiber purchased from Cenibra, unrefined, 40% Northern Bleached Softwood Kraft (NBSK) fiber from the Grand Prairie mill owned by International Paper and 30% Metsa NBSK from Metsa Fibre (Maanpääntie 9. P.O. BOX 165 FI-26101 RAUMA FINLAND, phone #+358 (0)10 466 8999). The two NBSK fibers were co-refined in a conical refiner at 80 kwh/metric ton. Kymene 5377 (a polyamide-epichlorohydrin resin) at 9.0 kg (dry basis)/metric ton was added to the NBSK fiber stream after the refiner. After blending the NBSK and EUC fiber, Hercobond 2800 (a anionic polyacrylamide) at 5.0 kg (dry basis)/metric ton was added to the fiber stream. Additionally, 1.5 kg (dry basis)/metric ton of Hercobond 6950 (a polyvinyl amine) was added to each layer to aid in fiber retention prior to the fan pumps. These chemistries can all be purchased from Solenis (3 Beaver Valley Rd ste 500 Wilmington, Del. 19803 phone 506-233-0042).

    [0160] The furnish (mixture of fiber and chemicals) was diluted to a solids of approximately 0.5% consistency and fed to separate fan pumps which delivered the slurry to a triple layered headbox. The headbox pH was controlled to approximately 7.5 pH by addition of sodium bicarbonate to the stock prior to the fan pumps. The headbox delivered the furnish slurry to a gap former twin wire C-wrap with an outer wire (T-star Max 453, from Asten Johnson 4399 Corporate Rd, Charleston, S.C. 29405, phone #843-747-7800) and inner wire (T-star max 451, from Asten Johnson). When the fabrics separated, the nascent web followed the inner wire and was dried to approximately 23% moisture using a series of vacuum boxes and steambox.

    [0161] The web was then transferred using vacuum to the laminated composite TAD fabric described in Example 1 with the inner wire running at 1005 m/min and TAD fabric running at approximately 1000 m/min. The vacuum at transfer was −50 kpa using a single slotted vacuum box followed by another vacuum box with 2 slots, the first at −35 kpa, and the second slot a −52 kpa, to help facilitate fiber penetration into the TAD fabric and provide caliper to the nascent web. The web was pre-dried using two through air dried drums, the first drum with a supply air temperature of 150 deg C., and the second drum with a supply air temperature of 120 deg C. The web was then transferred to a Yankee dryer at approximately 85% solids. The Yankee dryer has a chemical package to aid in sticking the sheet to the dryer and provide adhesion for creping at the crepe blade. The chemical package was the following: 65 total mg/m.sup.2 comprised of 52% Rezosol 8207 PVOH (from Solenis), 42% 3222 Adhesive (from Solenis), 4% Rezosol 5150 oil (from Solenis), and 2% monoammonium phosphate. The web was dried to approximately 97.5% solids using the Yankee dryer and installed hot air impingement hood prior to being creped at a speed differential of 11% using a 65 deg steel blade with a blade holder angle of 25 deg. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 145 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 3 in Tables 1 and 2.

    Example 4

    [0162] A 2 ply TAD rolled towel was produced in the same manner as Example 3 but the roll was made with a sheet count of 99 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 4 in Tables 1 and 2.

    Example 5

    [0163] A 2 ply TAD rolled towel was produced in the same manner as Example 3 but the roll was made with a sheet count of 125 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 4 in Tables 1 and 2.

    Example 6

    [0164] A laminated composite fabric with a web contacting layer made up of an extruded netting of thermoplastic polyurethane (TPU) 16×6 (16 machine direction elements per inch by 6 cross-direction elements per inch in the top web contacting layer) was provided. The extruded netting had the following characteristics and geometries: machine direction (MD) elements having a width W3 of 0.48 mm and cross direction (CD) elements having a width W2 of 0.86 mm, with a mesh of 16 MD strands per inch and a count of 6 CD strands per inch, contact area of 28% (with the paper web) with solely MD elements in plane in static measurement and 44% contact area (with the paper web) under load (50 kN/m) as the structure compressed and the CD elements moved up into the same plane as the MD elements, due to use of the thermoplastic polyurethane (TPU) elastomeric material. The TPU material is a softer material and measured in the range of 65 to 75 Shore A Hardness while the woven supporting layer comprised of harder PET measured 95 to 105 Shore A Hardness using a portable Mitutoyo Hardmatic HH-300 series, ASTD Shore A Durometer test device calibrated per ASTM D 2240. The distance W1 between MD elements in the web contacting layer was 1.53 mm, and the distance L1 between the CD elements was 4.69 mm. The overall average pocket depth T1 was 0.76 mm with a min of 0.45 mm and a max of 0.95 mm. The pocket depth E1 from the top surface of the netting to the CD mid-rib element was 0.40 mm. The TPU netting had a natural color, the permeability of the TPU laminated belt was 500 CFM with a caliper of 1.27 mm. The peel force required to remove the web contacting layer from the woven supporting layer was 2359 gf/in, and the embedment distance of the web contacting layer into the woven supporting layer was 0.23 mm. The supporting layer had a 0.27×0.22 mm cross-section rectangular MD yarn (or filament) at 56 yarns/inch, and a 0.35 mm thickness CD yarn at 41 yarns/inch. The weave pattern of the base layer was a 5-shed, 1 MD yarn over 4 CD yarns, then under 1 CD yarn, then repeated. The material of the base fabric yarns was 100% PET. The fabric was unsanded, with an air permeability of 675 CFM. The weft yarns received 0.40% carbon black content by weight in the CD, and 0.14% carbon black content by weight in the MD. A 20 percent by weight carbon black master batch was let down into neat polyethylene terephthalate to generate the desired concentration (from 0.4 to 0.14 weight percent) of carbon black in the yarn. The carbon black was evenly mixed by addition of the carbon black to the polymer pellets in a hopper prior to molten extrusion. The TPU netting was placed under 0.50 PLI (pounds per linear inch) of tension as it was being laminated to the supporting layer. The welding laser was purchased from Leister Technologes (1275 Hamilton Parkway Itasca, Ill. 60143). The welding laser was a NOVOLAS Basic AT with fiber-coupled (line-coupled) roll optics with nominal 300 W, 940 nm laser set to 40% power level (161 watts), at a welding head speed of 50 mm/sec and an optical line width of 34 mm with a 1 mm overlap between laser passes (line energy output 3200 J/m).

    [0165] The composite belt was used on a TAD machine with a three layer headbox. The towel web was multilayered with the three layers from top to bottom labeled as air, core, and dry. The air layer is the outer layer that is transferred to the TAD fabric from the inner forming fabric. The dry layer is the outer layer that is closest to the surface of the Yankee dryer and the core is the center layer of the towel web. Each of the three layers were prepared using 30% eucalyptus (Euc) fiber purchased from Cenibra, unrefined, 40% Northern Bleached Softwood Kraft (NBSK) fiber from the Grand Prairie mill owned by International Paper and 30% Metsa NBSK from Metsa Fibre (Maanpääntie 9. P.O. BOX 165 FI-26101 RAUMA FINLAND, phone #+358 (0)10 466 8999). The two NBSK fibers were co-refined in a conical refiner at 100 kwh/metric ton. Kymene 5377 (a polyamide-epichlorohydrin resin) at 9.0 kg (dry basis)/metric ton was added to the NBSK fiber stream after the refiner. After blending the NBSK and EUC fiber, Hercobond 2800 (a anionic polyacrylamide) at 5.0 kg (dry basis)/metric ton was added to the fiber stream. Additionally, 1.5 kg (dry basis)/metric ton of Hercobond 6950 (a polyvinyl amine) was added to each layer to aid in fiber retention. These chemistries can all be purchased from Solenis (3 Beaver Valley Rd ste 500 Wilmington, Del. 19803 phone 506-233-0042).

    [0166] The furnish (mixture of fiber and chemicals) was diluted to a solids of approximately 0.5% consistency and fed to separate fan pumps which delivered the slurry to a triple layered headbox. The headbox pH was controlled to approximately 7.5 pH by addition of sodium bicarbonate to the stock prior to the fan pumps. The headbox delivered the furnish slurry to a gap former twin wire C-wrap with an outer wire (T-star Max 453, from Asten Johnson 4399 Corporate Rd, Charleston, S.C. 29405, phone #843-747-7800) and inner wire (Albany Q592, from Albany International 216 Airport Drive Rochester, N.H. 03867 USA Phone Number: 603-330-5850). When the fabrics separated, the nascent web followed the inner wire and was dried to approximately 23% moisture using a series of vacuum boxes and steambox.

    [0167] The web was then transferred using vacuum to the laminated composite TAD fabric described previously in this Example with the inner wire running at 1005 m/min and TAD fabric running at approximately 1000 m/min. The vacuum at transfer was −30 kpa using a single slotted vacuum box followed by another vacuum box with the one slot at −20 kpa to help facilitate fiber penetration into the TAD fabric and provide caliper to the nascent web. The web was pre-dried using two through air dried drums, the first drum with a supply air temperature of 190 deg C., and the second drum with a supply air temperature of 140 deg C. The web was then transferred to a Yankee dryer at approximately 85% solids. The Yankee dryer had a chemical package to aid in sticking the sheet to the dryer and provide adhesion for creping at the crepe blade. The chemical package was the following: 65 total mg/m.sup.2 comprised of 52% Rezosol 8207 PVOH (from Solenis), 42% 3222 Adhesive (from Solenis), 4% Rezosol 5150 oil (from Solenis), and 2% monoammonium phosphate. The web was dried to approximately 97.5% solids using the Yankee dryer and installed hot air impingement hood prior to being creped at a speed differential of 11% using a 65 deg steel blade with a blade holder angle of 25 deg. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 133 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 6 in Tables 1 and 2.

    Example 7

    [0168] Example 7 was made under the same conditions as Example 6 with the following exceptions: vacuum at transfer to the TAD fabric was conducted using −47 kpa of vacuum; the NBSK was refined at 120 kwh/ton, and the second TAD drum temperature was increased to 150 deg C. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 136 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 7 in Tables 1 and 2.

    Example 8

    [0169] Example 8 was made under the same conditions as Example 7. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 93 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 8 in Tables 1 and 2.

    Example 9

    [0170] Example 9 was made under the same conditions as Example 7. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 118 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Example 8 in Tables 1 and 2.

    Example 10

    [0171] Example 10 was performed in order to display the surface topography differences that drive Vvd and Sdr values. In order to obtain a higher Vvd (14.312 micron) to Sdr (37.886%) ratio, the general surface topography of the paper towel sheet was smoothed throughout the larger peaks and valleys while still utilizing a similar general surface profile as created in Examples 1 through 9. The smoothing of the surface topography was done digitally. As shown in FIG. 11, the surface displays a high Vvd due to the large peaks and valleys, but a lower Sdr due to the lack of smaller changes in height throughout the overall topography.

    Example 11

    [0172] Example 11 was also performed in order to display the surface topography differences that drive Vvd and Sdr values. In order to obtain a lower Vvd (5.418 micron) to Sdr (58.174%) ratio, the general surface topography was roughened throughout the larger peaks and valleys while still utilizing a similar general surface profile as created in Examples 1 through 9. The roughening of the surface topography was done digitally. As shown in FIG. 12, the surface displays a lower Vvd due to the reduction in large peaks and valleys, but a higher Sdr due to the increase in smaller changes in height throughout the overall topography.

    Comparative Example

    [0173] A TAD fabric was provided made up of an 8-shed woven fabric, comprised of polyester (PET) with a 40 mesh×28 count. The machine direction (MD) strands had a yarn width of 0.39 mm and cross direction (CD) strands had a yarn width of 0.62 mm, with a contact area of 18%, air permeability of 600 cfm, and caliper of 1.14 mm. The average pocket depth was 0.60 mm. The fabric was used on a TAD machine with a three layer headbox. The towel web was multilayered with the three layers from top to bottom labeled as air, core, and dry. The air layer is the outer layer that is transferred to the TAD fabric from the inner forming fabric. The dry layer is the outer layer that is closest to the surface of the Yankee dryer and the core is the center layer of the towel web. Each of the three layers were prepared using 50% eucalyptus (Euc) fiber purchased from Cenibra, refined in a conical refiner at 10 kwh/metric ton, and 50% Northern Bleached Softwood Kraft (NBSK) fiber from the Grand Prairie mill owned by International Paper refined in a conical refiner at 70 kwh/metric ton. Kymene 5377 (a polyamide-epichlorohydrin resin) at 9.0 kg (dry basis)/metric ton was added to the NBSK fiber stream after the refiner. After blending the NBSK and EUC fiber, Hercobond 2800 (an anionic polyacrylamide) at 5.0 kg (dry basis)/metric ton was added to the fiber stream. Additionally, 1.5 kg (dry basis)/metric ton of Hercobond 6950 (a polyvinyl amine) was added to each layer to aid in fiber retention prior to the fan pumps. These chemistries can all be purchased from Solenis (3 Beaver Valley Rd ste 500 Wilmington, Del. 19803 phone 506-233-0042).

    [0174] The furnish (mixture of fiber and chemicals) was diluted to a solids of approximately 0.5% consistency and fed to separate fan pumps which delivered the slurry to a triple layered headbox. The headbox pH was controlled to approximately 7.5 pH by addition of sodium bicarbonate to the stock prior to the fan pumps. The headbox delivered the furnish slurry to a gap former twin wire C-wrap with an outer wire (T-star Max 453, from Asten Johnson 4399 Corporate Rd, Charleston, S.C. 29405, phone #843-747-7800) and inner wire (Albany Q592, from Albany International 216 Airport Drive Rochester, N.H. 03867 USA Phone Number: 603-330-5850). When the fabrics separated, the nascent web followed the inner wire and was dried to approximately 23% moisture using a series of vacuum boxes and steambox.

    [0175] The web was then transferred using vacuum to the TAD fabric described in this Example with the inner wire running at 1065 m/min and TAD fabric running at approximately 1000 m/min. The vacuum at transfer was −37 kpa using a single slotted vacuum box followed by another vacuum box with two slots at −37 kpa and −50 kpa to help facilitate fiber penetration into the TAD fabric and provide caliper to the nascent web. The web was pre-dried using two through air dried drums, the first drum with a supply air temperature of 150 deg C., and the second drum with a supply air temperature of 110 deg C. The web was then transferred to a Yankee dryer at approximately 85% solids. The Yankee dryer had a chemical package to aid in sticking the sheet to the dryer and provide adhesion for creping at the crepe blade. The chemical package was the following: 65 total mg/m.sup.2 comprised of 52% Rezosol 8207 PVOH (from Solenis), 42% 3222 Adhesive (from Solenis), 4% Rezosol 5150 oil (from Solenis), and 2% monoammonium phosphate. The web was dried to approximately 97.5% solids using the Yankee dryer and installed hot air impingement hood prior to being creped at a speed differential of 3% using a 65 deg steel blade with a blade holder angle of 25 deg. The web was wound into rolls and then converted into 2-ply finished product towel rolls using the DEKO emboss method with a steel emboss roll patterned as shown in FIG. 10, with a sheet count of 116 sheets, a sheet length of 152.4 mm, a sheet width of 279.4 mm, and a roll diameter of 148 mm. The properties of this two ply TAD rolled towel product is shown as Comparative Example in Tables 1 and 2.

    [0176] Now that embodiments of the present invention have been shown and described in detail, various modifications and improvements thereon can become readily apparent to those skilled in the art. Accordingly, the exemplary embodiments of the present invention, as set forth above, are intended to be illustrative, not limiting. The spirit and scope of the present invention is to be construed broadly.