US20170027392A1

US20170027392A1 - Flushable hydroentangled moist wipe or hygiene tissue

Info

Publication number: US20170027392A1
Application number: US15/302,230
Authority: US
Inventors: Anders Strålin; Hannu Ahoniemi; Lars Fingal; Anna Nihlstrand
Original assignee: SCA Hygiene Products AB
Current assignee: Essity Hygiene and Health AB
Priority date: 2014-04-08
Filing date: 2014-04-08
Publication date: 2017-02-02
Also published as: MX363090B; EP3129552A4; ES2731223T3; WO2015156713A1; RU2656307C2; AU2014390093A1; MX2016013059A; CN106164373B; CN106164373A; EP3129552A1; RU2016143537A; RU2016143537A3; AU2014390093B2; EP3129552B1

Abstract

A flushable wipe or hygiene tissue includes a hydraulically entangled nonwoven material impregnated with a wetting composition, wherein the nonwoven material includes cellulose pulp fibers and/or manmade staple fibers. The nonwoven material includes disintegration elements having a projected surface area between 2 and 50 mm²and an aspect ratio (L/D) between 1 and 10. The disintegration elements may be selected from the following group: botanical elements, paper containing a wet-strength agent, nonwoven material, and film material, and will result in a material that is more readily disintegratable when flushed in a sewer.

Description

CROSS-REFERENCE TO PRIOR APPLICATION

This application is a §371 National Stage application of PCT International Application No. PCT/SE2014/050433 filed Apr. 8, 2014, which is incorporated herein in its entirety.

TECHNICAL FIELD

The present disclosure refers to a flushable hydroentangled wipe or hygiene tissue impregnated with a wetting composition, wherein the nonwoven material includes cellulose pulp fibers and/or manmade staple fibers.

BACKGROUND

Pre-moistened wipes or hygiene tissue, are commonly used for cleansing different parts of the human body. Examples of specific uses are baby care, hand wiping, feminine care and toilet paper or a complement to toilet paper.
Since a long period of time often elapses from the time of manufacture of pre-moistened wipes until the time of use, they must have a sufficient structural integrity for their intended wiping function during such period. Adding a wet strength agent to the wipe will provide such wet integrity. However, especially when used as toilet paper, there is a strong desire that the wipe or tissue can be flushed in the sewer without causing problems with blocked pipes and filters. Wipes or tissue having a high wet strength will not disintegrate or break up into small fibre clumps when flushed in conventional household toilet systems, which may cause plugging of the drainage system.
Previously moist flushable pre-moistened wipes and toilet papers which were on the market were flushable due to their small size. They could move along the drainage and sewage pipes, but were not readily dispersible and could therefore cause problems with blocked pipes and filters. Nowadays disintegratable materials are available for use in flushable wipes and hygiene tissue.
U.S. Pat. No. 4,755,421 discloses a hydroentangled disintegratable nonwoven fabric used as a flushable wet wipe. The fabric comprises a mixture of pulp fibers and staple length regenerated cellulose fibers. No binder is added.
US 2004/0013859 discloses a hydroentangled nonwoven web used as a wet wipe that is disintegrated with mild agitation in water. The nonwoven web comprises natural cellulose fibers and high crystallinity cellulose fibers, preferably lyocell fibers. A binder is also added, for example in the form of binder fibers. The nonwoven web is said to have high wet tensile strength but disintegrates or disperses with mild agitation in water, making it flushable in a sewer.
WO 2013/015735 discloses a hydroentangled moist wipe that is flushable. The wipe material comprises pulp fibers and poly(lactic acid) fibers having a length between 8 and 20 mm. The wipe is free from added binders and wet-strength agents.
JP 2008073357 discloses a hydroentangled wipe material that has water dissolving properties. The wipe material comprises hydrophilic fibers and fibers having a modified cross-section.
JP 2012057289 discloses a flat hollow rayon fiber with creases formed in the outer surface. These flat rayon fibers may be used in different kinds of products, wherein water-dispersible sheets are mentioned as one example.
There is however still a need for a moist wipe or hygiene tissue which has sufficient structural integrity for its intended wiping function but which is readily disintegratable when flushed in a sewer.

SUMMARY

It is desired to provide a moist wipe or hygiene tissue having sufficient wet strength for its intended use but which is disintegrated when flushed in a sewer. One such moist wipe or hygiene tissue includes a hydraulically entangled nonwoven material impregnated with a wetting composition, said nonwoven material containing cellulose pulp fibers and/or manmade staple fibers, wherein the nonwoven material also includes disintegration elements having a projected surface area between 2 and 50 mm²and an aspect ratio between 1 and 10.
These disintegrating elements will create spots in the nonwoven material, that weaken the material resulting in a material that disintegrates or disperses in water under mild agitation, such as present in a standard sewer.
The flushable wipe or hygiene tissue may include between 0.5 and 2.5 weight % of said disintegration elements as calculated on the dry weight of the wipe or hygiene tissue.
Said disintegration elements may be of a material having a disintegration time as measured by French Standard NF Q 34-020 that differs from the nonwoven material.
Said disintegration elements may be of a material having a slower disintegration time as measured by French Standard NF Q 34-020 than the nonwoven material.
The disintegration elements may be of a material selected from the following group: botanical elements, paper containing a wet-strength agent, nonwoven material, film material.
The disintegration elements may have an aspect ratio between 1 and 7.
The thickness of the disintegration elements may be between 50 μm and the thickness of the nonwoven material, for example below 1 mm.
The disintegration elements may be embedded by fibers in the nonwoven material.
The disintegration elements may have a different colour or tint than the rest of the nonwoven material.
The disintegrating elements may have a decorative and/or informative shape, such as symbols, characters, logotypes and the like.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a schematic sketch of a hydroentangled material including disintegration elements according to an embodiment of the invention.

FIG. 2 a-h are schematic sketches of disintegration elements having different shapes and illustrate how the aspect ratio is measured.

DETAILED DESCRIPTION OF PARTICULAR EMBODIMENTS

A premoistened wipe or hygiene tissue according to embodiments of the invention includes a hydroentangled nonwoven material impregnated with a wetting composition. The wetting composition may contain a major proportion of water and other ingredients depending on the intended use. Wetting compositions useful in moist wipes and hygiene tissue are well-known in the art.
Hydroentangling or spunlacing is a technique for forming a nonwoven web introduced during the 1970'ies, see e g CA patent no. 841 938. The method involves forming a fibre web, which is either drylaid or wetlaid, after which the fibres are entangled by means of very fine water jets under high pressure. Several rows of water jets are directed against the fibre web, which is supported by a movable foraminous support or a perforated drum. In this process, the fibres entangle with one another providing sufficient bonding strength to the fibrous web without the use of chemical bonding agents. The entangled fibrous web is then dried. The fibres that are used in the material can be natural fibres, especially cellulosic pulp fibres, manmade staple fibres, and mixtures of pulp fibres and staple fibres. Hydroentangled materials can be produced with high quality at a reasonable cost and they possess a high absorption capacity.
The wipe or hygiene tissue according to embodiments of the invention may include a mixture of cellulosic pulp fibers and manmade fibers, and, in particular embodiments, biodegradable manmade fibers such as regenerated cellulose fibres, e.g. viscose, rayon and lyocell, and/or poly(lactic acid) fibers. The length of these manmade fibres may be in the range of 4 to 20 mm. Other natural fibres than pulp fibres may also be included in the fibrous web, such as cotton fibres, sisal, hemp, ramie, flax etc. These natural fibres usually have a length of more than 4 mm.
Cellulose pulp fibres can be selected from any type of pulp and blends thereof. In particular embodiments, the pulp is characterized by being entirely natural cellulosic fibres and can include wood fibres as well as cotton. Preferred pulp fibres are softwood papermaking pulp, although hardwood pulp and non-wood pulp, such as hemp and sisal may be used. The length of pulp fibres may vary from less than 1 mm for hardwood pulp and recycled pulp, to up to 6 mm for certain types of softwood pulp. Pulp fibres are advantageous to use since they are inexpensive, readily available and absorbent.
A suitable amount of cellulose pulp fibers in the nonwoven material forming the moist wipe or hygiene tissue may be between 0 and 95% by weight cellulose pulp fibers, between 50 and 95% by weight cellulose pulp fibers, or between 70 and 95% by weight cellulose pulp fibers. A suitable amount of manmade fibers in the nonwoven material forming the moist wipe or hygiene tissue may be between 5 and 100% by weight manmade fibers, between 5 and 50% by weight manmade fibers, or between 5 and 30% by weight manmade fibers. The wipe or hygiene tissue may have a basis weight in the range 30 to 100 gsm, or 40 to 80 gsm, based on the dry weight of the material.
The fibers forming the nonwoven material may be wetlaid, wherein a slurry including the fibres is wetlaid on a moving forming fabric by a headbox as in a conventional papermaking equipment. A special variant of wetlaying or wetforming is foamforming, wherein the fibres are dispersed in a foamed liquid containing water and a surfactant. Alternatively the fibers may be drylaid on a moving forming fabric to form a drylaid fibrous web which is subsequently hydroentangled.
In addition to the fibers the nonwoven material 1 includes disintegration elements 2 in the form of flakes having a projected surface area between 2 mm²and 50 mm²and an aspect ratio L/D between 1 and 10, or between 1 and 7. The projected surface area may be measured by image analysis.
The aspect ratio is defined as the ratio of the length L to the width D of the disintegration element 2. The length L is defined as the longest straight line that can be drawn/found in the element. The width D is defined as the longest straight line that can be found/drawn in said element perpendicular to the line L. No parts of the lines L and D should cross the edge of the element, i.e. the full length of the lines L and D must be inside the element. In cases where two or more lines with the same length can be found (L1=L2= . . . Lx), the length L which generates the longest line D, i.e. resulting in the lowest L/D ratio, should be used.
FIG. 2 a-h illustrate how the aspect ratio L/D is measured for disintegration elements having varying shapes.
The disintegration elements 2 are mixed with the fibers, for example in the slurry used in wetlaying.
The disintegration elements 2 in the form of flakes having the above mentioned proportions are different from fibers and will not easily entangle with the fibers during hydroentangling. They will rather form spots in the nonwoven material that will weaken the material, for example in the cross direction, CD, thus making it more readily disintegratable when flushed in a sewer.
The disintegration elements 2 may be contained in the nonwoven material 1 in an amount between 0.5% by weight and 2.5% by weight as calculated on the dry weight of the nonwoven material, i.e. excluding the wetting composition. The disintegration elements 2 can be distributed throughout the area of the nonwoven material 1.
The disintegrating elements 2 may be of a material selected from: botanical elements, wet-strong paper, i.e. paper containing a wet-strength agent, nonwoven material, film material. In particular embodiments, the disintegrating elements 2 are of a biodegradable material. They should further be of a material that has a disintegration time as measured by French Standard NF Q 34-020 that differs from the nonwoven material as such, for example a slower disintegration time, such as at least 10% longer disintegration time than the nonwoven material. This will ensure that they will maintain their effect of weakening the nonwoven material until this has been disintegrated. The thickness of the disintegration elements should be at least 50 μm and not more than the thickness of the nonwoven material, for example less than 1 mm.
Examples of botanical elements suited for use as disintegrating elements are petals, e g from marigold, lavender or similar flowers. Such botanical elements may have a colour or tint different from the nonwoven material as such. They may also have a fragrance and/or a skin care effect.
The disintegrating elements 2 may be formed of cut pieces of a sheet material, e g wet-strong paper, nonwoven or film material. These pieces may have a colour or tint different from the rest of the nonwoven material. They may also have a decorative and/or informative shape such as symbols, characters, logotypes and the like.

Description of Test Method

The test method for measuring disintegration time is French Standard NF Q 34-20 Aug. 1998. In addition to measuring the disintegration time, the weight of the remaining lump of fibers (if any) in the test vessel is also measured. The test was performed in the following manner:

- Put the dried sample in a climate room 23° C., 50% humidity for minimum 4 hours;
- Weigh the sample before start;
- Stop the timer when the sample is disintegrated into pieces smaller than 1 cm²and record the disintegration time;
- Alt. 1: Start stirring again and let stir until 10 minutes have passed (including the initial disintegration time);
- Alt. 2: Omit the additional step of stirring 10 minutes;
- Pick up the remaining lump with a pair of tweezers;
- Put the lump in a 900 ml beaker filled with water up to 300 ml, wait 5 sec.;
- Pick up the lump with tweezers and let excess water drip off, wait 5 sec.;
- Put the lump in a second 900 ml beaker filled with water up to 300 ml, wait 5 sec.;
- Pick up the lump with tweezers and let excess water drip off, wait 5 sec.;
- Put the lump on a tissue paper to drain excess water;
- Put the lump in a climate chamber for 2 h 80° C. to dry;
- Put the dried lump in a climate room 23° C., 50% humidity, for minimum 4 h;
- Weigh the lump;
- Calculate the remaining weight of the dried lump as a percentage of the initial dry sample weight (dry weight of remaining lump/dry weight of sample)×100(%).

Examples

Trials have been made on hydroentangled nonwoven materials containing disintegration elements in the form of marigold petals and a reference sample containing no disintegration elements. The samples had the following composition.
Reference: 80 wt % cellulose pulp+10 wt % lyocell fibers 12 mm+10 wt % PLA:poly(lactic acid) fibers 12 mm. The basis weight was 60 gsm and the material was hydroentangled with 3 manifolds/jet strips on each sides of the web with 60 bars with entanglement nozzles hole diameter 115 μm with a pitch of 0.8 mm between holes. The sample size and number of folds was adapted to Samples 1-4 referred to below.
Sample 1: 79 wt % cellulose pulp+10 wt % lyocell fibers 12 mm+10 wt % PLA:poly(lactic acid) fibers 12 mm+1 wt % marigold petals. The basis weight was 60 gsm and the material was hydroentangled with 3 manifolds/jet strips on each side of the web with 60 bars with entanglement nozzles. Sample size was 10×25 cm, folded twice in longitudinal direction.
Sample 2: 79 wt % cellulose pulp+10 wt % lyocell fibers 12 mm+10 wt % PLA:poly(lactic acid) fibers 12 mm+1 wt % marigold petals. The basis weight was 60 gsm and the material was hydroentangled with 3 manifolds/jet strips on each side of the web with 60 bars with entanglement nozzles. Sample size was 10×25 cm, folded once in longitudinal direction.
Sample 3: a) 79 wt % cellulose pulp+10 wt % lyocell fibers 12 mm+10 wt % PLA:poly(lactic acid) fibers 12 mm+1 wt % marigold petals; b) 77 wt % cellulose pulp+10 wt % lyocell fibers 12 mm+10 wt % PLA:poly(lactic acid) fibers 12 mm+3 wt % marigold petals. The basis weight was 60 gsm and the materials were hydroentangled with 3 manifolds/jet strips on each side of the web with 60 bars with entanglement nozzles. Sample size was 10×10 cm with no fold.
Sample 4: 77 wt % cellulose pulp+10 wt % lyocell fibers 12 mm+10 wt % PLA:poly(lactic acid) fibers 12 mm+3 wt % marigold petals. The basis weight was 60 gsm and the material was hydroentangled with 3 manifolds/jet strips on each side of the web with 60 bars with entanglement nozzles. Sample size was 10×25 cm folded once in longitudinal direction.
Wet strength in water in CD according to SS-EN ISO 12625-5:2005 was measured for the different samples as well as disintegration time and weight of remaining lump were measured. The following results were obtained.
Sample 1


CD wet tensile	Basis weight²	Disintegration	Lump
strength¹(N/m)	(g/m2)	time³(sec)	(wt-%)

Reference	24.5	62.0	163	Small, not
				measured
1%	24.4	63.4	139	Small, not
Marigold				measured
Difference	−0.2%		−14.7%
(Ref-1%):

¹Average of 10 samples
²Average of 15 samples
³Average of 8 samples

Sample 2


			Lump at
	Basis		10 min
CD wet tensile	weight²	Disintegration	(Alt. 1)
strength¹(N/m)	(g/m2)	time²(sec)	(wt-%)

Reference	24.5	61.4	156	9.8
1% Marigold	24.4	63.8	124	4.8
Difference (Ref-	−0.2%		−20.5%
1% Marigold):

¹Average of 10 samples
²Average of 9 samples

Sample 3


CD wet			Lump at
tensile	Basis		disintegration
strength¹	weight¹	Disintegration	time¹(Alt. 2)
(N/m)	(g/m2)	time¹(sec)	(wt-%)

Reference	—	64.1	107	9.5
1% Marigold	—	64.1	80	4.1
3% Marigold	—	64.2	119	19.9
Difference (Ref-			−24.8%
1% Marigold):
Difference (Ref-			+12.0%
3% Marigold):

¹Average of 5 samples

Sample 4


	Basis		Lump
CD wet tensile	weight	Disintegration	at 10 min
strength¹(N/m)	(g/m2)	time (sec)	(Alt. 1) (wt-%)

Reference	35.3	64.6²	151²	2.1²
3% Marigold	26.9	63.9³	146³	3.9³
Difference	−23.9%		−2.8%
(Ref-3%):

¹Average of 5 samples
²Average of 4 samples
³Average of 9 samples

It is interesting to note that a 1% admixture of marigold petals resulted in a significantly lower disintegration time as well as lump than for the reference, while the CD wet strength was maintained. A 3% admixture of marigold petals, however, resulted in an increased disintegration time and lump and a decrease in CD wet strength.

Claims

1. A flushable wipe or hygiene tissue comprising a hydraulically entangled nonwoven material impregnated with a wetting composition, said nonwoven material comprising cellulose pulp fibers and/or manmade staple fibers and disintegration elements having a projected surface area between 2 and 50 mm²and an aspect ratio (L/D) between 1 and 10.

2. The flushable wipe or hygiene tissue according to claim 1, wherein the amount of the disintegration elements in the flushable wipe or hygiene tissue is between 0.5 and 2.5 weight % as calculated on the dry weight of the wipe or hygiene tissue.

3. The flushable wipe or hygiene tissue according to claim 1, wherein said disintegration elements are of a material having a disintegration time as measured by French Standard NF Q 34-020 that differs from the nonwoven material.

4. The flushable wipe or hygiene tissue according to claim 3, wherein said disintegration elements are of a material having a slower disintegration time as measured by French Standard NT Q 34-020 than the nonwoven material.

5. The flushable wipe or hygiene tissue according to claim 1, wherein said disintegration elements are of a material selected from the group consisting of: botanical elements, paper containing a wet-strength agent, nonwoven material, and film material

6. The flushable wipe or hygiene tissue according to claim 1, wherein said aspect ratio of said disintegration elements is between 1 and 7.

7. The flushable wipe or hygiene tissue according to claim 1, said disintegration elements have a thickness between 50 μm and the thickness of the nonwoven material.

8. The flushable wipe or hygiene tissue according to claim 1, wherein said disintegration elements are embedded by fibers in the nonwoven material.

9. The flushable wipe or hygiene tissue according to claim 1, wherein said disintegration elements have a different colour or tint than the rest of the nonwoven material.

10. The flushable wipe or hygiene tissue according to claim 1, wherein said disintegrating elements have a decorative and/or informative shape.