阅读说明：本技术 羊毛处理方法以及产品 (Wool treatment process and product ) 是由 亚历山德拉·霍奇森 保罗·米德伍德 穆罕默德·阿扎姆·阿里 德勒利·波卓兹-史密斯 于 2015-06-01 设计创作，主要内容包括：本发明涉及羊毛处理方法和通过所述羊毛处理方法生产的羊毛产品。具体地,本发明涉及生产具有增强的吸收性能的羊毛产品的羊毛处理方法和具有增强的吸收性能的羊毛产品。(The present invention relates to a wool treatment process and a wool product produced by the wool treatment process. In particular, the present invention relates to a wool treatment process for producing wool products having enhanced absorbency properties and to wool products having enhanced absorbency properties.)

1. A method of treating a wool substrate comprising:

a first reaction step of treating the wool substrate with an alcohol and base reaction mixture for a reaction time of 5 to 60 minutes; and a second reaction step of treating the resulting wool substrate obtained from the first reaction step with an aqueous mixture of an oxidizing agent, wherein the method enhances the absorption properties of the wool substrate compared to an untreated wool substrate,

wherein the method enhances the hand dryness of the wool substrate compared to an untreated wool substrate,

wherein the first reaction step and the second reaction step do not substantially damage the wool substrate.

2. The method of claim 1, wherein the fleece substrate used in the first reaction step is a chemically untreated nonwoven fleece substrate.

3. A method according to claim 1 wherein the fleece substrate used in the first reaction step is a chemically untreated knop impregnated nonwoven substrate.

4. The method of claim 1, wherein the wool substrate used in the first reaction step is selected from (i) a needled wool nonwoven substrate comprising carded wool fibers or (ii) a hydroentangled wool nonwoven substrate comprising carded wool fibers.

5. The method of claim 1, wherein the wool substrate used in the first reaction step comprises loose wool fibers.

6. A method according to any one of claims 1 to 4 wherein the fleece substrate has a density of from 100 grams per square metre to 1000 grams per square metre.

7. The method of any one of claims 1 to 4, wherein the wool substrate has a density of from 200 grams per square meter to 600 grams per square meter.

8. The method of claim 1, wherein the alcohol is selected from methanol, ethanol, propanol, butanol, or mixtures thereof.

9. The process of claim 1, wherein the base is selected from potassium hydroxide or sodium hydroxide or mixtures thereof.

10. The method of claim 9, wherein the base has a concentration of 0.5% w/v to 5% w/v in the alcohol and base reaction mixture.

11. The process of claim 9 or 10, wherein the base has a concentration of 1% w/v-2% w/v in the alcohol and base reaction mixture.

12. The process of any one of claims 9 to 11, wherein the base has a concentration of 1.5% w/v in the alcohol and base reaction mixture.

13. The method of claim 1, wherein the oxidizing agent is hydrogen peroxide.

14. The method of claim 13, wherein the oxidizing agent has a concentration of 0.5% v/v-5% v/v.

15. The method of claim 13 or 14, wherein the oxidizing agent has a concentration of 1% v/v-2% v/v.

16. The method of any one of claims 13 to 15, wherein the oxidizing agent has a concentration of 2.0% v/v.

17. The method of claim 1, wherein the reaction time of the first reaction step is 5-30 minutes.

18. The method of claim 17, wherein the reaction time of the first reaction step is 10-30 minutes.

19. The method of claim 17 or 18, wherein the reaction time of the first reaction step is 10 minutes.

20. The method of claim 17 or 18, wherein the reaction time of the first reaction step is 12-14 minutes.

21. The method of claim 1, wherein the reaction time of the second reaction step is 30-180 minutes.

22. The method of claim 21, wherein the reaction time of the second reaction step is 30-120 minutes.

23. The method of claim 21 or 22, wherein the reaction time of the second reaction step is 30-90 minutes.

24. The method of claim 23, wherein the reaction time of the second reaction step is 60 minutes.

25. The method of any one of the preceding claims, which is carried out at a fiber to liquid ratio of 1:10 to 1: 40.

26. A wool product obtained by the method of any one of claims 1 to 25, wherein the wool product has at least 800% higher absorbency than an untreated wool substrate.

27. The wool product of claim 26, wherein the wool product has at least 1000% greater absorbency than an untreated wool substrate.

28. A wool product according to claim 26 or claim 27 wherein the wool product has an absorbency of at least 1200% greater than that of an untreated wool substrate.

29. A wool product according to claim 26 or claim 27 wherein the wool product has an absorbency of at least 1500% greater than that of an untreated wool substrate.

30. A wool product according to claim 26 or claim 27 wherein the wool product has an absorbency performance of at least 2400% higher than that of an untreated wool substrate.

31. A wool product according to any one of claims 26 to 30, wherein the wool product is further for use in one or more products requiring a material having absorbent properties.

32. A wool product according to claim 31 wherein the one or more products requiring material having absorbent properties comprise: athletic garments, such as garments used for sports, outdoor activities, everyday activities, and the like; personal hygiene products such as diapers, pads, diapers, and the like; wound or surgical dressings, and the like; chemical spills or cleaning products, etc.

33. The wool product of claim 31, which is one or more of an anti-odor, anti-microbial, moisture wicking, breathable, chemical free, non-synthetic, non-petroleum, rash reduction, flame retardant, temperature controlled, hypoallergenic, warm keeping, comfort, biodegradable, and compostable wool product.

Technical Field

The present invention relates to a wool treatment process and to wool products produced by the wool treatment process. In particular, the present invention relates to a wool treatment process for producing wool products having enhanced absorption properties and to wool products having enhanced absorption properties.

Background

One area of concern for today's environmentally and health conscious consumers is the large volume of non-biodegradable waste generated by disposable products such as diapers, urinary pads and incontinence pads. Disposable diapers contain chemical compounds such as superabsorbent polymers, polypropylene, adhesives, elastics, and pulp. Large quantities of these products are eventually landfilled and take a considerable period of time to degrade, resulting in long-term environmental hazards.

Many consumers are seeking alternatives to the type of products currently available. Consumers are particularly looking for odorless, chemical-free, biodegradable, and environmentally friendly products that are reasonably priced and still provide the absorbency needed for such products.

There is also a need for absorbent products in other situations, for example in domestic, commercial and industrial cleaning and when handling fluid spills, as well as for personal hygiene and health care products such as diapers, use as nursing pads and wound and surgical dressings. Furthermore, there is a need for absorbent garments for use in sports, outdoor activities and general everyday fashion items.

Wool is a natural product with many properties that make it the product or product ingredient of choice for today's environmentally and health conscious consumers. Important characteristics of wool are that it is renewable, biodegradable, non-allergenic, breathable, natural insulators, durable, elastic and washable. However, wool is hydrophobic as an untreated natural product, with very limited absorbency.

There is therefore a need to provide absorbent materials that are reasonably priced, originate from naturally occurring and renewable sources and are acceptable to an increasing number of environmentally and health conscious consumers. There is a further need to provide at least a useful alternative to currently available absorbent materials.

Summary of The Invention

In a first aspect, the present invention provides a method of treating a wool substrate comprising:

a first reaction step of treating the wool substrate with an alcohol and base reaction mixture for a reaction time of about 5 minutes to 60 minutes; and a second reaction step of treating the resulting wool substrate obtained from the first reaction step with an aqueous oxidizing agent mixture.

In one embodiment, the fleece substrate used in the first reaction step is a chemically untreated nonwoven fleece substrate.

In another embodiment, the fleece substrate used in the first reaction step is a chemically untreated knop-impregnated nonwoven substrate.

In another embodiment, the fleece substrate used in the first reaction step is selected from (i) needled or (ii) hydroentangled (hydroentangled) fleece nonwovens comprising layered spunbond or carded wool fibers.

In another embodiment, the fleece substrate has a density of about 100 grams per square meter to 1000 grams per square meter. In one embodiment, the fleece substrate has a density of about 200 grams per square meter to 600 grams per square meter.

In another embodiment, the wool substrate used in the first reaction step comprises loose wool fibers, preferably untreated but scoured wool fibers.

In one embodiment, the alcohol is selected from methanol, ethanol, propanol, butanol or mixtures thereof.

In one embodiment, the base is selected from potassium hydroxide or sodium hydroxide or mixtures thereof.

In one embodiment, the concentration of base in the alcohol mixture is about 0.5% to 5%. Preferably, the concentration of base in the alcohol mixture is about 1% to 2%. More preferably, the concentration of base in the alcohol mixture is about 1.5%.

In one embodiment, the oxidizing agent is hydrogen peroxide.

In one embodiment, the concentration of the oxidizing agent in the aqueous mixture is about 0.5-5%. Preferably, the concentration of the oxidizing agent in the aqueous mixture is about 1-2%. More preferably, the concentration of the oxidizing agent in the aqueous mixture is about 2.0%.

In one embodiment, the reaction time of the first reaction step is about 5 to 30 minutes. More preferably, the reaction time of the first reaction step is about 10 to 30 minutes. When the fleece substrate is a nonwoven fleece substrate, the preferred reaction time for the first reaction step is about 10 minutes. When the wool substrate comprises loose wool fibers, the preferred reaction time for the first reaction step is about 12-14 minutes.

In one embodiment, the reaction time of the second reaction step is about 30 to 180 minutes. Preferably, the reaction time of the second reaction step is about 30 to 120 minutes. More preferably, the reaction time of the second reaction step is about 30 to 90 minutes. Most preferably, the reaction time of the second reaction step is about 60 minutes.

In one embodiment, the process of the invention is carried out with a fiber to liquid ratio of from 1:10 to 1: 40.

In a second aspect, the present invention provides a wool product obtainable by the above process, wherein the wool product has at least 800% higher absorbency than an untreated wool substrate.

In one embodiment, the wool product has at least 1000% greater absorbency than an untreated wool substrate. In another embodiment, the wool product has an absorbency performance at least greater than 1200% greater than that of an untreated wool substrate.

When the wool substrate comprises loose wool fibers, the treated wool has an absorbency at least 1500% higher than that of untreated loose wool fibers and up to 2400% higher than that of untreated loose wool fibers.

In one embodiment, the wool product is further used in one or more products requiring a material with absorbent properties. Such products include personal hygiene products (e.g., diapers, pads, diapers, and the like), wound or surgical dressings, and the like, chemical spill or cleaning products, and the like, as well as athletic, outdoor, and general day-to-day fashion garments.

This summary broadly describes the features and advantages of certain embodiments of the invention. Further features and advantages will be described in the following detailed description of the invention.

The novel features which are believed to be characteristic of the invention will be better understood from the detailed description when considered in connection with the figures and examples. However, the drawings and examples are intended to help illustrate the invention or assist in understanding the invention, and are not intended to limit or restrict the scope of the invention.

Brief Description of Drawings

FIG. 1: a flow chart of a method of treating wool in one aspect of the invention.

FIG. 2: results of absorption tests evaluated by contact angle (θ) using goniometer measurement techniques are shown. The absorbance was measured after the alkaline first reaction step and then after the oxidative second reaction step.

Fig. 3(a) and 3 (b): a photograph showing the comparative absorbency results comparing an untreated fleece substrate 3(a) with a treated fleece substrate 3(b) in the presence of an ink sample.

FIG. 4: an absorption experiment set up for the impregnation stage of the wool fibre substrate treatment is shown.

FIG. 5: an absorption experiment set up for the drainage phase of wool fiber substrate treatment is shown.

FIG. 6: a carded treated wool fibrous substrate is shown compared to a control sample.

FIG. 7: standard test absorbency data for the treated wool fibrous substrates are shown.

FIG. 8: showing the simulated sanitary absorbency of the treated wool fibrous substrate.

FIG. 9: the percent fiber loss of the treated wool fibrous substrate during hand carding is shown.

FIGS. 10 to 17: scanning electron micrographs at low and high magnification of 8 samples of treated wool fiber substrate are shown.

Detailed Description

Before explaining the present invention in detail, it is helpful to provide definitions of certain terms used in this specification.

The term "about" as used in connection with a reference numerical indicator means that the reference numerical indicator is plus or minus at most 10% of the reference numerical indicator. For example, the phrase "about 50" units encompasses a range of 45 units to 55 units.

The term "wool substrate" as used herein includes unprocessed wool substrates such as unprocessed sheep wool, loose wool fibers (including unprocessed untreated wool fibers), cashmere, mohair, angora, 100% cross-type wool; merino wool, a washed and dried raw wool substrate; a raw fleece substrate that is cleaned, dried and needled into a nonwoven web or mat. The fleece substrate preferably has a density of 100-1000 grams per square meter, such as 100gsm, 200gsm, 400gsm, 600gsm, 800gsm, or 1000 gsm.

The wool treatment process of the present invention produces wool products with enhanced absorbency properties, making the wool produced by the treatment process of the present invention a useful absorbent product or useful component of products requiring absorbency, such as diapers, diaper pads, wound and surgical dressings, urinary incontinence pads, and the like, as well as athletic garments for sports, outdoor activities, and daily activities.

In a first aspect, the present invention provides a method of treating a wool substrate comprising:

a first reaction step of treating the wool substrate with an alcohol and base reaction mixture for a reaction time of about 5 to 60 minutes; and a second reaction step of treating the resulting wool substrate obtained from the first reaction step with an aqueous oxidizing agent mixture.

In one embodiment, the concentration of base in the alcohol mixture is about 0.5-5%. Preferably, the concentration of base in the alcohol mixture is about 1-2%. More preferably, the concentration of base in the alcohol mixture is about 1.5%.

In one embodiment, the alcohol and base reaction mixture comprises a mixture of ethanol and potassium hydroxide.

In one embodiment, the alcohol and base reaction mixture comprises about 1.5% sodium hydroxide (e.g., 2.8kg sodium hydroxide in 217 liters of ethanol). In another embodiment, the alcohol and base reaction mixture comprises about 1.5% potassium hydroxide (e.g., 3.0kg potassium hydroxide in 200 liters of 96% ethanol).

In one embodiment, the concentration of the oxidizing agent in the aqueous mixture is about 0.5-5%. Preferably, the concentration of the oxidizing agent in the aqueous mixture is about 1-2%. More preferably, the concentration of the oxidizing agent in the aqueous mixture is about 2.0%.

In one embodiment, the oxidizing agent is hydrogen peroxide.

In one embodiment, the aqueous oxidizer mixture comprises 2% hydrogen peroxide (e.g., 9 liters of 50% hydrogen peroxide in 224 liters of water).

In one embodiment, the reaction time of the first reaction step is about 5 to 30 minutes. More preferably, the reaction time of the first reaction step is about 10 to 30 minutes. When the fleece substrate is a nonwoven fleece substrate, the preferred reaction time for the first reaction step is about 10 minutes. When the wool substrate comprises loose wool fibers, the preferred reaction time for the first reaction step is about 12-14 minutes.

In one embodiment, the reaction time of the second reaction step is about 30 to 180 minutes. Preferably, the reaction time of the second reaction step is about 30 to 120 minutes. More preferably, the reaction time of the second reaction step is about 30 to 90 minutes. Most preferably, the reaction time of the second reaction step is about 60 minutes.

In one embodiment, the process of the invention is carried out at a fiber to liquid ratio of from 1:10 to 1: 40. The preferred ratio will depend on the nature and amount of the wool substrate being treated, the size of the reaction vessel, etc.

In one embodiment, the reagents (particularly alcohols) are recovered and recycled, if possible, reducing costs and hazardous waste.

In another embodiment, the method includes the additional step of rinsing the wool substrate with water between the first and second reaction steps.

In another embodiment, the method comprises the further step of rinsing the wool product with water after the second reaction step.

In another embodiment, the method includes the further step of rinsing and subsequently drying the wool product after the second reaction step.

Preferably, the fleece substrate comprises 100% cross-type fleece (approximately 35-42 microns).

The method is preferably applied to a nonwoven fleece substrate.

In one embodiment of the invention, the nonwoven fleece substrate is 400 grams per square meter (gsm), however, the nonwoven fleece substrate may have other densities, such as 200gsm or 600 gsm.

In one embodiment, the nonwoven fleece substrate is produced in rolls of about 1.5 meters by 30 meters, however it is understood that any suitable width and/or length may be used.

In another embodiment, the method is applied to a bulk wool fiber substrate.

Without wishing to be bound by any theory, it is believed that the method of the present invention is a wet treatment, which affects the overall wool fiber structure (wool surface and wool matrix). Wool fibers undergo relaxation (breaking and recombining the structure of the wool fiber bonds) by chemical changes. More specifically, the basic-OH ions disrupt the disulfide bonds and cause the wool material to become significantly absorbent by interacting with the acidic hydrogen atoms next to the sulfur atoms.

The treatment method of the present invention produces highly absorbent wool products, such as treated wool substrates. In a preferred embodiment, the wool product is capable of absorbing up to 1200-1500% of its weight in water (compared to 30% of wool that has not been treated by the method of the invention). In another preferred embodiment, the wool product is capable of absorbing up to 2400% of its weight in moisture.

Useful properties of the wool product of the invention may include: superabsorbent, odor resistance, antimicrobial (natural wicking through moisture and breathability of the material), chemical-free, non-synthetic and non-petroleum, rash reduction, flame retardance, temperature control, hypoallergenic, warm keeping, comfortable, breathable, biodegradable and compostable, renewable and sustainable wool products that can be cut or formed into any desired shape suitable for the desired purpose.

The wool products of the invention can be used in a variety of applications, including household, commercial and industrial cleaning products and cleaning accessories; cosmetic cleansing aids (e.g., facial masks, exfoliating wipes/gauze, soap dispensers, and scrubbing aids); diaper components (e.g., impregnated pads, liquid acquisition layers, and urine pads); toilet training base pads & booster pads; a nursing pad for the mother; incontinence pads and pants; animal toilet pads; bedding for pets; oil and mechanical fluid spills; an aid to absorb any fluid exposed to the electronic device; medical devices (e.g., wound care dressings, gowns, surgical gauze, and body warmers); fashion athletic apparel for use in athletic, outdoor, and everyday activities.

The process of a preferred embodiment of the present invention is shown in figure 1 of the accompanying drawings.

In this embodiment of the invention, the treatment process includes a preliminary or pretreatment step to prepare the first reagent and the second reagent.

Once the reagents are prepared, the treatment process is started. Wool (e.g., a roll of nonwoven fleece substrate) is treated by immersion in a bath containing a first reaction mixture. The fleece substrate is left in the bath of the first reaction mixture for a predetermined period of time, for example about 5-60 minutes.

The fleece substrate was removed from the bath and allowed to drain. The first reaction mixture is further processed to recover ethanol (which may be reused).

The treated wool substrate was then rinsed with water. Multiple flush cycles may be used.

In a second reaction step of the treatment process, the wool substrate resulting from the first reaction step is treated by immersion in a bath containing a second reaction mixture. The fleece substrate is left in the bath of the second reagent for a predetermined period of time, for example about 60-180 minutes.

The fleece substrate was removed from the bath, drained and rinsed with water. Furthermore, multiple flush cycles may be used.

After this rinsing, the wool substrate is dried to produce the treated wool product of the invention.

Typically, the reagents used in the methods of the invention will be at a temperature of about 20 ℃ (i.e., room temperature), and typically the methods are performed at about 20 ℃ (i.e., room temperature).

The invention will now be described with reference to examples.

Experiment of

Example 1 reaction conditions

1) Preparation of a 1.5% solution of potassium hydroxide (KOH) in ethanol (EtOH):

200 liters of EtOH with 3.0kg of KOH particles or 400 liters of EtOH with 6.0kg of KOH (it was found most feasible to make small amounts and higher concentrations; e.g., 3.0kg in 20 liters, then suitably dilute it with EtOH to obtain a 1.5% KOH solution).

(1a) 20 liters of EtOH was added to a clean container (glass or stainless steel or suitable plastic).

(1b) 3.0kg of KOH particles were slowly added to (1a) and mixed until all KOH particles were completely dissolved (note: some heat may be generated by mixing the solution/vessel).

(1c) The appropriate amount of EtOH was then added to (1a) until a total of 1.5% KOH concentration in EtOH was obtained.

2) A suitable fleece substrate (e.g. 200gsm, 400gsm or 600gsm fleece substrate) is selected. The overall size and weight of the wool substrate was measured and determined.

3) Treatment/processing protocol for EtOH containing 1.5% KOH:

(3a) a suitable dry and clean treatment vessel (preferably glass or stainless steel) is selected.

(3b) Sufficient 1.5% KOH in EtOH solution (pre-prepared) was added to the vessel (3a) and shipped carefully (using appropriate safety equipment and conditions).

(3c) A fleece substrate (e.g., 400gsm fleece substrate) is added and completely immersed in a treatment solution containing a concentration of 1.5% KOH in EtOH for 20 minutes (preferably without agitation) at room temperature (20 ℃ ± 2 ℃).

(3d) The treatment liquor is recovered for reuse if applicable, or is used to treat a second or third batch of wool substrates.

(3e) The treated wool substrate is then rinsed (preferably, at least 5 times) in Reverse Osmosis (RO) water at room temperature. The method may include applying hydrogen peroxide (H)₂O₂) The wool substrate is dried prior to the treatment step.

4) Preparation of 2% Hydrogen peroxide (H)₂O₂) The aqueous solution of (a):

option 1: calculate H₂O₂Is added to the reaction vessel and then filled with water until the desired concentration (i.e., 2%) is obtained.

Option 2:

(4.2a) 100 liters of RO water was added to a clean vessel (glass or stainless steel or suitable plastic).

(4.2b) 1.5kg of H₂O₂(provided that it has been diluted to 30%) was added to (4.2a) and mixed at room temperature to ensure H₂O₂And (4) uniformly dissolving. To (4.2a) was added an appropriate amount of water to obtain 2% H₂O₂And (4) concentration.

(4.2c) treatment conditions: total exposure/treatment time of 60 minutes at room temperature (20 c 2) without agitation is preferred. Followed by at least 5 rinses with water before drying (using hot air or otherwise). Drying at temperatures of up to 120 ℃ is recommended, which may lead to yellowing of the substrate.

Example 2 optimization of reaction conditions

Samples of 100% New Zealand sheep wool substrate (needled wool nonwoven substrate) cut into circles and having a diameter of 100mm and a mass of 200gsm or 400gsm were used as substrates. Potassium hydroxide (KOH), 97.6% absolute ethanol (EtOH), hydrogen peroxide and ammonium solution were used for pretreatment/post-treatment of wool substrates.

Wool samples were conditioned for 48 hours (20 ℃, 65% relative humidity) and then treated with treatment solutions formulated to contain different concentrations (e.g., 1%, 1.5%, and 2%) of KOH/EtOH for different periods of time (e.g., 10 minutes, 20 minutes, and 30 minutes).100mm round diameter wool samples were treated at room temperature using a pretreatment method with 1% KOH/EtOH for periods of 10 minutes, 20 minutes, and 30 minutes, respectively. Then using 2% H₂O₂The pre-treated samples were treated (i.e., post-treated) at room temperature for periods of 60 minutes, 90 minutes, and 120 minutes, respectively. Similarly, a pretreatment experiment was performed to treat wool samples with 1.5% strength, 2% strength KOH/EtOH followed by H under the conditions described above₂O₂And (4) carrying out aftertreatment on the solution. The results are detailed in table 1 below.

Table 1: the following test variables, their concentrations and conditions for the treatment of the woolen substrates (400gsm and 200gsm)

Reagent and treatment formulation	Concentration and conditions (e.g. time, temperature)
		Concentration of potassium hydroxide in ethanol (KOH/EtOH)	1%, 1.5% and 2%; room temperature (about 20 ℃ C.)
Exposure time to KOH/EtOH	10min, 20min and 30 min; room temperature (about 20 ℃ C.)
		For 2% hydrogen peroxide H2O2Exposure time of	60min, 90min and 120 min; room temperature (about 20 ℃ C.)

A panel of test samples (n-5) was generated for each treatment (pre-treatment and post-treatment) associated with the specified treatment formulation and processing time for absorbency testing. The water-saline absorbency test method selected for evaluating the untreated (control) and treated wool samples was based on ISO standard ISO 11948: 1-1998: total absorbent capacity.

All wool samples (treated and untreated) were conditioned for 48 hours (20 ℃, 65% relative humidity) under the same environmental conditions as required by the ISO standard (ISO 11948: 1-1998) before the water absorption efficacy test (change in mass). The surface hydrophilicity of the resulting wool products was investigated with a water contact angle meter (KSV CAM 101). The absorbency was measured after the alkaline first reaction step and then after the oxidative second reaction step. Measurements were taken after 30 seconds of contact and an average of 5 measurements were recorded. The results of the absorption test evaluated by contact angle (θ) using the goniometer measurement technique are shown in fig. 2. The structure-function properties of the wool were studied using ftir (atr) before, during and after treatment. The surface morphology of the wool fibers was analyzed by Scanning Electron Microscopy (SEM) image analysis. Water absorption studies were carried out by the following standard method (ISO 11948: 1-1998: Total absorption Capacity).

The hydrophilicity/absorbency results for the resulting fleece product for a 200gsm substrate are tabulated in table 2 below.

Table 2: group descriptive statistics of percent Water-saline absorption (200gsm wool substrate)

From these results, it can be seen that the treated wool sample exhibited a significant water-saline absorption capacity (about 1300% by weight) compared to the control (untreated wool substrate). Treatment of the wool substrate did not alter the physical properties of the wool, such as its flexibility, brittleness, structural integrity and odor. The treated wool product was slightly brighter (whiter) in color than the untreated wool substrate.

The hydrophilicity/absorbency results for the resulting fleece product for the 400gsm substrate are tabulated in table 3 below.

Table 3: group descriptive statistics for percent Water-saline absorption (400gsm wool substrate)

Total percent absorbent capacity (weight after absorption/initial weight of sample x 100)

As can be seen from the results in table 3, the treated wool samples exhibited significant water-saline absorption capacity (about 1300% by weight) compared to the control (untreated wool substrate). Treatment of the wool substrate did not alter the physical properties of the wool, such as its flexibility, brittleness, structural integrity and odor. The treated wool product was slightly brighter (whiter) in color than the untreated wool substrate.

Fig. 3(a) and 3(b) clearly show the comparative absorbency of the untreated fleece substrate in 3(a) compared to the treated fleece substrate in 3(b) in the presence of the ink sample. Figure 3(a) shows the hydrophobicity of an untreated wool pad and the ink beading on the surface of the wool substrate. In contrast, fig. 3(b) shows that the ink is easily absorbed into the fleece substrate without forming any beads at all on the surface of the fleece substrate.

Example 3 reusability of the reaction mixture

A study was conducted to determine the reusability of the 1.5% KOH/EtOH reaction mixture for 4 reactions/batch cycles. After the third period, the 1.5% KOH/EtOH reaction mixture turned cloudy yellow/orange in color, and also appeared slightly colored in the treated wool substrate, where a light yellowish wool substrate appeared.

The percent water-saline absorption is shown in table 4 below. As can be seen from the results, no significant difference in absorbency was observed between the wool substrate resulting from fresh KOH/EtOH treatment of the reaction mixture and the wool substrate resulting from the KOH/EtOH reaction mixture reused in cycles 1-3. This strongly suggests that the first reaction mixture is reused in multiple treatment cycles without compromising the absorbency results obtained. It will also be appreciated that EtOH may be recovered by distillation from the reaction mixture.

Table 4: percent water-saline absorbency and descriptive statistics demonstrating reusability of KOH/EtOH reaction mixtures (exposure lasting 10 minutes) while still producing a highly absorbent wool product of 400gsm wool substrate over 4 reaction cycles

Example 4 treatment of wool fibers

Wool fibers were supplied by a Hawkes Bay wool scourer. The fibers are strong wool with excellent color and low scour of vegetable matter (Strong wool, 3/4Romney variety, second cut), with an expected average fiber diameter of 35-42 microns and an expected fiber length of 100-120 mm.

Chemicals used for treatment and testing (remarked as supplier) were:

1. potassium hydroxide (analytical reagent), Fisher Chemical;

2. ethanol (96% v/v, food grade), Southern grins;

3. hydrogen peroxide (25% v/v, from 50% v/v technical grade), Jasol;

4. sodium chloride (AR, ACS), proalys; and

5. reverse Osmosis (RO) water.

All treatments were performed at ambient conditions and all tests were performed at standard textile test conditions (20 ℃ and 65% relative humidity).

All treatments were run at a fiber to liquid ratio of 1: 40. A series of treatments with 1.5% KOH/EtOH and 2% hydrogen peroxide were run, each treatment having a different ethanol hydroxide treatment duration but the same (60 minute) hydrogen peroxide soak period.

The following treatment times were used for this treatment:

1. control group (untreated)

2.8 minutes

3.10 minutes

4.12 minutes

5.14 minutes

6.16 minutes

7.18 minutes

8.20 minutes

Each sample was then rinsed 5 times in RO water followed by drying at 40 ℃ for 30 minutes. Prior to testing, the dried samples were placed in labeled bags and then moved to a conditioned environment (bags not sealed) for at least 48 hours.

Each treated sample was tested for "Total absorption Capacity" (ISO 11948: 1-1998). The sample size was 10cm × 10cm (5 replicates for each change).

The method comprises the following steps: a plastic mesh with square openings (3mm width, 20mm openings), a small screen (pre-weighed), and a metal mesh that covers the screen and holds the fibers in place.

Standard methods of procedure are as follows:

1) the dried conditioned product was weighed and placed in a sieve with a metal mesh over the top (to retain the fibers). The screen is placed on a plastic net.

2) The mesh was lowered and sieved into a reservoir of sodium chloride solution (9g/l, 1000ml) and soaked for 5 minutes.

3) The grid was raised and the sample was purged from the reservoir and left to drain for 5 minutes.

4) The sieve was removed, the lid removed and weighed.

5) The difference between dry and wet weight was calculated for 5 x samples.

6) The mean and standard deviation of the results were calculated.

The experimental set-up is shown in fig. 4 and 5.

A simulated sanitary absorbency test was also performed. For each treatment time, an additional sample was run by pouring 250ml of the solution evenly over the sample (covered by the metal mesh and on top of the plastic mesh). It was allowed to soak for 5 minutes and then drained for 5 minutes before weighing. This technique was tested in terms of comparable liquid volume applications from above (but not below) as it represents the mode of action of a hygiene or diaper type product.

For each sample, a rectangular conditioned black woven wool fabric (25cm x 20cm) was cut. It is then weighed and subsequently spread out on a flat surface. An accurately weighed 5g sample of each treatment duration was taken from the bulk material and then manually carded in sequence over the piece of fabric. Each sample was carded into 4 sections, 10 times each. After carding, the fabric was reweighed and fiber loss during manual carding was calculated. The carded fibers were bagged and marked and observations were recorded regarding ease of carding, fiber hand, volume and appearance. Fig. 6 shows the carded fibers, carded fibers and wool 'fiber catching' fabric of the control sample.

Scanning Electron Microscopy (SEM) was used to obtain information about the physical changes induced to the fibers during the treatment. The sample is imaged by the SEM by scanning the sample with a beam of electrons in a raster scan pattern. The material is observed under high magnification, and the surface appearance, the composition and other properties of the fiber are researched. The samples were sputter coated from a gold/palladium leaf source to impart conductivity to the sample surface. The samples were studied using a JEOL JSM 7000F field emission gun scanning electron microscope. The microscope was operated at 10kV and the samples were observed over a working distance range of 11.3mm to 13.7 mm. The samples treated from 8 to 14 minutes (including 8 and 14 minutes) did not show any significant signs of more fiber damage than is typically found on scoured wool fibers (control samples). Once the treatment time reached 16 minutes, there was evidence of damage to the fiber surface. In particular, there is evidence that longitudinal 'wrinkles' form on the fibres; longitudinal 'wrinkles' were more severe on the 18 and 20 minute samples. Fig. 10-17 show scanning electron microscopy images obtained from different processed samples.

Each fiber sample was evaluated according to how felt it was when touched. There is a risk that this treatment will render the sample brittle and rigid and can be easily felt when touching the wool. Since the test was subjective, the samples were evaluated by 3 volunteers and general comments were recorded. Both carded and unrooted samples were evaluated.

Results

Total absorption capacity

A complete set of results is provided in tables 5-7 below.

Table 5: total absorption capacity ISO 119848: 1-1998

Table 6: total absorbency, mean and standard deviation

Table 7: simulating hygiene absorbency

Time of treatment	Sample Mass (g)	Mass after impregnation (g)	Difference (g)	% absorptionProperty of (2)
					Control	5.04	19.70	14.66	291.11
8 minutes	5.00	108.60	103.59	2070.02
					10 minutes	5.04	110.46	105.42	2092.79
12 minutes	5.02	104.82	99.80	1988.34
					14 minutes	5.06	117.78	112.72	2229.83
16 minutes	5.01	106.30	101.29	2022.45
					18 minutes	5.06	101.72	96.66	1910.46
20 minutes	5.08	83.35	78.27	1542.24

The standard test method results are shown graphically in fig. 7 and the simulated sanitary method is shown in fig. 8.

FIG. 7: standard test method absorbency data

The average total absorbent capacity of the treated samples ranged from 1884-2502%, and the untreated samples averaged 473%. The treated sample with the lowest absorbency was the 20 minute sample (longest duration). The standard deviation for the 20 minute sample (see table 6 above) was lowest and the standard deviation for the 8 minute sample was highest, with the remaining samples having similar standard deviations (including the control sample). This can be taken as an indication of the levelness of the fibre treatment, 8 minutes being insufficient time for the liquid to penetrate and react evenly throughout the fibre bundle, meaning that samples taken from different regions of the treated material will behave differently.

FIG. 8: simulating hygiene absorbency

The individual tests, which simulate 'in use' conditions based on the sanitary article, gave similar results to the standard test method (fig. 8). The lowest absorbency of the treated samples is exhibited by samples of 20 minute duration.

It was observed that for both test methods, the 18 and 20 minute samples soaked most rapidly, while the 8 and 10 minute samples soaked most slowly. However, no pressure was applied to wet all 7 treated samples, while the control sample tended to float on the surface of the solution until the mesh was placed on top of the screen.

There is a risk that an extended duration of treatment may substantially damage the fibres and render them unsuitable for any subsequent machining process that is required in order to make a yarn or fabric from these fibres. The manual carding test constitutes a simple comparison taking into account the effect of treatment time on the fibers. The weakened fibers may break more easily and the resulting staple fibers may tend to be lost during carding. The amount of fiber lost during manual carding is shown in fig. 9. The results clearly show that most of the treatment duration experienced fiber loss at levels comparable to the control samples. The 20 minute sample lost almost 3 times more mass than the other samples, indicating a higher level of fiber damage.

The objective of this work was to determine the potential of scoured loose wool fibers to be rendered superhydrophilic by the treatment method of the present invention and still be able to withstand moderate processing. The results from absorbency, hand-carding and SEM all demonstrate that as the duration of treatment increases, so does the damage to the fibers. Although wetting with the test solution is easiest, a decrease in the absorption results is observed at 20 minutes duration. After examining the SEM images, it became apparent that a plurality of longitudinal 'wrinkles' appeared on the fibers, which also appeared to collapse internally. It is possible that the above affects the absorbency by providing channels that promote absorption (by capillary action) but also allow the solution to drain more easily, and also by reducing the ability of the interior of the fiber to retain moisture (which has partially collapsed). The lower apparent elasticity of the fibers may also reduce the ability of the fibers to retain large amounts of water between the fibers. A similar effect was observed on the SEM image of the 18 minute sample.

For combing, the 20 minute sample was the only treated sample that significantly exhibited greater fiber loss when compared to the control sample. It also has the driest hand and the lowest observable bulk and elastic properties. At the other end of the range of duration values, the 8 minute sample had the largest standard deviation of the total absorbency data. This indicates that the treatment may not be uniform throughout the sample. Considering all the data collected and observations made, a treatment time of 12-14 minutes is recommended for loose fibres. At this level, the absorbency of the fibers is in the 2400% region, the SEM images show the lowest fiber damage (compared to the control sample), the sample does not contain any reinforced regions and is easily hand-carded. The hand observed was drier than the control, but bulk and elasticity were not adversely affected, although this was assessed only by subjective testing.

The invention and its embodiments are described in detail. However, the scope of the present invention is not intended to be limited to the embodiments described in the specification. Modifications and variations may be made to the disclosed embodiments without departing from the scope or essential characteristics of the invention.