CN118043507A - Method for producing regenerated cellulose fiber - Google Patents

Abstract

A method and production facility for producing regenerated cellulose fibers. The spinning solution is extruded into a coagulation bath containing a salt and preferably a base. The spinning solution comprises cellulose dissolved in an aqueous solvent comprising NaOH and ZnO, and the coagulation bath has a pH of at least 7. The processing facility includes a cutter to cut the fiber tows into cut fibers in an undried state, fleece forming means for suspending the cut fibers and collecting them in the form of a nonwoven fibrous layer, and at least one pressing means for pressing the nonwoven fibrous layer, thereby imparting natural crimp on the fibers.

Description

Method for producing regenerated cellulose fiber

Technical Field

The present disclosure relates to innovations in the field of production, use and application of man-made cellulose fibers. In particular, the present disclosure relates to a method of producing regenerated cellulose fibers produced according to a cold alkali process, fibers produced thereby, and uses thereof.

Description of related Art

Man-made cellulosic fibers are fibers made based on cellulosic material as the source material.

In the context of the present disclosure, the term "cellulose" means an organic compound derived from a plant cell wall or synthetically produced. Cellulose is a polysaccharide and is unbranched. Typically, cellulose contains several hundred to ten thousand β -D-glucose molecules (β -1, 4-glycosidic linkages) or cellobiose units, respectively. Cellulose molecules which are used by plants for the production of cellulose fibres are also used in technical processes for the production of regenerated cellulose.

The term "regenerated cellulose" means a class of materials made by converting natural or recycled cellulose to a soluble cellulose derivative or directly dissolved cellulose solution and subsequently regenerating, forming shaped bodies such as fibers (e.g., rayon), films or foils (e.g., cellophane (cellophane)) or bulk solids (e.g., beads, powders or pellets).

As used herein, the term "fiber" refers to continuous filaments as well as cut staple fibers of any desired length.

The cellulosic fibers may also be in the form of a woven fabric, knit fabric, or nonwoven fabric comprising cellulosic fibers. Woven fabrics comprise woven planar fabrics made from at least two systems of intersecting yarns (crosslinked THREAD SYSTEMS), which may be referred to as warp and weft yarns. In contrast, the yarns in the knitted fabric follow a meandering path (course), symmetrically forming symmetrical loops (loops) (also known as loops (bight)) above and below the average path of the yarns.

The term "nonwoven" means a fabric that is neither woven nor knitted. The nonwoven may be in the form of a fabric comprising randomly oriented fibers and/or cut yarns of finite length. The nonwoven may also comprise endless yarns (ENDLESS YARNS) made, for example, by a melt-blowing process.

Viscose refers to regenerated cellulose fibers produced by a wet spinning process known as the viscose process. The starting material for the viscose process is cellulose, which is usually provided on the basis of wood. From this starting material, high purity cellulose in the form of chemical pulp is obtained. Additionally or alternatively, other cellulosic materials, such as bamboo, cotton linters, recycled cellulosic materials, reed, and the like, or mixtures of these materials, may be used as starting raw materials. In the subsequent process stage, the pulp is first treated with caustic soda (NaOH), whereby alkali cellulose is formed. In the subsequent conversion of the alkali cellulose with carbon disulphide, a cellulose-xanthate is formed. Thus, by further supplying NaOH, a viscose spinning solution is generated, which is pumped into the coagulation bath (also called spinning bath) via the holes of the spray spinning nozzle. In this case, each spinning nozzle orifice produces a viscose filament yarn by coagulation. To coagulate the spinning solution, an acidic coagulation bath is used. The viscose filaments thus produced are subsequently worked up. Post-processing typically includes several washing and drawing steps and cutting the filaments into viscose staple fibers. The uncut and/or cut fibers may be subjected to several other post-processing steps such as crimping, bleaching and/or finishing ("soft finishing"). As used herein, the term "viscose process" means such xanthate process (xanthogenate process).

As used herein, the term "lyocell" refers to a regenerated fiber type comprising cellulose made according to a direct solvent process. Cellulose for the lyocell process is extracted from a raw material containing cellulose. The pulp thus obtained can then be dissolved in a suitable solvent without chemical modification under dewatering. In large-scale industrial practice, N-methylmorpholine-N-oxide (NMMO) is currently used as solvent, although other solvents, such as ionic liquids, are known to be useful in the process. The solution is then filtered and, for the production of fibres, is subsequently extruded via a spinning nozzle into an air gap, where they are drawn and coagulated by means of a wet air flow and then fed into a coagulation bath containing an aqueous NMMO solution. The fibers may then be further processed, such as washing, bleaching, finishing, crimping, cutting into staple fibers, and the like.

Another well known method for manufacturing regenerated cellulose fibers is the urethane process, which is similar to the viscose process, but uses urea instead of carbon disulphide. Yet another process known as the modal process (modal-process) is the modified viscose process for producing higher quality fibers. For these methods, an acidic coagulation bath is also used.

Furthermore, methods for manufacturing cellulose products are known, which can use alkaline spinning baths containing salts. To prepare the spinning solution, cellulose is dissolved in an aqueous alkaline medium at a controlled temperature. Such a process is generally referred to herein as a "cold caustic process".

WO2018/169479 discloses an example of a fiber produced by a cold alkali process. The method comprises the following steps: providing a spin dope comprising a solution of cellulose and an additive in an alkaline solvent, the cellulose being present in the solvent in a concentration of about 5 to 12 wt%, the additive being present in a range of 0.1 to 10 wt% based on the cellulose; contacting the cellulose dope with an aqueous coagulation bath fluid having a pH above 7 and comprising a salt; forming a regenerated cellulose fiber composition; and stretching and washing the fiber composition in one or more wash and stretch baths.

EP3231901A1 discloses a similar process in which the dope is prepared by dissolving cellulose in an aqueous NaOH solution. The spinning bath comprises a coagulation liquid comprising an aqueous sodium salt solution.

EP3231899A1 discloses a process for preparing a spinning dope by direct dissolution of cellulose in cold alkali.

WO2020171767A1 discloses a method of forming a fiber tow involving a wet spinning procedure comprising the steps of: dissolving a cellulose pulp in an alkaline aqueous solvent to form a cellulose dope composition, spinning the cellulose dope composition in a coagulation bath having a pH greater than 7.0, preferably a pH of at least 10 to produce fiber tows, and passing the produced fiber tows through a series of successive drawing and washing steps, wherein the formed fiber tows are washed with a washing liquid by a counter-current washing procedure.

Fibers made according to the cold alkali process present a number of challenges, particularly for post-processing of the fibers. Subsequent production steps, such as carding, spinning, textile production or fleece production (fleece production), require staple fibers with, for example, sufficiently high tenacity, low brittleness and proper crimping.

Crimping of the fibers is typically accomplished by specially shaped rolls that compress the fiber tows into a corrugated pattern before they are cut into staple fibers in a cutter. The fiber tows must be crimped as long as they remain in a sufficiently formable state. The resulting staple fibers have a characteristic appearance in which bundles of fibers arranged in a perfectly parallel pattern of corrugations can be identified. The crimp of all the fibers exhibits the same length and curvature, which gives them a regular appearance.

For many applications, a more natural curl is preferred. As used herein, the term "natural crimp" refers to a fiber crimp pattern comprising corrugations having different and randomly distributed curvatures and lengths. Such fibers are more closely related to the crimp of some natural fibers, such as cotton or wool.

Disclosure of Invention

The present disclosure describes methods and apparatus for producing recycled fibers, particularly for post-processing of fiber tows of recycled cellulosic fibers, which are capable of producing natural crimped fibers produced according to the cold alkali process.

In a first aspect, the present disclosure relates to a method of producing regenerated cellulose fibers comprising extruding a spinning solution comprising cellulose dissolved in an aqueous solvent comprising NaOH and ZnO into a coagulation bath comprising a salt and preferably a base to produce fiber tows, the coagulation bath having a pH of at least 7, wherein the method comprises at least the steps of: cutting the fiber tows into cut fibers in an undried state, suspending the cut fibers and collecting them in the form of a nonwoven fibrous layer, and pressing the nonwoven fibrous layer, thereby imparting natural crimp on the fibers. The method is capable of producing natural crimped fibers with improved post-processing properties.

Those skilled in the art having the benefit of the teachings disclosed herein are able to select an appropriate salt for the coagulation bath. The salt promotes coagulation of the spinning solution and may preferably be present in the coagulation bath in a ratio of 10 to 30 wt.%. Preferably, the salt is a sodium salt, such as sodium carbonate or sodium sulfate. Other suitable salts may be selected by taking into account the hofmeister series (Hofmeister series) (also known as lyotropic series (lyotropic series)) that sorts ions in the order they are capable of precipitating. The salt should firstly be able to achieve rapid solidification and secondly should promote recovery and recycling of the compound. Alternative but less preferred sodium salts of coagulation include sodium salts in which the counter ion is carboxylate (e.g., formate, acetate, propionate, butyrate or benzoate), aliphatic or aromatic sulfonate (e.g., benzenesulfonate, toluenesulfonate or methanesulfonate), aliphatic or aromatic phosphonate ion, or mixtures thereof. Preferably, the anionic counterion has a dense charge such that it is at the beginning of the Hofmeister sequence (Hofmeister series). Anionic counterions with dense charge are characterized as strong "salting out" proteins due to their ability to increase surface tension and organize water molecules in their surrounding solvated shells. In addition, the coagulated sodium salt is preferably a sodium salt precipitated as a hydrate. Preferably, the molar ratio of water to sodium salt in the precipitated hydrate is at least 4:1.

In one embodiment, the method may comprise the steps of: wherein the fibers in the fiber tows are drawn to substantially their final cellulose specific diameter and oriented to substantially their final state prior to being cut into staple fibers in an undried state. This enables the production of fibers having good properties in terms of tensile strength and elongation.

As used herein, the term "drawn to substantially the final cellulose specific diameter" should be interpreted as the effect of not subjecting the fiber tow to a further drawing step downstream of this drawing step, i.e. the diameter of the fibers remains substantially constant until the fibers are cut (after which a small amount of relaxation is unavoidable and sometimes even intentional) or dried (wherein the actual measured fiber diameter is reduced due to liquid loss, typically without any change in the drawing of the fibers).

As used herein, the term "cellulose specific diameter" means the diameter in a substantially washed and dried state, i.e. comprising only dried cellulose. One example of a specific diameter of cellulose used in conjunction with fibers is fiber denier, which is defined as the weight of cellulose content per unit length of fiber.

In the case of fibers having a circular cross-section, the diameter corresponds to the diameter of the circular cross-section. As a general definition, as used herein, a diameter corresponds to the diameter of the largest circle that can be inscribed into the fiber cross-section (across the main axis). For example, a diameter of a fiber having an elliptical diameter corresponds to the length of the minor axis of the ellipse.

As used herein, the term "oriented to substantially their final state" should be interpreted as that the molecular orientation of the cellulose in the fibers does not actively change, i.e. maintains a constant effect, during downstream processing steps, except for minor changes that may occur naturally or as (often unwanted) side effects of other downstream processing steps.

As used herein, the term "undried" defines a state in which the wet fibers are dehydrated only by mechanical means (i.e., by extrusion) and have not undergone any drying step. More specifically, the term refers to fibers that have not been dried (new-dried), i.e., fibers that have not undergone any drying step after extrusion.

According to a further embodiment, after leaving the coagulation bath, the fiber tows are fed to at least one conditioning bath (conditioning bath) comprising 10 to 30 wt% of a salt that promotes further coagulation of the spinning solution, the conditioning bath preferably being fluidly separated from the downstream wash line, wherein the fibers in the fiber tows are drawn in the at least one conditioning bath to substantially their final cellulose specific diameter and oriented to substantially their final state. The method enables cost-effective fiber production and reduces the complexity of laying down fiber tows at production start-up. It has surprisingly been found that stretching the fibers to their final cellulose specific diameter and state within the conditioning bath enables economical and controllable production of fibers with suitable properties to enable, for example, spinning of the fibers into yarns. The method can be extended to large industrial scale.

As used herein, the term "fluid separation" refers to a system associated with a completely separated circulatory system, or a system connected via a device that significantly alters the properties of a liquid (e.g., by adding and/or removing substances from the liquid or by concentrating or diluting the liquid).

The salt in the conditioning bath may preferably be the same as that used in the coagulation bath, or it may be selected according to the same requirements as those outlined above for the salts in the coagulation bath.

In a further embodiment, the coagulation bath and the conditioning bath are fluidly connected, wherein the temperature of the coagulation bath and the temperature of the conditioning bath may preferably be set, adjusted and/or maintained independently. This helps to set the optimum process conditions to achieve complete and favourable orientation of the fibres in the conditioning bath and strong stretching.

As used herein, the term "fluidly connected" means that units (e.g., baths, such as coagulation or conditioning baths, or wash units) associated with the same circulatory system have no intervening devices that significantly alter the properties of the liquid (e.g., by adding and/or removing substances from the liquid or by concentrating or diluting the liquid). For example, one unit may be connected in series to another unit and traversed by a liquid stream, for example in a counter-current arrangement or a co-current arrangement. In another approach, the fluidly connected units may be fed independently from the same reservoir.

Instead of just one conditioning bath, a series of two or more conditioning baths may also be employed. This enables the temperature of the coagulation liquid to be adjusted separately and the fiber to be drawn stepwise at different temperatures. This will increase the cost and complexity of the production process on the one hand and it will on the other hand be possible to improve the fibre properties.

According to another embodiment, the fiber tows are conveyed through a washing line comprising at least one washing step, wherein the washing line is preferably arranged downstream of the at least one conditioning bath, and wherein the tension of the fiber tows and the cellulose specific diameter of the fibers are preferably kept substantially constant in the washing line. This further "fixes" the orientation and elongation of the molded body and achieves good properties of the molded body, for example in terms of strength and ductility.

The methods described herein may be further improved by any technically feasible combination of one or more of the following steps:

Preferably, the fiber tows or the nonwoven fiber layers are washed with water. Washing the cut fibers in the form of a nonwoven fibrous layer can be accomplished in a more economical manner than an uncut fibrous tow.

-Neutralizing the fiber tows or the nonwoven fiber layer with an acidic liquid, wherein the acidic liquid may preferably be selected from dilute acetic acid, lactic acid, sulfuric acid, etc. The alkaline residue can thus be neutralized. The neutralization step may preferably be followed by a second washing step to wash out salts formed during the neutralization step.

Bleached fiber tows or nonwoven fiber layers.

Applying a cross-linking agent on the fiber tows or the nonwoven fiber layer, for example to reduce fibrillation.

-Applying a finish, in particular a soft finish, to the fiber tows or the nonwoven fiber layer. The (soft) finish improves, for example, the spinnability of the fibers and the quality of the products produced therefrom.

Drying the nonwoven fibrous layer, preferably in a drum dryer or a conveyor dryer. The cut fibers are not subjected to tensile stress during the drying process (which would be the case if the fiber tows were dried prior to cutting), which may improve fiber quality.

Extruding the fibre tows or the nonwoven fibre layer before and/or after any other processing steps. Extrusion can be readily accomplished, for example, by running a nonwoven fibrous layer of cut fibers through a press roll. The additional pressing can alter and further improve the degree and quality of crimping, especially at the beginning of the post-processing of the nonwoven fibrous layer.

The steps listed above may be implemented in any technically reasonable and useful order and those skilled in the art having knowledge of the present teachings are able to implement many configurations without departing from the present disclosure.

In another preferred embodiment, the post-processing may further comprise at least one step of opening the nonwoven fibrous layer to loosen and/or at least partially separate the fibers. This opening may improve downstream post-processing steps such as drying and baling, and facilitate opening of baled fibers. On the other hand, this opening enables a fiber layer with a higher density to be provided in an upstream post-processing step, which can thus be implemented in a more economical manner.

In a second aspect, the present disclosure relates to a processing plant for producing regenerated cellulose fibers comprising a spinneret for extruding a spinning solution comprising cellulose dissolved in an aqueous solvent comprising NaOH and ZnO into a coagulation bath comprising salt and preferably alkali to produce fiber tows, the coagulation bath having a pH of at least 7, wherein the processing plant comprises a cutter to cut the fiber tows into cut fibers in an undried state, a fleece forming device for suspending the cut fibers and collecting them in the form of a nonwoven fiber layer, and at least one pressing device for pressing the nonwoven fiber layer, thereby imparting natural crimp on the fibers. The processing facility enables industrial implementation and scale-up of the methods disclosed herein. No crimping equipment in the fiber strand production line is required.

In a preferred embodiment, the facility further comprises at least one drawing device for drawing the fibers in the fiber bundles to substantially their final cellulose specific diameter and orienting the cellulose in the fibers to substantially their final state.

According to another embodiment, the installation may further comprise at least one conditioning bath downstream of the coagulation bath, said conditioning bath comprising from 10 to 30 wt% of a salt that promotes further coagulation of the spinning solution, said conditioning bath preferably being fluidly separated from the downstream wash line, and at least one drawing device for drawing the fibers in the fiber tows to substantially their final cellulose specific diameter and orienting the cellulose in the fibers to substantially their final state within said at least one conditioning bath.

According to yet another embodiment, the coagulation bath and the conditioning bath are fluidly connected, wherein the temperature of the coagulation bath and the temperature of the conditioning bath may preferably be set, adjusted and/or maintained independently. By setting these parameters, the setting speed can be optimized to provide a sufficiently strong and ductile fiber.

According to a further embodiment, the fiber tows are conveyed through a washing line comprising at least one washing step, wherein the washing line is preferably arranged downstream of the at least one conditioning bath, and wherein the tension of the fiber tows and the cellulose specific diameter of the fibers are preferably kept substantially constant in the washing line. Washing the fiber tows in tension (and preferably without further stretching them) may improve fiber properties.

According to other embodiments, the facility may further comprise one or more treatment facilities independently selected from:

one or more washing devices for washing the fiber tows or the nonwoven fiber layers,

One or more further pressing devices for pressing the fiber tows or the nonwoven fiber layers,

A neutralizer for neutralizing the cut or uncut fibers with an acidic liquid,

Bleaching means for bleaching cut or uncut fibres,

Crosslinking means for applying a crosslinking agent on the cut or uncut fibres,

Finishing means for applying a finishing agent, in particular a softening finishing agent, to cut or uncut fibres,

An opener for opening the nonwoven fibrous layer to loosen and/or at least partially separate the cut fibers,

-A dryer, preferably a drum dryer or a conveyor dryer, for drying the fibers.

This improves scalability and allows for large-scale industrial applications. The above-listed facilities may be implemented in any technically reasonable and useful order and those skilled in the art having knowledge of the present teachings are able to implement many configurations without departing from the present disclosure.

In a third aspect, the present disclosure relates to regenerated cellulose fibers produced in a processing facility as described herein and/or produced by a method as described herein. The fibers may meet enhanced quality standards in view of the requirements for further processing steps and in terms of the properties of the intermediate and final products comprising the fibers.

In another aspect, the present disclosure relates to a product, particularly a consumer product or intermediate product, comprising regenerated cellulose fibers as disclosed herein. Preferably, the product may be selected from yarns, fabrics, textiles, household textiles, clothing, nonwovens, hygiene products, upholstery, technical applications, such as filter materials, papers.

Brief Description of Drawings

Exemplary embodiments of the present invention will be described below with reference to the accompanying drawings, in which

FIG. 1 is a schematic and exemplary illustration of a fiber production process according to the present disclosure, which focuses on dope preparation, and

Fig. 2 is a schematic and exemplary illustration of a processing facility according to the present disclosure, focusing on post-processing of spun fibers.

Detailed description of the drawings

FIG. 1 shows a flow chart representative of an exemplary fiber production method according to the present disclosure. The figure is a simplified representation and shows the method in a schematic manner.

The method can be divided into the following basic steps, which are indicated with roman numerals in fig. 1:

I. Supplying raw materials

For the method according to the present disclosure, a wide range of possible cellulosic raw materials may be used. In general, the inherent viscosity and degree of polymerization of cellulose used as a raw material are lower than those commonly found in the viscose or lyocell process. For example, a dissolving pulp (kraft pulp or sulfite pulp) having an intrinsic viscosity (measured as Cuen according to SCAN-CM 15:99) of about 200mL/g to 700mL/g (degree of polymerization DP 500 to 1900), preferably between about 250 to about 400mL/g (DP 600 to 950) may be used. In addition, recycled pulp or cotton linters (preferably having the same DP as described above) may be used. Recycled pulp may, for example, originate from waste paper, recycled viscose textile material, recycled modal textile material, recycled lyocell textile material and/or recycled cotton fiber textile material. Blends of pulps of different origins, such as blends of virgin pulp with recycled pulp, are possible and may even be desirable.

In fig. 1, the main part of the dissolving pulp 1 is exemplarily depicted as raw material.

II pretreatment of raw materials

The cellulosic raw material may be subjected to a pretreatment in which the degree of polymerization is adjusted to the desired DP to adjust the viscosity of the dope to a value that allows filtration and spinning. Pretreatment may include subjecting the raw material to an acid pulp treatment, wherein the DP value is primarily affected by the duration of the pretreatment and the acid concentration. In other cases, the preprocessing may be omitted if the DP value is already at the desired value. For example, pulp derived from cellulosic regenerated fibers may have a DP that allows direct dissolution without pretreatment.

In a more specific example, an acidic pulp treatment with 1-10 wt% sulfuric acid for a duration of 5 minutes to 2 hours at 50 ℃ to 95 ℃ may be used as the pretreatment. Since the long duration of this treatment step reduces the profitability of the process, it is generally preferred to minimize the duration of the pretreatment as much as possible. Those skilled in the art who have the benefit of the teachings of this disclosure are able to find appropriate parameters and optimize them without undue burden.

The pretreatment further includes washing the cellulosic material with water and pressing to reduce the moisture content, for example to about 50% by weight of the cellulosic material.

In fig. 1, a source 2 of pretreatment chemicals, such as sulfuric acid, and a pretreatment vessel 3 are schematically depicted. After pretreatment in the pretreatment vessel 3, the cellulosic material may be pressed and washed to reduce the amount of acid that is transferred to the next step.

III, preparation of spinning solution

To prepare the spin dope (also referred to as spin solution), the wet and pretreated pulp is first cooled to about 0 ℃ (while the pulp should be prevented from freezing) and an aqueous solvent comprising NaOH and ZnO is prepared. The solvent is preferably adjusted to provide a spinning solution comprising 5 to 10 wt% NaOH and 0.8 to 3wt% ZnO. The solvent is cooled to a process temperature preferably between-5 ℃ and-10 ℃.

The pulp and the solvent are blended to dissolve the cellulose in the solvent. In order to improve the processability, the preparation of the dope comprises a mixing step followed by a homogenization step. During the mixing step, the blend is mixed with high shear stress, which may be performed in a high shear mixer. Such high shear mixing is preferably carried out for only a relatively short period of time, for example the mixing may be carried out for 1-2 minutes. In a subsequent homogenization step, the blend is stirred at a lower shear strength. The homogenization step may last longer than the mixing step, for example about 5 minutes.

During the mixing and homogenizing steps, the temperature of the mixture is controlled, in particular cooled. The temperature is preferably kept below 0 ℃. The process temperature should not exceed 5 ℃, as the solution may thicken with it and incur irrecoverable losses.

The spinning solution thus prepared is then filtered and degassed. For example, the dope may be filtered at least twice through a KK Filter (Kolben-Korb-Filter, lenzing technology) having a mesh size of 15 microns.

For degassing, the spinning solution is exposed to reduced pressure. This step is known per se from the viscose process. Other techniques for filtering and degassing the dope are known to those skilled in the art.

The dope prepared should be void free, have a uniform consistency and a suitable viscosity for extrusion in a spinneret used in a subsequent extrusion step.

In a preferred embodiment, the falling ball viscosity of the dope should be in the range of about 30 to 200 seconds. The falling ball viscosity can be measured in accordance with DIN 53015-2019. The viscosity of the dope can be adjusted by several different means. For example, the viscosity can be adjusted by changing the DP value of the cellulose, by changing the composition of the solvent and/or the concentration of cellulose in the dope. For example, the concentration of cellulose may be from about 4% to about 12% by weight, particularly from about 5% to about 8% by weight, preferably from about 6% to about 7% by weight.

Specific parameters for the mixing, homogenizing, and filtering steps can be found by routine experimentation by those skilled in the art having the benefit of this disclosure.

In fig. 1, a chemical reservoir 4 for storing a solvent component, a solvent cooling device 5 for cooling at least a part of the solvent, a pulp cooling device 6, a mixing vessel 7 and a deaeration filter 8 are exemplarily depicted. The mixing vessel 7 is provided with a cooling jacket 9.

Extruding into coagulation bath

The dope may be extruded directly into the coagulation bath via a nozzle. In the case of adding an additive to the dope, the dope may be homogenized by a static mixer to incorporate the additive. The spinning dope may preferably be tempered to a spinning temperature, for example to a temperature of 5 ℃ to 30 ℃, prior to the extrusion step. For fiber production, one straightforward method may be to use a spinneret as extrusion nozzle, the spinneret comprising, for example, up to 150 cups of diameter 12.5 to 16mm, comprising up to 3000 holes of diameter about 40 to 75 microns, corresponding to dimensions known per se and commonly used in connection with viscose spinning processes. Nevertheless, it has surprisingly been found that a wider diameter can improve process stability and promote coagulation and stretching of the fibers in connection with cold alkali processes. According to the present disclosure, it is therefore suggested to use a spinneret comprising holes having a diameter of about 80-120 μm, preferably 90-110 μm. For example, in an industrial scale production plant, one spinneret may comprise up to 150 cups of 12.5 to 16mm diameter comprising about 600 to 1400 holes of about 80-120 μm diameter, preferably 90 to 110 μm diameter. The relatively large diameter of the spinning holes results in a different solidification process, i.e. the freshly extruded fibres are first solidified only at the outer surface, while the middle of the fibres remains liquid for a longer time. This enables higher stretching and can maintain the stretching condition in a more stable manner.

The coagulation bath comprises a base (preferably NaOH) and a salt (preferably sodium carbonate Na ₂CO₃ or sodium sulfate Na ₂SO₄). As an example, the coagulation bath may comprise 10 to 30 wt% Na ₂CO₃ or Na ₂SO₄ and 0 to 3 wt% NaOH, preferably 0.1 to 3%, more preferably 0.2 to 0.7 wt% NaOH. In one specific example, the coagulation bath can include about 22 wt% Na ₂CO₃ and about 0.5 wt% NaOH. The temperature of the coagulation bath may be adjusted, for example, to between 10 ℃ and 30 ℃, and is preferably tempered at about 20 ℃.

The optimal distance of the newly extruded fiber through the coagulation bath (i.e., the coagulation bath distance) depends on, among other things, the extrusion speed, the draw speed (pull-off speed), the composition and consistency of the spin dope, the composition and temperature of the coagulation bath. Without being limited to these values, under most parameter conditions, an optimal coagulation bath distance of about 10cm to about 100cm can be found. The preferred value for the coagulation bath distance is from about 15cm to about 60cm.

The fiber tows are pulled from the coagulation bath to a conveying section, which may comprise several godet rolls and/or pulleys, which convey the fiber tows through a series of post-processing stages. The pulling force (pull-off force) applied to the freshly extruded fibers can be adjusted by the extrusion speed and the speed of the first conveying unit (or godet) which can preferably be positioned outside the coagulation bath. The fibers have been drawn in the coagulation bath due to the pulling force exerted on the freshly extruded fibers by the first conveying unit. Further stretching steps may be performed during subsequent processing of the fiber.

In fig. 1, a coagulation bath 10 containing a coagulation liquid 11, a spinneret 12 and a first godet 13 are schematically depicted. The spinneret 12 extrudes a plurality of fibers 14 (corresponding to the number of holes of the spinneret 12) into the coagulation liquid 11. The newly extruded fibers 14 are gathered by the first godet 13 into fiber tows 15. By adjusting the extrusion speed at the spinneret 12 and the speed of the godet 13, the amount of stretching that is accomplished directly after extrusion in the coagulation bath 10 can be set. Although the inclination of the spinneret 12 (and newly extruded fibers 14) is shown in fig. 1, those skilled in the art having the knowledge of the present teachings are able to apply other spinning arrangements known per se in the art, for example from viscose production.

V. post-processing of fiber tows

As used throughout this disclosure, the term "post-processing" includes all processing steps performed on the extruded fiber after the extruded fiber has been removed from the coagulation bath. The post-processing step may be applied to the fiber tow while it is conveyed on the conveying unit. In addition, the fiber tows may be cut in a cutting device and the cut fibers may be subjected to further post-processing steps.

In fig. 1, the post-processing is indicated only schematically by the respective reference sign V.

Post-processing of the fibers may include, but is not limited to, any combination of one or more of the following steps:

Washing the fiber tows and/or cutting the fibers,

Extruding fiber tows and/or cutting fibers to reduce the amount of liquid therein,

Neutralizing the fiber tows and/or cutting the fibers with an acidic liquid,

Bleaching the fibre tows and/or cutting the fibres,

Crosslinking the fiber tows and/or the cut fibers by applying a crosslinking agent to the fibers,

Applying a finish ("soft finish") to the fiber tows and/or the fibers of the cut fibers,

-Drying the cut fibers.

Immediately after the fibers in the fiber tows are removed from the coagulation bath, they have been drawn to some extent, but may not have reached their final elongation (and final cellulose specific diameter).

In a different approach, several successive stretching steps may be performed during the post-processing. For example, countercurrent washing may be performed in a post-process, wherein the fibers in the fiber tows are gradually stretched during and/or between several washing steps until they reach their final elongation.

According to another method, the fiber tows may be introduced into a conditioning bath containing 10 to 30 wt% of a salt that promotes further coagulation of the spinning solution, which conditioning bath is preferably separated from any downstream washing facility fluid and drawn into the conditioning bath to the substantially final cellulose specific diameter of the fibers and oriented to substantially their final state. The conditioning bath may contain a coagulation liquid similar to or the same as the coagulation bath liquid. The coagulation speed in the conditioning bath can be regulated by the temperature of the liquid therein, which can preferably be controlled independently of the coagulation bath.

After the second bath, the fiber tows may be washed in a downstream wash line where no additional stretching is applied to the fibers.

Depending on the circumstances (and depending on the requirements), further post-processing steps may be provided in the processing line according to any technically useful configuration.

Fig. 2 is a schematic block diagram showing an exemplary configuration of a post-processing facility for processing fiber tows produced in accordance with the present disclosure, such as by the facility depicted in fig. 1.

The fibers 14 are extruded through a spinneret 12 into a coagulation liquid 11 in a coagulation bath 10 and are gathered into fiber bundles 15 (similar to fig. 1) by a first godet 13. From the first godet 13, the fiber tows are directed to a second godet 18. Between the first godet 13 and the second godet 18, the fiber tows 15 are diverted via guides 16, e.g., rolls, bars, etc., and immersed in a conditioning bath 17 containing coagulation liquid 11'. The coagulation liquid may be the same as or similar to coagulation liquid 11 in coagulation bath 10. Preferably, the coagulation liquid 11 in the coagulation bath 10 and the coagulation liquid 11' in the conditioning bath 17 circulate in a common fluid circulation. Preferably, the temperature of the coagulation liquid 11' in the conditioning bath 17 can be controlled independently of the temperature of the coagulation liquid 11 in the coagulation bath 10. In general, higher temperatures are preferred for the coagulation liquid 11' in the conditioning bath 17. For example, the temperature of the coagulation liquid 11 in the coagulation bath 10 may be adjusted to a value between about 10 ℃ and about 20 ℃, and the temperature of the coagulation liquid 11' in the conditioning bath 17 may be adjusted to a value between about 20 ℃ and about 40 ℃.

Between the first godet 13 and the second godet 18 and substantially within the conditioning bath 17, the fibers in the fiber tows are drawn to substantially their final cellulose specific diameter and oriented to substantially their final state.

In fig. 2, only one conditioning bath is shown. Nevertheless, it is possible to install more than one conditioning bath, for example two successive conditioning baths or a series of successive conditioning baths. Preferably, the conditioning bath shares the same fluid circuit with the coagulation bath and has substantially the same or at least similar salt and/or alkali content. The temperature of the conditioning bath may be the same or independently controlled, as the case may be. Depending on the configuration, the fibers may be drawn, for example, in a cascade fashion, i.e., with successive conditioning baths having increasing draw ratios. The fibers may also be drawn in an upstream conditioning bath (or several upstream conditioning baths) to substantially their final state and then further coagulated and "set" at a constant rate and draw in the downstream conditioning bath(s). Those skilled in the art having the benefit of the teachings disclosed herein are able to optimize the number of conditioning baths, their temperature and elongation as assessed by routine testing and experimentation without departing from the scope of the present disclosure. The fiber parameters such as tensile strength, elongation, crystallinity, etc. can thus be optimized in an organized manner.

From the second godet 18, the fiber tows 15 are directed to a washing line 19, which may include several washing steps, which are exemplarily depicted as washing steps 20 and 20' in fig. 2. The washing circuit 19 may also comprise only one washing step 20 or any number of washing steps exceeding two, as the case may be. In addition, any washing technique known per se in the art for washing fiber tows may be used for washing line 19.

The conveying means for the fiber bundles in the washing line, such as rolls and godet rolls, are run at a constant speed to keep the tension substantially constant and no further stretching of the fibers in the fiber bundles takes place. This also maintains the orientation of the fibers substantially in the state they leave the second godet 18 after being stretched in the conditioning bath.

After washing the line 19, the fibre tows 15 are led to a cutter 21, which cuts the fibre tows into staple fibres 22. During the washing step 20, the consistency of the fibers is already sufficiently stable that the fibers substantially maintain their specific cellulose diameter, elongation and orientation even if they are cut in a wet state or never-dried state. Accordingly, the fiber tows 15 do not have to be dried prior to cutting, which can reduce costs and enable more efficient post-processing steps.

In the lower part of fig. 2, an exemplary post-processing facility for cutting short fibers (cut staple fibers) is shown. The cut staple fibers are conveyed (or dropped) from the cutter 21 to a fleece forming apparatus 23 having a tank 24 filled with a liquid (e.g., water) and a conveyor belt 25. The conveyor belt 25 is liquid permeable and remains flowing (current) in the trough to transport the fibers suspended in the liquid in the trough to the conveyor belt 25 where they are collected and form a nonwoven fibrous layer 26 on the top surface of the conveyor belt 25. The surface of the conveyor belt is inclined and the newly formed nonwoven fibrous layer 26 is output from the liquid to additional conveying equipment (not shown in fig. 2 for simplicity). The newly cut staple fibers 22 should be regularly distributed across the width of the fleece forming apparatus 23 so that the nonwoven fibrous layer 26 has a uniform width and consistency.

After leaving the fleece forming apparatus 23, the nonwoven fibrous layer 26 is pressed in a first pressing apparatus 27a to remove some of the liquid in the nonwoven fibrous layer 26. Several further pressing devices 27b to 27e may be arranged downstream between several processing steps. In particular, the first pressing device 27a, as well as other pressing devices, create natural curls on the fibers in the nonwoven fibrous layer, which is preferred for many fiber applications (appliances).

As shown in fig. 2, the post-processing of the nonwoven fibrous layer 26 includes a neutralizer 28, a bleaching facility 29, a crosslinking facility 30, a finishing facility 31, an opener 32, a dryer 33, and a bagging press 34.

In the neutralizer 28, the fibers, which may still contain alkali residues, are neutralized with an acidic liquid, which may be selected from dilute acetic acid, lactic acid, sulfuric acid, etc. Depending on the particular processing conditions, a neutralization step may not always be necessary.

The fibers in the nonwoven fibrous layer 26 are then bleached in a bleaching facility 29. If appropriate, a further washing step (not shown in fig. 2) may be carried out between the neutralizer 28 and the bleaching plant 29. The water used for this (and any other) washing step may be sent in the form of a counter-current washing system to the washing step upstream of the washing line 19 and/or to the cutter 21.

In the crosslinking facility 30, a crosslinking agent may be applied to the fibers to reduce fibrillation of the fibers and improve fiber processing and handling in the textile chain.

In finishing facility 31, a finish or soft finish may be applied to the fibers.

After dewatering the nonwoven fibrous layer 26 in the pressing device 27e, the nonwoven fibrous layer 26 is fed to an opener 32 which breaks up and opens the structure of the fibrous layer 26 to improve the drying efficiency in a subsequent dryer 33 as well as to improve the further processing of the finished staple fibers.

Reference numerals

Dissolving pulp 1

Pretreatment chemical Source 2

Pretreatment vessel 3

Chemical reservoir 4

Solvent cooling device 5

Pulp cooling device 6

Mixing vessel 7

Degassing filter 8

Cooling jacket 9

Coagulation bath 10

Coagulation liquid 11

Spinneret 12

First godet 13

Fiber 14

Fiber tows 15

Guide 16

Conditioning bath 17

Second godet 18

Washing line 19

Washing step 20

Cutting machine 21

Staple fibers 22

Pile fabric forming device 23

Groove 24

Conveyor belt 25

Nonwoven fibrous layer 26

Pressing device 27

Neutralizer 28

Bleaching plant 29

Crosslinking facility 30

Finishing facility 31

Opener 32

Dryer 33

Packing press 34

Claims (16)

1. A process for producing regenerated cellulose fibers comprising extruding a spinning solution comprising cellulose dissolved in an aqueous solvent comprising NaOH and ZnO into a coagulation bath comprising a salt and preferably a base to produce fiber tows, the coagulation bath having a pH of at least 7, wherein the process comprises at least the steps of:

a. cutting the fiber tows into cut fibers in an undried state,

B. suspending the cut fibers and collecting them in the form of a nonwoven fibrous layer,

C. Pressing the nonwoven fibrous layer thereby imparting a natural crimp on the fibers.

2. The method of claim 1 wherein the fibers in the fiber tows are drawn to substantially their final cellulose specific diameter and oriented to substantially their final state prior to cutting into staple fibers in an undried state.

3. The method according to claim 1 or 2, wherein after leaving the coagulation bath, the fiber tows are fed into at least one conditioning bath comprising 10 to 30 wt% of a salt that promotes further coagulation of the spinning solution, the conditioning bath preferably being separated from the downstream wash line fluid, wherein the fibers in the fiber tows are drawn in the at least one conditioning bath to substantially their final cellulose specific diameter and oriented to substantially their final state.

4. A method according to claim 3, wherein the coagulation bath and the conditioning bath are fluidly connected, wherein the temperature of the coagulation bath and the temperature of the conditioning bath can preferably be set, adjusted and/or maintained independently.

5. The method according to any one of claims 1 to 4, wherein the fiber tow is conveyed through a washing line comprising at least one washing step, wherein the washing line is preferably arranged downstream of the at least one conditioning bath, and wherein the tension of the fiber tow and the cellulose specific diameter of the fibers are preferably kept substantially constant in the washing line.

6. The method according to any one of claims 1 to 5, wherein the method further comprises at least one step selected from the group consisting of:

Preferably washing the fiber tows or the nonwoven fiber layer with water,

Neutralizing the fiber tows or the nonwoven fiber layer with an acidic liquid, wherein the acidic liquid is preferably selected from dilute acetic acid, lactic acid, sulfuric acid, and the like,

Bleached tows or nonwoven fibrous layers,

Applying a cross-linking agent to the fiber tows or the nonwoven fiber layer,

Applying a finish, in particular a soft finish, to the fiber tows or the nonwoven fiber layer,

Drying the nonwoven fibrous layer, preferably in a drum dryer or a conveyor dryer,

-Pressing the fibre tows or the nonwoven fibre layer before and/or after any other processing step.

7. The method of any one of claims 1 to 6, wherein the post-processing further comprises at least one step of opening the nonwoven fibrous layer to loosen and/or at least partially separate fibers.

8. A processing plant for producing regenerated cellulose fibres, comprising a spinneret for extruding a spinning solution comprising cellulose dissolved in an aqueous solvent comprising NaOH and ZnO into a coagulation bath comprising salt and preferably alkali to produce fibre tows, the coagulation bath having a pH of at least 7, wherein the processing plant comprises a cutter to cut the fibre tows into cut fibres in an undried state, fleece forming means for suspending the cut fibres and collecting them in the form of a nonwoven fibre layer, and at least one pressing means for pressing the nonwoven fibre layer, whereby natural crimp is applied on the fibres.

9. The processing facility of claim 8, wherein the facility further comprises at least one drawing device for drawing the fibers in the fiber tows to substantially their final cellulose specific diameter and orienting the cellulose in the fibers to substantially their final state.

10. The processing facility according to claim 8 or 9, wherein the facility further comprises at least one conditioning bath downstream of the coagulation bath, preferably fluidly separated from the downstream wash line, and at least one drawing device for drawing the fibers in the fiber tows to substantially their final cellulose specific diameter and orienting the cellulose in the fibers to substantially their final state within the at least one conditioning bath.

11. The processing facility according to claim 10, wherein the coagulation bath and the conditioning bath are fluidly connected, wherein the temperature of the coagulation bath and the temperature of the conditioning bath can preferably be set, adjusted and/or maintained independently.

12. The processing plant according to any one of claims 8 to 11, wherein the fiber tows are conveyed through a washing line comprising at least one washing step, wherein the washing line is preferably arranged downstream of the at least one conditioning bath, and wherein the tension of the fiber tows and the cellulose specific diameter of the fibers are preferably kept substantially constant in the washing line.

13. The processing facility of any one of claims 8 to 12, wherein the facility further comprises one or more treatment facilities independently selected from the group consisting of

One or more washing devices for washing the fiber tows or the nonwoven fiber layers,

One or more further pressing devices for pressing the fiber tows or the nonwoven fiber layers,

A neutralizer for neutralizing the cut or uncut fibers with an acidic liquid,

Bleaching means for bleaching cut or uncut fibres,

Crosslinking means for applying a crosslinking agent on the cut or uncut fibres,

Finishing means for applying a finishing agent, in particular a softening finishing agent, to cut or uncut fibres,

An opener for opening the nonwoven fibrous layer to loosen and/or at least partially separate the cut fibers,

-A dryer, preferably a drum dryer or a conveyor dryer, for drying the fibers.

14. Regenerated cellulose fibers produced in a processing facility according to any one of claims 8 to 13 and/or by a method according to any one of claims 1 to 7.

15. A product, in particular a consumer product or an intermediate product, comprising regenerated cellulose fibers according to claim 14.

16. A consumer product according to claim 15, wherein the product is selected from the group consisting of yarns, fabrics, textiles, household textiles, clothing, nonwovens, hygiene products, upholstery, technical applications, such as filtration materials, paper.