Method of producing dissolving pulp, dissolving pulp and use of method

Abstract

A method of producing dissolving pulp from a recycled fibrous feedstock. The method comprises providing a fibrous material comprising cellulose, lignin and hemicellulose, said fibre source further having a lignin content of 0.1 to 7% lignin and an ash content of up to 3%; subjecting the fibrous material to an alkaline extraction at a temperature of about 0 to 25° C., to produce fibres having a reduced content of hemicellulose; subjecting the fibres thus obtained to a bleaching treatment carried out with oxidative chemical reagents in order to reduce the lignin content of the fibres; and recovering the fibres thus obtained. By means of the method, dissolving pulp can be produced from recycled paper and cardboard products.

Description

The present invention relates to dissolving pulps. In particular the invention concerns a method of producing dissolving pulps according to the preamble of claim 1.

In a method of the present kind, a cellulosic feedstock is subjected, optionally after a pretreatment step which comprises reducing the content of lignin or hemicelluloses or both, to cold alkaline extraction.

The present invention also relates to uses of the method.

The demand for dissolving pulps has increased during the recent years. In particular, dissolving pulps are much sought for as raw-material for special fibres, and since the demand has surpassed the supply, the price of suitable dissolving pulp stocks has soared. At the same time, the supply of competing raw-materials, such as cotton, has been limited.

Typically dissolving pulps are produced directly from wood raw-materials by suitable cooking methods which are particularly tailored for making dissolving pulps. There are also disclosed in literature various approaches for converting industrial paper pulps into dissolving pulp, e.g. extraction with alkaline agents and optionally enzymatic treatments with hemicellulases to remove hemicelluloses, such as xylan, from the pulps. In this respect reference is made to Hyatt, J., Fengel, R., Edgar, J. & Alvarez, M., Process for the co-production of dissolving-grade pulp and xylan and International Patent Application No. WO 9816682.

U.S. Pat. No. 6,254,722 discloses a method of producing dissolving pulps from cellulosic fibers, more particularly from recycled waste paper formed by envelope clippings and ledger papers, wherein the fibre source is subjected to an extraction with aqueous sodium hydroxide in order to remove or degrade hemicelluloses at a temperature of about 23° C.

Thus, the method is based on a specific kind of cellulosic, in practice lignin-free raw-material which is not particularly abundant.

WO 2010/104458 is directed to a process for combining the production of cellulosic fiber products from virgin lignocellulosic fibres such as wood and straw in a kraft, sulfite or soda AQ pulp mill with a process for dissolving cellulose using a new solvent system wherein at least a part of the spent cellulose solvent chemicals are recovered in one or more unit operations in the pulp mill chemical recovery cycle.

EP 0 637 351 discloses the preparation of a variety of wood-free and white paper products from recyclable paper and card products having low lignin content.

It is an aim of the present invention, to provide dissolving pulps from recycled cellulosic fibres which are available in large volumes and which form an inexpensive feedstock.

In particular it is an aim of the present invention to provide dissolving pulps from recycled cellulosic fibres that are already degraded in terms of mechanical properties and that typically contain difficult to remove compounds and dirt.

The present invention is based on the concept of using as a cellulosic feedstock for the production of dissolving pulps or similar fibrous products, which are capable of being subjected to dissolution with dissolving reagents, recycled or circulated papers or cardboards which contain cellulose, lignin and hemicelluloses. The recycled or circulated papers or cardboards may also contain fillers, metals, fines and other impurities. Such a feedstock is modified, if necessary, to provide a fibrous raw-material having a low to modest lignin content and a low ash content. The fibrous raw-material is then subjected to cold alkaline extraction to reduce hemicelluloses concentration, and to a bleaching treatment with an oxidative chemical reagent to reduce lignin content, and the fibrous material thus obtained is recovered as pulp.

The method can be used for preparing pulp for the production of regenerated cellulosic fibres, films and foams, impregnated fiber products, and for the production of cellulosic derivatives, and for the production of nanocellulosic products. Particularly interesting applications are in the field of production of regenerated cellulosic products by the viscose process, NMMO process, enzymatic processes and the carbamate process.

More specifically, the method of the present invention in mainly characterized by what is stated in the characterizing portion of claim 1.

The uses according to the present invention are characterized by what is stated in claims 17 to 19.

Considerable advantages are obtained by the present invention. Thus, is has been found that recycled fibres for paper and cardboard products serve well as raw-material for dissolving pulps. Based on results obtained, dissolving pulps produced by the present technology have properties comparable with or even superior to the commercial reference pulps used for reference. For example recycled fluting pulp gave dissolving pulps having excellent properties in terms of the Fock value and could be used for producing regenerated fibres, as evidenced by excessive spinning testing, and films.

Also uncoated fines papers (office papers) were useful and gave good results when the pulp was dissolved using dissolution chemicals such as carbamic acid.

The present invention which utilizes recycled fibers for preparing dissolving pulps represents an important step toward a more sustainable and non-polluting textile industry.

The present invention provides for the manufacture for other products than e.g. paper, cardboard and similar traditional products which are prepared from the instant raw-materials. The cellulose material of the used fibres can be recovered and subjected to chemical modification to provide cellulose chemicals or regenerated fibre. These targets place high demands on the quality of the cellulose.

In the present invention, recycled fibres which exhibit mechanical properties which are weakened and which typically contain substances and impurities and dirt which are difficult to remove. Conventionally, dispersion of recycled fibres aims at decomposing printing ink and sticky compounds and other impurities to smaller compounds and to remove them from the fibres to allow for removal from the fibrous pulp at a later stage. These kinds of conventional processing steps are not sufficient to provide fibres suitable for the above mentioned aims, such as dissolving pulp.

Next the invention will be examined in more detail with reference to a number of working examples.

In the attached drawings,

FIG. 1 shows the process scheme for an embodiment of a method of preparing dissolving pulp from deinked fine paper according to the present technology;

FIG. 2 shows the corresponding process scheme for an embodiment of a method, according to the present technology, of preparing dissolving pulp from cardboard; and

FIG. 3 shows schematically a spinning line consisting of three godet rolls, one stretching bath with hot demineralised water, two washing baths with cold demineralised water and a fibre collector.

As discussed above, the present method of producing dissolving pulp from a recycled fibrous feedstock, comprises in combination the following steps:

• • providing a fibrous material comprising cellulose, lignin and hemicellulose, said fibre source further having a lignin content of 0.1 to 7% lignin and an ash content of up to 3%;
  • subjecting the fibrous material to an alkaline extraction at a temperature of about 0 to 25° C., to produce fibres having a reduced content of hemicellulose;
  • subjecting the fibres thus obtained to a bleaching treatment carried out with oxidative chemical reagents in order to reduce the lignin content of the fibres; and
  • recovering the fibres thus obtained.

In a preferred embodiment, the recycled fibrous feedstock is selected from recycled paper and recycled cardboard products and combinations thereof which comprise at least 1%, typically at least 5%, and in particular about 7 to 50%, by weight of lignocellulosic fibre materials. Examples of suitable feedstock materials are the following: office papers and other fine papers which typically are uncoated, envelopes papers, single layered or multilayered cardboards, fluting and liner sheets of corrugated boards, and folding box boards. In a particular embodiment, the recycled papers are selected from office papers, and the recycled cardboard products are selected from liner clippings. As will be discussed below, the recycled paper or cardboard product can be deinked in conventional manner before further processing.

The fibrous material typically comprises at least 50% by weight of cellulosic fibres. The fibres can consist of up to 100% by weight of cellulose (woodfree) fibres. Typically, the fibres of the fibrous material are formed by mixtures of fibres obtained from chemical and mechanical pulping. In one embodiment, the fibrous material comprises 50 to 95% by weight of fibres of chemical pulping and 5 to 50% by weight of fibres of mechanical pulping. The fibres of the mechanical pulping are generally rich in lignin, the concentration of which may be up to 20% by weight of the dry fibres.

The cellulosic fibres of the fibrous material can be derived from deciduous tree, coniferous tree or combinations thereof. Examples of deciduous tree species include birch, aspen and other species of the Populus genus, alder, eucalyptus, mixed tropical wood and mixtures of the above mentioned species. Examples of coniferous tree species include spruce and pine and mixtures thereof.

Preferably at the most 70%, in particular at the most 60%, by weight of the fibre source consists of fibres derived from deciduous tree.

In an embodiment, the fibrous material comprises the recycled fibrous feedstock as such.

In a another embodiment, the fibrous feedstock comprises recycled paper or recycled cardboard products or combinations thereof having an original ash content of up to 10% or more, for example up to 20%, which have been subjected to pretreatment for reducing the ash content to less than about 3, in order to provide said fibrous material. In such an embodiment, the feedstock can be subjected to a mechanical or chemical operation, for example by fine classification or sieving, to lower the content from about 10 to 20% to 3% or less.

In still another embodiment, which can be combined with the previous one, the fibrous feedstock comprises recycled paper or recycled cardboard products or combinations thereof having an original lignin content of up to 20% by weight, which is subjected to chemical delignification for reducing the lignin content to less than 10% by weight, in particular less than 5% by weight, in order to provide said fibrous material.

The pre-processing can be effected for example by an alkaline treatment using hydroxide or carbonate compounds, such as alkali metal or earth alkaline metal hydroxides or carbonates or combinations thereof. In particular, the delignification can be carried out by kraft pulping, soda pulping typically or oxygen delignification, preferably at an increased temperature (of 50-200° C.). The kraft pulping or soda pulping are typically carried out about 140-180° C. and the oxygen delignification at 80-120° C.

During the alkaline conditions of the pre-treatment, also the hemicelluloses content will be reduced.

In a third embodiment which can be combined with both of the two earlier embodiments, the fibrous feedstock is first subjected to a preliminary step involving removal of impurities, washing or, in particular, deinking or pulping, for example for removing polymer films or coatings. This embodiment is applicable to printed matter made of paper and cardboard, alike.

Next, the fibrous material obtained, comprising the recycled feedstock or comprising the recycled feedstock which has been treated as explained above for reducing the ash and lignin content, is subjected to alkaline extraction (cold alkali extraction).

Typically, the cold alkali treatment is carried out by mixing the fibrous material with an alkali solution, for example with a concentrated alkali solution, so as to obtain a mixture containing from about 50 and up to 200 g/l, in particular 50 to 150 g/l of the alkali. The solution is allowed to be absorbed into the fibrous material at a temperature of 0 to 40° C., preferably 10-25° C. The alkali dissolve hemicelluloses from the fibrous material and the hemicellulose containing solution is separated from the fibrous material and separately recovered.

The obtained fibrous mass can be used as such as a dissolving pulp.

However it can also be subjected to a bleaching treatment carried out with oxidative chemical reagents and subsequent alkaline extraction in order to reduce the lignin content of the fibres. Various bleaching treatment employing oxygen, peroxide and peroxo acids, chlorine dioxide, hypochlorite and ozone can be employed.

The fibres recovered after bleaching are subjected to a chemical treatment for increasing accessibility of the cellulosic fibres, which treatment is preferably carried out with an enzyme selected from the group of endoglucanases, or with hypochlorite.

In another embodiment, the recovered fibres, optionally after a chemical treatment for increasing accessibility of the cellulosic fibres, are subjected in an aqueous slurry to acid treatment, whereby the pH of the slurry is less than 3.5.

Turning now to the drawings, FIG. 1 depicts a specific embodiment of a method for preparing dissolving pulp from deinked fine paper.

The first stage shown in the drawing is designated “Super DDJ filtration”. The aim of this stage is to remove inorganic impurities (decreasing ash content) from the pulp. The second stage is the cold caustic extraction stage (CCE). By this treatment, hemicelluloses, especially xylan, are removed. The treatment of the deinked fine paper is continued by three-stage bleaching sequence, (DEpD) for removing residual lignin and to increase the pulp brightness and purity. After bleaching, preparation is continued by enzymatic treatment with endoglucanase (EG). The targets of this stage are to increase the pulp reactivity and to adjust the viscosity (or degree of polymerisation). The final, fifth step is acid washing (A). The objective of this stage is the removal of metals from the pulp.

FIG. 2 shows the treatment stages of cardboard.

The first stage of the preparation of dissolving pulp from the cardboard is Super DDJ filtration. Just as in the embodiment of FIG. 1, the aim of this stage is to remove inorganic impurities (decreasing ash content). The second stage in the process is an alkaline soda cooking. This stage removes lignin and hemicelluloses. Processing is then continued with cold caustic extraction stage (CCE). The objective of this stage is to remove hemicelluloses, especially xylan. The treatment of cardboard is continued by three-stage bleaching sequence, (DEpD) for removing the residual lignin and to increase the pulp brightness and purity. After bleaching, preparation is continued by enzymatic treatment with endoglucanase (EG). The targets of this stage are to increase the pulp reactivity and to adjust the viscosity (or polymerisation degree). Finally, just as in the procedure of FIG. 1, the obtained pulp is acid washed (A) in order to remove metals. Typically acid wash is carried out at a pH of below 3.

As a result of a process according to the present invention, fibres are recovered which exhibit at least one of the following properties:

• • a lignin content of less than 0.7% by weight, in particular a lignin content of 0.3 to 0.6% by weight;
  • a viscosity of 250 ml/g or more, preferably 550 ml/g or more;
  • a Fock value of 55% or better;
  • cellulose 90% or more; and
  • a R18% value of 88% or better

Typically, the fibres exhibit a hemicellulose content of 0.1 up to 10% by weight. A method as discussed above produces a dissolving pulp which can be used in the production of regenerated cellulosic fibres, films and foams, impregnated fiber products, and for the production of cellulosic derivatives, and for the production of nanocellulosic products.

Specifically, the pulp can be used for the production of regenerated cellulosic products for example by regeneration processes selected from the group of viscose process, NMMO process, enzymatic processes and the carbamate process.

In a particular embodiment, the method and the pulp can be used for the production of regenerated cellulosic products by carbamate process of a mechanochemical solvent free dry technique. In this respect reference is made in particular to the methods disclosed in U.S. Pat. No. 7,662,953 and U.S. Pat. No. 8,066,903, the contents of which is herewith incorporated by reference.

The following non-limiting examples illustrate the present technology.

Materials and Analysis Methods

The fibre raw material used in Example 1 was deinked fine paper and that in Example 2 was recycled cardboard. The detailed fibre compositions of the raw materials are presented in Table 1. The deinked fine paper had the following fibre composition: about 90% of wood free pulp fibres and 10% of wood containing pulp fibres. In the recycled cardboard the composition ratio wood free pulp fibres to wood containing pulp fibres was about 70:30.

TABLE 1
Fibre composition of recycled raw materials
	wood free pulps	wood containing pulps
	Bleached	Softwood	Semichemical/	Mechanical/
	hardwood	(unbl.)	CTMP	CTMP	Softwood:Hardwood
	kraft, %	kraft, %	hardwood, %	softwood, %	ratio
Fine paper	62	30	2	6	36:64
Cardboard	26	41 (27)	33	—	41:59

The chemical composition and other properties of the raw materials used in the experiments are presented in Tables 2 and 3. Due to the higher portion of wood containing pulp fibres in the cardboard, it had higher lignin, extractives and cellulose content, and lower brightness than the fine paper. The fine paper was deinked and therefore it had lower ash content, and the pulp brightness was higher.

TABLE 2
Chemical composition of recycled raw materials
			Extrac-		Gluco-
	Cellulose %	Lignin %	tives %	Xylan %	mannan %
Fine paper	76.6	2.4	0.2	15.9	4.9
Cardboard	57.6	16.6	5	14.5	6.3

TABLE 3
Properties of recycled raw materials
	Bright-	Kappa	Viscosity	Ash at	Ash at
	ness %	number %	ml/g	525° C. %	900° C. %
Fine paper	79.9	8.7	800	2.0	1.4
Cardboard	32.8	82.7	740	7.9	6.0

The properties of the raw materials and the produced pulps in Example 1 and 2 were analysed using the methods described in Table 4.

The polysaccharide composition, i.e. content of cellulose, xylan and glucomannan, was calculated based on Janson's method /1/.

In these calculations, the fine paper was supposed to consist of 64% of chemical hardwood fibres (birch) and 36% of chemical softwood fibres (pine).

The composition of the cardboard was supposed to be 59% of chemical hardwood fibres and 41% of chemical softwood fibres.

R18 analysis was used to measure alkali resistance of the pulp. It tells the amount of fibre material which does not dissolve to 18% NaOH solution at room temperature during one hour.

The Fock method was used to describe the reactivity of dissolving pulp /2/. In this method pulp is dissolved in an excess of NaOH and CS₂. Cellulose xanthate is formed and a certain amount of the xanthate is thereafter regenerated. Finally the cellulose yield was determined.

TABLE 4
Analysis methods used for raw materials and produced pulps
Fibre composition     internal based on microscopy
Chemical composition:
acetone extract       SCAN-CM 49: 03
lignin                TAPPI-T 222 om-02 modif
carbohydrates         SCAN-CM 71: 09
content of cellulose, Based on Janson J., Analytik der
xylan and glucomannan Polysaccharide in Holz und Zellstoff,
                      Faserforschung und Textiltechnik 25, 1974,
                      p. 375-382.
Ash content:
525° C.               ISO 1762: 2001
900° C.               ISO 2144: 199
Brightness            ISO 2470-1: 2009 from splitted sheet
Kappa number          ISO 302: 2004
Viscosity             ISO 5351: 2010
Metal content         wet combustion (the samples are dissolved
                      in nitric acid in a microwave oven before
                      the analysis) + ICP-AES
R18                   ISO 699: 1982
Fock                  Based on Fock, W., Das Papier 13(3), p.
                      92-95, (1959).

The produced dissolving pulps were dissolved using carbamate treatment. After the carbamate treatment the wet spinning was performed. Table 5 shows the methods used in analysing the carbamated pulps and carbamate solutions. Table 6 shows the methods used for analysing the wet spun fibres.

TABLE 5
Analysis method used for carbamated
pulps and carbamate solutions
DP degree of polymerization the viscosity is determined according to
                            ISO 5351: 2010 to evaluate the DP on
                            the empirical basis (Gullichsen, J.,
                            Paulapuro, H, Papermaking Science and
                            technology, Fapet 2000/3/)
Nitrogen content            Kjeltek device
Degree of purity of         by washing and by measuring the
the carbamate pulp          content of residues
Viscosity of the carbamate  conventional ball method (Sihtola, H.
solution                    Paperi ja puu 44(1962): 5, pp. 295-
                            300/4/) and/or by a Brookfield
                            viscometer
Fibre residue of the        microscopically by using a subjective
solution                    scale from 1 to 5 in such a way that 1:
                            clear solution with no fibres and %:
                            turbid solution containing a lot of whole
                            fibres, fibre bundles and/or gel-like
                            structures

The wet spun fibres were tested as follows: The fibres were conditioned at a relative humidity of 65 and temperature of 20° C. for at least 24 h. The mechanical properties were determined as an average of 20 measurements according to the ISO 1973 and ISO 5079 standards using a Vibroskop and Vibrodyn testing machines (Lenzing AG). The tests included titre, tenacity, elongation, Young's modulus at 1% elongation and work of rupture. The rate of elongation was 20 mm min-1 and the gauge length 20 mm.

EXAMPLE 1

Preparation of Dissolving Pulp from Deinked Fine Paper

The treatment stages of the deinked fine paper are presented in FIG. 1.

The first stage of the preparation of dissolving pulp from deinked fine paper was Super DDJ filtration. The aim of this stage was to remove inorganic impurities (decreasing ash content) from the pulp. Raw material was diluted (about 0.5-1% consistency) and filtrated using a tank with a 200-mesh wire and a mixer. This procedure was repeated eight times. Ash content decreased from 2.0% to 0.6%.

The second stage was cold caustic extraction stage (CCE). The objective of this stage was the removal of hemicelluloses, especially Xylan. Extraction stage was carried out at room temperature using 70 g NaOH/l alkali concentration and 10% consistency for one hour. After CCE stage pulp was washed five times by diluting it to 5% consistency with cold deionised water and dewatering it to about 15% consistency. After that the pulp was diluted to 4% consistency and pH was adjusted to 7. The next day the pulp was dewatered to 25-30% consistency.

The treatment of the deinked fine paper was continued by three-stage bleaching sequence, (DEpD). The target of the bleaching was to remove the residual lignin and to increase the pulp brightness and purity. Bleaching conditions are shown in Table 6.

TABLE 6
Bleaching conditions for DEpD sequence
	D0	Ep	D1
	ClO2 charge as act. Cl, %	1.5		1.0
	NaOH charge, %		0.9	0.1
	H2O2 charge, %		0.5
	Reaction time, min	60	60	120
	Temperature, ° C.	60	75	70
	Consistency, %	9	10	9

In D-stages preheated pulp was added to the reactor first and after that water and acid or alkali (for pH adjustment). After mixing pH was measured, and chlorine dioxide was charged into the reactor, and the cover of the reactor was closed immediately. During the reaction time the pulp was mixed. After the reaction time, final pH was measured from the pulp in the reaction temperature. The residual chlorine content of the bleaching filtrate was determined. The pulp was diluted and washed in a standard way.

In hydrogen peroxide assisted alkaline extraction stage (Ep) the pulp and most of water was heated to the reaction temperature in a microwave oven and placed into the reactor. Alkali and hydrogen peroxide with additional water was charged and the pulp slurry was mixed and pH was measured. During the reaction time the pulp slurry was mixed. After the reaction time, final pH was measured from the pulp in the reaction temperature. The residual hydrogen peroxide content of the bleaching filtrate was determined. The pulp was diluted and washed in a standard way.

Washing between bleaching stages was always a standard laboratory washing: Pulp was diluted to 5% consistency with deionized water, which temperature was the same as that of the preceding bleaching stage. After dewatering, the pulp was washed two times with cold deionized water with amount equivalent to ten times the absolutely dry pulp amount.

After the bleaching, preparation was continued by enzymatic treatment with endoglucanase (EG). The targets of this stage were to increase the pulp reactivity and to adjust the viscosity (or degree of polymerisation). Enzyme charge was about 6 ml/kg. At first the pulp and part of water were heated to the reaction temperature in a microwave oven and placed into the reactor. Then pH of the pulp was adjusted with sulphur acid to pH value of 5. Enzyme was mixed with the rest of the preheated water and added into reactor. Reaction conditions were as follows: 50° C., 9% consistency and 120 minutes. After the reaction time pulp was washed with hot water (>85° C.) by diluting pulp to 4% consistency (retention time 10 minutes). After dewatering, the pulp was washed two times with cold deionized water with amount equivalent to ten times the absolutely dry pulp amount.

The next step was acid washing (A). The objective of this stage was the removal of metals from the pulp. Acid wash was carried out at pH 2.5, room temperature and in 2.5% consistency. Sulphur acid was used for pH adjustment. The pulp was diluted and washed in a standard way. The last preparation stage was drying of the pulp. Drying was carried out over night in an oven having temperature of about 40° C.

Preparation procedure described above gave dissolving pulp, which had alkali resistance of 93.9%, reactivity of (according to Fock method) 62.9%, viscosity of 510 ml/g, xylan content of 4.8%, lignin content of 0.2%, extractives content of 0.08% and ash content of 0.04%. These properties are rather typical or even better than those with commercial dissolving pulps. Only the pulp reactivity was slightly lower and the xylan content higher. The properties of the produced dissolving pulp are presented in Tables 7 and 8.

TABLE 7
Chemical composition of dissolving pulp
produced from deinked fine paper.
			Extrac-		Gluco-
	Cellulose %	Lignin %	tives %	Xylan %	mannan %
Fine paper	90.4	0.2	0.08	4.8	4.3

TABLE 8
Properties of dissolving pulp produced from deinked fine paper.
			Viscos-	Ash at	Ash at
	Bright-	Kappa	ity	525° C.	900° C.	R18	Fock
	ness %	number	ml/g	%	%	%	%
Fine	87.1	0.9	510	0.05	0.04	93.8	62.9
paper

EXAMPLE 2

Preparation of Dissolving Pulp from Cardboard

The treatment stages of cardboard are presented in FIG. 2.

The first stage of the preparation of dissolving pulp from the cardboard was Super DDJ filtration. The aim of this stage was to remove inorganic impurities (decreasing ash content). Raw material was diluted (about 0.5-1% consistency) and filtrated using a tank with a 200-mesh wire and a mixer. This was repeated eight times. Ash content decreased from 7.9% to 1.4%.

The second stage was alkaline soda cooking. The target of this stage was the removal of lignin and hemicelluloses. Cooking conditions were as follows: NaOH charge 20%, cooking temperature 165° C., H factor 1000 and liquor to wood ratio 6. After cooking stage pulp was washed and then the delignification was continued with oxygen delignification stage. Process conditions were as follows: 12% consistency, 100° C. temperature, 4% NaOH charge, 13.5 bar oxygen pressure and 95 minutes reaction time. After the oxygen delignification the pulp was washed.

Processing was continued with cold caustic extraction stage (CCE). The objective of this stage was to remove hemicelluloses, especially Xylan. Extraction stage was carried out at room temperature using 70 g NaOH/1 alkali concentration and 10% consistency for one hour. After CCE stage the pulp was washed five times by diluting it to 5% consistency with cold deionised water and dewatering it to about 15% consistency. After that the pulp was diluted to 4% consistency and pH was adjusted to 7. The next day the pulp was dewatered to 25-30% consistency.

The treatment of card board was continued by three-stage bleaching sequence, (DEpD). The target of the bleaching was to remove the residual lignin and to increase the pulp brightness and purity. Bleaching conditions are shown in Table 9.

TABLE 9
Bleaching conditions for DEpD sequence
	D0	Ep	D1
	ClO2 charge as act. Cl, %	1.0		0.4
	NaOH charge, %		0.9	0.05
	H2O2 charge, %		0.5
	Reaction time, min	60	60	120
	Temperature, ° C.	60	75	70
	Consistency, %	9	10	9

In D-stages preheated pulp was added to the reactor first and after that water and acid or alkali (for pH adjustment). After mixing pH was measured, and chlorine dioxide was charged into the reactor, and the cover of the reactor was closed immediately. During the reaction time the pulp was mixed. After the reaction time, final pH was measured from the pulp in the reaction temperature. The residual chlorine content of the bleaching filtrate was determined. The pulp was diluted and washed in a standard way.

In hydrogen peroxide assisted alkaline extraction stage (Ep) the pulp and most of water was heated to the reaction temperature in a microwave oven and placed into the reactor. Alkali and hydrogen peroxide with additional water was charged and the pulp slurry was mixed and pH was measured. During the reaction time the pulp slurry was mixed. After the reaction time, final pH was measured from the pulp in the reaction temperature. The residual hydrogen peroxide content of the bleaching filtrate was determined. The pulp was diluted and washed in a standard way.

Washing between bleaching stages was always a standard laboratory washing: Pulp was diluted to 5% consistency with deionized water, which temperature was the same as that of the preceding bleaching stage. After dewatering, the pulp was washed two times with cold deionized water with amount equivalent to ten times the absolutely dry pulp amount.

After the bleaching, preparation was continued by enzymatic treatment with endoglucanase (EG). The targets of this stage were to increase the pulp reactivity and to adjust the viscosity (or degree of polymerisation). Enzyme charge was about 6 ml/kg. At first the pulp and part of water were heated to the reaction temperature in a microwave oven and placed into the reactor. Then pulp pH was adjusted with sulphur acid to 5. Enzyme was mixed with the rest of the preheated water and added into reactor. Reaction conditions were 50° C., 9% consistency and 120 minutes. After reaction time pulp was washed with hot water (>85° C.) by diluting pulp to 4% consistency (retention time 10 minutes). After dewatering, the pulp was washed two times with cold deionized water with amount equivalent to ten times the absolutely dry pulp amount.

Next pulp was acid washed (A) in order to remove metals. Acid wash was carried out at pH 2.5, room temperature and in 2.5% consistency. Sulphur acid was used for pH adjustment. The pulp was diluted and washed in a standard way. The last preparation stage was drying of the pulp. Drying was carried out over night in an oven having temperature about 40° C.

Preparation procedure described above gave dissolving pulp, which had alkali resistance of 90.7%, reactivity of (according to Fock method) 81.1%, viscosity of 250 ml/g, xylan content of 4.2%, lignin content of 0.6%, extractives content of <0.05% and ash content of 0.11%. These properties are rather typical or even better than those of commercial dissolving pulps. The xylan content of the pulp was higher, and also the lignin content was slightly higher than that of the commercial dissolving pulp (<0.5%). The properties of the produced dissolving pulp are presented in Tables 10 and 11.

TABLE 10
Chemical composition of dissolving pulp produced from cardboard
			Extrac-		Gluco-
	Cellulose %	Lignin %	tives %	Xylan %	mannan %
Cardboard	91.2	0.6	<0.05	4.2	3.8

TABLE 11
Properties of dissolving pulp produced from cardboard
			Viscos-	Ash at	Ash at
	Bright-	Kappa	ity	525° C.	900° C.	R18	Fock
	ness %	number	ml/g	%	%	%	%
Cardboard	85.9	0.6	250	0.11	0.08	90.7	81.1

EXAMPLE 3

Treatment of the Dissolving Pulps (Example 1 and 2) Using Carbamate Method and Wet Spinning

Carbamate Treatment

The obtained dissolving pulps (Example 1 and 2) were treated using carbamate method /5, 7/. In this method is first prepared carbamate cellulose which is then dissolved in NaOH-solution which is finally spinned and regenerated into fibres. The carbamation synthesis is done in dry state with urea. The urea feed is 20% calculated from dry pulp. Dissolving is performed in two steps, first by moistening cellulose carbamate pulp with a dilute alkaline solution, as cold as possible, to the pulp under intensive stirring. The technique utilizes the low freezing point of the aqueous NaOH solution at the concentration of 18%, wherein the freezing point is below −20° C., and the intensive stirring function of the dissolve mixer device during the dosage. It is possible to prepare solutions of high quality and having high dry matter content in a mixing time of a few minutes only.

Table 12 indicates the characteristics of pulps after of the carbamate reaction. DP (Degree of polymerization) gives an estimate of the mechanical and physical properties of the final product (e.g. fibres and films) and it is the main adjustable parameter in the process. The higher the DP level, the more diluted solutions must be used, if the level of viscosity is limited because of application technique (here fiber spinning) The optimal DP level and cellulose content must be found separately in each case. Normally, on the manufacture of regenerated fibres, the desired DP level is in the range from 200 to 400. N % the nitrogen content of the solution indicates the degree of substitution. The degree of substitution refers to the average number of substituent attached to one glucose unit.

TABLE 12
Characteristics of pulps after carbamate reaction
	Carbamated pulp grade	DP	N %
	Fine paper	289	1.5
	Cardboard	290	2.2
	ref commercial dissolving pulp	330	1.2

Wet Spinning

The fibres were spun using a laboratory wet spinning machine /6/. The spin dope was pushed from a sealed reservoir to a gear pump by nitrogen gas. The spinning head with one spinneret was immersed in a vertical spin bath tank. The spinneret used had 100-250 orifices of 45-51 lm and was made of a gold/platinum material. The spinning line consisted of three godet rolls, one stretching bath with hot demineralised water, two washing baths with cold demineralised water and a fibre collector (FIG. 3). A solution of sodium lauryl sulphate (0.1%) was used to lubricate the godet rolls I, II, III during spinning.

Table 13 shows the common processing and material parameters for the laboratory wet spinning trials.

TABLE 13
Common processing and material parameters
of example spinning trials
Cellulose concentration %        6.3
Solution NaOH %                  8.5
Solution ZnO %                   1
Solution temperature C.          2
Spin bath temperature C.         20
Spin bath content                8% H2SO4, 10% Na2SO4
Solution ball viscosity s (T 20° C.) 20
Solution turbidity NTU           <50
Filtering sieve figure μm        10
Spinneret n × d - μm             100 × 51
Line speed VIII m/min            20

Table 14 shows the processing stretch ratio, fibre titre and mechanical properties of the fibres obtained in wet spinning

TABLE 14
Processing stretch ratio, fibre titre, and
mechanical properties of example fibres
	Stretch	Titre	Tenacity
Pulp grade	ratio %	(dtex)	(cN/dtex)	Stretch %
Fine paper	60	2.42	1.93	21
	80	2.31	2.02	20
	100	1.97	2.00	17
	120	1.86	2.07	16
Cardboard	60	2.55	1.72	22
	80	2.40	1.83	20
	100	2.06	1.91	18
	140	1.99	1.97	16
Ref commercial dissolving pulp	60	2.58	1.98	21
	80	2.10	2.01	18
	100	1.97	2.14	15
Ref viscose/6/		1.9	2.1

Summarizing the above, it can be noted that the process of the present technology comprises in a preferred embodiment a stage for removing inorganic impurities, a cold caustic extraction stage for the xylan extraction, bleaching with oxidative chemicals for delignification and to increase the pulp brightness and purity, a stage to increase the reactivity of pulps and to adjust pulp viscosity (or degree of polymerisation), and finally acid washing for metals removal. For the raw material having high initial lignin content additional delignification stages can be carried out using alkaline delignification agents.

With the technology disclosed, including the above purification procedure, dissolving pulps having alkali resistance (R18) and cellulose content of over 90% and reactivity of 60 to 85%, in particular 63 to 81%, measured using Fock method, can be prepared.

The dissolving pulps thus obtained have very good mechanical properties. During testing it has been found that the tenacity of fibers is approximately the same as for native dissolved reference cellulose made from commercial dissolving pulp and approximately the same as for existing commercial viscose nonwoven fibers. “Approximately” stands for a variation of max.±10%.

A particular use for the dissolving pulps prepared from recycled fibers is as a raw-material for the carbamate process.

As is apparent from the above, the present invention achieves considerable advantages. It has surprisingly been found that by means of the present invention recycled fibres, even mechanically degraded and weakened fibres, selected from but not limited to recycled or circulated papers or cardboards containing cellulose, lignin and hemicelluloses, further containing fillers, metals, fines and other impurities that are typically difficult to remove, serve well as raw material for dissolving pulps. Based on the examples given, dissolving pulps produced by the present technology have properties comparable with or even superior to the commercial reference pulps used for reference.

REFERENCES

• 1. Janson J., Analytik der Polysaccharide in Holz und Zellstoff, Faserforschung und Textiltechnik 25, 1974, p. 375-382.
• 2. Fock, W. Eine modifizierte method zur Bestimmung der Reaktivität von Zellstoffen für viskosherstellung. Das Papier 13(3), p. 92-95, (1959)
• 3. Gullichsen, J., Paulapuro, H, Papermaking Science and Technology, Fapet 2000.
• 4. Sihtola, H. Paperi ja puu 44(1962):5, pp. 295-300.
• 5. U.S. Pat. No. 8,066,903.
• 6. Vehviläinen, M., Kamppuri, T., Rom, M., Janicki, J., Ciechańska, D., Grönqvist, S., Siika-aho, M., Elg Christoffersson, K., Nousiainen, P. Effect of wet spinning parameters on the properties of novel cellulosic fibres, Cellulose (2008) 15:671-680.
• 7. U.S. Pat. No. 7,662,953
• 8. U.S. Pat. No. 6,254,722
• 9. WO2010/104458
• 10. European Patent Application No. 0 637 351

Claims

1. A method of producing dissolving pulp from a recycled fibrous feedstock, comprising the steps of

providing a fibrous material comprising cellulose, lignin and hemicellulose, said fibre source further having a lignin content of 0.1 to 7% lignin and an ash content of up to 3%;

subjecting the fibrous material to an alkaline extraction at a temperature of about 0 to 25° C., to produce fibres having a reduced content of hemicellulose;

subjecting the fibres thus obtained to a bleaching treatment carried out with oxidative chemical reagents in order to reduce the lignin content of the fibres; and

recovering the fibres thus obtained.

2. The method according to claim 1, wherein the recycled fibrous feedstock is selected from recycled paper and recycled cardboard products and combinations thereof which comprise at least 1% by weight of lignocellulosic fibre materials.

3. The method according to claim 1, wherein the fibrous material comprises the recycled fibrous feedstock or is produced therefrom.

4. The method according to claim 1, wherein the fibrous material comprises at least 50% by weight of cellulosic fibres.

5. The method according to claim 1, wherein the fibrous material comprises 50 to 95% by weight of fibres of chemical pulping and 5 to 50% by weight of fibres of mechanical pulping.

6. The method according to claim 1, wherein the cellulosic fibres are derived from deciduous tree, coniferous tree or combinations thereof.

7. The method according to claim 1, wherein the fibres recovered after bleaching are subjected to a chemical treatment for increasing accessibility of the cellulosic fibres.

8. The method according to claim 1, wherein the recovered fibres are subjected in an aqueous slurry to acid treatment, whereby the pH of the slurry is less than 3.5.

9. The method according to claim 1, wherein the fibrous feedstock comprises recycled paper or recycled cardboard products or combinations thereof having an original ash content of up to 10% or more, which have been subjected to a mechanical or chemical operation for reducing the ash content to less than about 3, in order to provide said fibrous material.

10. The method according to claim 1, wherein the fibrous feedstock comprises recycled paper or recycled cardboard products or combinations thereof having an original lignin content of up to 20% by weight, which have been subjected to chemical delignification with an alkaline cooking chemical for reducing the lignin content to less than 10% by weight in order to provide said fibrous material.

11. The method according to claim 10, wherein the delignification is carried out by kraft pulping, soda pulping or oxygen delignification.

12. The method according to claim 1, wherein said bleaching is carried out with oxidative chemicals selected from the group of peroxides and peracids, chlorine dioxide, hypochlorite and ozone and combinations thereof.

13. The method according to claim 1, wherein the recycled papers are selected from office papers, and the recycled cardboard products are selected from liner clippings.

14. The method according to claim 1, wherein the fibres recovered exhibit at least one of the following properties:

a lignin content of less than 0.7% by weight;

a viscosity of 250 ml/g or more;

a Fock value of 55% or better;

cellulose 90% or more; and

a R18% value of 88% or better

15. The method according to claim 1, wherein the fibres recovered exhibit a hemicellulose content of 0.1 up to 10% by weight.

16. A dissolving pulp produced by a method according to the steps of:

providing a fibrous material comprising cellulose lignin and hemicellulose, fibre source further having a lignin content of 0.1 to 7% lignin and an ash content of up to 3%;

subjecting the fibrous material to an alkaline extraction at a temperature of about 0 to 25° C., to produce fibres having a reduced content of hemicellulose;

subjecting the fibres thus obtained to a bleaching treatment carried out with oxidative chemical reagents in order to reduce the content of the fibres; and

recovering the fibres thus obtained.

17. (canceled)

18. (canceled)

19. (canceled)