The invention relates to a method and a system for isolating xylan from plant material, and xylan. The invention also relates to calcium carbonate and cellulose fibre. The invention further relates to the use of xylan prepared by a method according to the invention as an auxiliary agent or additive, preferably in the manufacture of cellulose based fibre, in papermaking, in a food product, or in a cosmetics product, as well as the use of xylan as a thickening agent, an emulsifier or a coating agent.
Hemicelluloses are heteropolysaccharides which are present in plants and are typically water soluble and amorphous. Together with lignin they control the water content in the cell walls of plants. The content and composition of hemicelluloses vary between different plants. For example in trees, the content of hemicellulose is typically about 20 to 35 weight percent of the dry weight of the wood, and the main types of wood hemicelluloses are glucomannan and xylan. In industry, hemicelluloses can be used as such or they can be refined to e.g. sugars. The use of hemicelluloses is limited by the fact that is typically difficult to isolate them from plant material with a good yield.
The present invention discloses a new method and system for isolating xylan from plant material, preferably hardwood, as well as xylan, cellulose fibre and calcium carbonate isolated by the method. Further, the use of xylan isolated by a method according to the invention as an additive, preferably in the manufacture of cellulose based fibre, in papermaking, in a food product, or in a cosmetics product, as well as the use of xylan isolated by the method according to the invention as a thickening agent, an emulsifier or a coating agent are disclosed.
The present invention makes it possible to isolate xylan from plant material that contains xylan, in a cost efficient way. In the approach according to the invention, inexpensive substances such as sodium hydroxide (NaOH), carbon dioxide (CO2) and calcium hydroxide (Ca(OH)2) are typically used for isolating xylan from plant material.
The method according to the invention for isolating xylan will be presented in claim 1. The xylan according to the invention will be presented in claim 9. The cellulose fibre according to the invention will be presented in claim 10. The calcium carbonate according to the invention will be presented in claim 11. The system according to the invention for isolating xylan will be presented in claim 12. The use of xylan according to the invention will be presented in claims 13 to 17.
The method according to the invention comprises one or more of the steps listed hereinbelow: In other words, the invention comprises one, two, three, four, five, six, seven, eight, nine, ten, eleven, or all the twelve steps described below:
The system according to the invention comprises:
In the method according to the invention, xylan is isolated from plant material that contains xylan, advantageously from hardwood. Preferably, xylan is isolated from birch and/or eucalyptus. The plant material, from which xylan is isolated, is preferably chemically treated for reducing the content of lignin. In other words, the material is preferably chemically defibrated cellulose fibre or so-called pulp.
Thanks to the sodium hydroxide used in the extraction, a sufficient content of xylan can be dissolved into the extraction solution and clearly better compared with, for example, dissolving xylan by means of calcium hydroxide. By the method according to the invention, it is possible to achieve an industrially applicable, cost effective process for isolating xylan from plant material that contains xylan, preferably from hardwood. Precipitated calcium carbonate and cellulose fibres are also obtained as products in the same process. Advantages of the invention include, among other things, typically cheap auxiliary chemicals, such as CO2, Ca(OH)2 and alum which may be used as an auxiliary in the flocculation of xylan, as well as the recyclability of NaOH used in the extraction of the pulp, for re-use.
Xylan prepared by the method according to the invention can be used, for example, as an auxiliary agent in the process of manufacturing paper or paperboard. Xylan can also be used, for example, in a food product, in a cosmetics product, as a thickening agent, as an emulsifier, or as a coating agent.
In the following, the invention will be described in more detail with reference to the appended drawing, in which
In this application, reference is made to
In the present application, the term “extraction solution” refers to the solution used for extraction, the so-called solvent, into which one or more compounds are transferred from the source material during the extraction. The extraction solution used is sodium hydroxide 15.
In the present application, the term “extract solution” 17 refers to the solution that contains said extraction solution and xylan.
In the present application, the term “brightener” 18 refers to the solution that contains sodium carbonate.
In the present application, the term “xylan-containing cellulose fibre” 10 refers to untreated plant fibres that contain xylan. Most advantageously, the cellulose fibres are softwood fibres, preferably birch fibres and/or eucalyptus fibres. The proportion of hardwood fibres is advantageously at least 80%, more advantageously at least 90% of all the cellulose fibres. Xylan is naturally present, among other things, in the inner parts of hardwood fibres. The content of birch fibres and/or eucalyptus fibres (in dry content) is advantageously at least 50 wt %, more advantageously at least 70 wt % and most advantageously at least 90 wt % of all the cellulose fibres. Advantageously, cellulose fibres from hardwood, preferably birch and/or eucalyptus, are used.
Bleached birch pulp is an excellent source of xylan. In birch, xylan is particularly pure, because 98% of the hemicelluloses in birch consist of xylan. Furthermore, birch has an exceptionally high content of xylan, and therefore the yield of xylan obtained from birch is high, up to about 10% of the dry content of the wood. Thanks to this, for example hardwood pulp consisting of unrefined or slightly refined chemically defibrated wood fibres can be used in the approach according to the invention.
The cellulose fibres according to the invention may comprise unrefined, slightly refined, and/or wet beaten cellulose fibres. According to an advantageous example, the Schopper-Riegler (SR) value of the cellulose pulp used as the fibre raw material is in the range of 10 to 40, for example 15 to 30.
In the alkali extraction step 20, cellulose fibres are extracted with sodium hydroxide 15 for dissolving xylan from said fibres in the extraction solution, wherein xylan from the cellulose fibres is dissolved in the extraction solution. Thus, xylan is typically dissolved from the inner parts of the fibres as well. Cellulose fibres made by the method according to the invention have a reduced xylan content. According to an advantageous example, the extraction of xylan is continued until 2 to 100%, more advantageously 5 to 50%, and preferably 7 to 25% of the xylan in the fibres has been extracted from the fibres into the extraction solution.
According to an advantageous example, the extraction 20 is performed at a fibre consistency of about 10%, for example 3 to 25%. In an example, the extraction 20 is performed at a fibre consistency of 3 to 5%. In another example, the extraction 20 is performed at a fibre consistency of 5 to 15%.
In the approach according to the invention, xylan is extracted from cellulose fibres by using sodium hydroxide 15. Advantageously, the extraction 20 is performed with 0.25 to 1.25 M sodium hydroxide (NaOH), more advantageously with 0.5 to 1.0 M sodium hydroxide. In an advantageous example, the extraction time at room temperature (for example, at the temperature of 18 to 27° C.) is about one hour, for example 45 to 90 minutes. The pH of the mixture formed after the extraction may be, for example, about 12 to 13.
After this, the extract solution 17 that contains xylan is isolated from the cellulose fibres. This isolation 21 of the cellulose fibres can be carried out, for example, by using a filter, such as a so-called wire cloth. The isolated cellulose fibres 11 having a reduced xylan content are recovered, after which they can be washed. Cellulose fibres made by the method according to the invention and having a low xylan content can be used, for example, in a papermaking process.
Xylan is precipitated 22 by adding a gas that contains carbon dioxide 14, preferably gaseous carbon dioxide 14, to the extract solution that contains xylan after the extraction. From the extract solution, xylan is typically precipitated as a white polymer. Furthermore, as a result of the reaction, sodium carbonate is formed as follows:
2 NaOH+CO2 (g)→Na2CO3 (aq)+H2O.
The degree of purity of the carbon dioxide 14 used for precipitating 22 xylan is preferably between 10 and 100%. The precipitation 22 of xylan with carbon dioxide 14 is performed in such a way that the precipitation step is started in a strongly alkaline extraction solution. As the precipitation proceeds, the pH of the extraction solution decreases, thanks to the addition of carbon dioxide 14. Preferably, the pH of the mixture is maintained alkaline (pH>7) during the whole precipitation of xylan. Advantageously, carbon dioxide 14 is added until the pH of the mixture is between 7.5 and 10.5, preferably between 9 and 10. In an example, the precipitation 22 of xylan is intensified by adding a component for intensifying the precipitation to the mixture. In an example, so-called alum or cationic polyacrylamide (PAM) is added as a flocculating agent to the solution.
After this, the remaining solution, i.e. the so-called brightener 18, and xylan 12 are separated from each other as well as possible in the xylan isolating step 23. The step 23 of isolating precipitated xylan 12 can be carried out, for example, by allowing the brightener 18 that contains precipitated xylan 12 to settle for several hours, for example 1 to 8 hours. Thus, precipitated xylan 12 settles onto the bottom of the settling space, such as a container, from which said settled xylan 12 is recovered. Alternatively, the step 23 of separating precipitated xylan 12 can be carried out, for example, by centrifugation. In addition or alternatively, the step 23 of separating precipitated xylan 12 can be carried out, for example, by applying a filtering technique.
The isolated precipitated xylan 12 can be treated further, for example, by washing with a liquid, advantageously with water and/or acetone and/or ethanol. The precipitated xylan can also be subjected to a so-called dialysis treatment for removing salts.
Finally, the dry content of xylan 12 is preferably increased again until the dry content reaches a predetermined level. Preferably, the drying is carried out by so-called spray and/or freeze drying.
To the remaining brightener 18, calcium hydroxide 16 is added for precipitating 24 calcium carbonate. Preferably, the mixture is stirred after the addition of calcium hydroxide 16. After this, the mixture can be allowed to settle. Finally, the precipitated calcium carbonate precipitate 13 is isolated.
The content of calcium hydroxide to be added can be, for example, about 0.5 mol per mol of NaOH. In an example, the content of calcium hydroxide to be added is 0.2 to 1.0 mol per mol of NaOH. The addition of calcium hydroxide 16 to the brightener 18 not only precipitates calcium carbonate but also converts sodium carbonate, formed in connection with the precipitation of xylan, into sodium hydroxide. The reaction, in which the calcium hydroxide 16 reacts with the formed sodium carbonate in such a way that precipitated calcium carbonate (PCC) 13 and sodium hydroxide 15 are obtained as the final products, is the following:
Na2CO3+Ca(OH)2→2 NaOH+CaCO3.
As a result of the reaction, the pH typically rises to a value of about 13.
The reaction conditions, by which it is possible to affect the particle size and quality (temperature, pH, time, concentration, among other things) of PCC 13 are preferably determined in such a way that the desired, predetermined particle size and shape of PCC 13 are obtained.
After the precipitation 24 of calcium carbonate, the dry content of the precipitated calcium carbonate is increased; that is, sodium hydroxide 15 is removed from the mixture, for isolation 25 of calcium carbonate. This can be carried out, for example, by a filtering technique or by centrifugation. Preferably, the removed sodium hydroxide is recovered and recycled in part or in whole.
The sodium hydroxide 15 recovered from the process can be re-used, for example, for the extraction of xylan, or it can be conveyed to another process, or it can be recovered for another further use. Said filtrate recovered from the process can be treated, to increase the degree of purity of the sodium hydroxide.
Thanks to the invention, it is possible to separate xylan from plant fibres, preferably hardwood fibres. At the same time, in the process according to the invention, precipitated calcium carbonate and cellulose fibres may be produced for industrial needs. The sodium hydroxide 15 needed in the process according to the invention can be recirculated at least partly in the process. The method according to the invention is particularly suitable for isolating xylan from bleached birch pulp and/or eucalyptus pulp. In an example, the extraction of xylan is performed in connection with the bleaching of the fibre, preferably in connection with the last bleaching step.
The invention is not limited solely to the examples presented in
Number | Date | Country | Kind |
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20125345 | Mar 2012 | FI | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FI2013/050338 | 3/26/2013 | WO | 00 |