DE3213856C2 - Process for delignifying a chemically produced cellulose pulp - Google Patents

Abstract

When using gaseous oxygen and alkali to delignify and bleach a chemical cellulose pulp, it is not possible to remove more than about half the amount of lignin that remains in the cellulose pulp after cooking, because of the risk of intense and uncontrollable degradation of the carbohydrates in the Cellulose pulp is made. According to the invention it is now possible to remove three quarters of the amount of the remaining lignin while maintaining good pulp properties; The present invention relates to a process for delignifying a chemical cellulose pulp, in which the pulp is brought into contact with a gas phase containing NO ↓ 2 in an activation stage and gaseous oxygen is supplied to the activation stage, so that the nitrogen oxide formed as an intermediate product is used to activate the Pulp is exploited and the activation step is carried out under severe conditions, which is characterized in that the pulp is then subjected to an oxygen gas / alkali treatment process in a pulp / water mixture, the partial pressure of the gaseous oxygen during the oxygen gas / alkali treatment process is maintained at 0.005 to 0.18 MPa and the partial pressure of the gaseous oxygen does not fall below the lower partial pressure limit during any part of the treatment process.

Description

The present invention relates to a method for bleaching chemically produced cellulosic pulps especially alkaline and cooked pulps. Alkaline cooked pulps are e.g. B. sulfate, polysulfal and soda pulps. The term soda pulp includes pulps made with sodium hydroxide as a cooking chemical have been digested in the presence of various additives. Such additives are z. B. Redox catalysts, like anthraquinone. The present invention can also be applied to other cellulose chemical pulps, z. B. sulfite pulps, may be used.

Clarke [in Paper Trade Journal, Tappi Sect. 118, 62 (1944)] has found that cellulose pulp partially can be delignified by leaving the pulp in an aqueous suspension for 1 to 1.5 hours at 90 ° C treated with nitrogen dioxide and then 30 minutes at 90 ° C or 60 minutes at 50 ° C at pulp concentration of 7% and an alkali concentration corresponding to 2% NaOH, calculated on the dry weight of the Pulp, extracted.

This treatment leads to a very high degradation of the cellulose, which is reflected in a pulp viscosity, which in comparison to that of a pulp, which is subjected to chlorination and alkali extraction has been, is extremely small.

The FR-PS 21 58 873 reports a depolymerization by means of a delignification process that In the Treatment with nitrogen dioxide at low temperatures, preferably temperatures below 20 "C. and for a long period as well as a subsequent alkali extraction under mild conditions. The level of However, delignification is very low and the process does not solve current environmental problems. at The treatment conditions used require very high additions of nitrogen dioxide, for example 9.5% based on dry pulp. Even so, only about 40% of what is available can be used with normal kraft pulps Llgnlns to be removed. The process is therefore uneconomical.

In CA-PS 10 70 909 is a two-stage process has been described in which the pulp with nitrogen dioxide is pretreated and then subjected to a bleaching step with gaseous oxygen. This method however, leads to a significant reduction in viscosity, although it is the achievement of a high Malles of delignification made possible.

For environmental reasons it is important to have an economic Finding method that eliminates the need for chlorination of a cellulose pulp in the manufacture of bleached chemical pulps.

In practice, pulp bleaching with gaseous oxygen usually requires a high oxygen gas pressure, often used throughout the procedure. The reduction in oxygen gas pressure leads to a decrease in the amount or rate of delignification and a reduced selectivity as viscosity at a given κτ number according to the Bleaching stage with gaseous oxygen. Delignification during treatment under given conditions the oxygen gas stage can be improved if this treatment is preceded by an activating stage, in which the pulp is treated with nitrogen dioxide. Improved selectivity can also be achieved can be achieved by such activation, although it is only possible using previously known methods was. a limited degree of delignification without and without relatively severe depolymerization of the cellulose Use of very expensive equipment to achieve.

So is z. B. in DE-OS 31 22 297 describes a process in which the activation takes place in the presence of water in a nitrogen dioxide-containing gas phase which is obtained by supplying NO and / or NO. In order to use the NO formed as an intermediate for the activation process, oxygen is supplied to the activation stage in liquid form and / or as a gas in such an amount that practically all of the NO and NO ₂ are consumed at the end of the activation stage. In the subsequent bleaching stage, pure oxygen gas is also used, which is produced according to the Linde process and accordingly makes the process more expensive. In addition, with the usual oxygen Pa. partial pressures of 0.5 to 0.8 MPa worked, so that no full selectivity is achieved.

In the procedure described in SE-OS 80 08 374-3 ' activation with nitrogen dioxide is followed by treatment with hot akali. This requires a very high alkali loading and leads to high losses of carbohydrates if the two-stage Process should achieve a low lignin content.

The object of the invention is therefore to provide an economical process for removing cellulose halves provide material that has a high degree of delignification with high pulp yield and high selectivity, d. H. strong reduction of the lignin content while maintaining a high viscosity, enables and also z. B. carried out with air instead of pure oxygen in the bleaching stage with relatively small amounts of alkali can be.

The subject of the invention is the method characterized in the main claim.

A partial pressure of gaseous oxygen of 0.18 MPa during most of the oxygen gas / AI kai i treatment process gives rapid delignification and good selectivity during delignification occurs slowly at 0.005 MPa. A partial pressure below 0.005 MPa affects the brightness of the pulp. The pulp gets a greyish color while a at The pulp treated with a higher oxygen gas pressure turns pure yellow. In addition, the pulp yield decreases. An improved pulp brightness for a given kappa number and an improved selectivity is obtained. when the partial pressure is between 0.015 to 0.09 MPa. If z. B. an unbleached, made of softwood Sulphate pulp is classified as the best Hr results regarding selectivity and brightness a range of 0.03 to 0.09 MPu. By working in this area, even at moderate temperatures, a reasonable residence time in the oxygen gas / alkali treatment step in this treatment step possible.

Changes in the intrinsic molar viscosity of the cellulose pulp, determined according to SCAN, are used as a measure of how far the cellulose molecules are broken down. The values given below were all determined without removal of lignin and hemicellulose, which is the most easily reproducible method in the case of pulps with medium lignin contents (e.g. sulphate pulps with a kappa number below 35). It should be noted, however, that lignin and hemicellulose contribute little to viscosity compared to the same weight of cellulose molecules, and that bleaching is said to reduce the lignin content and also to release the hemicellulose, while the loss of pure cellulose is only under the conditions used is low. In cases where depolymerization of the cellulose is negligible, I increase the intrinsic molar viscosity number. With Fichteiisuifaihalbsiopen the type used in most of the examples of the present application, a decrease in the kappa number by 10 units leads to an increase in viscosity of about 50dm ^! / kg under conditions where depolymerization of the cellulose can be ignored, while a corresponding increase in the case of sulphite and hardwood sulphate pulps is markedly higher because more hemicellulose is lost. Viscosity measurements according to SCAN C 15:62 were used to check that a certain amount of degradation of the cellulose molecules takes place during the activation step; these measurements can be carried out on the activated pulp after washing it with water and rapid drying at 35 ° C. and determining the viscosity immediately.

In the process according to the invention, after its activation and washing with water, the pulp exhibits the same intrinsic viscosity as it had before the activation step, or preferably such an intrinsic viscosity. which is at least 5% lower than the original. An even higher degree of delignification can be achieved if the viscosity is reduced even further, e.g. B. by more than 8%. In the case of the majority of types of pulp, the viscosity during the activation can suitably be increased by 2 to 35%. preferably 5 to 25%, and particularly 10 to 20%. Depolymerization of the activated pulp occurs easily. if you z. B. uses extremely long drying times, extremely high temperatures during the pulp drying process and during storage. Therefore, it is usually not practical in routine work to determine the viscosity immediately after activation.

In practice, it is often expedient to adjust the conditions during the activation so that the halide exhibits the desired viscosity after the treatment process with gaseous oxygen and alkali. In normal cases, a Sauerstüflgas / alkali treatment subjected pulp is suitably an intrinsic viscosity according to SCAN, the 0 to 25 V. ¹ advantageously from 5 to 20% and preferably 10 to 15
is lower than that of the unbleached pulp. These values apply particularly to softwood sulphate pulps. For sulphite and hardwood / sulphate pulps, the preferred viscosity reduction is half of these values.

The nitrogen dioxide present in the activation stage is _{fed to it only in the form of practically pure NO 3} or is allowed to form in the reactor after nitrogen oxide and oxygen have been introduced. You can also introduce NO ₂ plus NO.

The term nitrogen dioxide (NO ₂ ) also includes dinitrogen tetroxide (N ₂ O ₄ ) and other forms of polymers. One mole of nitrous oxide is considered to be equivalent to 2 moles of nitrogen dioxide. Adducts in which nitric oxide is present are calculated in the same way as nitric oxide. For example, nitrous oxide (N ₂ Oj) is considered to be equivalent to 1 mole of nitrogen oxide and 1 mole of nitrogen dioxide. Adducts with oxygen are believed to be present as intermediates.

A given amount of gaseous oxygen must be _{introduced into the activation stage when adding nitrogen dioxide (NO 2} ) as well as nitrogen oxide (NO).

In order to achieve the best possible results with the simplest device, however, it is expedient to introduce the oxygen into the activation stage in the form of practically pure gaseous oxygen. Liquid oxygen can also be fed to the activation stage and vaporized, e.g. B. upon entry into the reactor in which the activation process is carried out. The amount of oxygen introduced into the activation step should be at least 0.05 moles, calculated as O ₂ , per mole of NO _{2 introduced.} In many cases a larger amount is used, expediently 0.1 to 5 moles of O ₂ per mole of NO _{2 used} , in order to achieve the desired result. The best results in a device tested were obtained when the amount introduced was 0.15-0.30 moles of O ₂ per mole of NO ₂ introduced. Liquid nitrogen dioxide is a commercial product that can be introduced into the process in this form. The nitrogen dioxide is expediently evaporated before or in connection with its introduction into the reactor in which the activation step is carried out. Nitrogen dioxide can also be obtained by oxidizing nitrogen oxide with oxygen. Nitrogen oxide is expediently produced by catalytic combustion of ammonia, which expediently takes place in connection with the bleaching plant in which the process according to the invention is carried out. The _{gas phase containing NO 2} is obtained by reacting oxygen with nitrogen oxide before or during the activation stage. Calculated per mole of tip. Guided nitrogen oxide, the total amount of O ₂ introduced should be at least 0.55 mol, advantageously 0.6 to 5 and preferably 0.65 to 0.80 mol of O ₂ . so that both the nitrogen oxide introduced and the nitrogen oxide formed as an intermediate product are utilized in the activation process, and so that practically all of the nitrogen oxide and nitrogen dioxide formed by the nitrogen oxide are consumed at the end of the activation stage.

A mixture of NO and NO ₂ can also be introduced into the activation stage. In this case, the amount of oxygen introduced is adjusted to the amount of each of these nitrogen oxides in accordance with the proportions given above, with Dmers. Polymers and adducts need to be considered in the manner outlined above. The amounts in which the nitrogen oxides (N0 .- + N0) defined above are introduced into the process reaches a total of 3 to 300, expediently 10 to MO and preferably 25 to 75 g-mol. calculated on 100 kg of dry cellulose pulp. The total pressure in the activation reactor is expediently kept at a value below atmospheric pressure, preferably at a value in the vicinity of atmospheric pressure.

To achieve the best activation resultsc and to ensure the lowest possible release of nitrogen oxides from the reactor, it is important that as little inert gas as possible, e.g. B. air, the reactor enters during pulp feed. It was found that entering the activation reactor Amount of the inert gas not more than 50 g-mol, expediently not more than 20 g-mol and preferably 0.05 to 5 g-moles per 1000 kg of completely dry pulp.

A desirable activation effect with subsequent depolymerization of the cellulose during the activation stage is achieved if the temperature is kept at 42 to 100.degree. C., expediently 50 to 90.degree. A lower temperature is normally require uneconomically long treatment time, while a very high temperature ührt ^f in excessive depolymerization of the cellulose. For many pulps, the preferred temperature range is between 55 to 70 ° C. The residence time is adapted to the amount of NO ₂ and / or NO introduced, the activation temperature, the type of pulp and its concentration, and is determined by changing the viscosity according to one of the determined above procedure. When the process is carried out at temperatures within the preferred range of 50 to 90 ° C, the activation time according to the mathematical formulas should be over 10-0.2 (f-50) minutes and shorter than 660-16 (f-50) minutes , where ι is the temperature in ⁰ C. At high pulp concentrations and a high loading of NO ₂ and / or NO, the time should be close to the lower limit, while at low pulp concentrations and low loading the activation time should be increased.

The pulp consistency should be kept at 16 to 50% during the activation stage. The upper Limit may be difficult to reach. The most appropriate range in practice is 22 to 42%, preferably 27 to 36%.

After the activation step, the pulp becomes useful washed with water and / or a suitable aqueous solution. If this washing stage is omitted, then significantly more alkaline neutralizing agent is used in the subsequent treatment process. Instead of washing the pulp with water, or preferably after washing it with Water Is it appropriate to treat the pulp with a solution of an alkaline reagent, e.g. B. a waste bleach liquor or a waste liquor derived from the oxygen gas / alkali treatment stage.

According to a preferred embodiment, the Cellulose pulp after the activation stage with water and / or dilute aqueous solution. under such Washed conditions that an acidic solution is obtained, which is used to wash the pulp after the Cooking, preferably after replacing the cooking pot by a liquor obtained from the other alkaline stage, can be used.

Regardless of whether the pulp after the activation stage was washed with water or an aqueous solution to obtain an acidic solution, or whether this Washing has been omitted, it is advisable to wash the pulp with an alkaline solution, expediently at a temperature of 40 to 80 ° C before the oxygen / alkali treatment stage.

In principle, the half-stole can have a low consistency during the oxygen gas / alkali treatment stage, /. B. from 3 to 8%. This requires the recycling of large amounts of waste liquor from this stage and thus leads to an expensive nail burn. One can also use a high-consistency bleaching pulp from which the excess free liquid, ι. B. by pressing to a material consistency of over 22%. / .. B. 27 to 35% or more, has been removed. This can be particularly useful when the necessary equipment is available, e.g. For example, if the process according to the invention is used in an existing bleaching plant with gaseous oxygen, or in other processes for the treatment of highly concentrated substances.

An even better selectivity was achieved with a semi-finished product of average consistency, namely a consistency of 8 to 22%, using a relatively simple fschCP. A ⁿⁿ i ^l .nUyr Cr / iCl ·. AM ^ Crst tfünslluf * Frunhnl ^ sp were obtained with a pulp consistency of 10 to 20%, although the pulp was sticky at the upper limit. Laboratory tests in a rotating autoclave showed that the preferred range of keel sulfate pulp is 12-18%.

Although the conditions during the activation stage are sharp, one can be surprising according to the invention employ mild conditions in the oxygen gas / alkali treatment stage and still use a strong one Delignification in a simple and cheap device without guiding the selectivity and thus the Achieve properties of the papleres produced from the pulp. As shown in the examples, the Delignification to be continued to more than 60%, expediently to more than 70%. combined in both stages, wherein the intrinsic viscosity of the pulp during the oxygen gas / alkali stage is less than 20% or, if milder conditions are used, less than 10%. A requirement in this regard Is it that the oxygen gas pressure, the alkali charge and the temperature adjusted so that delignification does not occur too quickly. the Dwell in the oxygen gas / alkali stage is conveniently longer than is normally the case in current plants common. In the case of delignification to more than 60%. preferably to more than 70%, the time should be 30 to 300, expediently 45 to 240 and preferably 60 to 180 minutes. If only low requirements the degree of delignification and selectivity are set or in the case of pulps that can be quickly dellgnified, z. B. sulfite pulps, a shorter time can be used. Length of treatment times increase the Plant costs, however, lead to increased selectivity.

That in the oxygen gas / alkali treatment process The alkali used is preferably sodium hydroxide. According to a preferred embodiment of the present Invention can a waste liquor containing lignin residues after replenishing with freshly supplied Alkali can be used in the oxygen gas / alkali treatment process. The amount of sodium hydroxide introduced is adapted to the amount of water present during this treatment stage, so that the concentration of the free sodium hydroxide 1 to 30, expediently 3 to 20 and preferably 4 to 10 g of free NaOH per kg is water present during the alkali treatment. If there is no waste liquor from the alkali treatment process is returned to the system and the pulp is thoroughly washed with water after the activation stage

scr is washed, then the amount of free sodium hydroxide present is equal to the total introduced Amount of sodium hydroxide. Is waste caustic / around the system / urUckgel 'and if the half-tunnel remaining Contains alkali from the alkaline washing stage, or if If the IlalbsiolT contains nitric acid, then the concentration of free sodium hydroxide as the amount of alkali delineated, which is obtained in the half-stole immediately after the addition of this alkali, whereby this amount through potentiometric titration with hydrochloric acid to pH 9 The alkali used may be different from the above and e.g. B. a catfish liquor or oxidized white liquor. Is sulfide in the alkali charge present, then the sulphide can be removed by precipitation before the concentration is reached free sodium hydroxide determined by titration.

The treatment temperature in the oxygen gas / alkali stage has proven to be a less critical variable orwii '"on; iU 7eM. .Sauersinffeasdruck and alkali thickening. In the case of pulps with a low content of carboxyl groups and hemicellulose, e.g. B. softwood sulphate pulps, a suitable temperature is between 50 and 140 ° C., preferably 90 to 120 ° C.

The temperature range from 85 to Ι0Γ C can be appropriate with llalbstoffen with a high content of carboxyl groups or hemicellulose, e.g. With sulfite pulps and hardwood sulfate pulps.

With <"by special use of the invention Process can use gaseous oxygen in a conventional manner during the oxygen gas / alkali treatment process introduced into the system, d. H. once during this stage, e.g. D. at one point during a continuous process. When bleaching a pulp with a high pulp consistency, e.g. B. a consistency of 25 to 36%. the concentration of gaseous oxygen is equalized in a bleaching tower, and gaseous oxygen is constantly brought into contact with the pulp and supplied to it, how it is consumed. When bleaching low consistency pulp, e.g. B. one by 3 to 22%, it is often necessary to keep the pulp / water mixture in place during all or part of the oxygen gas / alkali treatment process keep moving in order to improve the oxygen transfer into the liquid phase, this agitation of the pulp / water mixture z. B. by stirring means, advancing means such as screws and scrapers, and / or by moving the bleaching device, e.g. B. their rotation is achieved.

Gaseous oxygen is expediently mixed intensively with the pulp by adding it to a introduces rapidly rotating mixer, the gaseous oxygen then reacting with the pulp while the pulp / water mixture is passed through the bleaching tower (e.g. upwards this) is carried out. In order to avoid exhaustion of the gaseous oxygen, it is expedient and im In the case of intensive delignification it is often necessary to disperse the gaseous oxygen at two or more intervals or throughout the oxygen gas / alkali treatment process.

To achieve a high degree of selectivity in the process and at the same time a treated pulp with great brightness, it is convenient to control the pressure of the gaseous oxygen during the initial stage of the oxygen gas / alkali treatment process to a lower value than it Pressure this gas at a later stage of this

ι j ο_ »υ

IO

Procedure is. It is therefore often advisable that the Partial pressure of the gas In the final stage of this procedure higher than the pressure during most of the initial stage. So can / B. during the initial stage the oxygen gas / alkali treatment process uses air at atmospheric pressure, z. B. during an initial period of 5 to 30 minutes, whereupon gaseous oxygen with the Ilalbstoll / Wasser-M-ichung is mixed so that its partial pressure in the gas phase z. B. at OJS MPa or preferably 0.09 MPa or less. Through these measures, the process necessary for the oxygen gas / alkali treatment Time Compared to treatment of the pulp with air at atmospheric pressure during the Entire oxygen gas / alkali treatment process can be shortened considerably. The mentioned pressure in this stage refers to the pressure in the device. In which the oxygen gas / alkali treatment is carried out. In the case of pumps, heavy-duty mixers and decorating, usually at least 20%, preferably at least 25% and expediently 30 to 80%, calculated on the basis of the quantity of lignin prior to this oxygen gas / alkali treatment process, be.

To reduce the extent to which the cellulose becomes depolymerlsicrl and the loss of hemicellulose during the oxygen gas / alkali treatment process To keep the alkali to a minimum, it is advisable during this treatment process to reduce the alkali progressively, either intermittently or continuously, as the process progresses. These Mode of operation has proven itself in the preferred embodiment Proven to be very effective, in which the substance consistency to 8 to 22, expediently 10 to 20 and preferably 12 to 18%. In this case it is expedient, at least 50% of the amount for the donation process introduce required alkalis prior to commencing the oxygen gas / treatment process; or this percentage of alkali should be used during the first

N, ii'l wctCFicii uic iidiuaiüiiVcFwciiZcii ^-:; j tMinüicn diVwcscFiu if, among other things, SäüCFSiöffgäS / Aika-

Less than 60 seconds or preferably less than 30 seconds, a higher pressure of the gaseous Oxygen can be admitted without the selectivity and other advantages of the present process leading. The process can also be followed by further bleaching with gaseous oxygen under usual conditions Conditions at high oxygen gas pressure follow. This is particularly useful when the device for Carrying out such a bleaching process is already installed and if the requirements for strength properties des halbsiolTes are lower than U.η require far.

In many cases it has proven to be useful the pulp after the activation step, a hot alkali treatment process without intended To subject the introduction of an oxygen-containing gas before the pulp then the oxygen gas / alkali

subject to

This! S ¹

A particularly useful measure if the alcohol is to be subjected to a further bleaching process after this oxygen gas / alkali treatment process. If the pulp is to be delignified to a high degree, a simplified device can also be used according to the invention, in particular if the pulp is to be subjected to an oxygen gas / alkali treatment process without washing after the hot alkali treatment process. A saving in gaseous oxygen can also be achieved if the pulp is not washed. A further oxygen saving is possible if the waste liquor after the hot alkali stage, z. By pressing and / or washing the pulp, although this method usually gives less beneficial effects than the preferred embodiments. in which the pulp / water mixture is passed directly from the hot alkali treatment stage to the oxygen gas / alkali treatment stage. The hot alkali treatment stage is expediently carried out at a temperature which is approximately the same as the temperature of the subsequent oxygen gas / alkali treatment stage, e.g. B. a temperature of 80 to 135 ° C, expediently 95 to 125 ³ C and preferably 101 to 120 ⁰ C. Carrying out this hot alkali treatment leads to increased selectivity. In order to achieve a good selectivity and at the same time a high yield and a high degree of brightness of the deügnified pulp after the oxygen gas / alkali treatment process, the degree to which the pulp is delignified in the oxygen gas / alkali stage should

li delignification process begins. Meddling of the alkali during the duration of the process is expedient if the oxygen ring gas with the alcohol / water mixture mixes or afterwards.

Regardless of whether or not Alkall is used during the period in which the Procedure takes place, is introduced or not, the pH of the bleaching plant should normally be in the range from 9.0 to 12.5, suitably from 9.5 to 11.5 and preferably 10.0 to 11.2 are kept by following Him controlled continuously or from time to time. The values refer to measurements at room temperature.

The pulp treated according to the invention can be used directly for paper manufacture. Often it is however, it is better to subject the pulp treated according to the invention to a final bleaching step, wherein it is preferable to use bleaches which are harmless to the environment, e.g. B. bleaches such as chlorine dioxide. Peroxide and ozone.

The invention of the invention of a chemical Cellulose pulp has numerous advantages. A crucial factor in the present invention is that the process is both environmentally friendly and highly selective, and Compared to conventional ones Bleaching process saves energy.

In a comparison between the method according to the invention and a conventional identification method, in which a cellulose pulp is bleached with chlorine and then treated with alkali, shows that the method according to the invention is essential Is more environmentally friendly. When using the invention The waste liquors can be recovered and combined with the cooking waste liquor in one process conventional soda recovery boilers can be evaporated and burned without any effort. This is included when bleaching Chlorine not the case.

Compared to a bleaching process with gaseous oxygen without activation with nitrogen oxides the process according to the invention shows a much higher selectivity, i. i.e., it enables the removal of significantly more lignin from the cellulose pulp while maintaining a high viscosity.

Compared to the treatment of a cellulose pulp with nitrogen dioxide and then hot According to the invention, it is possible to delignify the pulp to a much greater extent with alkali treatment processes, while maintaining a high pulp

Il

yield and using less alkali. A KicfersulfathalbstolT with a kappa number of 31 in one stage according to the invention with a loss of carbohydrate from 2 to 2.5% to a kappa number of 8 dellgnlllzleri, while in a single stage Treatment with nitric oxide and hot alkali to get the same kappa number about twice as much Carbohydrate is consumed. When using the inventive. With this kappa number, you get a brightness of 55 according to ISO, while a Treatment of the pulp with: nitric oxide in the same Catfish and subsequent hot alkali treatment of the pulp gives a brightness of 35 according to ISO. The pulp treated according to the invention was yellow in color, while that according to the usual method treated pulp was grayish. This is shown in the Tappis standard procedure T524 om-79 Color measurements. In the method according to the invention, with a kappa number of 10, the Values (CIE) L * - 86.6. a * = -2.0. b * = 27.0 obtained while if the kappa number is the same, the reference method is 74.2. 1.4 and 24.0.

A particular advantage of the method according to the invention over currently known methods is provided in that the oxygen / alkali gasification process is carried out at low oxygen gas pressure in a simple device and that the selectivity is significantly higher than when the normal, customary partial oxygen gas pressure of 0.5 to 0.8 MPa is applied. It is particularly surprising that the pulp can be bleached to lower levels of lignin than this Up to now it was possible without a degradation of the cellulose to such an extent that the properties of the pulp Papleres produced were significantly affected, although the low oxygen gas pressure is used.

Another advantage of the method according to the invention is the possibility of air in whole or in part during the oxygen gas / chemical treatment process to use, while with other methods the use of air is not possible or at least is inexpedient. In the case of processes other than the process according to the invention, a highly pure, gaseous oxygen is used, which is produced by the Linde process. According to the invention can with Advantage of gaseous oxygen of a lower concentration, e.g. B. gaseous oxygen, which is 2 to 15% inert Contains gas, and which is produced by other, less expensive processes, can be used.

According to the invention, numerous tests were carried out in parallel with a number of comparative tests. Implementation welfare and results are in the following Examples shown.

Example I.

Technical pine sulphate pulp with a kappa number of 32.1 and an intrinsic viscosity of 1215 dm '/ kg, measured according to SCAN-C 15:62, was washed with water and pressed to a pulp consistency of 36%. The pulp was loosened in a chopper and placed in a reactor ^{at 60 ° C.} The air in the reactor was evacuated, the temperature dropping to 55 ° C. Gaseous nitrogen dioxide obtained by evaporating liquid N ₂ O ₄ was introduced into the reactor over a period of 4 minutes; this addition corresponded to 75 g-moles of NO ₂ per 100 kg of pulp. After the introduction of the nitrogen dioxide, 15 g-Moi of gaseous oxygen were introduced within 4 minutes. The temperature was maintained at 55 ° C. by rotating the reactor in a water bath. The treatment procedure was continued for 120 minutes, calculated from the point at which the nitrogen dioxide supply was started.

After activating the half-fruit for 120 minutes, its viscosity had fallen by 190 dm / kg; then it was washed with water, pressed and kneaded with magnesium sulfate and sodium hydroxide Impregnated.

The oxygen gas / alkali treatment process was carried out in a rotary autoclave at a pulp consistency of 11% and a temperature of 105 ° C with an NaOH charge of 8% and a magnesium sulfate charge equivalent to 0.3% Mg, both charges being calculated on the dry weight of the halftone are. If the gaseous atmosphere in the autoclave comprised air (initial pressure of gaseous oxygen 0.025 MPa and final value 0.0'8 MPa). a kappa number of 9.0 was achieved after 60 minutes. The intrinsic viscosity of the half-molar was 1039 dm '/ kg. compared to a value of 1040 dm '/ kg obtained before this treatment procedure. In a comparison test using the same batch of activated pulp, the pressure of the gaseous oxygen was increased to 0.8 MPa, giving a kappa number of ^1J .O after just 20 minutes. In this case the viscosity fell to 9 ⁷ O dm '/ kg.

These experiments show that when using air at a pressure close to atmospheric Pressure during the oxygen / alkali treatment stage a better selectivity is obtained than when carrying out the treatment with gaseous oxygen a pressure above atmospheric pressure, as is common practice Is :.

Examples 2 to 4

The Haibsiof! became like in example! treated, whereby however, the temperature in the activation stage is set to 52X and semi-sour consistency and alkali loading into the oxygen gas / alkali treatment process were changed to 16 and 10%, respectively. If the gaseous atmosphere comprised air, after 30 Minutes a kappa number of 9.0. The viscosity was 1105 compared to 1160 after the activation step. At a partial pressure of the gaseous oxygen of 0.12 MPa, this kappa number was already after 15 minutes achieved. The viscosity was 1030. In a comparative test at an oxygen pressure of 0.7 MPa the viscosity achieved at a kappa number of 9 was 956 dm '/ kg. The reaction time was 10 minutes. When the NaOH loading was reduced to 3.0%, it took 120 minutes to reach one Kappa number of 9.0 required at an oxygen gas pressure of 0.12 MPa. The viscosity was 1100.

The experiments show that the process according to the invention provides a higher selectivity than the usual method. There couldn't be any difference in the carbohydrate yield to be established. The amount of alkali introduced can be increased by moderately increasing the oxygen gas pressure and considerably reduced by moderately increasing the reaction time without impairing the selectivity will.

Examples 5 and 6

From red pine shavings and pine shavings in equal parts by weight, a polysulfide pulp with a Kappa number of 34.7 and a viscosity of 1272dmVkg and activated as in example i.

The viscosity of the pulp treated in this way was noticeable 1120 dm '/ kg. The MalbsiolT was wiped with water and at a pulp consistency of 29 '\, and a temperature of 105' C with the addition of O.J'V. Mg as magnesium hydroxide and an amount of alkali corresponding to 1.5% NaOH, calculated on the dry weight of the pulp to an oxygen gas / alkali treatment process subject.

When the pulp was treated with air, it fell Partial pressure of gaseous oxygen by about 20v while using in the comparative lapses the oxygen gas pressure was not noticeably influenced by pure oxygen.

The results are shown in the following table:

Table 1

O; TcildriiL'k viscose.

Time in now door

MPa for kappa number Kappa number

10 8 10 8

became a hot alkali treatment process in its essence of oxygen at the same temperature for 1 hour before the oxygen gas / alkali treatment column switched on. Between the alkaline levels

There was no washing. The inert gas in the reactor was dwell exchanged gaseous oxygen, whereupon heating was continued immediately. Examples A and B mentioned in the table are comparative experiments only with a hot alkali treatment on the same

Ii pulp consistency. Temperature and alkali content, but in the absence of oxygen and without the addition of magnesium sulfate.
The results are given in Table 2.

Table 2

Ex.

name is

Alkali-

treatment

C) -NaOH treatment

Kappa number viscosity

dm '/ kg

0.024 1060 1020 30 120

guest ". 0.8 1030 970 12 40

oxygen
(Cf.)

The experiments show let the oxygen gas / Alkali / treatment of the pulp with air at low pressure, even with a pulp with a high pulp consistency, leads to a better selectivity than if this stage with oxygen was below the usual levels Printing conditions takes place.

Examples 7-11

Fin fuel. made of pine mixed with red spruce (20 ¹ V) and hardwood (10%), with a kappa number of 34.9 and an intrinsic viscosity of 1231 dm '/ kg, was treated with nitrogen dioxide and gaseous oxygen as in Example 1, but with the pulp consistency 32%. the temperature was 53 "C and the total treatment time was 55 minutes.

After the activation step, the pulp had a viscosity of II70 dm '/ kg. Washing and mixing of chemicals to a pulp consistency of 11% were carried out as in Example 1. except that the alkali loading was reduced to 4.3%. The temperature was kept at 114 "C. The initial pressure of the gaseous Oxygen was 0.085 MPa. the final pressure 0.07 to 0.08 MPa. It became an oxygen gas with a Content of 12% inert gas (nitrogen and noble gas) used.

In Example 7, 8 and 10, the oxygen gas was 1. 2 and 10, respectively. Present for 3 hours at 114 "C. In Examples 9 and 11

A 2

7 0

8 0

9 1
B 3

10 0

11 1

13.4 1151 11.5 1092 10.0 1072 10.2 1126 12.6 1150 9.4 1952 9.4 1098

Table 2 shows that when the method according to the invention is carried out, a significant reduction in the kappa number compared with an NO _; O ₂ activation is obtained in combination with a hot Alkallbehandlung, and that the decrease in viscosity in comparison ^D! E ch is moderate to a conventional Sauerstoflgasbleiche!. The table further shows that a hot alkali treatment process immediately prior to the oxygen gas / alkali treatment step reduces the time necessary in the oxygen gas column to achieve the same level of delignification and that a higher viscosity is obtained than if acid / T is present throughout the process . Pressure measurements indicated that the hot alkali treatment resulted in a reduction in gaseous oxygen consumed by at least 30%. The carbohydrate loss compared with the same kappa number. did not differ appreciably from the process in which no 'intermediate hot alkali treatment was used. As can be seen, the embodiment of the invention, in which the pulp is subjected to a hot alkali treatment process after the activation step and before the oxygen gas / alkali treatment step, brings about important practical and economic advantages.

Claims (10)

Patent claims: 1. Process for delignifying a cellulose pulp, produced by chemical cooking of an iignocellulosic material, the pulp in an activation stage with a No. containing gas phase is brought into contact and gaseous Oxygen is introduced into the activation stage, so that the intermediate product NO to Activation of the pulp is exploited, and the activation step under severe conditions, d. H. is carried out at such high temperatures that a certain degradation of the cellulose molecules takes place, characterized in that the pulp thus treated after washing or hot Subjected alkali treatment in a pulp / water mixture to an oxygen gas / alkali treatment being the partial pressure of the gaseous oxygen during the oxygen gas / alkali treatment step is maintained at 0.005 to 0.18 MPa and in which the Partial pressure of the gaseous oxygen during no point in the treatment process below the lower partial pressure limit falls. 2. The method according to claim 1, characterized in that the partial pressure of the gaseous oxygen is maintained at 0.015-0.09 MPa during the oxygen gas / alkali treatment and the partial pressure of the gaseous oxygen during any time of the treatment process below the lower partial pressure limit falls. 3. The method according to claim I. characterized in that that the partial pressure of the gaseous oxygen during the oxygen gas / alkali treatment is kept at 0.03 to 0.09 MPa and the partial pressure of the gaseous oxygen during no point in time of the treatment process falls below the lower partial pressure limit. 4. The method according to any one of claims I to 3, characterized in that the temperature during the activation stage to 50 to 90 ° C, preferably 55 to 80 ° C, in particular 60 to 70 ° C, and the activation tent for more than 10-0.2 (t-50) minutes and is less than 660-16 (t-50) minutes, where t is the temperature in ° C. 5. The method according to any one of claims 1 to 4, characterized in that the pulp consistency in the oxygen gas / alkali treatment step to 8 to 22, preferably 10 to 20 and especially 12 to 18% is held. 6. The method according to any one of claims 1 to 5, characterized in that the gaseous oxygen twice or more times or during the entire oxygen gas / alkali treatment process is introduced to avoid oxygen depletion to report in the liquid phase. 7. The method according to any one of claims 1 to 6, characterized in that the partial pressure during the initial stage of the oxygen gas / alkali treatment of gaseous oxygen is kept at a lower level than during the later and / or the final phase of this stage. 8. The method according to any one of claims I to 7, characterized in that the pulp after the Aküvlerungsstufe a heKJen alkali treatment at a temperature of 80 to 135 ° C. preferably 95 to 125 "C and in particular 101 to 120 ¹ C. and then without intermittent washing with oxygen is subjected to gas / alkali treatment processes. 9. The method according to any one of claims 1 to 8, characterized in that the depolymerization cellulose is reduced and the loss of hemi- > cellulose is kept to a minimum by the alkali required for delignification can be used intermittently or continuously during the course of the process which introduces oxygen gas / alkali treatment. 10. The method according to any one of claims 1 to 9, characterized in that the oxygen gas / alkali treatment carried out in the presence of waste liquors containing lignin residues will.