JPH09268488A - Production of kraft pulp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce an operation load of pulp and improve a yield of pulp in a method for producing a kraft pulp. SOLUTION: A lignocellulose material is cooked by using a cooking liquid comprising sodium sulfide, a polysulfide-type sulfur, sodium carbonate and sodium hydroxide and having 0.5-0.9mol/L concentration of the sodium carbonate, >2.0 molar ratio of the sodium hydroxide to the sodium carbonate and >=2g/L concentration of the polysulfide-type sulfur.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing kraft pulp, which comprises a lignocellulosic material cooking step.

[0002]

2. Description of the Related Art Among the methods for producing pulp for papermaking, the method for producing pulp by the kraft method has established a method for recovering cooking chemicals and heat energy from cooking waste liquor, and is capable of using various tree species as raw materials and It is a typical method of chemical pulp manufacturing because it can produce good pulp. According to the conventional kraft pulp manufacturing method,
In the cooking step, a lignocellulosic material such as wood chips is cooked with an aqueous solution (white liquor) containing sodium sulfide and sodium hydroxide. The obtained cooking product is solid-liquid separated, and is separated into pulp and cooking waste liquid. The separated pulp is washed with water, and the washing waste liquid is mixed with the cooking waste liquid. This mixed liquid is called black liquor, and contains a large amount of water, and since organic substances in the black liquor cannot be burned as it is, the water is removed by a vacuum evaporator (evaporator) to obtain concentrated black liquor. This concentrated black liquor is introduced into a recovery boiler, the organic matter in the black liquor is burned, the steam is generated by the heat of combustion, and thermal energy is recovered.

In the recovery boiler, a reducing atmosphere is formed by the combustion pyrolysis of organic matter in the black liquor, and under this reducing atmosphere, the sulfur content and the sodium content in the cooking waste liquor produce sodium sulfide (Na ₂ S). However, the excess sodium content reacts with carbon dioxide gas generated by the combustion of organic matter to become sodium carbonate. These compounds are in a molten state in the recovery boiler and are called smelt. This smelt is introduced into water from the bottom of the recovery boiler to form an aqueous solution containing sodium carbonate and sodium sulfide, and this aqueous solution is called green liquor.

Since the green liquor usually lacks the alkaline strength (sodium hydroxide content) necessary for cooking as it is, sodium carbonate in the green liquor is converted to sodium hydroxide in the causticizing step. That is, calcium oxide is added to green liquor to cause a carbonate group / hydroxyl group exchange reaction between calcium hydroxide fine particles in which calcium oxide is hydrated and sodium carbonate in the aqueous solution, so that the calcium carbonate fine particles and the sodium hydroxide aqueous solution are separated from each other. To generate. A value obtained by dividing the amount of sodium hydroxide in the aqueous solution (white liquor) obtained in the causticizing step by the total amount of sodium carbonate and sodium hydroxide is called a causticizing rate. The causticizing rate in the causticizing step is The closer to the upper limit (equilibrium value) determined by temperature and liquid composition, the more preferable. In the causticizing step, sodium sulfide contained in green liquor does not substantially change. The aqueous solution obtained in the causticizing step is called white liquor and is sent to the cooking step and used as a cooking liquor.

On the other hand, calcium carbonate produced in the causticizing step is solid fine particles, and after being separated from the white liquor by a method such as gravity settling or filtration with a filter cloth, the alkaline component remaining in the fine particle cake is washed and removed. After that, it is dehydrated, dried in a kiln using a fossil fuel as a heat source, and further calcined at a temperature sufficient to decompose and release carbon dioxide, and regenerated as calcium oxide. This calcium oxide is again sent to the causticizing process, where it is used for causticizing sodium carbonate. Since the washing wastewater after washing the calcium carbonate fine particles in the causticizing step is used as the water for dissolving the smelt, sodium hydroxide derived from the white liquor component is present in the green liquor.

In the cooking process of conventional kraft pulp production, a lignocellulosic material such as wood chips, which is a raw material for pulp, and white liquor are charged into a pressure cooker, heated to a predetermined temperature by steam heating, and further maintained at the temperature. After that, the cooking reaction is stopped by releasing the mixture of the cooking product and the cooking effluent to atmospheric pressure. The key operating factors in this cooking process are the ratio of alkaline content to wood and the temperature and time. Of these, the temperature and time are usually controlled using a relative reaction rate index called H factor defined below.

[Equation 1] The pressure cooker for digestion has a batch system and a continuous system. The batch method is a method in which an empty pressure cooker is filled with wood chips as a raw material, then white liquor is added, and then the cooker is closed and heated with steam.When the cooking is completed, the contents of the cooker are blown from the bottom of the cooker. It The continuous method is a method in which wood chips and white liquor are continuously charged from one end of a pressure cooker provided with high-pressure rotary valves at both ends of a cylindrical container.
The reaction product is heated so as to obtain a predetermined H factor while moving in the cylindrical kettle, and the cooking product is discharged from the other end.
The reaction between the lignocellulosic material and the alkali in the cooking process will be described below. Lignocellulosic materials such as wood include lignin, which is an organic polymer compound that forms a tree structure in addition to cellulose and hemicellulose useful as pulp, low-molecular polysaccharides, various organic acids, and resins. There is. The main function of alkaline chemicals in kraft cooking is to destroy the polymer structure of lignin and convert it into a low-molecular compound that dissolves in an aqueous alkaline solution. Further, the alkali also has a function of keeping the pH of the solution alkaline so as to prevent re-polycondensation of the low molecular weight compound. The alkaline chemicals are also consumed for neutralization of organic acids, hydrolysis of low molecular weight polysaccharides and neutralization of organic acids produced thereby. That is, alkaline chemicals are indispensable in the kraft pulp manufacturing method, and the consumption amount is proportional to the pulp production amount. The weight ratio of the effective alkali to the raw wood varies depending on the tree species, but is generally about 16% for conifers and 12% for hardwoods. The various facilities used in the above-mentioned kraft pulp manufacturing process have a design capacity determined according to the planned production amount of pulp, but the capacity is generally flexible with respect to load fluctuations. Therefore,
At times when pulp demand increases, by increasing the amount of alkali added to the digester or raising the digestion temperature, and by increasing the temperature of the evaporator and reducing the amount of water brought in, the design capacity is exceeded. Increased pulp production is often done. However, in the case of increased pulp production, the capacity of the recovery boiler, which is relatively inflexible in terms of equipment capacity, is the limit. That is, the upper limit of the capacity of the recovery boiler is often determined by the amount of heat generated, and the amount of heat generated in the boiler also increases in proportion to the increase in pulp production. Therefore, there has been a demand for a new method for increasing pulp production by suppressing an increase in heat generation amount in a recovery boiler. For causticizing equipment, pulp production can be increased by increasing the amount of calcium oxide used in proportion to the amount of pulp produced. This is done by adding industrial quicklime to the stream of calcium oxide that is normally circulating in the lime kiln. However, some problems occur due to the excess amount of quicklime added. The first problem is that unreacted calcium hydroxide fine particles are mixed into the white liquor because excess calcium oxide is added than usual, resulting in poor solid-liquid separation, which significantly increases the concentration of solid suspended substances in the white liquor. Will be increased. This solid suspended substance causes troubles such as scaling to equipment and piping, and hinders the work of the pulp manufacturing process. The second problem is that excess calcium carbonate content that exceeds the capacity of the lime kiln must be discharged from the lime circulation stream, resulting in an increase in industrial waste. Therefore, a new method for reducing the load in the causticizing process to increase pulp production has been required.

In the chemical regeneration circulation cycle in the kraft pulp production method, steam generated in the recovery boiler is used to produce electric energy as power for the power generation turbine, is used for vacuum generation in the evaporator and is used as a heat source, and is further used in the digester. It effectively recovers the energy used as a heat source for pulp and the pulp manufacturing process. However, the causticizing process, lime kiln, is the only process that consumes fossil fuels, and reducing the operational load of this process will not only improve the economic efficiency of pulp production described above, but also reduce fossil fuel consumption and reduce the global environment. It is a very important technical issue to protect the environment.

[0008] Various improved methods for producing kraft pulp which have been proposed so far include an improved continuous cooking method, a superbatch method, a one-stage polysulfide cooking method, and the like, which all increase pulp yield. Although it is a method of improving the pulp quality, it has a problem that it cannot significantly reduce the operation load and requires large-scale remodeling and additional installation of equipment.

Among these, the improved continuous cooking method is a method of increasing the pulp yield by introducing the cooking chemicals into the continuous kraft digester by dividing them into the pre-stage, the mid-stage and the post-stage of the cooking process. In this method, the alkali concentration level in each stage of the cooking process is more uniform than the one-stage introduction of cooking chemicals, and as a result, the collapse reaction of cellulose due to excess alkali is suppressed and the pulp yield is increased. However, if this method is applied to an existing continuous digester, a large amount of investment is required due to a large-scale modification of the equipment, and it cannot be applied to an existing batch digester. Further, in this method, the amount of cooking chemicals used may be the same as that in the conventional method or may be slightly increased, so that it cannot be expected to reduce the operational load in the pulp manufacturing process.

Further, the superbatch method is an improved method of producing kraft pulp in a batch digester, and prepares wood chips to be introduced into the kettle by using warm black liquor separated from the pulp after finishing the digestion. Although this is a treatment method, a facility for storing and transferring warm black liquor must be newly installed, and a significant reduction in operational load in the pulp manufacturing process cannot be expected.

In the one-stage polysulfide cooking method, polysulfide sulfur protects hemicellulose end groups from oxidation,
This is a method that expects an increase in pulp yield due to the mechanism that prevents cellulose from being disintegrated by alkali, and the technology for producing polysulfide sulfur by the catalytic oxidation of white liquor is applied to actual factory operations. The effect of the increase is also confirmed. However, this method has the following limitations. That is, sodium sulfide must be present in the cooking chemicals used to make kraft pulp, which is at least 10 g / L as Na ₂ O.
is necessary. If the amount of sodium sulfide is less than the above range, the pulp is not kraft cooked but alkali cooked, and the quality of pulp produced is significantly changed. Moreover, in this method, when the sodium sulfide contained in the white liquor is subjected to catalytic oxidation to be converted into polysulfide sulfur, only a part of the sodium sulfide in the white liquor can be used, and it is generated in the white liquor. The concentration of polysulfide sulfur caused is naturally limited. Further, in the case of one-stage polysulfide, it is unavoidable that the polysulfide sulfur is decomposed in the early stage of the cooking process, and the polysulfide sulfur contributing to the pulp yield increase is further reduced. Moreover, in this method, the total amount of white liquor must be catalytically oxidized, and the oxidation equipment becomes large.

[0012]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for producing a kraft pulp, which reduces the pulp operation load and improves the pulp yield.

[0013]

Means for Solving the Problems The present inventors have conducted intensive studies to solve the above-mentioned problems, and as a result, have completed the present invention.

That is, according to the present invention, the lignocellulosic material contains sodium sulfide, polysulfide sulfur, sodium carbonate and sodium hydroxide, and the sodium carbonate concentration is in the range of 0.5 to 0.9 mol / L. Provided is a method for producing kraft pulp, which comprises cooking with a cooking liquor having a molar ratio of sodium hydroxide to sodium carbonate of more than 2.0 and a polysulfide sulfur concentration of 2 g / L or more. According to the present invention,
A step of cooking a lignocellulosic material using an alkaline cooking liquor containing sodium sulfide and polysulfide sulfur, a step of separating a cooking product into pulp and a cooking waste liquor, a step of concentrating the cooking waste liquor, and burning a concentrated cooking waste liquor And a step of dissolving the combustion residue in water, a step of causticizing by adding calcium oxide to the aqueous solution of the combustion residue, a step of separating calcium carbonate from a causticized product, and the obtained causticizing aqueous solution In the method for producing kraft pulp circulated in the cooking step, (i) a part of the combustion residue aqueous solution is subjected to an oxidation treatment to be converted into an aqueous solution containing polysulfide sulfur and sodium carbonate, (ii) oxidation of the combustion residue aqueous solution. Preparing a cooking liquor by combining the treatment liquid and the rest of the causticizing aqueous solution, and (iii) using the obtained cooking liquor to lignocellulose To cooking quality, manufacturing method of kraft pulp is provided, wherein. further,
According to the present invention, a step of cooking a lignocellulosic material using an alkaline cooking liquor containing sodium sulfide and polysulfide sulfur, a step of separating a cooking product into pulp and a cooking effluent, and a step of concentrating the cooking effluent. , The step of burning the concentrated cooking waste liquor, the step of dissolving the combustion residue in water, the step of causticizing by adding calcium oxide to the aqueous solution of the combustion residue, and the step of separating calcium carbonate from the causticized product, In the method for producing kraft pulp in which an aqueous causticizing solution is circulated in the cooking step, (i) a part of the combustion residue aqueous solution is oxidized to be converted into an aqueous solution containing polysulfide sulfur and sodium carbonate;
i) oxidizing the rest of the causticizing solution to convert it into an aqueous solution containing polysulfide sulfur, sodium sulfide, and sodium hydroxide; (iii) combining these two aqueous solutions to prepare a cooking liquor; iv) A method for producing kraft pulp is provided, which comprises cooking a lignocellulosic material using the obtained cooking liquor.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION The lignocellulosic material used as a pulp raw material in the present invention includes various woods and non-woods such as bagasse, rice straw and hemp.

In the cooking process of the lignocellulosic material of the present invention, lignocellulose is converted into sodium sulfide (Na ₂ S).
And polysulfide sulfur (S) and sodium carbonate (Na
It is a cooking step of cooking using a cooking liquor containing ₂ CO ₃ ) and sodium hydroxide (NaOH). In the cooking liquor used in the present invention, the sodium carbonate concentration is 0.5 to 0.
It is in the range of 9 mol / L and the molar ratio of sodium hydroxide to sodium carbonate exceeds 2.0, preferably 2.
It is in the range of more than 5 and less than 4.0, and the polysulfide sulfur concentration is 2 g / L or more, preferably 2 to 10 g / L.
In the range.

In the cooking step according to the present invention, the cooking liquor to be used contains sodium sulfide and polysulfide sulfur, and also contains, as an alkali content, three kinds of sodium sulfide, sodium carbonate and sodium hydroxide, and further, the sodium carbonate concentration. Is maintained at a higher value than the conventional Kraft white liquor, the lignocellulosic material is mildly digested and pulped as compared to the case where only sodium hydroxide is used as the alkali content.
That is, since the cooking liquor used in the present invention contains a relatively large amount of sodium carbonate, the lignocellulosic material is mildly cooked to prevent the disintegration of cellulose, and moreover, the cooking liquor contains a relatively large amount. Due to the presence of polysulfide sulfur, the ends of hemicellulose are efficiently oxidatively protected by polysulfide sulfur, which effectively prevents the collapse of cellulose, resulting in
The pulp yield is improved. The polysulfide sulfur as used herein means sulfur produced from sodium polysulfide (Na ₂ S ₂ ) according to the reaction formula shown below.

Embedded image

The lignocellulosic material cooking process according to the invention can be carried out either batchwise or continuously.

Next, the present invention will be described in detail with reference to the drawings. FIG. 1 shows an example of a flow sheet of the method of the present invention,
FIG. 2 shows another example of the flow sheet of the present invention. In these figures, 1 is a cooking step, 2 is a pulp separation and washing step, 3 is a black liquor concentrating step, 4 is a concentrated black liquor burning step, 5 is a combustion residue dissolving step, 6 is a causticizing step, and 7 is a burning step. , 8 indicates a green liquor oxidation step, and 9 indicates a white liquor oxidation step. In FIG. 1, the lignocellulosic material is fed through line 10 to digestion step 1 where it is digested using a combined liquor of oxidized green liquor from green liquor oxidation step 8 and white liquor from causticization step 6. It

The digestion product obtained in the digestion step 1 is sent to a pulp separation and washing step 2 through a line 11. The pulp separation and washing step 2 is a step of separating and washing pulp from the digested product. For separation of pulp, usual solid-liquid separation, for example, centrifugation, vacuum filtration separation, filter press separation and the like are adopted. The pulp (kraft pulp) separated in the pulp separation and washing step 2 is recovered through a line 13, while the cooking waste liquid (black liquor) separated from the pulp is sent through a line 12 to a black liquor concentration step 3. To be
The black liquor concentration step 3 is a step of removing water from the black liquor, and as the apparatus, any apparatus can be used as long as it can remove the water in the black liquor.
A vacuum evaporator (evaporator) is used. By this black liquor concentration step, the black liquor is made into concentrated black liquor, and is sent to the concentrated black liquor combustion step 4 through the line 14.

The concentrated black liquor burning step 4 is a step of burning the organic substances in the concentrated black liquor and recovering the inorganic substances in the concentrated liquid as combustion residues. As a device therefor, a conventional recovery boiler is used. In this recovery boiler, the organic matter in the concentrated black liquor is pyrolyzed by combustion, and the combustion heat of the organic matter is recovered as steam. Further, in this recovery boiler, the sodium content and the sulfur content in the concentrated black liquor produce sodium sulfide (Na ₂ S) under a reducing atmosphere formed by combustion decomposition of organic matter, and Excess sodium content reacts with carbon dioxide gas generated by the combustion of organic matter to react with sodium carbonate (Na ₂ CO ₃ ).
Becomes These sodium sulfide and sodium carbonate constitute the main components of the combustion residue, and become a high temperature molten liquid (smelt) in the recovery boiler, which is withdrawn from the bottom of the recovery boiler and subjected to the combustion residue dissolution step 5. Sent. The combustion residue dissolving step 5 is a step of pouring smelt into water and dissolving it to prepare a combustion residue aqueous solution (green liquid). This green liquor is passed through line 16 to causticizing step 6
A portion of which is sent through line 17 to green liquor oxidation step 8.

The causticizing step 6 is a step of causticizing sodium carbonate in the green liquor to convert it into sodium hydroxide and converting the green liquor into white liquor. This causticizing step 6 is carried out by adding calcium oxide to the green liquor to disperse it as calcium hydroxide fine particles, and reacting sodium carbonate with this calcium hydroxide to convert it into sodium hydroxide. The finely divided calcium carbonate produced as a by-product in the causticizing step 6 is separated from the mother liquor (white liquor) by solid-liquid separation, is sent to the firing step 7 through the line 18, and is fired here, and then is calcium oxide powder. Is recycled to causticizing step 6 through line 19. As the firing furnace in this case, a rotary kiln type, a moving bed type, or a fluidized bed type firing furnace is usually used. The white liquor obtained in the causticizing step 6 is supplied to the cooking step 1 through the line 21.

In the present invention, a part of the green liquor obtained in the combustion residue dissolving step 5 is sent to the green liquor oxidizing step 8 through the line 17, and is oxidized there. The oxidation treatment of the green liquor in this case is carried out by bringing oxygen or oxygen-containing gas (air, oxygen-enriched air, etc.) into contact with the green liquor. This oxidation of green liquor oxidizes sodium sulfide in the green liquor to convert it into sulfur and sodium hydroxide, and the main reaction consists of the reaction between sodium sulfide and sulfur to form sodium polysulfide. If, sodium sulfide and polysulfide sodium thiosulfate (Na ₂
A side reaction occurs which is oxidized to S ₂ O ₃ ). (Main reaction) Na ₂ S + 1 / 2O ₂ + 2H ₂ O → S + 2NaOH (1) 2Na ₂ S + S → Na ₂ S ₂ (2) (Side reaction) Na ₂ S ₂ + 3O ₂ → 2Na ₂ S ₂ O ₃ (3) 2Na ₂ S + 2O ₂ + H ₂ O → 2Na ₂ S ₂ O ₃ + 2NaOH (4) The oxidation treatment of the green liquor uses a catalyst at 60 to 100 ° C., preferably 70 to 90. Temperature of 0 ° C and 0-2 kg / cm ² G,
It is preferably carried out under the condition of a pressure of 0 to 0.5 kg / cm ² G. As the catalyst, various conventionally known oxidation catalysts can be used, but an activated carbon catalyst is preferably used. The activated carbon catalyst can be in various forms such as a granular form, a fibrous form, and a cloth form. Further, as the oxidation treatment device, a catalyst tower having a catalyst filled therein is generally used. In the oxidation treatment of the green liquor, the reaction rate (oxidation rate) of sodium sulfide should be kept in the range of 40 to 95%, preferably 70 to 90%. If the oxidation rate of sodium sulfide exceeds the above range, the side reaction is apt to occur, and the amount of sodium thiosulfide that does not contribute to cooking increases, which is not preferable. Prior to the oxidation treatment, the green liquor to be oxidized is treated with a filter material such as cloth, sand or anthrite in order to prevent the catalyst performance from being deteriorated due to the accumulation of solid suspended solids in the green liquor on the catalyst. It is also possible to substantially remove beforehand the solid suspended substance in the green liquor by carrying out the filtration treatment used.

The proportion of green liquor to be subjected to the oxidation treatment depends on the dissolution step 5
It is preferably 50% or less, and more preferably 20 to 40% of the total green liquor obtained in the above step. If the proportion of the green liquor to be subjected to the oxidation treatment exceeds 50%, the flow rate of the causticizing aqueous solution supplied to the digestion step 1 becomes small, and the lignocellulosic substance cannot be smoothly digested, which is not preferable. On the other hand, if the proportion of green liquor to be oxidized becomes lower than 20%,
In order to smoothly cook the lignocellulosic material in the cooking step, it is necessary to increase the amount of sodium sulfide or sodium hydroxide used, which is not preferable because the process efficiency deteriorates.

In the flow sheet shown in FIG. 2, the white liquor obtained in the causticizing step 6 is once sent to the white liquor oxidizing step 9,
Here, it is the same as the flow sheet of FIG. 1 except that the flow sheet shown in FIG. 1 merges with the oxidized green liquor after the oxidation treatment. The oxidation treatment of the white liquor in this case is performed in the same manner as the oxidation treatment of the green liquor described above. By this oxidation treatment of the white liquor, part of sodium sulfide in the white liquor is converted into polysulfide sulfur, and an oxidized white liquor containing sodium sulfide, polysulfide sulfur and sodium hydroxide is obtained. Since this oxidized white liquor contains polysulfide sulfur, it exhibits an action of preventing the collapse of cellulose in the cooking step.

In the pulp production method of the present invention, as mentioned above, since the cooking step is carried out using a specific cooking liquor, the pulp yield can be improved and the pulp is used in connection with the causticizing step. The operational load of the firing process is reduced. That is,
In the case of the present invention, not all of the green liquor obtained in the combustion residue dissolving step is introduced into the causticizing step, but only a part of it is introduced into the causticizing step, so the calcium oxide used in the causticizing step is inevitable. It also reduces the amount used. Therefore, the load of the firing process for converting the calcium carbonate by-produced in the causticizing process into calcium oxide is also reduced, and as a result, the equipment such as the firing furnace is downsized and the fuel amount is also reduced.

[0027]

Next, the present invention will be described in more detail with reference to examples. The following green liquor, oxidized green liquor, white liquor and oxidized white liquor were used. (Green liquor) Part of the green liquor used in the factory was used. The component composition of this green liquor is as follows. Na ₂ S: terms of Na ₂ O amount 31.0 g / L (0.500 mol _{/ L) Na 2 CO 3:} 83.6g in terms of Na ₂ O weight / L (1.349 mol / L) NaOH: Na ₂ O equivalent amount 13.0 g / L (0.210 mol / L) polysulfide sulfur: 0 g / L (oxidized green liquor) was the green liquor prepared by air oxidation using activated carbon as a catalyst. In this case, the oxidation rate of sodium sulfide was 70% as the oxidation rate obtained from the sodium sulfide concentrations before and after the oxidation. The component composition of this oxidized green liquor is as follows. Na ₂ S: Na ₂ in O equivalent amount 8.0 g / L (0.129 mol _{/ L) Na 2 CO 3:} 85.3g in terms of Na ₂ O weight / L (1.376 mol / L) NaOH: Na 33.5 g / L at ₂ O equivalent amount (0.540 mol / L) polysulfide sulfur: one S conversion amount 8.6 g / L (white liquor) the green liquor white liquor used in the collected factory Parts were used. The component composition of this white liquor is as follows. Na ₂ S: terms of Na ₂ O amount 31.0 g / L (0.500 mol _{/ L) Na 2 CO 3:} 17.4g in terms of Na ₂ O weight / L (0.281 mol / L) NaOH: Na ₂ O equivalent amount 79.2 g / L (1.278 mol / L) Porisarufado sulfur: 0 g / L was a portion of the oxidized white liquor are used in factories were taken (oxidized white liquor) the white liquor . The component composition of this oxidized white liquor is as follows. Na ₂ S: terms of Na ₂ O amount 12.6 g / L (0.203 mol _{/ L) Na 2 CO 3:} 17.7g in terms of Na ₂ O weight / L (0.286 mol / L) NaOH: Na ₂ O conversion amount 97.4 g / L (1.571 mol / L) Polysulfide sulfur: S conversion amount 7.3 g / L

Example 1 Deformed chips and dust were removed from the eucalyptus chips used in the factory, stored in a polyethylene bag, a part thereof was taken out, and 500 g of the dry weight was accurately sampled to obtain 10 liters. It was put in the pressure cooker. Then 335 at 25 ° C
g of the oxidized green liquor and 602 g of white liquor were mixed and charged, and then the kettle was closed. Immediately start heating with an electric heater 2
It was heated to 173 ° C. at a temperature rising rate of 3 ° C./min and kept at this temperature for 43 minutes for cooking. After removing the contents of the pressure cooker and thoroughly washing with water to remove cooking waste liquid adhering to the pulp, only the pulp component is separated by a screen, and this is dried, and its weight is measured. The yield was determined and the kappa number of the pulp was measured. In addition, when adding the mixed solution,
Water was added and adjusted so that the chip weight ratio was 4.

Example 2 In Example 1, 327 g of the oxidized green liquor and 580 g
The experiment was conducted in the same manner except that the oxidized white liquor of Example 1 was used.

Comparative Example An experiment was conducted in the same manner as in Example 1 except that 735 g of white liquor was added instead of the oxidized green liquor.

The following experimental results were obtained by the experiments of the above-mentioned Examples and Comparative Examples.

[0032]

[Table 1]

The contents of the item items shown in Table 1 are as follows. (Pulp Yield) The relative yield is shown when the pulp yield of the comparative example is 100. In this case, the pulp yield is the ratio of the weight of air-dried pulp to the weight of absolutely dry chips. (Kappa number of pulp) A value indicating the degree of cooking by the residual amount of lignin. (Effective Alkali Addition Rate) It is shown as a relative ratio when the effective alkali addition rate of the comparative example is 100. In this case, the effective alkali addition rate is kg in terms of Na ₂ O of alkali added per ton of air-dried pulp. (Recovery boiler load) The organic content in the concentrated black liquor per ton of pulp is shown as a relative ratio when the comparative example is 100. (Caustic load) Na ₂ C per ton of pulp to be causticized
The O ₃ weight (kg) is shown as a relative ratio when the comparative example is 100.

As can be seen from the experimental results shown in Table 1,
An improvement in pulp yield is achieved by using a cooking step of cooking with a mixed liquid of oxidized green liquor and white liquor or oxidized white liquor. Further, when such a cooking process is used, the operational load of the causticizing process for causticizing the green liquor to obtain white liquor is significantly reduced, which means that the burning of calcium carbonate performed in connection with the causticizing process is performed. This means that the operational load of the process is also significantly reduced, and the economical efficiency in pulp production is significantly improved. In addition, the organic content in the cooking liquor is reduced, and the load on the boiler that burns black liquor is also reduced.

[0035]

According to the present invention, as compared with the conventional kraft pulp manufacturing method, the pulp yield is improved and the process economy is significantly improved.

[Brief description of drawings]

FIG. 1 shows an example of a flow sheet of the method of the present invention.

FIG. 2 shows another example of the flow sheet of the method of the present invention.

[Explanation of symbols]

 1 Cooking Process 2 Separation and Washing Process of Pulp 3 Black Liquor Concentration Process 4 Concentrated Black Liquor Combustion Process 5 Combustion Residue Dissolving Process 6 Causticizing Process 7 Firing Process 8 Green Liquor Oxidation Process 9 White Liquor Oxidation Process

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazuhiro Nakamura 3-4-2 Marunouchi, Chiyoda-ku, Tokyo Sanryo Paper Co., Ltd. (72) Inventor Yoshihiro Oguchi 12-12 Tsurumi Chuo, Tsurumi-ku, Yokohama-shi, Kanagawa No. 1 in Chiyoda Corporation (72) Inventor Sachio Asaoka 2-12-1, Tsurumi Chuo, Tsurumi Ward, Yokohama City, Kanagawa Prefecture No. 1 in Chiyoda Corporation (72) Eiji Sasaki, Tsurumi Chuo, Tsurumi Ward, Yokohama City, Kanagawa Prefecture 2-12-1 Chiyoda Kakoh Construction Co., Ltd.

Claims (3)

[Claims] 1. A lignocellulosic material comprising sodium sulfide, polysulfide sulfur, sodium carbonate and sodium hydroxide, the concentration of sodium carbonate being 0.5 to 0.9.
A kraft pulp characterized by being cooked using a cooking liquor having a molar ratio of sodium hydroxide to sodium carbonate of more than 2.0 and a polysulfide sulfur concentration of 2 g / L or more in the range of mol / L. Production method. 2. A step of cooking a lignocellulosic material using an alkaline cooking liquor containing sodium sulfide and polysulfide sulfur, a step of separating a cooking product into pulp and a cooking waste liquor, and a step of concentrating the cooking waste liquor, The steps of burning the concentrated cooking waste liquor, dissolving the combustion residue in water, adding calcium oxide to the aqueous solution of the combustion residue to causticize, and separating calcium carbonate from the causticized product were obtained. A method for producing a kraft pulp in which an aqueous causticizing solution is circulated in the cooking step, comprising: (i) oxidizing a part of the combustion residue aqueous solution to convert it into an aqueous solution containing polysulfide sulfur and sodium carbonate; (ii) Preparing a cooking liquor by combining the oxidation treatment liquid of the combustion residue aqueous solution and the rest of the causticizing aqueous solution, and (iii) using the obtained cooking liquor To cooking the Roh cellulosic material, method of manufacturing kraft pulp, wherein 3. A step of cooking a lignocellulosic material using an alkaline cooking liquor containing sodium sulfide and polysulfide sulfur, a step of separating a cooking product into pulp and a cooking waste liquor, and a step of concentrating the cooking waste liquor, The steps of burning the concentrated cooking waste liquor, dissolving the combustion residue in water, adding calcium oxide to the aqueous solution of the combustion residue to causticize, and separating calcium carbonate from the causticized product were obtained. A method for producing a kraft pulp in which an aqueous causticizing solution is circulated in the digesting step, comprising: (i) oxidizing a part of the combustion residue aqueous solution to convert it into an aqueous solution containing polysulfide sulfur and sodium carbonate; The rest of the causticizing solution is oxidized and converted into an aqueous solution containing polysulfide sulfur, sodium sulfide and sodium hydroxide. , (Iii) these two aqueous solutions joined to prepare a cooking liquor that, (iv) to cooking a lignocellulosic material with a resultant cooking liquor, the manufacturing method of kraft pulp, wherein.