CA1279157C - Process for causticizing of an aqueous solution containing alkali carbonate - Google Patents
Process for causticizing of an aqueous solution containing alkali carbonateInfo
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- CA1279157C CA1279157C CA 526272 CA526272A CA1279157C CA 1279157 C CA1279157 C CA 1279157C CA 526272 CA526272 CA 526272 CA 526272 A CA526272 A CA 526272A CA 1279157 C CA1279157 C CA 1279157C
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- causticizing
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- hydroxide
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Abstract
ABSTRACT
Process for causticizing of an aqueous solution contain-ing alkali carbonate with calcium oxide and hydroxide by bringing the aqueous solution containing alkali carbonate into contact with the calcium oxide or hydroxide and by separating the alkali hydroxide solution arisen in the causticizing from the calcium carbonate precipitate. The aqueous solution containing alkali carbonate is conducted through a bed which has been formed by mixing calcium oxide and calcium carbonate in the causticized alkali solution and by removing the excess alkali solution.
Process for causticizing of an aqueous solution contain-ing alkali carbonate with calcium oxide and hydroxide by bringing the aqueous solution containing alkali carbonate into contact with the calcium oxide or hydroxide and by separating the alkali hydroxide solution arisen in the causticizing from the calcium carbonate precipitate. The aqueous solution containing alkali carbonate is conducted through a bed which has been formed by mixing calcium oxide and calcium carbonate in the causticized alkali solution and by removing the excess alkali solution.
Description
~L2~9~L5i7 A process for caugtici~zing o~ an aqueous solution containing alkali carbonate The preqent invention relates to a process for causticizing a water solution contalning alkali carbonate, usually green liquor, with calcium oxide and/or hydroxide. This invention relates in particular to a method for causticizing a water solution contai-ning alkali carbonate, in which the alkali carbonate containing water solution is brought into contact with calcium o~ide or/and hydroxide, upon which the alkali hydroxide solution produced in the cau5ticizing is separated from the calcium carbonate precipi-tate. With the method according to the present invention a diges-tion liquor intended to be u~ed in the preparation process of soda or sulphate pulp can be prepared from green liquor.
In the pulp preparation process, for instance according to the sulphate process, the regeneration of cooking chemicals is an im-portant partial process. By the present causticizing process, the sodium carbonate and the sodium sulphide melt are dissolved into weak white liquor, whereby a water solution of sodium carbonate and sodium sulphide and other sodium salts (sodium sulphate), which are more or less inert with regard to the cooking prncess, as well as to a certain extent other metal salts appearing as impurities~ Is obtained. When this so-called green liquor has been purified from ~olid impurities, it is causticized into whlte li-quor. Nowadays the causticizing is carried out a~ follows.
Calcined lime (CaO) is added to the green liquor, whereby the calcium oxide first is extinguished by reaction with the water of the green liquor, thus forming drowned lime. The calcium ions, which are generated by the dissolving of the calcium hydroxide, then form togather with the carbonate ions of the solution a cal-clum carbonate precipitate, whereby the hydroxide ion concentra-tion grows and its carbonate ion concentration decreases.
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~7915~ 22203-258 The above process o extinction and causticizing can be described ln principle with the following balance reaction:
CaO( ) + H O --> Ca(OH) Ca(OH)2(s) => Ca2 + 20H
Ca2+ + C03 < > CaC03(s) From a reaction kinetic point of viewl the causticizing event is a heterogeneous system in two senses, as the calcium has first to be dissolved from the solid calcium hydroxide and then to form a precipitate with the carbonate ions of the solution.
Typical of heterogeneous systems is that they pass very slowly towards the state of equilibrium because of the slow inter-phasial diffusion. These conditions are particularly conspicuous in the causticizing process because of its double heterogeneity and above all because of the low solubility of calcium hydroxide.
The diffusion rate being highly dependent of the temperature, the causticizing rate decreases further as the temperature sinksO
For the above reasons a disadvantage of the causticizing process used at present is that a relatively long retention time, and thus also relatively large causticizing vessels, are required.
Still the causticizing degree required by a reaction balance is not achieved, as a relatively large portion of the carbonate solution to be causticized has a much shorter retention time than the average retention time when series connected mixing caustic-izing receptacles are being used.
The correct batching of the lime quantity is also difficult. If too li-ttle lime is batched, the causticizing degree is naturally low, and again, if too much is batched, the settling of the . .
~X7~57 -3- 22203-2~8 white liquor becomes difficult and the combustion capacity need and heat consumption of the caustic sluclge increases.
In addition, the impurities of the above green liquor have to be efficiently removed from the green liquor, for the settling of the white liquor to succeed. For these reasons also, the settling of the green liquGr and the white liquor require large clarifiers.
With the present causticizing process, the settling of the causticizing and the green liquor as well as the white liquor has to take place at a temperature that is as high as possible, since the diffusion rate is a decisive factor, and this again is highly dependent on the temperature. The high temperature and the high alkali concentration lead to accentuated material requirements e.g. with regard to the filters and wires in the present process.
The purpose of the invention is to remove or at least reduce the above disadvantages appearing in the present causticizing methods by minimizing the restriction brought about by the diffusion as to the causticizing rate, and thus achieve a rapid causticizing, regardless of the temperature.
Thus the present invention provides a process for causticizing an aqueous alkali carbonaceous solution with calcium oxide and/or hydroxide by contacting the aqueous alkali carbonaceous solution with calcium oxide and/or hydroxide and separating an alkali hydroxide solution produced in the causticizing from a calcium carbonate precipitate, characterized in that the aqueous alkali carbonaceous solution is conducted through a bed which has been formed by mixing the calcium oxide ~279~57 -3a- 22203-248 and the calcium carbonate with an already causticized alkali solution and by withdrawing excess alkali solution.
In the preferred embodiment of the invention, a water solution containing alkali carbonate is put into contact with calcium hydroxide by conducting the water solution containing alkali carbonate through a bed formed by calcium hydroxide and calcium carbonate mother crystals. The bed containing calcium hydroxides and calcium carbonate mother crystals is thus advantageously formed by adding calcium carbonate to white liquor andtor calcium oxide, by mixing the calcium oxide and the white liquor and filtering or displacing the white liquor in order to generate a bed which contains calcium hydroxide and calcium carbonate mother crystals.
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For each mole of calcium oxide and hydroxide at least 1/3 and ad-vantageously at least 1 mole of calcium carbonate is added.
The green liquor is displaced through the bed thus formed, where-by the green liquor gradually is transformed into calcium carbo-nate. By this displacing technique, a diffusion layer, which is as thin as possible, is produced around the calcium hydroxide and calcium carbonate crystals. As the bed contains already in the initial step calcium carbonate crystals, the settling of the cal-cium carbonate around these mother crystals is as rapid as pos-sible and moreover, the grain size of the caustic sludge thus formed becomes remarkably greater compared to the present method and consequently, the filtering is rapid and convenient, and thus the size of the apparatus is smaller than the present one.
In order to obtain as high a causticizing degree as possible, and to utilize and consume the calcium hydroxide in the bed as effi-ciently as possible, the above green liquor displacement is ad-vantageously divided into at least two displacing steps so that in the first displacing step green liquor is used, which contains also white liquor and is obtained from the subsequent displacing step and of which the amount compared to that of the calcium hyd-roxide contained in the bed is such, that it does not consume the full amount of calcium hydroxide contained in the bed, but the bed still contains calcium hydroxide after the displacement. In the second displacing step, only green liquor is used, so that the solution contains a surplus of sodium carbonate compared to the calcium hydroxide contained in the bed, in order to be able to consume all the calcium hydroxide contained in the bed, by adjusting the amount of green liquor to be used so that the liquid removed in the displacement contains both carbonate and hydroxide.
For the adjustment, the hydroxide concentration of the removed solution is measured. The adjustment does not have to be exact and still the above advantages are achieved, i.e. all the active lime is consumed and the causticity of the removed white liquor ~279~
is as high as possible. The liquid removed in the second displa-cing step only has to vary between nearly pure green liquor and nearly pure white liquor.
In order to prevent as efficiently as possible that part of the calcium carbonate arisen during the displacement causticizing i5 crystallized on top of the wire or the filter fabric and thus would obturate it, the above bed is preferably formed in two steps, so that the portion of the bed next to the wire or the filter fabric contains merely calcium carbonate and only on top of this the above calcium hydroxlde-calcium carbonate bed is ~or-med.
The calcium carbonate arisen from the calcium hydroxide crystals, which are next to the wire or the filter fabric, i9 crystallized on top of the lime sludge crystals in the bed layer below.
The forming of the calcium hydroxide and calcium carbonate bed and the connected preforming of the bed and the subsequent was-hing with water and drying of the lime sludge bed arisen in the displacing caus~icizing accor~ing to the process, can be car-ried out either as a periodical or a continuous process. In both cases, the different process steps are however similar and only the required device solutions d~ffer from each other.
In both cases, the required process devices already exist. In the periodical case, the main device may be for instance a so-called pressure filter in accordance with the FI patent specification 65 455, which nowadays has been used for the water washing of caus-tic sludge and to some extent also as white iquor filter. In the case of the invention, the entire displacing causticizing advan-tageously takes place in the same pressure Eilter before the was-hing and the drying of the lime sludge produced in it. In the periodical case, the bed remains in the same chamber all the time, starting from the step of precoating the wire with lime sludge until the lime sludge has been dried wlth air, i.e. during both . .
~ ~6- ~Z~915~ 22203-2~8 the forming of the calcium hydroxide-calcium carbonate bed and the two step displacement causticizing. By means of a valve system, the chamber concerned is connected to the suspension, liquid or air feeding system concerned, and to the storage tank of the corresponding filtrate.
In the continuous embodiment, e.g. a so-called filter band press may be used, which so far has been used both in lime sludge washing and white liquor filtering. The pre-bed formed and the calcium hydroxide-calcium carbonate bed formed on top of it move along with the filter band through the displacing steps and the washing and drying steps.
The invention is described in detail below with refer-ence to the enclosed drawings, in which Figure 1 represents a flow diagram of the preferred embodiment of the process according to the invention, Figure 2 represents a vertical ~erspective of the heat transfer equipment, which can be used in the process according to Figure 1 and Figure 3 represents the causticizing degree as a function of the causticizing period and temperature.
In Figure 1 the causticizing process according to the invention is presented step by step.
In step A a bottom bed 12 is formed on top of the caustic sludge-white liquor slurry 11, and the excess white liquor 13 is filtered away.
In step B a bed 16 is formed by feeding white liquor, slaked lime and lime sludge 15, on top of the bottom bed 12 and the excess white liquor 17 is filtered away.
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In step C the green liquor 25 is displaced through the bed, the green liquor being partly causticized and further causticized up to the final causticizing degree before it is removed as white li-quor 21.
The bed 20, which remains after the displacing C, still contains calcium hydroxide, and through this in step D green liquor 41 is displaced, which partly is causticized as far as the amount of calcium hydroxyde in the bed 20 permits.
The remaining lime sludge bed 24, which contains green liquor, is washed with water 26 in step E, whereby thin green liquor 28 and lime sludge 27 containing water is obtained.
The dry matter content of the lime sludge 27 is increased in step F by displacing air 29 through it, 50 that the major part of the water amount contained in it is separated as a flow 31.
The thin green liquor 28 and the above water flow ~1 are combined into the flow 32, which is used in step H, in which the melt 38 deriving from the soda recovery unit is dissolved.
, .
The green liquor 39 formed is conducted into step I, in which its impurities 42 are removed and washea with water 40 and from which the green liquor 41 is lead into the above step D.
A portion 35 of the washed and dried lime sludge 30 from the ~tep F is mixed with the portion 14 of the white liquors 13, 17 and 21 in step J, in which slurry 11 for the pre-bed 12 is prepa-red.
A second portion 36 of the lime sludge 30 from the step F is mixed with the burnt lime 37 and the mixture is extinguished with the portion 18 of the white liquors 17 and 21 in step K, in which the slurry 15 is formed, which is used in the above step B.
,_ -8- 12~9~57 22203-248 The fi,nal portion 33 of the dried caustic sludge 30 is conducted to the lime sludge reburning kiln G, where it is burnt into lime 37 and carbon dioxide 38.
The resulting white liquor is removed as a flow 22 from the white liquor flow 21 of step C.
Since the slaking is a heat producing reaction, the temperature of the slurry 15 produced in the extinction step K is higher than that of the white liquor 18 used in this step. In case one wishes to adopt this extinction temperature, in order to obtain a temperature which is as high as possible for the white liquor produced, but still wants to keep the process steps A-H at a relatively low temperature, the heat transfer system schematically presented in Figure 2 may for instance be used for transferring heat from the slurry flow 15 to the white liquor produced 22.
The slurry 15 deriving from the extinction K is con-ducted to two or several expansion vessels 19, in which a pressure is maintained, which is lower than the pressure corresponding to the boiling point of the slurry 15, so that its temperature sinks and the fresh white liquor 22 is heated with the expansion steam produced 23 either directly or indirectly with the heat exchanger.
The vapour 23' from the last expansion vessel 19 is condensed with water 26, of which the temperature thus rises.
This heated water can then be used in -the washing of the caustic sludge in step E' (E`igure 1).
By adjusting the pressure in the last expansion step of the slurry for instance by means of a vacuum pump and the temper-ature and amount of the used cooling water, the temperature of the j~
1279~7 22203-248 slurry used in step B (Figure 1) and thus also the temperature of the displacing causticizing is adjusted.
With this heat transfer system it is possible to produce a white liquor of which the temperature is even above 100C
and still keep the temperature in the causticizing step very low, e.g. at 60-70C.
With the present causticizing methods the rate of causticizing is relatively slow, particularly if the temperature is low. Figure 3 represents the causticizing degree as a function of the causticizing period and temperature. With the method of the invention tests have been made at a temperature of 25C.
With a displacing causticizing a causticizing degree was obtained, which corresponded approximately to the causticizing degree in the state of equilibrium, i.e. a causticizing degree of about 85 ~
with a concentration of white liquor of 110 g active alkali/liter calculated as sodium oxide.
As it appears from Figure 3, in a conventional caustic-izing process, in its initial step, i.e. immediately upon the hydration of the lime, the rate of causticizing is slower than after a certain period of time (in Figure 3 the rate of caustic-izing is the derivative of the curve). For instance at a temper-ature of 45C the maximal rate is not achieved until after about two hours. This phenomenon cannot be explained otherwise than that the calcium carbonate crystallization is a limiting partial event of the causticizing event in the initial step of the causticizing. The reason for this is that the solution has to be very supersaturated in respect of the calcium carbonate, before it begins to crystallize, there being very few so-called mother ~ i _ 9a 12 79~.S7 22203-248 crystals in the beginning, on top o~ which the calcium carbonate could settle. By adding calcium carbonate or lime sludge into green liquor in conventional causticizing, the causticizing can be accelerated, particularly in its initial step. In addition, in this way one achieves also the advantage that the produced calcium carbonate ~' 9~L5~7 22203~248 i.e. lime sludge has greater crystals, whereby the clarifica-tion or filtering of the white liquor becomes easier and more ra-pid. The white liquor obtained is purer, and the lime sludge obtained i8 easier to wash and purer.
With the method according to the invention the following advanta-ges are achieved:
- It is posYible to obtain a white liquor, of which the concen-tration of active alkali is higher than with present causticizing methods and thus e.g. the heat consumption in a pulp cooking pro-cess is reduced and the chemical charge of the regeneration pro-cess of chemicals is lower. The heat consumption of the evapora-tion plant and the lime sludge reburning kiln decreases, the chemical losses as well.
- A purer white liquor i9 obtained and thus the problems caused by e.g. incrusts are reduced.
- Smaller space requ~rement and smaller investment costs.
- Simple adjustment.
~.
In the pulp preparation process, for instance according to the sulphate process, the regeneration of cooking chemicals is an im-portant partial process. By the present causticizing process, the sodium carbonate and the sodium sulphide melt are dissolved into weak white liquor, whereby a water solution of sodium carbonate and sodium sulphide and other sodium salts (sodium sulphate), which are more or less inert with regard to the cooking prncess, as well as to a certain extent other metal salts appearing as impurities~ Is obtained. When this so-called green liquor has been purified from ~olid impurities, it is causticized into whlte li-quor. Nowadays the causticizing is carried out a~ follows.
Calcined lime (CaO) is added to the green liquor, whereby the calcium oxide first is extinguished by reaction with the water of the green liquor, thus forming drowned lime. The calcium ions, which are generated by the dissolving of the calcium hydroxide, then form togather with the carbonate ions of the solution a cal-clum carbonate precipitate, whereby the hydroxide ion concentra-tion grows and its carbonate ion concentration decreases.
.P`d ~3;~:/
~J , I
~7915~ 22203-258 The above process o extinction and causticizing can be described ln principle with the following balance reaction:
CaO( ) + H O --> Ca(OH) Ca(OH)2(s) => Ca2 + 20H
Ca2+ + C03 < > CaC03(s) From a reaction kinetic point of viewl the causticizing event is a heterogeneous system in two senses, as the calcium has first to be dissolved from the solid calcium hydroxide and then to form a precipitate with the carbonate ions of the solution.
Typical of heterogeneous systems is that they pass very slowly towards the state of equilibrium because of the slow inter-phasial diffusion. These conditions are particularly conspicuous in the causticizing process because of its double heterogeneity and above all because of the low solubility of calcium hydroxide.
The diffusion rate being highly dependent of the temperature, the causticizing rate decreases further as the temperature sinksO
For the above reasons a disadvantage of the causticizing process used at present is that a relatively long retention time, and thus also relatively large causticizing vessels, are required.
Still the causticizing degree required by a reaction balance is not achieved, as a relatively large portion of the carbonate solution to be causticized has a much shorter retention time than the average retention time when series connected mixing caustic-izing receptacles are being used.
The correct batching of the lime quantity is also difficult. If too li-ttle lime is batched, the causticizing degree is naturally low, and again, if too much is batched, the settling of the . .
~X7~57 -3- 22203-2~8 white liquor becomes difficult and the combustion capacity need and heat consumption of the caustic sluclge increases.
In addition, the impurities of the above green liquor have to be efficiently removed from the green liquor, for the settling of the white liquor to succeed. For these reasons also, the settling of the green liquGr and the white liquor require large clarifiers.
With the present causticizing process, the settling of the causticizing and the green liquor as well as the white liquor has to take place at a temperature that is as high as possible, since the diffusion rate is a decisive factor, and this again is highly dependent on the temperature. The high temperature and the high alkali concentration lead to accentuated material requirements e.g. with regard to the filters and wires in the present process.
The purpose of the invention is to remove or at least reduce the above disadvantages appearing in the present causticizing methods by minimizing the restriction brought about by the diffusion as to the causticizing rate, and thus achieve a rapid causticizing, regardless of the temperature.
Thus the present invention provides a process for causticizing an aqueous alkali carbonaceous solution with calcium oxide and/or hydroxide by contacting the aqueous alkali carbonaceous solution with calcium oxide and/or hydroxide and separating an alkali hydroxide solution produced in the causticizing from a calcium carbonate precipitate, characterized in that the aqueous alkali carbonaceous solution is conducted through a bed which has been formed by mixing the calcium oxide ~279~57 -3a- 22203-248 and the calcium carbonate with an already causticized alkali solution and by withdrawing excess alkali solution.
In the preferred embodiment of the invention, a water solution containing alkali carbonate is put into contact with calcium hydroxide by conducting the water solution containing alkali carbonate through a bed formed by calcium hydroxide and calcium carbonate mother crystals. The bed containing calcium hydroxides and calcium carbonate mother crystals is thus advantageously formed by adding calcium carbonate to white liquor andtor calcium oxide, by mixing the calcium oxide and the white liquor and filtering or displacing the white liquor in order to generate a bed which contains calcium hydroxide and calcium carbonate mother crystals.
~, .
~2~91~;~
For each mole of calcium oxide and hydroxide at least 1/3 and ad-vantageously at least 1 mole of calcium carbonate is added.
The green liquor is displaced through the bed thus formed, where-by the green liquor gradually is transformed into calcium carbo-nate. By this displacing technique, a diffusion layer, which is as thin as possible, is produced around the calcium hydroxide and calcium carbonate crystals. As the bed contains already in the initial step calcium carbonate crystals, the settling of the cal-cium carbonate around these mother crystals is as rapid as pos-sible and moreover, the grain size of the caustic sludge thus formed becomes remarkably greater compared to the present method and consequently, the filtering is rapid and convenient, and thus the size of the apparatus is smaller than the present one.
In order to obtain as high a causticizing degree as possible, and to utilize and consume the calcium hydroxide in the bed as effi-ciently as possible, the above green liquor displacement is ad-vantageously divided into at least two displacing steps so that in the first displacing step green liquor is used, which contains also white liquor and is obtained from the subsequent displacing step and of which the amount compared to that of the calcium hyd-roxide contained in the bed is such, that it does not consume the full amount of calcium hydroxide contained in the bed, but the bed still contains calcium hydroxide after the displacement. In the second displacing step, only green liquor is used, so that the solution contains a surplus of sodium carbonate compared to the calcium hydroxide contained in the bed, in order to be able to consume all the calcium hydroxide contained in the bed, by adjusting the amount of green liquor to be used so that the liquid removed in the displacement contains both carbonate and hydroxide.
For the adjustment, the hydroxide concentration of the removed solution is measured. The adjustment does not have to be exact and still the above advantages are achieved, i.e. all the active lime is consumed and the causticity of the removed white liquor ~279~
is as high as possible. The liquid removed in the second displa-cing step only has to vary between nearly pure green liquor and nearly pure white liquor.
In order to prevent as efficiently as possible that part of the calcium carbonate arisen during the displacement causticizing i5 crystallized on top of the wire or the filter fabric and thus would obturate it, the above bed is preferably formed in two steps, so that the portion of the bed next to the wire or the filter fabric contains merely calcium carbonate and only on top of this the above calcium hydroxlde-calcium carbonate bed is ~or-med.
The calcium carbonate arisen from the calcium hydroxide crystals, which are next to the wire or the filter fabric, i9 crystallized on top of the lime sludge crystals in the bed layer below.
The forming of the calcium hydroxide and calcium carbonate bed and the connected preforming of the bed and the subsequent was-hing with water and drying of the lime sludge bed arisen in the displacing caus~icizing accor~ing to the process, can be car-ried out either as a periodical or a continuous process. In both cases, the different process steps are however similar and only the required device solutions d~ffer from each other.
In both cases, the required process devices already exist. In the periodical case, the main device may be for instance a so-called pressure filter in accordance with the FI patent specification 65 455, which nowadays has been used for the water washing of caus-tic sludge and to some extent also as white iquor filter. In the case of the invention, the entire displacing causticizing advan-tageously takes place in the same pressure Eilter before the was-hing and the drying of the lime sludge produced in it. In the periodical case, the bed remains in the same chamber all the time, starting from the step of precoating the wire with lime sludge until the lime sludge has been dried wlth air, i.e. during both . .
~ ~6- ~Z~915~ 22203-2~8 the forming of the calcium hydroxide-calcium carbonate bed and the two step displacement causticizing. By means of a valve system, the chamber concerned is connected to the suspension, liquid or air feeding system concerned, and to the storage tank of the corresponding filtrate.
In the continuous embodiment, e.g. a so-called filter band press may be used, which so far has been used both in lime sludge washing and white liquor filtering. The pre-bed formed and the calcium hydroxide-calcium carbonate bed formed on top of it move along with the filter band through the displacing steps and the washing and drying steps.
The invention is described in detail below with refer-ence to the enclosed drawings, in which Figure 1 represents a flow diagram of the preferred embodiment of the process according to the invention, Figure 2 represents a vertical ~erspective of the heat transfer equipment, which can be used in the process according to Figure 1 and Figure 3 represents the causticizing degree as a function of the causticizing period and temperature.
In Figure 1 the causticizing process according to the invention is presented step by step.
In step A a bottom bed 12 is formed on top of the caustic sludge-white liquor slurry 11, and the excess white liquor 13 is filtered away.
In step B a bed 16 is formed by feeding white liquor, slaked lime and lime sludge 15, on top of the bottom bed 12 and the excess white liquor 17 is filtered away.
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In step C the green liquor 25 is displaced through the bed, the green liquor being partly causticized and further causticized up to the final causticizing degree before it is removed as white li-quor 21.
The bed 20, which remains after the displacing C, still contains calcium hydroxide, and through this in step D green liquor 41 is displaced, which partly is causticized as far as the amount of calcium hydroxyde in the bed 20 permits.
The remaining lime sludge bed 24, which contains green liquor, is washed with water 26 in step E, whereby thin green liquor 28 and lime sludge 27 containing water is obtained.
The dry matter content of the lime sludge 27 is increased in step F by displacing air 29 through it, 50 that the major part of the water amount contained in it is separated as a flow 31.
The thin green liquor 28 and the above water flow ~1 are combined into the flow 32, which is used in step H, in which the melt 38 deriving from the soda recovery unit is dissolved.
, .
The green liquor 39 formed is conducted into step I, in which its impurities 42 are removed and washea with water 40 and from which the green liquor 41 is lead into the above step D.
A portion 35 of the washed and dried lime sludge 30 from the ~tep F is mixed with the portion 14 of the white liquors 13, 17 and 21 in step J, in which slurry 11 for the pre-bed 12 is prepa-red.
A second portion 36 of the lime sludge 30 from the step F is mixed with the burnt lime 37 and the mixture is extinguished with the portion 18 of the white liquors 17 and 21 in step K, in which the slurry 15 is formed, which is used in the above step B.
,_ -8- 12~9~57 22203-248 The fi,nal portion 33 of the dried caustic sludge 30 is conducted to the lime sludge reburning kiln G, where it is burnt into lime 37 and carbon dioxide 38.
The resulting white liquor is removed as a flow 22 from the white liquor flow 21 of step C.
Since the slaking is a heat producing reaction, the temperature of the slurry 15 produced in the extinction step K is higher than that of the white liquor 18 used in this step. In case one wishes to adopt this extinction temperature, in order to obtain a temperature which is as high as possible for the white liquor produced, but still wants to keep the process steps A-H at a relatively low temperature, the heat transfer system schematically presented in Figure 2 may for instance be used for transferring heat from the slurry flow 15 to the white liquor produced 22.
The slurry 15 deriving from the extinction K is con-ducted to two or several expansion vessels 19, in which a pressure is maintained, which is lower than the pressure corresponding to the boiling point of the slurry 15, so that its temperature sinks and the fresh white liquor 22 is heated with the expansion steam produced 23 either directly or indirectly with the heat exchanger.
The vapour 23' from the last expansion vessel 19 is condensed with water 26, of which the temperature thus rises.
This heated water can then be used in -the washing of the caustic sludge in step E' (E`igure 1).
By adjusting the pressure in the last expansion step of the slurry for instance by means of a vacuum pump and the temper-ature and amount of the used cooling water, the temperature of the j~
1279~7 22203-248 slurry used in step B (Figure 1) and thus also the temperature of the displacing causticizing is adjusted.
With this heat transfer system it is possible to produce a white liquor of which the temperature is even above 100C
and still keep the temperature in the causticizing step very low, e.g. at 60-70C.
With the present causticizing methods the rate of causticizing is relatively slow, particularly if the temperature is low. Figure 3 represents the causticizing degree as a function of the causticizing period and temperature. With the method of the invention tests have been made at a temperature of 25C.
With a displacing causticizing a causticizing degree was obtained, which corresponded approximately to the causticizing degree in the state of equilibrium, i.e. a causticizing degree of about 85 ~
with a concentration of white liquor of 110 g active alkali/liter calculated as sodium oxide.
As it appears from Figure 3, in a conventional caustic-izing process, in its initial step, i.e. immediately upon the hydration of the lime, the rate of causticizing is slower than after a certain period of time (in Figure 3 the rate of caustic-izing is the derivative of the curve). For instance at a temper-ature of 45C the maximal rate is not achieved until after about two hours. This phenomenon cannot be explained otherwise than that the calcium carbonate crystallization is a limiting partial event of the causticizing event in the initial step of the causticizing. The reason for this is that the solution has to be very supersaturated in respect of the calcium carbonate, before it begins to crystallize, there being very few so-called mother ~ i _ 9a 12 79~.S7 22203-248 crystals in the beginning, on top o~ which the calcium carbonate could settle. By adding calcium carbonate or lime sludge into green liquor in conventional causticizing, the causticizing can be accelerated, particularly in its initial step. In addition, in this way one achieves also the advantage that the produced calcium carbonate ~' 9~L5~7 22203~248 i.e. lime sludge has greater crystals, whereby the clarifica-tion or filtering of the white liquor becomes easier and more ra-pid. The white liquor obtained is purer, and the lime sludge obtained i8 easier to wash and purer.
With the method according to the invention the following advanta-ges are achieved:
- It is posYible to obtain a white liquor, of which the concen-tration of active alkali is higher than with present causticizing methods and thus e.g. the heat consumption in a pulp cooking pro-cess is reduced and the chemical charge of the regeneration pro-cess of chemicals is lower. The heat consumption of the evapora-tion plant and the lime sludge reburning kiln decreases, the chemical losses as well.
- A purer white liquor i9 obtained and thus the problems caused by e.g. incrusts are reduced.
- Smaller space requ~rement and smaller investment costs.
- Simple adjustment.
~.
Claims (3)
1. A process for causticizing an aqueous alkali carbonaceous solution with calcium oxide and/or hydroxide by contacting the aqueous alkali carbonaceous solution with calcium oxide and/or hydroxide and separating an alkali hydroxide solution produced in the causticizing from a calcium carbonate precipitate, character-ized in that the aqueous alkali carbonaceous solution is conducted through a bed which has been formed by mixing the calcium oxide and the calcium carbonate with an already causticized alkali solution and by withdrawing excess alkali solution.
2. A process according to claim 1, characterized in that the aqueous alkali carbonaceous solution is led through the bed of calcium oxide (calcium hydroxide) and calcium carbonate in at least two steps, so that into the first step is led the partly causticized aqueous solution displaced from the second step, the carbonate molar quantity of which is greater than the total calcium hydroxide and oxide molar quantity of the bed before displacement.
3. A process according to either claim 1 or 2, characterized in that the aqueous alkali carbonaceous solution is conducted through a bed of calcium hydroxide and calcium carbonate mother crystals and through a calcium carbonate mother crystal bed below it.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA 526272 CA1279157C (en) | 1986-12-24 | 1986-12-24 | Process for causticizing of an aqueous solution containing alkali carbonate |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA 526272 CA1279157C (en) | 1986-12-24 | 1986-12-24 | Process for causticizing of an aqueous solution containing alkali carbonate |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1279157C true CA1279157C (en) | 1991-01-22 |
Family
ID=4134638
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA 526272 Expired - Fee Related CA1279157C (en) | 1986-12-24 | 1986-12-24 | Process for causticizing of an aqueous solution containing alkali carbonate |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1279157C (en) |
-
1986
- 1986-12-24 CA CA 526272 patent/CA1279157C/en not_active Expired - Fee Related
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