RU2017822C1 - Process for refining sugar-containing solution - Google Patents

Abstract

FIELD: sugar industry. SUBSTANCE: this method prescribes carrying out defecation and saturation of solution in several steps with introducing lime into solution in between these steps. Disclosed method further prescribes that lime be introduced for defecation and inbetween saturation steps in amount sufficient to enable it to be solely dissolved and conducting saturation process at each stage until degree of carbonization attains level of 20 to 60 %. EFFECT: greater degree of refinement.

Description

 The invention relates to the sugar industry, and in particular to a technology for the purification of sugar-containing solutions, in particular diffusion juice.

 A known method of purification of diffusion juice, providing for pre-defecation, defecation and saturation with periodic passage of saturation gas through a layer of defecated juice, until the alkalinity of the juice in the apparatus reaches the optimum value (periodic saturation) [1]. As the gas is passed, the alkalinity of the defecated juice decreases from the initial to the optimal juice of the 1st saturation.

 The disadvantage of this method is that for its implementation requires several tanks, the number of which reaches five, and the associated difficulty in automating the process.

 A known method of purification of sugar-containing solutions, providing for progressive predefecation, defecation and saturation. According to the method, calcium hydroxide and carbon dioxide are introduced alternately into the defecated juice with the stages of the appearance of crystallization centers. The method is carried out in a defekosurator, divided in height by horizontal mass transfer plates into sections [2]. Calcium hydroxide is supplied to each section. To implement the method, it is necessary to strictly maintain a countercurrent throughout the apparatus so that the juice with high alkalinity is in contact with a gas of low carbon dioxide content.

The disadvantage of this method is the formation of an insufficient number of centers of crystallization of calcium carbonate, since the juice with high alkalinity is in contact with a gas of low CO ₂ content.

The closest technical solution to the proposed one is the method in which diffusion juice without heating passes through the processing stages in a pre-defecator and defecator, where 2.5-3.0 g and 6.5-7.0 g of CaO per 1 liter of solution are respectively added. Then the juice is heated to 70-80 ^{° C} and in the apparatus saturiruyut special design, consisting of four consecutive chambers. Carbon dioxide is introduced into the lower part of the chambers in countercurrent to the juice. Juice goes from camera to camera. When the juice moves from chamber to chamber, calcium hydroxide is added. When leaving the first chamber, the juice contains 0.11% CaO, from the second - 0.09% CaO, from the third - 0.08% CaO and from the fourth - 0.07% CaO [3].

The disadvantages of the method include the high degree of carbonization of each introduced fraction of lime to the state of grown crystals of CaCO ₃ , which reduces the cleaning effect, as well as contacting the lime sediment with a saturation gas.

 The aim of the invention is to increase the cleaning effect of the sugar-containing solution.

 The goal is achieved by the fact that in the proposed cleaning method, which involves defecation of the solution, its saturation in several stages with the introduction of lime into the solution between them, lime for defecation and between the stages of saturation is introduced in an amount to ensure its dissolution, while the saturation process at each stage is carried out to achieve a degree of carbonization of 20-60%.

 The method of purification of a sugar-containing solution is as follows.

With diffusion juice, progressive predefection is carried out using calcium hydroxide, then defecation is carried out with the amount of lime that can dissolve under these conditions. After defecation, the juice is carbonated to a degree of carbonization of 20-60%, after which calcium hydroxide and carbon dioxide are introduced in stages, moreover, the calcium hydroxide in each portion is contained in such a quantity that the solution is only saturated, i.e. until Ca (OH) ₂ appears in the precipitate. The number of steps depends on the lime taken for cleaning and its solubility. After each batch of Ca (OH) ₂ , carbon dioxide (saturation gas) is introduced into the solution to the degree of carbonization of each batch of 20-60% and so many times until all the lime taken for cleaning is used up. The last stage is completed in the existing apparatus of I saturation.

When carbon dioxide is introduced into a defecated juice containing an excess of calcium hydroxide, the reaction proceeds in two directions: with dissolved Ca (OH) ₂ and in the sediment. The content of dissolved Ca (OH) ₂ decreases and reaches a minimum value at 30-35% degree of carbonization of calcium hydroxide. Since lime is present in the sediment, it must restore calcium hydroxide that has left the solution to form CaCO ₃ . However, such a recovery is not observed. In this case, we have just the case when the lime, which is in excess (in the sediment), loses its activity due to its interaction with carbon dioxide. The activity of such lime corresponds to the activity of a suspension of Ca (OH) ₂ obtained from low quality limestone, or in case of gross violations of the firing regime, which led to the formation of a skip. The amount of such lime may be 1.5-2.0% by weight of the juice, i.e. most of it from the initial amount, if we take the total consumption of lime in 2.2-2.5%.

In the proposed method, firstly, an excess of lime (precipitate) does not come into contact with CO ₂ , because a precipitate is not allowed, and secondly, after Ca (OH) _{2 is} added to the juice and dissolved, CO ₂ is introduced and, thus, affect juice with a high concentration of Ca (OH) _{2 with a} saturation gas with a high content of CO ₂ ; thirdly, we can assume that all the lime taken for cleaning is first transferred to the solution, after which crystallization centers are formed, the concentration of which reaches a maximum value; fourthly, lime taken for cleaning is completely and completely used only in its active form, i.e. in the form in which milk of lime is formed and which corresponds to the use of lime in the first stage of periodic saturation.

PRI me R 1. The prototype method. Take 2 L diffusion juice (purity coefficient = 84.6%) with a temperature of 40 ^C, was added 0.5% CaCO ₃ slurry, and then portsialno administered within 10 min of lime milk in an amount of 0,3% CaO by weight of the juice, so that the alkalinity of the juice progressively increases to a pH of 11.2 (progressive predefection). Then preliming juice was added with stirring 0,7% CaO by weight of juice is heated 10 minutes (cold defecation), heated to ⁸⁰ ° C and for 10 minutes with stirring again incubated (hot defecation). After this, the defecated juice is saturated with alkali 0.11% CaO (degree of carbonization ≈82%) to alkalinity - the first stage of saturation. Then, 0.5% CaO to the mass of juice is introduced into the juice and 0.09% CaO is carbonated to alkalinity (degree of carbonization ≈84%) - the second stage. Then, 0.5% CaO to the mass of juice is again introduced into the same juice and 0.08% CaO is saturated to alkalinity (carbonization degree ≈86%) - the third stage. The last portion of lime is introduced into the juice - 0.5% CaO to the mass of juice and final saturation is made until alkalinity is 0.07% CaO (carbonization level ≈88%) - the fourth stage. After step I saturation, the juice is filtered. The filtrate is heated to 90 ^about C, add 0.25% CaO to the mass of juice, incubated for 3 min (defecation before II saturation), then carry out II saturation to pH 9.3. After filtration, the purity and purification effect are determined in the juice. They have the following results: the benignity of juice of the second saturation was 89.4%, the cleaning effect of 35.2%.

PRI me R 2. The proposed method. Take 2 L diffusion juice (purity coefficient = 84.6%) with a temperature of 40 ^C, was added 0.5% CaCO ₃ slurry, and then portsialno administered within 10 min of lime milk in an amount of 0,3% CaO by weight of the juice, so that the alkalinity of the juice progressively rises to a pH of 11.2 (progressive predefection). Then preliming juice was added with stirring 0,7% CaO by weight of juice is heated 10 minutes (cold defecation), heated to ⁸⁰ ° C and for 10 minutes with stirring again incubated (hot defecation). After this, the defecated juice is saturated to alkalinity with 0.4% CaO (degree of carbonization ≈40%) - the first stage of saturation. Then, 0.5% CaO to the mass of juice is introduced into the juice and 0.3% CaO is saturated to alkalinity (carbonization degree ≈40%) - the second stage. Then lime is again introduced into the same juice in an amount of 0.5% CaO to the mass of the juice and saturated with alkalinity 0.3% CaO (carbonization degree ≈40%) - the third stage. And, finally, the last portion of 0.5% CaO lime to the juice mass is introduced into the juice and the final saturation to alkalinity is 0.07% CaO (carbonization degree 88%). After that, the precipitate is filtered off. The filtrate is heated to 90 ^° C, 0.25% CaO is added to the juice mass, incubated for 3 minutes (defecation before II saturation), then II saturation is carried out to pH 9.3 and filtered. After filtration, the purity and purification effect are determined in the juice. They have the following results: the benignity of juice of the second saturation was 90.0%, the purification effect of 38.7%. The increase in the cleaning effect in comparison with the prototype was 3.5%.

PRI me R 3. Take 2 l of diffusion juice (DB = 84.6%) with a temperature of 40 ^about C and clean as in example 2, but at the first saturation, saturation after the introduced portions of lime is carried out to a degree of carbonization equal to 20% . After that, the precipitate is filtered off. The filtrate is heated to 90 ^° C, 0.25% CaO is added to the juice mass, incubated for 3 minutes (defecation before II saturation), then II saturation is carried out to pH 9.3 and filtered. After filtration, the purity and the cleaning effect are determined in the juice. They have the following results: the benignity of juice of the second saturation was 89.8%, the purification effect of 37.8%. The increase in the cleaning effect in comparison with the prototype (example 1) was 2.6%.

PRI me R 4. Take 2 l of diffusion juice (DB = 84.6%) with a temperature of 40 ^about C and cleaned as in example 2, but at the first saturation saturation after the introduced portions of lime is carried out to a degree of carbonation equal to 60% . After that, the precipitate is filtered off. The filtrate is heated to 90 ^° C, 0.25% CaO is added to the juice mass, incubated for 3 minutes (defecation before II saturation), then II saturation is carried out to pH 9.3 and filtered. After filtration, the purity and the cleaning effect are determined in the juice.

 They have the following results: the benignity of the juice of the second saturation was 90.0%, the purification effect of 38.4%. The increase in the cleaning effect in comparison with the prototype was 3.2%.

PRI me R 5. Take 2 l of diffusion juice (DB = 84.6%) with a temperature of 40 ^about C and cleaned as in example 2, but at the first saturation saturation after the introduced portions of lime is carried out to a degree of carbonation equal to 18% . After that, the precipitate is filtered off. The filtrate is heated to 90 ^° C, 0.25% CaO is added to the juice mass, incubated for 3 minutes (defecation before II saturation), then II saturation is carried out to pH 9.3 and filtered. After filtration, the purity and the cleaning effect are determined in the juice. They have the following results: the benignity of juice of the second saturation was 89.6%, the cleaning effect of 36.0%. The increase in the cleaning effect in comparison with the prototype (example 1) was only 0.8%.

PRI me R 6. Take 2 l of diffusion juice (DB = 84.6%) with a temperature of 40 ^about C and cleaned as in example 2, but at the first saturation saturation after the introduced portions of lime is carried out to a degree of carbonization of 62%. After that, the precipitate is filtered off. The filtrate is heated to 90 ^° C, 0.25% CaO is added to the juice mass, incubated for 3 minutes (defecation before II saturation), then II saturation is carried out to pH 9.3 and filtered. After filtration, the purity and the cleaning effect are determined in the juice.

 They have the following results: the benignity of the juice of the second saturation was 89.6%, the cleaning effect of 35.9%.

 The increase in the cleaning effect in comparison with the prototype (example 1) was only 0.7%. As can be seen from examples 5 and 6 outside the range of the degree of carbonization of 20-60%, the cleaning effect increases slightly, only 0.7-0.8%. At the same time from examples 2-4 it follows that the greatest increase in the cleaning effect is observed in the range of the degree of carbonization of 20-60% and ranges from 2.6-3.5%.

 Thus, the advantages of the proposed method are to increase the cleaning effect of the sugar-containing solution by 2.6-3.5%. Using the proposed method will increase the sugar yield by 0.02-0.04% by weight of processed beets.

Claims (1)

 METHOD FOR CLEANING A SUGAR-CONTAINING SOLUTION, which involves defecating a solution and its saturation in several steps with the introduction of lime into the solution between them, characterized in that lime for defecation and between the degrees of saturation is introduced in an amount that ensures only its dissolution, while the saturation process at each stage is carried out to achieve a degree of carbonization of 20-60%.