FR2736932A1 - METHOD AND DEVICE FOR THE CONTINUOUS CRYSTALLIZATION OF A COMPOSITION CONTAINING SUGAR AS A LAST CRYSTALLIZATION JET - Google Patents

Abstract

A method for crystallising sugar from a sugar-containing composition having a non-sugar content which is such that the purity of the composition is of around 80-84. The method comprises continuously vacuum mixing the composition in a continuous vacuum mixer to crystallise the sugar contained in the composition.

Description

CONTINUOUS CRYSTALLIZATION PROCESS AND DEVICE
OF A COMPOSITION CONTAINING SUGAR AS A LAST JET
OF CRYSTALLIZATION.

 The present invention relates to a method and device for continuous crystallization of a composition containing sugar, as a last crystallization jet.

 The purpose of crystallization in a sugar refinery is to extract in crystallized form, with as high a yield as possible, the sugar (sucrose) dissolved in a syrup and thus to separate it from the soluble impurities (non-sugars) collected in the molasses.

 This process is based on related physical parameters such as solubility, viscosity, temperature, internal agitation without forgetting the criteria of purity (percentage of sugar on dry matter) and possible chemical degradation under certain conditions.

 The industrial operation is done by successive crystallizations called jets: according to the different diagrams in 4, 3 or 2 jets.

 - The first jet, which has the highest purity, is the sugar extraction jet enabling the quality objective of the desired sugar to be satisfied.

 - The last jet, or low product jet, which has the lowest purity is the molasses extraction jet aiming for the highest possible yield of crystallized sugar called exhaustion of molasses. The large amount of non-sugar in this jet slows the rate of crystallization.

To obtain the last jet of crystallization, one generally operates in a workshop comprising:
1.1 a rapid crystallization device in a continuous or discontinuous cooking appliance: the crystals are formed by sowing and magnification at a fixed temperature (from 75 ° C. to 85 ° C.) by maintaining by evaporation a given supersaturation of the supply syrup ;
the crystallized mass (or cooked mass) formed passes through a buffer casting mixer;
in this phase, it is necessary to adjust the purity of the baked mass formed to an optimal value required to obtain good exhaustion of the final molasses: this desirable purity is between 75 and 80: it results from a compromise between the rate of crystallization as a function of the sugar content and of the compactness of the baked mass linked to the crystal content;
1.2 taking into account the concentration of non-sugars, it is necessary to continue crystallization by slow and gradual cooling in a generally continuous mixing chain (example: vertical mixer type);
this device allows
to cool the cooked mass to an optimal temperature (approximately 40 "C);
to properly regulate the temperature drop during mixing (0.8 to 1 C / hour) by exchange with a fluid;
to adjust by dilution the proportion of non-sugars I water as a function of the temperature so as to obtain at any time the speed of crystallization at its maximum value: this is achieved by means of diluents;
reheating by means of a fluid at the end of kneading the cooked mass to a temperature compatible with the separation of the crystals on centrifuges (mechanical strength of the machines): temperature 45 to 55 ° C .;
one of the most important factors is the sufficient duration of mixing to obtain the targeted exhaustion of molasses:
most workshops require 40 to 60 hours of residence time to obtain molasses of purity 58 to 62 in the form of 4 vertical mixers: 3 in progressive cooling and 1 in heater;
the optimal adjustment of the purity of the cooked mass in a cooking appliance is not always possible: the purity of the syrups for feeding the last jet is often too high due to the overall pattern of crystallization for example, they are a function the purity of feed of the first jet which is very dependent on the quality of the raw material (beets);
1.3 pre-turbining
to correct this purity when it is too high, the pre-turbination process is conventionally used.

This process represents, compared to a re-entry of molasses in cooking appliances or kneaders, the advantage of avoiding the recycling of non-sugars and colors detrimental to the quality of brown sugar due to the long residence times;
it consists in removing during the mixing a proportion of cooked mass, extracting the crystals by centrifugation and recycling the centrifugation syrup (pseudo-molasses) in the rest of the cooked mass;
the sample can be taken from the casting mixer or from the first third of the mixers at a percentage calculated so as to reduce the crystal population;
it is compulsory to recycle the pseudo-molasses of the demulsed pre-turbination and devoid of micro crystals: this involves reheating equipment and a demulsification device (possibly under vacuum);
1.4 the cooked mass warmed at the end of mixing is wrung on centrifuges to give the final molasses and the final brown sugar;
this brown sugar and that from the pre-turbination are recycled in the form of a recast in the jet preceding the last jet;
it generally has the following characteristics: purity 94 to 96 coloration 3,500 to 4,500 ICUMSA;
to produce high purity white sugar in the first jet, we can use the refining of brown sugar last jet;
the ripening includes the mixing of the brown sugar with the syrup for feeding the last jet: this phase is called mashing;
the magma thus obtained is spun on a centrifuge producing a refined brown sugar of high purity (P 98 to 99) and much less colored (1,000 to 1,200 ICUMSA);
the syrup produced during the refining process is recycled to supply the last jet.

 French Patent No. 1,368,118 describes a crystallization process consisting in removing a part of the cooked mass from a cooking appliance, subjecting it to a blasting operation and reinjecting the mother liquor thus obtained, at the level of one of the crystallization stages. This process requires additional turbination on the one hand, leads to a loss of energy not used for crystallization, on the other hand. Furthermore, by taking up a large part of the mass cooked, the crystallization surface of the remaining cooked mass which is directed towards the mixer is reduced. This reinjected mother liquor spontaneously crystallizes by cooling, giving parasitic grains of small size which pass through the sieve of the centrifuges. which further reduces the extraction of crystals from the entire jet.

 French Patent No. 2,534,595 relates to a process for crystallizing a sugar syrup which consists in subjecting the syrup to continuous or discontinuous baking so as to obtain a baked mass and to subject the baked mass to continuous mixing under vacuum and then turbination making it possible to separate the crystals from the mother liquor known as the "lean sewer" from the crystallization jet under consideration, characterized in that the lean sewer from the crystallization jet under consideration is partly recycled during the steps of kneading under vacuum. the poor non-recycled sewer is directed to the next stream to be crystallized.

 This process as described is inapplicable to the treatment of the last crystallization jet, because the continuous mixing under vacuum, at this stage, is insufficient to obtain sufficient exhaustion of the mother liquor.

 In addition, this mother liquor is the final jet in the final molasses, the impurity rate of which prevents any crystallization in a following jet.

 One of the aspects of the invention is to propose a crystallization process which makes it possible to obtain the same results of depletion of the mother liquor of the last crystallization jet as the conventional processes but in a treatment time significantly reduced by half.

 One of the other aspects of the invention is also to provide a device making it possible to reduce the degradation of the sugar, therefore the losses in sucrose, and to improve the quality of the white sugar obtained on the first jet.

 One of the other aspects of the invention is to provide a crystallization process making it possible to suppress a crystallization jet in general 4-jet or 3-jet processes.

 One of the other aspects of the invention is to provide a simplified crystallization process allowing a gain in investment in material and in energy need.

 The subject of the invention is a process for crystallizing sugar from a composition containing sugar and a level of non-sugar such that the purity of the composition is from approximately 80 to approximately 84, characterized in that it comprises continuous mixing under vacuum of the above composition using a continuous vacuum mixer in order to crystallize the sugar contained in the composition.

 Purity is defined as the percentage of sucrose in the dry matter.

 According to an advantageous embodiment, in the process of the invention, the composition, at the outlet of the continuous vacuum mixer is separated into two fractions, in a ratio of about 0.66 to about 1.22, and advantageously in substantially equal mass, one of the fractions being treated so as to separate the sugar from the mother water, the mother water also being designated by pseudo-molasses, which is recycled in the continuous mixer under vacuum.

According to another advantageous embodiment, the method of the invention comprises the following steps
- At the outlet of the continuous vacuum mixer, the composition is separated into a first and a second fraction, in a ratio: second fraction to first fraction by weight, of approximately 0.66 to approximately 1.22, in particular using pumps,
the first fraction of the baked mass is treated by means allowing the crystallization to continue, for example by cooling, advantageously in vertical mixers,
- The second fraction is subjected to a pre-turbination step giving on the one hand pre-turbo sugar and on the other hand pseudo-molasses, which is recycled in the continuous mixer under vacuum.

 Advantageously, in the process of the invention, the continuous kneading under vacuum is carried out under a vacuum of about 900 x 102 Pa to about 920 x 102 Pa, corresponding to a temperature of the composition of about 65 "C. at around 60 "C, for a period of approximately 2 hours 30 minutes to approximately 4 hours, advantageously for a period of approximately 3 hours.

 According to an advantageous embodiment, the crystallization process comprises several successive crystallizations, also designated by "jets", in particular 2, 3 or 4 jets, and is characterized in that the above composition is a baked mass of the last so-called candy jet "base products" containing water, dissolved sugar, non-sugars and sucrose crystals, which composition advantageously comes from a so-called "sewer" sugar syrup from the jet preceding the above-mentioned last jet, which sugar syrup is previously subjected to a continuous or discontinuous cooking operation.

 The term “non-sugar” denotes dry matter other than sucrose.

 By dissolved sugar, is meant sucrose dissolved in mother water of the composition.

 By continuous cooking operation is meant, for example, a device allowing continuous magnification of the sucrose crystals of a composition previously containing small crystals. This device called continuous cooking works continuously without periodic emptying.

 To fix the ideas, the average opening of the crystals before the baking operation is 0.2 mm to 0.3 mm and at the end of the baking operation, it is 0.5 mm to 0, 6 mm.

 By discontinuous cooking operation is meant, for example, a device allowing formation of crystals by sowing and then a magnification of these crystals. This device called discontinuous baking works discontinuously with emptying as soon as the height of the cooked mass in the appliance has reached a maximum value (that is to say as soon as the appliance is full).

In the process of the invention, the composition, in particular the cooked mass at the inlet of the continuous vacuum mixing has the following characteristics
- percentage by weight of dry matter: 94 to 93.5;
- purity of the cooked mass: 80 to 84;
- sucrose crystal content: 37% to 40% by weight of the cooked mass;
- purity of the mother liquor: 67 to 70;
and the composition, in particular the baked mass, at the end of the continuous vacuum mixing has the following characteristics
- percentage by weight of dry matter: 94 to 93.5
- purity of the cooked mass: 76 to 79;
- sucrose crystal content: 30 to 35% by weight of the cooked mass;
- purity of the mother liquor: 63 to 65;
the increase in% by weight of the crystals between the inlet and the outlet of the vacuum mixer being from approximately 15% to approximately 250%
The increase in weight of the crystals results essentially from the magnification of the crystals entering the continuous mixer under vacuum; there is indeed very little or no formation of new crystals in the continuous vacuum mixer.

 In the process of the invention, the temperature of the composition, in particular of the cooked mass on its entry into the continuous mixer under vacuum, is from about 75 "C to about 85" C, and at its exit has a temperature d 'about 60 "C to about 65" C.

 In the process of the invention, the pseudo-molasses defined above is advantageously reheated to a temperature of approximately 86 "C to approximately 88" C, then this aforementioned pseudo molasses is then reintroduced into the continuous mixer under vacuum, in order to regulate the percentage by weight of crystals of the cooked mass treated in the continuous vacuum mixing, this percentage being advantageously from approximately 30% to approximately 35% by weight of the cooked mass (in the continuous vacuum mixer ).

 In the process of the invention, the two pumps which drive the two fractions of the composition, in particular of the cooked mass, regulate the height of the cooked mass in the continuous vacuum mixer, the percentage of crystals in the cooked mass being advantageously regulated by the speed ratio of the two pumps.

 To fix the ideas, and without limitation, the ratio of the flow rates of the two pumps is approximately 0.66 to approximately 1.22, in particular approximately 1.

According to one embodiment of the method of the invention, the composition, in particular in the baked mass, at the outlet of the vertical mixers, the molasses are separated, on the one hand from a purity of about 58 to about 62, and d on the other hand, brown sugar, with a coloration of approximately 3000 ICUMSA, in particular by turbination, which brown sugar is subjected to a pasting, in particular using a sewer, advantageously having the following characteristics:
purity: 80 to 84;
- percentage by weight of dry matter: 78;
and advantageously using sugar syrup called "sewer" from the jet preceding the last jet, which drain is taken before continuous or discontinuous cooking, defined above.

 In the process of the invention, the sugar coming from the pasting is subjected to a refining step to give on the one hand a refined sugar of coloring of approximately 1000 to 1200 ICUMSA, and on the other hand a refining sewer a dry matter percentage of about 80 and a purity of about 81 to about 82.

In the process of the invention, the pre-turbo sugar defined above, exhibiting in particular a coloration of approximately 1000 to approximately 3000 ICUMSA:
either is mixed, before mashing, with brown sugar from the turbination stage defined above,
- Either is introduced into the refined sugar obtained at the end of the refining step defined above.

In the process of the invention, the refined sugar defined above is added or not with pre-turbo sugar defined above, is advantageously remelted using first-throw sugar syrup having the following characteristics:
- percentage by weight of dry matter: 71;
- purity: 93 to 94;
to obtain a sugar syrup called "redesign syrup" having the following characteristics:
- percentage by weight of dry matter: 74 to 75;
- purity: 93.5 to 94.5;
this redesign syrup being recycled in one of the jets preceding the last jet, advantageously in the first jet.

 Advantageously, in the process of the invention, the refining sewer defined above is recycled into the sewer before the continuous or discontinuous cooking defined above.

The invention relates to a device for crystallizing a final crystallization jet, comprising
- one or more cylindrical mixers (6) comprising:
input means (6a) of the terracotta connected to the output
the casting mixer (4) and the outlet means (6b, 6c)
one of the means of mass output,
cooked (6b) being connected to preturbining means (11),
which pre-turbination means give on the one hand a
pseudo-molasses, and secondly turbinated sugar,
input means (6d) of the pseudo-molasses connecting the
output means (1 la) of the pre-turbination means (11)
to recycle the preheated pseudo-molasses
by means of heating (14) in the (the)
cylindrical mixer (s) (6).

Advantageously, the crystallization device of a final crystallization jet of the invention comprises
- one or more cylindrical mixers (6) comprising:
. input means (6a) of the terracotta connected to the output
the casting mixer (4) and the outlet means (6b, 6c)
one of the means of mass output,
cooked (6b) being connected to preturbining means (11),
which pre-turbination means give on the one hand a
pseudo-molasses, and secondly turbinated sugar,
. input means (6d) of the pseudo-molasses connecting the
output means (1 la) of the pre-turbination means (11)
to recycle the preheated pseudo-molasses
by means of heating (14) in the (the)
cylindrical mixer (s) (6) ;;
- one or more vertical mixers (15, 16) comprising inlet means (1 Sa) connected to outlet means for the baked mass (6c), and outlet means (16a);
- turbine means (22) connected to the outlet means (16a) of the vertical mixers.

According to another embodiment of the invention, the device for crystallizing a final crystallization jet, comprises
- a drain pan (20) containing sugar syrup from the jet preceding the last crystallization;
- means of continuous or discontinuous cooking (2) connected to an outlet of the drain pan (20);
- a casting mixer (4) connected to the outlet of the continuous or discontinuous cooking means (3);
- one or more cylindrical mixers (6) comprising:
input means (6a) of the terracotta connected to the output
the casting mixer (4) and the outlet means (6b, 6c)
one of the means of mass output,
cooked (6b) being connected to preturbining means (11),
which pre-turbination means give on the one hand a
pseudo-molasses, and secondly turbinated sugar,
input means (6d) of the pseudo-molasses connecting the
output means (1 la) of the pre-turbination means (11)
to recycle the preheated pseudo-molasses
by means of heating (14) in the (the)
cylindrical mixer (s) (6);
- one or more vertical mixers (15, 16) comprising inlet means (15a) connected to outlet means for the baked mass (6c), and outlet means (16a);
- turbine means (22) connected to the outlet means (16a) of the vertical mixers;
- pasting means (25) connected to the turbine means (22), to the drain pan (20) and possibly connected to the outlet corresponding to the pre-turbo sugar of the pre-turbo means (11);
- refining means (27) connected to the pasting means (25), the outlet of the refining means corresponding to the refined sugar possibly being connected to the outlet corresponding to the pre-turbo sugar of the pre-turbo means (11).

 The characteristics of the invention are essentially at the level of phases and devices 1-1, 1-2 and 1-3 described above as follows from the example below.

 Figure 1 schematically shows a device for implementing the invention.

Example
In the invention, the rapid crystallization process in a continuous or discontinuous cooking appliance is associated with the continuous vacuum mixing process (MCSV) applied to low purities 80-84 which can be carried out in 1 or 2 successive stages.

 A sugar syrup 1 (percentage by weight of dry matter = 78, purity: 80 to 84) coming from the drain pan 20 of the jet preceding the last crystallization jet is introduced into a cooking appliance 2, continuously or discontinuously, to give a baked mass of low products.

The cooked mass 3a leaving the casting mixer, if the cooking appliance is a discontinuous cooking or leaving directly from the cooking appliance if it is a continuous cooking, is extracted by a pump and is directed to a mixing device continuous vacuum 6, the characteristics of which are as follows:
. length: 3.2 m
diameter: 1.4 m
. total volume: 5 m3
motor power: 3 kW
. agitator rotation speed: 2 rpm.

The characteristics of the cooked mass 3a entering the continuous vacuum mixer are as follows:
percentage by weight of dry matter: 93.91 g% g
. throughput: 0.95 T / h
. crystals: 38.2% of the baked mass, ie 0.36 T / h
purity of the baked mass: 81.56
. purity of mother liquor: 68.84
temperature of the terracotta: 80 "C.

 The residence time of the cooked mass in the continuous vacuum mixer is approximately 3 hours.

 In the continuous vacuum mixer, there is a lowering of the temperature by self-evaporation under vacuum in a continuous regime of the water in the cooked mass.

 This causes effective and permanent agitation over a small and uniform thickness of baked mass, an acceleration factor for the rate of crystallization.

 The magnification of the crystals is ensured by recycling from the bottom and over the entire length of the mixer of the heated pseudo-molasses, thereby achieving the fluidification of the cooked mass.

 The essential difference between the continuous vacuum mixer and the other types of crystallizers is that the cooling is done by auto evaporation and not by exchange with a fluid.

The characteristics of the cooked mass leaving the mixer 6 are as follows:
. percentage by weight of dry matter: 93.19
throughput: 1.29 T / h
. crystals: 35.2% of the baked mass, i.e. 0.45 T / h
purity of the baked mass: 77.21
purity of mother liquor: 63.34
terracotta temperature: 65.5 "C.

 The ratio: weight of crystals taken out / weight of crystals entered is 1.25.

 At the outlet of the continuous vacuum mixer, the cooked mass is separated into two substantially equal fractions, 9 and 10, using pumps 7 and 8.

The fraction 9 is subjected to a pre-turbination in a turbine 11 to separate the pre-turbined sugar 12 from the pseudo-molasses 13 consisting of mother liquor, dissolved sugar and impurities. The characteristics of the pseudo-molasses after reheating through a heater 14 are as follows:
. percentage by weight of dry matter: 87.88
. flow rate: 0.35 T / h
. purity: 64.78
. temperature: 87.5 "C.

 The pre-turbinated mass flow rate is approximately 0.53 T / h (item 19), or 41% of the outgoing mass mass.

 The value of the vacuum in the continuous vacuum mixer at 18 is 113.33 mbar absolute.

 The "flash" produced at the inlet of the continuous vacuum mixer ensures at the same time the demulsion of the recycled pseudo-molasses: its reheating 14 causes additional crystallization by its rapid self-evaporation in the vacuum mixer.

 Due to the turbulent regime created by the entry of the cooked mass and of the reheated pseudo-molasses, it is possible to adjust the percentage of crystals of the cooked mass leaving the MCSV to an optimal value to obtain good exhaustion of the final molasses by the proportion and the distribution of the recycling of pseudo-molasses.

 The crystallization speed is 5 times higher than in the traditional process with cooling of 15 "C in 3 hours and recycling of pseudo-molasses of 30-35% MC input.

 Part of the cooked mass 10 is directed to the vertical mixers 15 and 16.

 The mass flow rate to the vertical mixers (item 17) is 0.76 T / h.

 The cooked MCSV output is then treated in a conventional kneading, continuous vertical type, as described above, of reduced duration (20 to 25 hours) to allow the same exhaustion of the final molasses to be achieved as the conventional scheme (purity: 58 to 62).

 The residence time in vertical mixers is 20 to 25 hours.

The temperature of the cooked mass at the outlet of the vertical mixers is from 45 "C to 55" C (item 21). The cooked mass undergoes a turbination 22, to give molasses 23 of purity from 58 to 62, and brown sugar 24, of coloration 3000 ICUMSA, which brown sugar is subjected to a pasting in a pasting 25, using sugar syrup 26 from drunk drain pan 20.

 The pre-turbo sugar 12 can be partly mixed with brown sugar before the pasting operation.

 After the pasting, the sugar is subjected to a refining 27, using water 28, to give a refined sugar 29 of coloring 1000 to 1200 ICUMSA and a refining sewer 30, of percentage by weight of dry matter of 80 and purity of 81, which is recycled in the drain pan 20.

 Pre-turbo sugar 12 can be partly combined with refined sugar 29.

 The refined sugar 29 is then subjected to an overhaul 31, of percentage by weight of dry matter from 74 to 75 and of purity 93.5 to 94.5, using first-jet syrup 32 (percentage by weight of matter dry: 71; purity: 93 to 94), then the syrup 33 from the redesign is sent to the crystallization of the first jet.

 The refining device as described above can be used to achieve the production of high purity white sugar in the first stream.

 Some of the advantages which the invention allows to be achieved are given below.

 The method and device for crystallization as a last candy jet according to the invention has the advantages indicated below.

 By introducing the continuous vacuum mixing process and device applied to low purities, the residence time in the final jet workshop is considerably reduced while obtaining the same molasses depletion results, ie in total 23 to 28 hours instead of 40 to 60 hours.

I1 results in a reduction in material dimensions
- fewer conventional cooling mixers, for example of the vertical type: either 2 devices instead of 4;
- no device for demulsing pseudo-molasses.

 The crystallization process according to the invention can be qualified as "cold crystallization". It considerably reduces any phenomenon of recoloration of baked mass linked to the residence time by thermal and chemical degradation.

 This clearly appears in the results concerning the coloring of the brown sugar obtained.

 This therefore results in less losses of sucrose since the coloring matters are the result of the degradation of the sugar and an improvement in the quality of the white sugar produced in the first jet.

 Due to the appreciable improvement in the crystallization speed in the process of the invention, linked to the MCSV device, the process can be applied to higher purities of syrup for the last spray while obtaining the purity. of cooked mass at the optimum outlet for the exhaustion of molasses.

 This process therefore allows identical exhaustion of molasses to suppress a crystallization jet for general patterns in 4 jets or 3 jets.

 In this case, this results in a significant gain in investment in equipment.

The general crystallization scheme thus simplified allows a gain
substantial in energy need:
- due to the suppression of a jet;
- less use of water during turbines linked to the improvement of
product quality. To fix the ideas, the amount of water used is
reduced by about 50% compared to the amount of water used in the
prior art methods.

Claims (14)

 1. A process for crystallizing sugar from a composition containing sugar and a level of non-sugar such that the purity of the composition is from approximately 80 to approximately 84, characterized in that it comprises a continuous kneading under vacuum of the above composition using a continuous vacuum mixer in order to crystallize the sugar contained in the composition.  2. Method according to claim 1, comprising the following steps  - At the outlet of the continuous vacuum mixer, separation of the composition into a first and a second fraction, in a ratio: second fraction to first fraction by weight, of about 0.66 to about 1.22, in particular at using pumps,  the first fraction of the cooked mass being treated by means making it possible to continue crystallization, for example by cooling, advantageously in vertical mixers,  - The second fraction being subjected to a pre-turbining step giving on the one hand pre-turbo sugar and on the other hand pseudo-molasses, which is recycled in the continuous mixer under vacuum.  3. Method according to one of claims 1 or 2, characterized in that the continuous mixing under vacuum is carried out under a vacuum of about 900 x 102 Pa to about 920 x 102 Pa, corresponding to. a temperature of the composition of approximately 65 "C to approximately 60" C, for a period of approximately 2:30 to approximately 4 hours, advantageously for a period of approximately 3 hours.  4. A crystallization method according to any one of claims 1 to 3, comprising several successive crystallizations, also designated by "jets", in particular 2, 3 or 4 jets, characterized in that the above composition is a baked mass of the last jet so-called "low product" candy containing water, dissolved sugar, non-sugars and sucrose crystals, which composition advantageously comes from a so-called "sewer" sugar syrup from the jet preceding the above-mentioned last jet, which sugar syrup is previously subjected to a continuous or discontinuous cooking operation.  5. Method according to any one of claims 1 to 4, characterized in that the composition, in particular the cooked mass at the inlet of the continuous mixing under vacuum has the following characteristics  - percentage by weight of dry matter: 94 to 93.5;  - purity of the cooked mass: 80 to 84;  - crystal content: 37% to 40% by weight of the cooked mass;  - purity of the mother liquor: 67 to 70;  and in that the composition, in particular the baked mass, at the end of the continuous mixing under vacuum has the following characteristics  - percentage by weight of dry matter: 94 to 93.5  - purity of the cooked mass: 76 to 79;  - crystal content: 30 to 35% by weight of the baked mass;  - purity of the mother liquor: 63 to 65;  the increase in% by weight of the crystals between the inlet and the outlet of the vacuum mixer being from approximately 15% to approximately 25%.  6. Method according to any one of claims 1 to 5, characterized in that the temperature of the composition, in particular of the cooked mass on its entry into the continuous vacuum mixer, is approximately 75 "C to approximately 85" C, and at its outlet has a temperature of about 60 "C to about 65" C.  7. Method according to any one of claims 1 to 6, characterized in that the pseudo-molasses is subjected to reheating advantageously at a temperature of about 86 "C to about 88" C, the above pseudo molasses being then reintroduced in the continuous vacuum kneader, in order to regulate the percentage by weight of crystals of the cooked mass treated in the continuous vacuum kneading, this percentage being advantageously from about 30% to about 35% by weight of the cooked mass.  8. Method according to any one of claims 1 to 7, characterized in that the two pumps which drive the two fractions of the composition, in particular of the baked mass regulate the height of the baked mass in the continuous mixer under vacuum, the percentage of crystals in the baked mass being advantageously regulated by the speed ratio of the two pumps.  9. Method according to any one of claims 1 to 8, characterized in that in the composition, in particular in the cooked mass, at the outlet of the vertical mixers, on the one hand the molasses are separated, in particular of purity of about 58 to approximately 62, and on the other hand brown sugar, of coloring of approximately 3000 ICUMSA, in particular by turbination, which brown sugar is subjected to a pasting, in particular using a sewer, advantageously having the following characteristics:  - purity: 80 to 84;  - percentage by weight of dry matter: 78;  and advantageously with the aid of so-called "sewer" sugar syrup from the jet preceding the last jet, which drain is taken before continuous or discontinuous cooking, defined in claim 4.  10. Method according to any one of claims 1 to 9, characterized in that the sugar coming from the pasting is subjected to a refining step to give on the one hand a coloring sugar of approximately 1000 to 1200 ICUMSA , and on the other hand a refining sewer with a percentage by weight of dry matter of approximately 80 and a purity of approximately 81 to approximately 82.  11. Method according to any one of claims 1 to 10, characterized in that the pre-turbo sugar defined in claim 7, having in particular a coloration of approximately 1000 to approximately 3000 ICUMSA:  either is mixed, before mashing, with brown sugar from the turbine stage defined in claim 9,  - either is introduced into the refined sugar obtained at the end of the refining step according to claim 10.  12. Method according to any one of claims 1 to 11, characterized in that the refined sugar obtained according to claim 10, with or without the addition of pre-turbo sugar defined in claim 2, is advantageously remelted using sugar syrup first jet with the following characteristics:  - percentage by weight of dry matter: 71; - purity:: 93 to 94;  to obtain a sugar syrup called "redesign syrup" having the following characteristics:  - percentage by weight of dry matter: 74 to 75;  - purity: 93.5 to 94.5;  this redesign syrup being recycled in one of the jets preceding the last jet, advantageously in the first jet.  13. Method according to one of claims 1 to 12, characterized in that the refining sewer defined in claim 10, is recycled into the sewer before the continuous or discontinuous baking defined in claim 4.  14. Device for crystallizing a final crystallization jet, comprising:  - a drain pan (20) containing sugar syrup from the jet preceding the last crystallization;  - means of continuous or discontinuous cooking (2) connected to an outlet of the drain pan (20);  - a casting mixer (4) connected to the outlet of the continuous or discontinuous cooking means (3);  - one or more cylindrical mixers (6) comprising:  input means (6a) of the terracotta connected to the output  the casting mixer (4) and the outlet means (6b, 6c)  one of the means of mass output,  cooked (6b) being connected to preturbining means (11),  which pre-turbination means give on the one hand a  pseudo-molasses, and secondly turbinated sugar,  input means (6d) of the pseudo-molasses connecting the  output means (1 la) of the pre-turbination means (11)  to recycle the preheated pseudo-molasses  by means of heating (14) in the (the)  cylindrical mixer (s) (6);  - one or more vertical mixers (15, 16) comprising inlet means (15a) connected to outlet means for the baked mass (6c), and outlet means (16a); ;  - turbine means (22) connected to the outlet means (16a) of the vertical mixers;  - pasting means (25) connected to the turbine means (22), to the drain pan (20) and possibly connected to the outlet corresponding to the pre-turbo sugar of the pre-turbo means (11);  - refining means (27) connected to the pasting means (25), the outlet of the refining means corresponding to the refined sugar possibly being connected to the outlet corresponding to the pre-turbo sugar of the pre-turbo means (11).