ITUD950013A1 - WALL DEFORMATION CONTROL PROCEDURE OF A THIN WALL CRYSTALLIZER AND CRYSTALLIZER FOR CONTINUOUS CASTING - Google Patents

Description

Description of the invention having as title

"PROCEDURE FOR CHECKING THE DEFORMATIONS OF THE WALLS OF A THIN-WALL CRYSTALLIZER AND CRYSTALLIZER FOR CONTINUOUS CASTING"

FIELD OF APPLICATION

The present invention relates to a method for controlling the deformations of the walls of a crystallizer and a thin-walled crystallizer for continuous casting as set forth in the respective main claims.

The invention is adopted in association with an ingot mold used in a continuous casting plant for the production of billets or blooms of any type and section.

STATE OF THE TECHNIQUE

In the field of continuous casting there is still a plurality of unsolved problems linked to the high temperatures to which the walls of the crystalliser are subjected.

More particularly, it has been known for a long time that the temperature of the crystallizer wall, despite the circulation of the cooling fluid, varies in the direction of co

maximum value that is reached around the meniscus of the liquid metal.

The non-uniform temperature along the longitudinal walls of the crystallizer causes non-uniform deformation of the same due to the thermal expansion of the material with consequent problems linked to the surface defects that this non-uniform deformation causes on the billets / blooms in formation.

Furthermore, it is known that during the descent into the crystallizer the skin of the solidifying billets / blooms tends to shrink.

This causes a detachment of the skin of the billet / bloom from the wall of the crystallizer, enormously reducing the heat exchange between billet / bloom and crystallizer to such an extent that the cooling of the billet / bloom, and therefore the formation of the skin, is practically blocked with very serious consequences. for the billet / bloom in formation.

In fig. 1 schematically shows, with a longitudinal section, a rigid mold of a known type.

In this type of rich ingot mold, the heat exchange has acceptable values only for the first section of the crystallizer, which extends for about a quarter of its length, in which the skin of the billet / bloom is substantially in contact with the wall of the crystallizer.

To ensure that the billet / bloom leaving the crystallizer has a skin thickness such as to avoid its breakage and the consequent leakage of the liquid metal, it is therefore necessary to adopt a reduced casting speed.

To avoid this detachment of the skin of the billet / bloom from the walls of the crystallizer, some models of variable section crystallizers have been proposed in which the side walls converge downwards.

More particularly, the shape of the course of the crystallizer walls along the casting direction has been proposed to be a function of the shrinkage coefficient of the material.

In this way, in most cases the detachment of the skin of the billet / bloom from the wall of the crystallizer is substantially reduced.

With the different conicities of the crystallizer, an attempt is made to minimize the gap of air that is created between the external face of the solidified skin and the wall of the crystallizer in order to avoid the significant reduction in heat flow due to the low heat exchange coefficient. of the air.

However, this system is not economically feasible since the crystalliser must be replaced every time the composition of the cast metal changes and in any case poses considerable problems even when the extraction speed varies, which becomes costly for the user.

To try to reduce the deformation of the crystallizer wall, rigid crystallizers have also been adopted whose walls have a thickness, in correspondence with the meniscus, of the order of 11 mm and even greater, but this expedient has not proved to be decisive.

In the case of billets / blooms with a square, rectangular or polygonal section in general, another problem is linked to the fact that the edges of the billet / bloom are subjected to a more intense cooling since, in correspondence with said edges, the heat is removed on both sides of the corner.

From this it follows that, at the edges of the billet / bloom, the skin forms more rapidly and the consequent shrinkage of the material causes the billet / bloom to detach very quickly from the crystallizer wall, thus interrupting the cooling and solidification process. and therefore tending to bring the solidified part back to the liquid state.

For this reason, at the edges, the skin of the billet / bloom has a reduced thickness with respect to its side walls and temperature gradients are established between the edges and the side walls of the billet / bloom. These temperature gradients generate tensions, both in the crystallizer wall and inside the cooling billet / bloom, which lead to the formation of cracks and other surface defects that lower the quality of the output product.

Furthermore, in order to avoid excessive abrasion of the walls of the crystallizer, the internal face of said walls is generally coated with Ni / Cr which however has a low coefficient of friction.

In known crystallizers it is therefore necessary to use lubricating oils or powders which involve an additional production cost and which further reduce the heat exchange.

To obviate the drawbacks of the known art and to obtain other and further advantages, such as in particular a significant increase in the extraction speed, the present applicant has studied, tested and implemented the present invention.

EXPOSURE OF THE FOUND

The present invention is expressed and characterized in the respective main claims.

The secondary claims set out variants to the main solution idea.

The object of the present invention is to provide a method for controlling the deformations of the walls of a crystallizer for continuous casting of billets / blooms in order to improve its operation and obtain higher extraction rates.

A further object is to provide a thin-walled crystallizer in which, on the one hand, the detachment of the skin of the solidifying billet / bloom from the crystallizer is reduced and, on the other hand, the thermal deformation of the crystallizer itself is minimized.

The crystallizer according to the invention has walls with reduced thickness, between 4 and 10 mm, which make its behavior substantially "elastic".

More particularly, the crystallizer according to the invention is suitable for adapting to the billet / bloom being formed as it solidifies as it passes through the crystallizer.

According to the invention, this action of adapting the walls of the crystallizer is brought about by the pressure of the cooling fluid so that, by varying said pressure, the deformation induced in the wall is varied and the same crystallizer can be adapted to several types of cast metal and to different casting speed ranges.

In the method according to the invention, at least one longitudinal wall of the crystallizer is associated with a specific pressure of the cooling fluid.

In the present invention, by refrigerant fluid is meant water for industrial use and in any case that water which is normally used in ingot molds to cool the crystallizer.

According to the invention, said water can have, upon entering the mold, a temperature of between 10 ° C and 60 ° C.

According to a variant, the invention provides for adopting, as a cooling fluid, water with additives which allow it to be used even at inlet temperatures below zero and up to -25 ° C / -30 ° C.

It is also a variant of the invention to use, as cooling fluid, other liquid substances, for example glycol, with an inlet temperature in the mold comprised between -10 ° C / -15 ° C and -70 ° C / -80 ° C.

A further variant of the invention is to use, as a cooling fluid, liquefied gases, pure or combined with other gases or liquids, having a temperature at the inlet of the mold comprised between -3 ° C and -270 ° C.

In the following, the various parameters indicated refer to a cooling fluid consisting of one of the various types of water, also known as normal water, as normally used to cool, in an industrial process, ingot molds for continuous casting and reference is made to a temperature of said between about 20 ° C and 50 ° C.

The crystallizer is made in such a way that its dimensions, both in the transverse and longitudinal directions, already take into account the thermal expansion deriving from its heating.

More particularly, the crystallizer is dimensioned in such a way that its cross section, when it is in the state of normal expansion due to the presence of the liquid metal inside it, corresponds to the section of the billet / bloom to be obtained at the outlet.

-Moreover, the crystallizer is dimensioned in such a way that its longitudinal section takes into account a typical expansion for a certain range of steels to be cast with said crystallizer.

The walls of the crystallizer cooperate externally with cooling chambers which have a specific intermediate wall for each wall of the crystallizer to define with said wall a channel for the circulation of the cooling fluid.

Said circulation channel has a section orthogonal to the axis of the crystallizer which, in terms of width, has a width less than the wall of the crystallizer and a value of up to three millimeters as a thickness, or transit opening of the cooling fluid.

The invention provides for the use of much higher pressures for traditional refrigerant fluids than those normally used.

The invention provides that, by regulating the pressure of the cooling fluid entering the circulation channel, it is possible to deform the walls of the crystallizer inwards.

This deformation can be managed differently at the various heights of the crystallizer, obtaining different effects.

In other words, the pressure of the refrigerant fluid adopted at the various heights of the crystallizer is a function of the deformation, or the recovery of the deformation, to be induced in the crystallizer wall at that point or in that area.

It is in the spirit of the invention to correlate the pressure of the refrigerant fluid to the value of the heat exchange coefficient which is to be obtained between the wall of the crystallizer and the refrigerant fluid.

In relation to the vertical area immediately under the molten metal meniscus, the pressure of the refrigerant fluid acting against the wall of the crystallizer therefore recovers at least a large part of the deformation induced by heat in the same wall of the crystallizer, linearizing it or substantially linearizing it.

In relation to the vertical wall of the crystallizer, the pressure of the refrigerant fluid can modify the local or total conicity of the wall itself as desired.

In relation to the underlying area at the beginning of the detachment of the skin forming from the internal wall of the crystallizer, with consequential formation of a layer of air, the pressure of the refrigerant fluid serves to minimize, up to canceling where possible, the intervention of air that is created between the crystallizer wall and the solidified skin of the billet / bloom.

According to the invention, the cooling chamber and the relative circulation channels are divided, in the longitudinal direction of the crystalliser, into at least two zones so that there are different and autonomous conditions of pressure of the refrigerant fluid in them.

According to the invention there are also differentiated and autonomous cooling zones.

According to the invention. said cooling and pressure conditions are enslaved to a processor which receives the necessary information from detecting means which cooperate with the walls of the crystallizer and / or with the surface of the bloom / billet as it comes out of the crystallizer.

According to the invention, autonomous and differentiated cooling and pressure conditions of the refrigerant fluid can be obtained within each zone, also relative to one or more faces of the crystallizer.

The detecting means can be means detecting the temperature of the wall of the crystallizer or, or also, detecting means of the surface temperature of the billet / bloom in the vicinity of the position of exit from the crystallizer, or again, or also, detecting means of the existing friction force. between the inner wall of the crystallizer and the skin of the forming billet / bloom.

In the crystallizer according to the invention, said temperature detecting means are associated at least with the lower part of the crystallizer where the detachment of the skin from the wall of the crystallizer is present.

According to a variant, the means for detecting the temperature are also associated with the surface of the billet / bloom which has just come out of the crystallizer.

According to the invention, thanks to the reduced thickness of the crystallizer wall it is possible to control, in each longitudinal or vertical zone, and in relation to each wall, the distortions and deformations of the walls of the crystallizer by using refrigerant fluid with differentiated pressures.

In the area where the deformations of the wall determined by the temperature of the molten metal must be controlled, the pressures according to the invention (at the inlet of the circulation channel associated with the relative area) vary from 1.5 to 15 bar, also depending on the thickness of the wall. and the type of molten metal.

In the area where the skin detaches from the wall of the crystallizer, the pressures according to the invention (at the inlet of the circulation channel associated with the related area) vary from 5 to 20 ba.r also depending on the thickness of the wall and the type of metal melted.

According to a variant, in the case of billets / blooms having a rectangular section, the long sides of the rectangle are subjected to independent and differentiated pressures with respect to the pressures acting on the short sides.

By extension, the invention provides that each side of the crystallizer is subjected to its own and autonomous pressure of the cooling fluid.

According to the invention, the cooling fluid can flow both in co-current and in counter-current with the direction of advancement of the billet / bloom inside the casting chamber.

The combination of the elastic walls and the differentiated pressure of the refrigerant fluid acting on them allows to recover the outward deformation that is created in the walls of the crystallizer in relation to the meniscus and to the area immediately below (see fig. 1).

According to the invention, by acting on the pressure of the refrigerant fluid, the detachment of the skin of the solidifying billet / bloom from the crystallizer wall is also considerably reduced, up to eliminating it, thus guaranteeing an always high heat exchange.

Since the thickness of the skin of the billet / bloom is proportional to the quantity of heat removed from the billet / bloom, the greater the heat exchange, the greater the casting speed with a consequent increase in the productivity of the plant itself.

According to the invention, the circulation channels do not affect the corner areas of the crystallizer to avoid causing excessive cooling of the edges of the billet / bloom in formation which cooperate with said corner areas.

This ensures uniform growth of the solidified layer and eliminates the tendency of the outgoing billet / bloom to assume a rhomboid section (romboidity).

According to the invention, said corner areas are cooled in a different way with respect to the rest of the wall of the crystallizer.

At the corners, the crystallizer according to the invention has stiffening elements suitable for at least controlling the deformations of the crystallizer caused by the thermal expansion resulting from its heating.

Said stiffening elements are obtained directly in the crystallizer itself or are external auxiliary elements which are fixed on or to cooperate with the edges of the crystallizer.

The crystallizer according to the invention advantageously has the internal face coated with coating materials having good thermal conductivity, good resistance to wear and high flowability (low coefficient of friction), such as for example carbides and / or other metal alloys. hard.

In the crystallizer according to the invention, said coating materials are advantageously applied by means of the plasma spray technique, also known as "plasma spray", which guarantees optimum adhesion of the coating materials also on the copper walls.

According to a further variant, in order to increase the heat exchange between the cooling fluid and the wall of the crystallizer, at least part of one face of the circulation channel has flow perturbing means which, by breaking the fluid threads of the boundary layer, cause the cooling fluid to flow in turbulent mode with consequent increase in heat exchange.

Said perturbing means can be made by means of roughness, hollows, sequences of widening and narrowing, etc.

Furthermore, to improve the heat exchange, the external wall of the crystallizer has lines or other shapes which make the exchange surface larger.

In an embodiment of the crystallizer according to the invention, the intermediate wall of the circulation chamber is movable orthogonally to the wall of the crystallizer and cooperates with adjustment means to approach or move away from it. This allows to vary the thickness or opening of the circulation channel and therefore the passage section of the cooling fluid when it cooperates directly with the external face of the crystallizer wall.

Said variation of the passage section allows to regulate the pressure and the speed of the said refrigerant fluid inside the circulation channel.

ILLUSTRATION OF DRAWINGS

The attached figures are provided by way of non-limiting example and illustrate some preferential solutions of the invention.

In the tables we have that:

- fig. 1 shows a schematic and partial longitudinal section of an ingot mold of a known type;

- figs. 2 show, with a partial cross section, six of the possible embodiments of the stiffening element;

- fig. 3 shows a longitudinal section of the mold adopting a crystallizer according to the invention; - fig. 4 shows a schematic and partial longitudinal section of an ingot mold adopting a crystallizer according to the invention; - fig. 5 shows, with a cross section, an ingot mold adopting a crystallizer according to the invention.

DESCRIPTION OF THE DRAWINGS

With reference to the attached figures, the reference number 10 generally indicates an ingot mold according to the invention with which an unloader 25 of liquid metal is made to cooperate.

In the present case, the mold 10 illustrated in the figures has a square cross section, but the invention relates both to molds with a rectangular section and to molds with a polygonal section and to molds having any cross section.

The mold 10 according to the invention comprises a crystallizer 11 whose walls have a thickness of between 4 and 10 mm, advantageously between 6 and 8 mm.

The inner face 12 of the walls of the crystallizer 11 is coated with a material having good thermal conductivity, good wear resistance and high smoothness (low coefficient of friction), such as for example carbides or other hard metal alloys.

Said coating materials are advantageously applied by means of the plasma spraying technique, or by means of hypersonic spraying.

The mold 10 according to the invention comprises containment walls 13 arranged externally to the crystallizer 11 and defining with said two or more cooling chambers 14 (114-214) placed in sequence and in which the refrigerant fluid under pressure is made to flow.

According to the heat exchange requirements between the cooling fluid and the crystallizer 11, and therefore in relation to the cooling and solidification process of the billet / bloom 24 under formation, the cooling fluid can be made to flow in countercurrent, or in the same direction of advancement as the billet / bloom 24 in formation. The cooling chambers 14 have a supply conduit 22a, equipped with regulation valve means 23a, and an outlet conduit 22b also equipped with regulation valve means 23b.

In the mold 10 according to the invention, the cooling chambers 14 have their own specific intermediate wall 20 for each side of the crystallizer 11, which can be transversely movable according to the arrows 17 of figs. 3 and 4 by means of relative motor means 32.

Between the intermediate wall 20 and the external face of the wall of the crystallizer 11 a circulation channel 21 is formed which, if the intermediate wall 20 is mobile, has a variable transit section.

In fact, by transversely positioning the intermediate walls 20 it is possible to vary the thickness, or opening, of the respective circulation channel 21 and therefore the hydraulic conditions of the flow of refrigerant fluid.

According to the invention, in the case of sections with unequal sides as in the case of rectangular sections, the wide faces have pressure factors differentiated from the pressure factors present in the short faces.

According to a variant, each face has its own autonomous range of pressures.

According to the invention, the circulation channels 21 do not directly cooperate with the edges 15 of the crystallizer 11, which are not cooled by the cooling fluid which flows inside said circulation channels 21.

In the embodiment illustrated in FIGS. 2, there is a section with increased thickness 35 in correspondence with the edges 15 of the crystallizer 11 so as to reduce the heat exchange with the cooling fluid.

The circulation channel 21 cooperates, at the lateral ends, with flared side walls 30 having the inclination which can vary as desired so as to modulate and graduate the heat exchange near the edges 15 of the crystallizer 11 (Figs. 2f, 5).

The crystallizer 11, around the meniscus 27 and below it, heats up due to the effect of the liquid metal flowing inside the casting chamber 31, deforms in an elastic manner and the pressure of the refrigerant fluid acting in the specific channels of circulation (121) relating to this area, compensates for this deformation.

Similarly, in the remaining longitudinal part of the crystallizer 11, which can have one or more chambers 14-214 and respective circulation channels 21-221, in relation to the behavior of the skin being formed, the pressure of the refrigerant fluid present in the relative and specific circulation channel 221 allows to reduce the gap 36 between the inner face 12 of the wall of the crystallizer 11 and the skin of the solidifying billet / bloom 24 and therefore to maintain a high heat exchange coefficient between billet / bloom 24 and crystallizer 11 as illustrated in fig. 4. In figs. 1 and 4 show the behavior of known crystallizers (Fig. 1) and according to the invention (Fig. 4).

In fig. 1 can be seen as - line 28 -, in correspondence with the meniscus 27, the wall of the crystallizer 11 expands and then resumes its position at the bottom; in the meantime, the forming skin of the billet / bloom 24 has withdrawn creating an air gap 36 which does not allow a good heat exchange.

With the invention (fig. 4), with the pressure of the refrigerant fluid, the expansion of the wall of the crystallizer 11 in the area below the meniscus 27 is substantially eliminated and it is recovered, deforming it inwards as desired - line 28 - aria 36 substantially canceling it out. By varying the pressure of the refrigerant fluid that circulates inside the individual circulation channels 21-121-221 it is possible to recover the deformations of the walls of the crystallizer 11 and substantially keep the walls of the crystallizer 11 close to the skin of the billet / bloom 24 also in the lower area of the crystallizer 11, thus ensuring a high heat exchange coefficient over its entire length.

In the case of a crystalliser 11 according to the invention with a rectangular section, at least its wide walls have cooling chambers 14 and circulation channels 21 which are autonomous and with autonomous pressures of the cooling fluid.

The cooling chamber 14, by means of chamber separators 34, in the case illustrated in Figs. 3 and 4, / is divided into two cooling chambers 114 and 214, each with autonomous circulation of coolant fluid (22a-22b, 23a-23b, 122a-122b, 123a-123b).

As said, according to the invention, the autonomous circulation can be pushed up to involve also the single vertical portions of the wall of the crystallizer 11,

The crystallizer 11 is vertically movable and rests on load cells 26 which record the friction force of the billet / bloom 24 on the walls of the crystallizer 11.

Furthermore, the crystallizer 11 is associated, at various heights and advantageously along its entire length, with temperature detection means 19 which detect the temperature of the various areas present on the wall of the crystallizer 11 and with the outlet (119) of the bloom / billet and as if it had just come out.

The load cells 26 and the temperature detection means 19-119 provide the data to a processor 18, which serves the regulating valve means 23a, 23b, 123a, 123b, adjusting the pressure in the various cooling chambers as required. 114 and 214, as well as in the respective circulation channels 121 and 221, in the limit, relative to each single vertical portion of. wall.

The processor 18 can also serve the motor means 32 which regulate the thickness, or gap, of the circulation channel 21-121-221 and can regulate and in any case control the electromagnetic stirrers 33 and 133 by imposing a concordant or discordant circulation of their flow. magnetic.

The crystallizer 11 has, or cooperates with, a section with increased thickness 35 at its edges 15 so as to reduce the heat exchange with the cooling fluid.

The section with increased thickness 35 can be obtained by means of stiffening elements 16 obtained entirely (16a, fig. 2c) or in part (116a, figs. 2b, 2d) directly from the wall of the crystallizer 11, or consisting of autonomous stiffening elements 16b (figs.2a, 2e, 2f).

The autonomous stiffening elements 16b can be associated or rigidly connected, for example by brazing, to the edges 15 of the crystallizer 11 according to the invention.

The stiffening element 16a, 116a obtained from the wall of the crystallizer 11 can be shaped in the shape of a solid polygon, in the shape of a "T" or have another shape.

In the case of autonomous stiffening elements 16b, they can be "T", "L" or omega-shaped or have other shapes.

In the embodiment illustrated in figs. 2d and 2f, the stiffening element, which in fig. 2d is partially obtained (116a) from the wall of the crystallizer 11 while in fig. 2f is an autonomous element (16b), is shaped like a "T" and is inserted inside a compartment 29 defined on the section with increased thickness 35.

The compartment 29 may or may not be traversed by refrigerant fluid.

The stiffening element 16, which can also be in several pieces, performs a dual function of stiffening and reducing the heat exchange at the edges 15 of the crystallizer 11.

To increase the heat exchange between the refrigerant fluid and the crystallizer 11, the faces which determine the circulation channels 21 can advantageously have perturbing elements which, breaking the fluid threads of the boundary layer, cause the refrigerant fluid to flow with turbulent motion inside the circulation channel 21 with consequent increase in heat exchange.

Said perturbing elements can be made both on the external face of the wall of the crystalliser 11 and on the internal face of the intermediate wall 20.

In order to increase the heat exchange, the outer face of the wall of the crystallizer 11 can have, advantageously but not exclusively vertically, channels, roughness, protuberances or other means suitable for increasing the exchange surface.

Claims (1)

CLAIMS 1 - Process for controlling the deformations of the walls of a crystallizer for continuous casting of billets / blooms (24) associated with an ingot mold (10), said crystallizer (11) cooperating externally with a box-like structure creating a cooling chamber (14) in in which the cooling fluid circulates and internally with the skin of the billets or blooms (24) being formed, the cooling chamber (14) comprising an intermediate wall (20) creating, in cooperation with the outer face of the crystallizer wall (11), a circulation channel (21), being present at least one upper zone cooperating at least with the part underneath the meniscus (27) of liquid metal and a lower zone starting around the detachment zone of the skin forming from the internal face (12) of the wall of the crystallizer (11) and extending towards the outlet of the crystallizer (11) itself, characterized by the fact that they are present in sequence for each pa network at least two autonomous circulation channels (21-121-221) cooperating with the respective upper and lower zones and that, at the inlet of the circulation channel (121), associated with the upper zone, the pressure of the refrigerant fluid is a function of deformation induced in the wall of the crystallizer (11) by the thermal field to which said wall is subjected, while at the inlet of the circulation channel (221) which cooperates with the lower zone, the pressure of the cooling fluid is a function of the desired deformation of the wall of the crystallizer (11) in correspondence to the lower zone of the crystallizer (11), being the pressure of the refrigerant fluid in the lower circulation channel (221) also a function of the skin temperature of the billet / bloom (24) just out of the crystallizer (11), and / or a function of the temperature of the wall of the crystallizer (11) and / or of the friction force between the skin in the formation of the billet / bloom (24) extracting and the inner face (12) of the wall of the crystallizer (11), this pressure of the cooling fluid being regulated by means enslaved to a processor (18). 2 - Process as in Claim 1, characterized in that the pressure of the refrigerant fluid is also correlated to the value of the heat exchange coefficient to be obtained between the wall of the crystallizer (11) and the refrigerant fluid. 3 - Process according to Claim 1 or 2, characterized in that the refrigerant fluid is normal water at a temperature between 10 ° C and 60 ° C. 4 - Process according to Claim 1 or 2, characterized in that the cooling fluid is water with additives at a temperature down to -25 ° C / “30 ° C. 5 - Process according to Claim 1 or 2, characterized in that the refrigerant fluid is glycol, or other similar substance, at a temperature between -10 ° C and -80 ° C. 6 - Process according to Claim 1 or Claim 2, characterized in that the refrigerant fluid is pure liquid gas or added with another gas or liquid, at a temperature between -3 ° C and -270 ° C. 7 - Process according to one or the other of the preceding claims, characterized in that, in the case of the refrigerant fluid consisting of normal water, the pressure at the inlet of the circulation channel (221) relative to the lower zone is between 5 and 20 bar. 8 - Process according to one or the other of the preceding claims, characterized in that, in the case of the refrigerant fluid consisting of normal water, the pressure at the inlet of the circulation channel (121) relative to the upper zone is between 1.5 and 15 bar. 9 - Process according to one or the other of the preceding claims, characterized in that the processor (18) is enslaved to temperature detection means (19,119) present at least in the zone corresponding to the lower part of the crystallizer (11). 10 - Process according to either of the preceding claims, characterized in that at least one longitudinal wall of the crystalliser (11) is associated with its own range of specific pressures of the cooling fluid. 11 - Process according to either of the preceding claims, characterized in that the edges (15) of the crystallizer (11) have at least a reduced cooling compared to the walls of the crystallizer (11). 12 - Thin-wall crystallizer for continuous casting of billets / blooms (24) associated with an ingot mold (10), said crystallizer (11) cooperating externally with a box-like structure creating a cooling chamber (14) in which the refrigerant fluid circulates and internally with the skin of the billet / bloom (24) in formation, the cooling chamber (14) comprising an intermediate wall (20) creating, in cooperation with the outer face of the crystallizer wall (11), a circulation channel (21) , there being at least an upper zone cooperating at least with the part underneath the meniscus (27) of liquid metal and a lower zone starting around the detachment zone of the skin forming from the inner face of the crystallizer wall (11) and extending towards the outlet of the crystallizer (11) itself, characterized by the fact that it has walls having a thickness between 4 and 10 mm and individual circulation channels (21) for each wall and that for each wall of the crystallizer (11) there are at least two independent circulation channels (121-221) placed in sequence and corresponding respectively to the upper and lower areas, the refrigerant fluid, in the case consisting of normal water, at the inlet of the circulation channel (221) associated with the lower zone presenting a pressure between 5 and 20 bar while at the inlet of the circulation channel (121) associated with the upper zone presenting a pressure between 1, 5 and 15 bar, there being at least means for detecting the temperature (19) of the wall of the crystallizer (11) associated with a processor (18), said processor (18) serving at least the pressure present in the circulation channel (221) associated with the zone inferior. 13 - Crystallizer as in claim 12, characterized in that the section of the circulation channel (21) orthogonal to the axis of the crystallizer (11) has a width less than the width of the relative wall of the crystallizer (11) and a thickness or light up to three millimeters. 14 - Crystallizer as claimed in Claim 12 or 13, characterized in that the edges (15) of the crystallizer (11) cooperate with a section of increased thickness (35). 15 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that it has stiffening elements (16) associated with the edges (15) of the crystallizer (11). 16 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that the stiffening elements (16a, 116a) are obtained directly from the walls of the crystallizer (11). 17 - Crystalliser as claimed in one or the other of claims 12 onwards, characterized in that the stiffening elements (16b) are external auxiliary elements which cooperate with the edges (15) of the crystalliser (11). 18 - Crystalliser as claimed in one or the other of claims 12 onwards, characterized in that the sides of the crystalliser (11) cooperate with autonomous circulation channels (21) with autonomous pressures of the cooling fluid. 19 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that the crystallizer (11) is associated with load cells (26) connected to the processor (18). 20 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that at least the lower part of the crystallizer (11) is associated with temperature detection means (19) connected to the processor (18). 21 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that at the outlet of the crystallizer (11) there are means for detecting the temperature (119) of the skin of the outgoing billet / bloom (24) associated with the computer (18). 22 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that at least part of the intermediate wall (20) of at least one side of the crystallizer (11) is adjustable with respect to said wall of the crystallizer (11). 23 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that at least one wide face defining the circulation channel (21) has elements perturbing the boundary layer of the fluid threads. 24 - Crystalliser as claimed in one or the other of claims 12 onwards, characterized in that the external face of the crystalliser wall (11) has roughness, channels or protuberances suitable for increasing the surface of 25 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that the inner face (12) of the wall of the crystallizer (11) is coated with carbides or other hard metal alloys. 26 - Crystallizer as in one or the other of claims 12 onwards, characterized by the fact that the lining of the inner face (12) of the wall of the crystallizer (11) is made by deposition via plasma or by deposition by hypersonic spraying. 27 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that the processor (18) serves the regulating valve means (23a, 23b, 123a, 123b) of the refrigerant fluid circulating in the specific channels of circulation (21,121,221). 28 - Crystallizer as claimed in one or the other of claims 12 onwards, characterized in that it has at least one electromagnetic stirrer (33,133) associated with the cooling chamber (14, 114, 214) and slave to the processor (18). 29 - Crystallizer as claimed in one or the other of claims from 12 onwards, characterized in that the processor (18) ensures the reciprocal position of at least one longitudinal section of the intermediate wall (20) with respect to the relative part of the crystallizer wall (11).