EP1673181B1 - Method of increasing the control precision of the path of a product in a levelling machine with interlocking rollers, and levelling installation used to implement same - Google Patents

Description

The document FR-A-2732913 discloses a method and an installation as defined in the preambles of claims 1 and 6.

The subject of the invention is a method for controlling the trajectory of the product in a nested roller planing machine and the planing installation for implementing the method.

For planing flat products and, in particular, laminated metal strips, a multi-roll planer is often used comprising two planing equipments each carrying a series of rollers with parallel axes and placed, respectively, above and below the strip, the rollers being offset longitudinally and vertically so as to interlock by determining a corrugated path of the strip which is thus subjected to tensile-bending effects in alternate directions.

The operation of such a machine has been the subject of advanced theoretical approaches. These theories of planing are based on the calculation of the maximum curvatures of the sheet in the planer, these curvatures cause a plasticization of the material in the thickness of the product which conditions stress relieving in the width and the thickness. Any planer can be broken down into two zones whose functions are very different but complementary and interactive. The entry zone, which includes the first three or four rollers, is a large plasticizing zone in which visual flatness defects such as long or long center edges, "quarter-band" defects and any distribution are eliminated. transverse heterogeneity of longitudinal stresses. The exit zone, which includes the last three or four rollers, has the function of reducing the gradients of the normal and transverse stresses in the thickness to ensure the sheet metal hanger and tile residual almost zero.

It is known to establish efficient theoretical calculations to obtain a precise theoretical result and can be used to preset the machines. The principle is based on the progressive decrease of the plastification rate. This can only be obtained with machines having a sufficient number of gliding rollers and allowing a proper adjustment of the nesting of each of these rollers. If the precision required for the first rollers is relatively low, since a high level of plasticization is sought, that required for the adjustment of the rollers of the exit zone is high, and all the more so since the thicknesses of the sheets to be hovered are more fines. It is therefore desirable to have machines whose rollers all have independent adjustment, which is of sufficient precision, reliable and repetitive.

A leveling installation therefore generally comprises a fixed support cage, two parallel roller leveling equipments placed respectively above and below the strip and whose rollers are nested so as to determine a path corrugated the band and means for adjusting and maintaining the spacing of said crews by pressing the fixed cage for adjusting the nesting of the rollers, each leveling unit having a row of parallel active rollers supported on a frame of support by means of at least one row of support rollers and rotatably mounted at their ends, each on two bearings defining an axis of rotation perpendicular to the direction of travel, said bearings being carried, respectively, by two side parts secured to the support frame.

Most often the lower leveling crew is fixed in position, the upper crew being able to move vertically for nesting adjustment. For this purpose, it is generally used four mechanical or hydraulic actuators mounted at the corners of the frame and to adjust the general level of the adjustable crew relative to the lower fixed crew and, therefore, the nesting rollers. In addition, the input and output actuators can be set differently, which allows to determine a tilt generally necessary to achieve the two planar effects established by the theory and discussed above. The actuators can also be adjusted differently from one side to the other by introducing lateral tilting so as to correctly distribute the planing effect over the width of the product to be hovered.

The efforts developed for planing are very high, especially when this operation is performed on a hot plate after hot rolling and accelerated cooling, or on a cold sheet. It is therefore necessary to give the planers a structure as rigid as possible so as to control the effects of planing. The deformation under stress of the different parts of the machine (also called ceding) distorts the accuracy of the control of the position of the leveling rollers, therefore the exact value of the curvature obtained on each roll. The overall capping of the machine modifies the desired level of plasticization, so risk in the entry zone of not completely eliminating flatness defects, it also modifies the decay rate of the plasticization, therefore the transition with the exit zone and may not eliminate residual stresses as expected. In addition it can occur a transverse cedar, from one side to the other, which will change the rate of plasticization in the entrance area and its homogeneity in the width of the product, it can even create flatness defects.

To overcome these drawbacks, hydraulic level planers were made for moving the moving planing equipment, and also for the individual control of each leveling roller, and a capping model based on effort and a theoretical calculation of the deformations of the machine under effort, to compensate for these deformations, as in the applicant's patent FR 2,732,913 .

But all these compensations are marred by errors due to the non-linearities of the ceding of the machine and which originate from the friction that is found between the fixed parts and the moving parts of the machine. In addition, the capping module of a leveling machine, even of robust design, is of the order of 100 t / mm per column, while the leveling force for a sheet of 3 meters of width can be from 1000 tonnes to 2500 tonnes. which leads to a cedar (without compensation) of 2.5 mm to 5 mm. The precision required is not very high in the entrance area of the machine and could accommodate a simple compensation cedar, there is however the risk of having refusal of commitment of the product in a machine set too tight as a precaution. On the other hand the necessary precision on the curvatures for the elimination of the residual stresses in the exit zone requires a precision of the control of the position of the rollers by a few tenths of a millimeter. The control of the transition zone finally implies having precise control on practically all the rollers, all the more so as for certain applications the steps of the rollers rigidly held in position will be varied so as to increase the capacity of the planer as it says in the patent FR 2,732,913 . This will have the effect of moving the entry zone and the exit zone and will therefore also contribute to a search for greater accuracy in controlling the position of all the rollers of the planer.

The invention therefore aims to increase the accuracy of control of these machines and a machine equipped with a new control device and to solve all of these problems without causing complication or excessive cost of the devices used.

The compensation of the cages is replaced by a real-time model of presetting of the position of the planing rollers associated with a direct measurement of the spacing of the active rollers.

The invention is defined in claims 1 and 6.

In a method according to the invention, a theoretical presetting model is installed which gives at least one reference value for the pre-adjustment of the nestings and one directly measures at least one value of the spacing of the planing rollers, which is compared to the reference values and acts on the adjusting members of the position of the leveling rollers to maintain the measured values equal to the values of the reference so as to maintain the trajectory of the product to be hovered inside the machine in accordance with the ripple provided by the model to achieve planing. In particular two measurements of the value of the spacing of the planing rollers are carried out, a first at the entrance of the machine and, respectively, a second at the exit of the machine, that each of these measurements is compared to the reference value given by the model for the same rollers, respectively at the inlet and at the outlet of the machine, and the elements for adjusting the position of the planing rollers at the inlet and at the outlet of the machine are adjusted. keep the measured value equal to the value of the reference so as to achieve the decrease of the rate of plastification provided by the model to achieve leveling. In particular, in a complete process a measurement is made of the value of the spacing of each of the leveling rollers which is compared with each reference value given by the model and acts on the individual adjustment members of the position of each of the leveling rollers to maintain the measured value equal to the value of the reference so as to achieve the corrugation and the decrease in the rate of plasticization provided by the model for performing leveling. But the position control requires to ensure that at uniform positions of planing rollers, given by position sensors, correspond identical leveling forces. It is necessary first to perform a kind of calibration so as not to depend on the mounting mode of the sensors in the machine and the position of their reference 'zero'.

In a preferred method according to the invention a calibration is carried out, called equilination of the active rollers on a flat machined sheet of known thickness by differentially modifying the position of the active rollers by lateral tilting from one side to the other so to achieve equal leveling efforts on both sides of the machine measured by the measuring devices. In a more elaborate method of the invention equilination is carried out on a moving sheet by differentially modifying the position of the active rollers by a lateral tilting from one side to the other and that one proceeds to the equalizing the averages of the forces recorded by the measuring devices on each side during said scrolling.

In a parallel roller leveling installation according to the invention there is provided a device for directly measuring the value of the spacing of the leveling rollers in at least one point so as to know the exact value of the nesting by a direct measurement. The installation preferably comprises an electronic device for controlling the measured spacing of the planing rollers to the theoretical value given by the model by acting on the adjustment devices of the nesting. In an improved version of the invention the adjustment devices of the nesting are hydraulically controlled.

In another arrangement of a preferable planing installation, the installation is provided with a device allowing the direct measurement of the value of the spacing of the leveling rollers in at least two points, one located in the zone d entry of the machine and the other located in the exit zone. In this case, the electronic device makes it possible to control the measured spacing of the leveling rollers located in the input zone of the machine and respectively in the output zone at the theoretical value given by the model for spacing the rollers located in the input zone of the machine and respectively in the output zone by acting independently on the devices for adjusting the nesting of the rollers of each of the inlet and outlet zones, respectively. These devices are preferably hydraulically controlled.

In a greatly improved arrangement of the invention, independent devices allow the direct measurement of the spacing value of each pair of active planing rolls separately. The parallel roll leveling installation comprises means for individually adjusting the position of each leveling roller and an electronic device enabling the measured distance of each of the leveling rollers to be controlled at the theoretical value given by the model for the leveling roller. spacing of each of these rollers by acting independently on their nest adjustment device.

The leveling installation advantageously comprises a device for adjusting the interlocking of each hydraulically controlled roller,

In a preferred parallel roller milling system the electronic devices for servocontrolling the measured gap of the leveling rollers to the theoretical value given by the model comprise a differential adjustment device for adjusting a lateral tilting of the rollers on one side. relative to the other and with respect to the setpoint value, to allow a calibration of the device by an equilination process on a flat machined sheet of known thickness.

But the invention will be better understood by the description of certain particular embodiments, given by way of example and shown in the drawings.

Figure 1 is an elevational view of the installation, in section along its vertical median plane parallel to the direction of travel, the planing crews being in the open position.

Figure 2 is an overall diagram of the control circuits of the cylinders.

FIG. 1 shows the mechanical part of the assembly of an installation according to the invention comprising, in a general manner, a support cage 1, an upper planing unit 2 and a lower planing unit 2 ' multi-roll.

In a general manner, the fixed support cage 1 comprises a lower bed base 11, two lateral uprights placed on either side of a longitudinal median plane P of travel of the band 10 to be hovered and an upper bed base 14.

Each lateral amount consists of a pair of spaced columns 12, 12 ', 13 (in the figures, only three columns are visible). These columns and the upper bed, generally forming a rigid slab, are equipped with various devices known in themselves and widely described in the prior art that can cooperate to allow vertical sliding of the bed base 14 along the four columns 12, 12 ' 13. This movement can be mechanical using motorized screws or hydraulic as shown in Figure 1. In this case there are four cylinders 3 installed at the top of each column. In the arrangement shown, each jack consists of a body 31 fixed to the bed base 14 and a piston 32 secured to the column. The lower bed base 11 being fixed, the upper bed base 14 can move, under the action of four cylinders 3, the pistons of the cylinders remaining at the same level. The cylinders 3 are positioned to adjust the desirable imbrication of the rolls with respect to the thickness of the sheet to be hovered so as to achieve the corrugation determined by the theoretical model. They exert the effort of planing during the passage of the product.

It is also possible to imagine other arrangements, such as that comprising moving pistons and fixed cylinder bodies, without departing from the scope of the invention.

Each planing unit 2, 2 'comprises a row of active rollers 4, 4' associated with a row of support rollers 5, 5 'the assembly being carried by a frame.

Each active roller 4, 4 'is rotatably mounted on two bearings defining its axis of rotation, it is supported on a support roller 5, 5' rotatably mounted on two end bearings.

In the representation of FIG. 1, the end bearings 51 of the upper planing unit 2 are supported on the upper bed base by means of a support member 52. In a more elaborate version of the invention, this support member may comprise an adjustment device which makes it possible to modify individually for each active roller its nesting, the overall value of which is given by the positioning of the bed base of the upper planing unit 2 with the aid of the cylinders 3 These adjustment devices can be mechanical, such as a wedge system, or they can be constituted by a row of hydraulic cylinders as in the patent FR 2,732,913 . In this case it will be possible, in addition to the individual adjustment of the nesting, to obtain by the differential adjustment of the cylinders of the same row, a bending effect of the active cylinders so as to better distribute the planing effect on the width of the tape to glide.

According to an essential characteristic of the invention there is at least one sensor 6 making it possible to continuously measure the absolute value of the spacing of the active rolls 4, 4 ', independently of the deformation of the columns and of the whole of the machine, installed for example between the upper planing crew 2 and lower 2 '. In the representation of Figure 1 there are shown two sensors 6 and 6 'one at the entrance of the machine and the other in the output area so as to control more precisely the variation of the rate of plasticization as well as this has been described in the general discussion of the problem.

In a particular embodiment of the invention, and for wider use of all the possibilities of the machine, it will be possible to install a sensor making it possible to individually measure the spacing of each pair 4, 4 'of active rollers.

The sensors can be of any type, and for example of the Linear Variable Differential Transformer (LVDT) type with the body attached to a planing unit and the rod to the other. They can also be contactless, for example ultrasonic, laser, optical filter, Bragg grating, etc.

FIG. 2 represents the set of mechanical and electrical devices associated to constitute a leveling machine according to the invention. The mechanical part of the machine is shown schematically in a cross section. The sensor or sensors 6 are mounted on one side of the machine, the hydraulic cylinders 3 are equipped with sensors 35 for measuring overall planing forces. These cylinders are powered by a conventional pump and accumulator device 8 via two servo valves or two groups of servo valves 71, 72 feeding each side of the machine. These servo valves are controlled by at least one electronic control circuit decomposing into two electronic circuits each controlling a servo valve or a group of servo valves.

In an installation according to the invention there is provided a closed loop of the measured value of the spacing of the active rollers 4, 4 'to the reference position introduced into the electronic control circuit of the servo valves.

These electronic circuits (91, 92), which may be analog or digital computers, include summing circuits and conventional proportional, integral and differential control circuits known as 'PID'.

According to a preferred embodiment of the invention, the reference values corresponding to the desirable nesting of the active rollers are elaborated by a leveling model 110 implemented in a process computer 100, they are introduced into the servo valve control electronic circuits. (91, 92) via an adder / differentiator stage 93, 94 which makes it possible to introduce a tilting control of the machine from one side to the other. The force sensors 35 are connected to the computer 100 in which will be developed a tilt instruction, it is summed to the nesting reference in the circuit 94 to be sent as a control signal for one side of the machine, it is differentiated from the same signal in the circuit 93 to be sent as a control signal for the other side of the machine.

Moreover, and conventionally the computer 100 is connected to operator interface devices such as screen and control panel 101, printer and recorder 102 so as to control the operation of the machine and manage its production.

In a more elaborate embodiment of the invention, for example with a sensor in the input area of the machine and the other in the output area, the same type of circuit will be used. The jacks 3 located on the input side and those on the output side are powered separately by servo valves and all the electronic circuits 9 described above are doubled for the independent control of each zone; of course it is the same computer 100 that develops all the references and distributes them on all the electronic control circuits.

In another embodiment, still according to the invention, the support members 52 of each upper support roller 5 are adjusting members and can individually control each upper active roller 4, an individual and separate embodiment is carried out separately. measuring the spacing between each of the upper and lower active rollers and a control device similar to that described is installed for each pair of active rolls.

In the case where the support members 52 are adjusting members consisting of hydraulic cylinders, there is provided a control device (9) of the type described above for each pair of active cylinder.

The computer 100 is used to develop all the instructions and to distribute them on all the electronic control circuits 9. In this case the main cylinders 3 are no longer used for these functions and are used to adjust the opening and the general closing of the machine. according to the thickness of the sheet to hover. The exact desired ripple is obtained by adjusting the individual nesting of each roll 4 by means of the adjusting devices 52.

In a method according to the invention, the distance between the active rollers 4,4 'is measured, compared with the reference setpoint produced using the planing model, and the necessary correction is introduced so as to cancel the error. resulting from deformations of the machine under the planing force by acting on the adjustment means of the nesting. The absolute measurement of the deviation of the active cylinders is obtained by means of the sensors 6, this value is compared with the reference in the circuits 91 and 92 and the resulting signal serves to control the servo valve 7 which makes it possible to move the cylinders 3 controlling the movement of the planing equipment.

The reference is obtained by combining the dimension developed by the leveling model 110 and the tilt instruction. The two quantities are added in the circuit 94 to be applied on one side of the machine, they are subtracted in the circuit 93 to be applied on the other side of the machine, so as to perform a balanced tilt and distributed on the side by to the value of the theoretical nesting needed to obtain the ripple defined by the model.

In a preferred embodiment of the invention, an absolute measurement of the difference between the active rolls 4, 4 'in the entry zone of the machine and another in the exit zone is carried out. These measurements are compared with the reference instructions developed using the leveling model for each of these two zones and the necessary corrections are introduced in order to cancel the errors resulting from the deformations of the machine under the planing force by acting on the means 3 for adjusting the imbrication of the entry zone and the exit zone, by acting separately by specific control circuits of the jacks 3 of the entry zone and those of the exit zone .

In another embodiment of the invention, an absolute measurement of the difference of the active rolls 4, 4 'for each pair of active rolls is carried out. These measurements are compared to the reference instructions developed using the planing model 110 for each of the pairs of active cylinders and the necessary corrections are introduced so as to cancel the errors resulting from the deformations of the machine under the planing force by acting on the means 52 for adjusting the nesting of each pair of active rolls.

It should be noted that the lower leveling crew has one more roll than the upper leveling crew. As a result, an upper leveling roller is always facing the space between two adjacent lower planing rolls. Under these conditions, the so-called "gap of the active rolls 4, 4 'for each pair of active rolls" is the distance between the horizontal tangent to an upper active roll and the tangent to the two lower rolls arranged below the upper roll. This difference can be measured by averaging the distance from the upper roll to each of the two corresponding lower rolls.

In all cases, and according to the method of the invention, the nesting references developed by the leveling model 110 are added to a tilt instruction to control one side of the machine, and entrenched to control the other side; in order to achieve a balanced tilt and distributed by side with respect to the value of the theoretical nesting necessary to obtain the undulation defined by the model. Of course, and always in the context of a method according to the invention, if the individual adjustment means of the nesting of the active cylinders 52 are constituted by a row of hydraulic cylinders, it will be advantageous to superimpose the adjustment of the nesting of the row of jacks, a differential individual adjustment of each cylinder to achieve a bending effect on the active roller so as to obtain a better distribution of the leveling effect on the width of the product to be hovered.

In a method according to the invention, the tipping instructions are established during an equilination phase on a flat machined product of known thickness as a gauge.

This product or template is introduced into the machine and a slight interlocking is controlled to cause the active rollers to be clamped on the product or template. We then measure the leveling forces induced on each side of the machine, for example using the force sensors 35 installed on the cylinders 3 when one is in the presence of a machine of the type described in Figure 2. It then controls a tilting so as to balance the forces on one side and the other of the machine, if they are not initially, by tightening the side of the machine that generates the smallest effort, and we note the value of the tilt which allows to obtain equal efforts on each side. All this sequence is managed by the computer 100 which makes it possible to memorize the values of the forces and those of the failovers produced. These values are then used during operation of the machine as a failover preset for all nesting settings that will be determined by the model installed in the computer 100, and according to the embodiment that has been described above. This equilination method is, according to the invention, used with all the embodiments of the method described, that is to say that it can be implemented by the two groups of cylinders 3 (one group for each side of the machine) in the case where only a sensor is available for measuring the distance of the active rollers, but it can also be implemented by performing a simultaneous equilagration but independent of the cylinders 3 of the zone of entry and those of the exit area in case one has a measurement in each of these areas.

It is also possible to establish an equivalent equiliation procedure, and still according to the method of the invention, in the embodiment for which the support devices 52 of each upper active roller 4 is a device consisting of a row of hydraulic cylinders, as well as an absolute measure of the spacing for each pair of active rolls. The procedure is the same and consists in ordering a tilting of each pair of active rolls until the equal forces applied at their end are obtained, and using this tipping value as a set point for all subsequent operation. of the machine.

According to an improved method of the invention, equilination is performed on a moving strip. For this purpose a flat machined product of known and constant thickness is used, a slight imbrication of the active rollers corresponding to a dimension a little smaller than the thickness of the product serving as caliber is controlled, and the produced in the machine. We measure and memorize the forces generated on each side of the machine and calculate their average value throughout the scrolling time. Equiliation will then be achieved by introducing the tilt that will equalize these average values.

Of course, the invention is not limited to the details of the embodiments that have been described as a simple example, variants that can be used without departing from the scope of the claims.

In a simplified embodiment in which a single sensor 6 is installed to measure the spacing of the active rollers 4,4 ', for example in the central zone of the machine, it is conceivable to introduce an adjustable tilting between the input zone and the output zone by introducing it at the level of the electronic circuits 9, so as to obtain a decrease in the rate of plasticity, which may be necessary in certain cases.

In summary, to plan a sheet by the method according to the invention, it begins by calculating using a planing model, the spacings that must present in load planing rollers. The leveling model that can be used is for example a model that the skilled person knows. Such a model calculates the behavior of the product to be hung and the planer from the geometric and mechanical characteristics of the sheet to planer and the planer (for example: thickness and width of the sheet, yield strength at the leveling temperature of the metal of which it is made, possibly amplitude and nature of the defects, number of glider rolls, distance between rollers of the same crew, roll diameter).

It allows, by methods that the skilled person will know how to implement, to determine an optimal setting of the planer, and thus to determine clamping instructions including input and output planer.

The setting instructions can be supplemented by balancing instructions between the two sides of the leveler determined by the equilination operation.

With the aid of the setting instructions, possibly supplemented by the balancing instructions, the vacuum planer is first pre-adjusted, then during leveling (when the planer is loaded), the spacings of the active rolls as measured so that they remain substantially equal to the set values.

The reference signs inserted after the technical features mentioned in the claims, are intended only to facilitate the understanding of the latter and in no way limit the scope.

Claims (15)

1. Method of controlling the path of the product in a flattening machine of the type comprising a fixed supporting frame (1), two flattening gangs of parallel rollers respectively located above (2) and below (2') the web, requisite devices (3, 52) for setting the imbrication of the rollers, and means (35) for measuring flattening forces at least on two sides of the machine, characterised in that a theoretical presetting model (110) gives at least one reference value for presetting the imbrications, and in that, in the course of flattening, at least one value of the spacing of the flattening rollers is measured directly, which value is compared with reference values, and in that the elements (3, 52) for setting the position of the flattening rollers are acted upon to maintain the measured values equal to the reference values with increased precision so as to maintain the path of the product to be flattened inside the machine in conformity with the undulation expected by the model (110) for carrying out the flattening.
2. Method of controlling the path of the product in a flattening machine, in accordance with claim 1, characterised in that two measurements of the value of the spacing of the flattening rollers are carried out, the measurements being respectively a first one at the entry to the machine and a second one at the exit from the machine, each of which measurements is compared with the reference value given by the model (110), and in that the elements (3, 52) for setting the position of the flattening rollers respectively at the entry and exit of the machine are acted upon to maintain the measured value equal to the reference value with increased precision so as to be able to achieve the decrease in the degree of plasticisation expected by the model (110) for carrying out the flattening.
3. Method of controlling the path of the product in a flattening machine, in accordance with claim 1, characterised in that measurement of the value of the spacing of each of the flattening rollers (4, 4') is carried out, each of which measurements is compared with the reference value given by the model (110), and in that the individual elements (3) for setting the position of each of the flattening rollers is acted upon to maintain the measured value equal to the reference value with increased precision so as to achieve the undulation and the decrease in the degree of plasticisation that are expected by the model (110) for carrying out the flattening.
4. Method of controlling the path of the product in a flattening machine, in accordance with any one of the preceding claims, characterised in that equilevelling of the active rollers is carried out on a flat machined metal sheet of known thickness by differently modifying the position of the active rollers by means of lateral tilting from one side to the other so as to obtain equal flattening forces on the two sides of the machine, which forces are measured by the measurement devices (35).
5. Method of controlling the path of the product in a flattening machine, in accordance with claim 4, characterised in that the equilevelling is carried out on an advancing metal sheet by differently modifying the position of the active rollers by means of lateral tilting from one side to the other, and in that the average values of the forces recorded by the measurement devices (35) on each side during said advancing are equalised.
6. Flattening installation comprising parallel rollers for carrying out the method according to any one of claims 1 to 5, comprising a fixed supporting frame (1), two flattening gangs of parallel rollers respectively located above (2) and below (2') the web, requisite devices (3, 52) for setting the imbrication of the rollers (4, 4'), and means (35) for measuring flattening forces at least on each side of the machine, characterised in that the installation is provided with at least one device (6, 6') allowing direct measurement of the value of the spacing of the flattening rollers at at least one point.
7. Flattening installation comprising parallel rollers, in accordance with claim 6, characterised in that it comprises at least one electronic device (9) making it possible for the measured spacing of the flattening rollers to be controlled in accordance with the theoretical value given by the model (110) by acting on the devices (3) for setting the imbrication.
8. Flattening installation comprising parallel rollers, in accordance with claim 7, characterised in that the devices (3) for setting the imbrication are hydraulically controlled.
9. Flattening installation comprising parallel rollers, in accordance with claim 6, characterised in that the installation is provided with a device making possible the direct measurement of the value of the spacing of the flattening rollers at at least two points, one point (6) being located in the entry zone of the machine and the other (6') being located in the exit zone.
10. Flattening installation comprising parallel rollers, in accordance with claim 9, characterised in that it comprises at least one electronic device (9) making it possible for the measured spacing of the flattening rollers located in the entry zone of the machine and, on the other hand, in the exit zone to be controlled in accordance with the theoretical value given by the model (110) for the spacing of the rollers located, respectively, in the entry zone of the machine and in the exit zone, by acting independently on the devices (3) for setting the imbrication of the rollers of, respectively, each of the entry and exit zones.
11. Flattening installation comprising parallel rollers, in accordance with claim 10, characterised in that the devices (3) for setting the imbrications are hydraulically controlled.
12. Flattening installation comprising parallel rollers, in accordance with claim 6, characterised in that the installation is provided with a device (6, 6') making possible the direct and separate measurement of the value of the spacing of each pair of active flattening rollers (4, 4').
13. Flattening installation comprising parallel rollers, in accordance with claim 12, characterised in that it comprises a means of individually setting the position of each flattening roller and at least one electronic device (9) making it possible for the measured spacing of each of the flattening rollers to be controlled in accordance with the theoretical value given by the model (110) for the spacing of each of those rollers by acting independently on their device (52) for setting the imbrication.
14. Flattening installation comprising parallel rollers, in accordance with claim 13, characterised in that the device (52) for setting the imbrication of each roller (4) is hydraulically controlled.
15. Flattening installation comprising parallel rollers, in accordance with any one of claims 8, 11 or 14, characterised in that the electronic device(s) (9) making it possible for the measured spacing of the flattening rollers to be controlled in accordance with the theoretical value given by the model (110) which the installation comprises makes it possible to set a differential lateral tilt of the rollers from one side to the other to a setpoint value.

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