The present invention, which falls within the field of metallurgy, and more particularly the manufacture of metal sheet, especially steel sheet, relates to the calibration of a multi-roll leveler, excluding those called multi-roll tension levelers.
It is known that levelers are designed to correct or considerably reduce any defects in metal sheet that result from various manufacturing stages (rolling, coiling, heat treatments). Mention may be made, for example, of developable defects (initial bend, “tile”) or nondevelopable defects (defects “along the edge” or “along the center”).
It will be recalled that the principle of cold leveling consists schematically in converting a geometrical defect into a system of variable residual strains within the thickness by means of alternating bending stresses. The sheet or strip to be leveled thus passes through a stand formed from an assembly comprising at least two series of lower and upper rolls placed facing each other. The two series are arranged so as to be approximately parallel to each other and perpendicular to the run direction of the strip. When the sheet passes between these rolls, it undergoes partial plastic deformation in bending in one direction and then in the opposite direction. The amplitude of the bending progressively decreases because the imbrication of the rolls decreases upon going toward the exit of the leveler. Consequently, it is possible to manufacture products of excellent flatness and with a very low level of residual stresses, capable of meeting certain applications in the fields of metal furniture, domestic electrical appliances and the automobile industry.
The ever tighter product tolerances, in terms of flatness or level of residual stresses, imposed by users, require ever better control of the mechanical behavior of levelers, without which their operation would remain uncertain. At this stage of the description, it seems worthwhile, in order for the various adjustment parameters to be better understood, to describe the main components of a multi-roll leveler.
For this purpose,
The adjustment assemblies according to the aforementioned example, of the screw-nut type, are actuated by the motors 19a and 19b by means of drive shafts 17a and 17b. The couplings 18a and 18b are used to temporarily decouple the adjustment assemblies that they connect, so as to be able to adjust the transverse parallelism (or “dislocation”) between the upper and lower rolls, both on the entry side and on the exit side of the leveler. The imbrication of the rolls is then adjusted by means of the motors, which simultaneously drive the adjustment assemblies at the entry or exit of the leveler.
The dislocation has to be removed by a considerable number of operations on the machine. The tilt is adjusted in a standard fashion in order to modify the imbrication of the rolls, in particular according to the characteristics of the leveled strip.
In the case of a leveler comprising 5 to 6 levels of superposed rolls (case not shown here), eccentric rollers are also present, these bearing on intermediate rolls and making it possible to adjust the clamping of the entry roll 12a and the exit roll 12m.
Thus, the overall adjustment of a leveler involves many parameters, and in particular:
the preadjustment settings or charts indicated by the manufacturers may prove unsuitable;
regular checking of the leveler calibration is often performed by the operators, using a ground bar or a round product of calibrated diameter introduced into the gap in order to check the value when the leveling rolls come into contact with this bar. This operation, carried out in the absence of load, therefore does not guarantee that there will be a precise gap when the leveler is under load (clamping onto a product) since the play and spring of the machine are not taken into account in this method. The precision of this calibration method is difficult to quantify, as it is obviously dependent on the sensitivity and the experience of the operators, and its reproducibility is not guaranteed.
However, a method has been proposed (“Modeling of the leveling process and applications to heavy plate mills and strip finishing mills”, METEC Düsseldorf 1994) for characterizing levelers under dynamic load and allowing them to be calibrated. This method relies on the use of reference sheets of different formats, which include strain gages placed in line with each counter-pressure means.
Although this method using instrumented sheets is perfectly suitable for defining the initial adjustments of a leveler, it is however poorly suited to regularly monitoring its proper operation. This is because its use requires the machine to be stopped for several hours and a skilled operator has to work on the machine, with sophisticated measurement means, thereby greatly penalizing productivity. In addition, in the case of large levelers, the size of such sheets and the difficulty of manipulating them become a not insignificant problem. There is therefore a great need to have an easily implementable method that would make it possible:
to detect any mechanical defects of a leveler;
to check the calibration of a machine in case of doubt;
to check that the initially defined adjustments have not drifted over time;
to carry out this calibration much more rapidly than by the instrumented sheet method, and with a precision and a reproducibility that are much better than with the current manual method using calibrated bars; and
to accurately adjust the clamping of the entry and exit rolls by acting on eccentrics or equivalent means.
The object of the present invention is to meet these requirements. In particular, the object of the invention is thus to determine, precisely and simply, the characteristics of a leveler by performing a reproducible under-load calibration with known loads.
The object of the invention is also to determine the position of the counter-pressure adjustments so as to be able to correct the bending of the leveling rolls.
The object of the invention is also to correct the “dislocation” of the leveler and to check its “tilt” with parallel beams.
The object of the invention is also in particular to ensure that the initial adjustments have not changed over time.
With these objectives in mind, the subject of the invention is a device for calibrating a multi-roll leveler for leveling a metal strip, comprising at least one assembly consisting of two series of rolls, namely lower rolls and upper rolls, placed facing each other so as to imbricate the rolls of one series into those of the other, these series of rolls being placed substantially parallel to each other and perpendicular to the run direction of the strip to be leveled, said device being characterized in that it furthermore includes a rigid measurement bar of sufficient length to be positioned in the leveling direction between said set of said upper and lower rolls, extending over all the rolls, rigid protrusions integral with the bar reproducing, when they are placed plumb with the lower rolls, the action of said lower rolls and their mechanical properties, and a thin metal plate that rests on these protrusions and is fastened to one of them at around the middle of the bar, said thin metal plate having extensometers for measuring its elastic deformations.
According to a preferred feature of the invention, the length of the instrumented thin plate is greater than the distance separating the first roll from the last roll of the leveler, the width of said plate preferably being less than that of a counter-pressure ramp or roller.
According to another advantageous feature of the invention, the geometrical and mechanical characteristics of said thin plate are chosen in such a way that, when this thin plate is subjected to a force corresponding to the leveling of strips with the lowest thickness, lowest yield strength and lowest elastic modulus that are treated in the leveler, these result in a deformation within the elastic region of the material of the plate.
According to another advantageous feature of the invention, the extensometers may be strain gages based on a change in resistance, or fiber-optic extensometers that measure the change in length of a Fabry-Perot cavity, or any other means for measuring the local deflection of said thin plate.
According to another feature of the invention, the bar includes an alignment stud that is inserted between two lower rolls in order to position said bar in a precise and reproducible manner along the longitudinal direction of said leveler.
According to another feature of the invention, at least two extensometers are positioned at the center and on the lower part of the plate, so that, once the instrumented bar is in place in the leveler, the extensometers are located in line with the fourth roll from the entry of the leveler and with the N-3th roll from the exit of the leveler, said leveler having in total N rolls.
Advantageously, at least two extensometers are positioned at the center and on the lower part of the plate, so that, once the instrumented bar is in place in the leveler, said extensometers are located in line with the second roll from the entry of the leveler and with the N-1th roll from the exit of the leveler, said leveler having in total N rolls.
According to another feature of the invention, the bar advantageously includes an extension for easily manipulating it within the leveler.
The subject of the invention is also a method for calibrating a multi-roll leveler using the instrumented-bar device defined above, characterized in that two such measurement bars, including a thin instrumented plate, are positioned near the bearings in the leveler, the counter-pressure ramps being completely lowered, the series of lower rolls and upper rolls are brought close together by acting on the clamping control means so as to exert a force on said measurement bars, this reference force corresponding to the leveling of strips having the lowest thickness, lowest yield strength and lowest elastic modulus that can be treated in the leveler, said plate being in a state of elastic deformation. Once this force is reached, the deformations of the bars are measured by means of said extensometers in order to deduce therefrom a reference gap, the dislocation and the tilt of said leveler, and, where appropriate, to apply corrections according to these results.
According to a preferred method of implementation, the calibration step defined above is carried out and then, in a subsequent step, the two measurement bars, including an instrumented plate, are positioned plumb with the counter-pressure ramps closest to the bearings and the two series of lower rolls and upper rolls are brought close together by acting on the clamping control means in order to bring them to the reference gap measured in the previous step, the displacements of the two aforementioned counter-pressure ramps are then varied in order to obtain a force identical to the reference force, measured from the deformations of the instrumented thin plate, and, by lateral displacement of the bars plumb with the other counter-pressure ramps, this operation is repeated as many times as necessary until all of the counter-pressure means have been calibrated.
According to another method of implementation, as many measurement bars, including an instrumented thin plate and defined above, are used as there are counter-pressure ramps, two said measurement bars are positioned close to the bearings in the leveler, the two series of rolls are brought close together by acting on the clamping control means so as to exert a reference force on the measurement bars, said force corresponding to the leveling of strips having the lowest thickness, lowest yield strength and lowest elastic modulus that are treated in said leveler, and, the plate being in a state of elastic deformation, the deformations undergone by the plates are measured by means of the extensometers in order to deduce therefrom the reference gap, and if appropriate to correct the dislocation and the tilt of said leveler, next, all of the measurement bars are placed in the leveler, positioned respectively in line with each counter-pressure ramp, the two series of rolls are brought close together by acting on the clamping control means in order to obtain the reference gap, the displacements of the counter-pressure means are varied in order to obtain the reference force, and the deformations undergone by the plates are measured by means of the extensometers in order to deduce therefrom the gap and the clamping force applied by the rolls and, where appropriate, corrections are applied to the calibration according to the results thus obtained.
Advantageously, the calibration methods described above are implemented using bars that include an alignment stud, which is inserted between two of the lower rolls in order to position each bar in a precise and reproducible manner along the longitudinal direction of the leveler, in such a way that the rigid protrusions reproducing the action of the lower rolls are placed in line with these rolls.
The invention will now be described more precisely, but not limitingly, with reference to the plates of drawings appended hereto, in which:
FIGS. 1 to 5, which illustrate the principle and the construction of a known multi-roll leveler, have already been commented upon previously;
The device illustrated in
A thin plate 82 rests on the protrusions 81. The presence of this plate simulates that of a thin product in linear contact with protrusions having a hardness comparable to that of the leveling rolls. The total length of this plate is greater than the distance separating the axis of the first roll from that of the last roll. The width of the plate, defined so that the overall support is sufficiently rigid, does not exceed the width of a counter-pressure means. The thin plate is integral with the bar, by being fastened to a single central protrusion of the bar, so as to allow free deformation of the plate on either side of the fastening point during clamping. This plate is fastened by a screw 86 as illustrated in
The characteristics of this metal plate are chosen according to the following points. As mentioned above, the stresses of this plate are those defined by the leveling conditions for the range of products that require the least load. By definition, these conditions result in the plastic deformation of the leveled products. The characteristics of the plate must however be chosen in such a way that these same conditions result only in its deformation within the elastic range. This means that at least one of the following characteristics of the plate—namely the yield strength, the thickness and the elastic modulus—must be greater than those of the leveled products.
Advantageously, the device includes an extension 85 that allows it to be easily manipulated, for example in order to move it transversely within the leveler. This extension also serves to provide the electrical connections to the strain gages.
As may be seen, two extensometers 83a and 83b (for example strain gages, fiber-optic strain gages, which measure the change in length of a Fabry-Perot cavity, or any other means for measuring the local deflection of the thin plate) are fastened to the lower part of the thin plate. Their precise location corresponds to the following data:
the two extensometers are placed as close as possible to the ends (entry and exit) of the leveler, so as to measure, by difference, the tilt of the machine as precisely as possible;
to obtain the greatest possible precision, the extensometers are placed in a region highly stressed in bending. Thus locating them at mid-distance between two upper and lower rolls (zero deformation) would not meet the desired objective;
advantageously, the extensometers are positioned on part of the thin plate that is stressed in tension. Although it is theoretically possible to locate them on a part stressed in compression, the difficulties in positioning them on a surface directly in contact with the rolls make this option substantially more difficult to implement;
it is also recommended to locate the extensometers at a point considered as being completely embedded, the boundary conditions of which are defined only by the positions of the rolls. This condition is not met in line with the rolls 12a and 12m in
however, it may also be advantageous to place extensometers in regions where the clamping has to be controlled more strictly, and where specific means are placed for acting thereon. This is the case at the leveler entry or exit, where the clamping may be modified especially by an eccentric acting indirectly on the rolls 12a and 12m. In this case, it may be advantageous to place extensometers at the center of the plate, in line with the two abovementioned rolls (83c and 83d, in
The total thickness of the device (bar+protrusions+plate+alignment system) is large enough to guarantee the stiffness of the assembly, while still remaining compatible with the maximum opening available in the leveler.
To carry out a measurement, the bar 8 is placed between the lower and upper rolls of the leveler. The stop 84 (or equivalent positioning system) positions the bar relative to these rolls and thus ensures that the entire bar is properly placed longitudinally relative to the leveler. Since the transverse position of a bar relative to a counter-pressure ramp is not critical, it may be positioned by placing the bar along the axis of the counter-pressure means using a standard measuring device or an equivalent system.
The following procedure describes a first step intended to determine and correct the dislocation and the tilt of a leveler:
two measurement bars 8 with an instrumented plate are placed in the leveler, these being placed as close as possible to the bearings 20, with the counter-pressure ramps 21 fully lowered. In a first step, the two series of rolls 11 and 12 are brought close together by acting on the clamping control means (motors 19a and 19b) so as to exert a leveling force. To ensure the greatest precision in the calibration method, this reference leveling force is chosen so as to reproduce the lowest force within the industrial application range of the leveler, which corresponds to the leveling of the thinnest products with the lowest elastic modulus and the lowest yield strength. The deformations measured on the bars 8 make it possible to deduce therefrom a value of the gap (which is termed the reference gap). By examination and comparison of the reference gap values measured along the longitudinal and transverse directions of the leveler, it is possible to correct the dislocation and the tilt of the leveler, for example by means of adjustments 16a, 16b, 16c, 16d of the screw/nut type or by equivalent devices.
The following procedure describes a subsequent step, aiming to determine the gap and the clamping force applied by the rolls in line with the counter-pressure means.
Two measurement bars 8 are positioned plumb with the first and second counter-pressure ramps 21a and 21k closest to the bearings. The two series of lower rolls 11 and upper rolls 12 are brought close together by acting on the clamping control means in order to bring them to the reference gap measured in the previous step. The displacements of the counter-pressure means 21a and 21k in question are varied so as to obtain the reference force, the measurement being carried out on the basis of the deformations of the instrumented thin plate 82 of the bars 8. This step is repeated, by laterally displacing the bars in line with two other counter-pressure means 21 as many times as necessary, until all of the counter-pressure means 21 have been calibrated.
For the purpose of carrying out the calibration and the adjustments more rapidly, it is also possible to employ as many measurement bars 8 including an instrumented thin plate 82 as there are counter-pressure ramps 21. The first step remains the same as that described above, whereas the next step consists in placing a bar 8 beneath each ramp 21.
As an example, the following results illustrate the invention: the device and the method were used so as to characterize a multi-roll leveler. In
It goes without saying that the invention is not limited to the examples described above, but extends to many equivalent alternative versions provided that its definition, given in the following claims, is reproduced. Thus, the invention described makes it possible to rapidly identify and correct any adjustment defects in multi-roll levelers. Being simple to use for the operator, it makes it possible to establish a diagnostic of any drift and to significantly increase the quality of the leveled products, by achieving better flatness and greater regularity.
Number | Date | Country | Kind |
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03/02845 | Mar 2003 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR04/00497 | 3/3/2004 | WO | 8/15/2006 |