This application is a National Stage entry of International Application No. PCT/FR2006/001793, filed Jul. 22, 2005, the entire specification claims and drawings of which are incorporated herewith by reference.
The invention relates to rolling mills. More particularly, the invention relates to a method and an installation for inspecting the quality of a sheet metal strip after rolling.
It is known that, upon completed rolling, the rolled sheet metal strip may exhibit certain aspect defects which may be due, for instance, to a slight variation in thickness in the transversal direction, caused by the deformation and the wear of the cylinders and/or the camber of the cage, or to marks left by the working rolls, whereas certain defects may also be to back-up rolls or to the cage properly speaking.
Such aspect defects are reproduced on each face, into the longitudinal rolling direction, with a period corresponding to the development, in this direction, of the circumference of the working rolls.
Still, it is more and more necessary to deliver sheet metals with a surface quality and, generally speaking, an aspect which is as perfect as can be. To do so, the surface condition of the sheet metal strip must hence be checked at the end of the rolling, in particular, for observing the marks left periodically on the strip by the passing thereof between the working rolls.
As known, it is possible, for instance, to sample a section of the sheet metal strip exiting the rolling mill, in order to inspect both faces. The inspection is conducted on a strip length, so-called inspection length enabling to observe the marks or prints left by the cylinders of the rolling mill and the inspection length hence corresponds to the greatest period of the marks of the different cylinders. In a tandem rolling mill fitted with several cages, the inspection length corresponds to the period of the marks produced in the uppermost cage, from which the strip is subjected to the greatest elongation while passing through the following cages.
As known, the inspection may be conducted in a particular installation where certain reels are conveyed for inspection, after the production thereof by the roll plant. The inspection installation includes a so-called inspection unwinder and horizontal tables enabling to unwind a length of product corresponding to the inspection length, whereon the operator may observe, locate, draw or record in any other way the marks shown on both faces of the sample used for the inspection.
Such an inspection installation is costly to provide as well as to operate. Indeed, a reel must be removed from the produced batch, conveyed to the inspection installation, and then inspected before proceeding with the delivery thereof. However, the roll plant continues to produce during the inspection of a sample of a rolled strip, and the detection of a significant defect hence leads to rejecting then the rolled sheet metal strips produced in the meantime.
It is possible to avoid this shortcoming in continuous rolling installations including several successive cages operating in tandem, whereas the rolled strip is wound into a reel after exiting the last cage. In such a case, indeed, the winding plant includes normally at least two mandrels operating alternately, for instance on a carrousel type coiler, and the strip is cut on the fly, once completely wound on a mandrel, for further winding on another mandrel. Two successive cuts may then be performed which are spaced apart so as to sample an inspection length, the latter then being conveyed towards an inspection table thanks to switching and driving systems. This inspection length has been subjected all the rolling steps, as the remains of the strip and its surface condition is hence quite illustrative of that of the strip.
Such a method is not, however, applicable to a reversible roll plant comprising at least one rolling cage arranged between two winding/unwinding devices between which the strip circulates alternately in one direction and in the other, each winder/unwinder device acting, according to the rolling direction, as a coiler downstream of the rolling cage and as an upstream uncoiler.
Indeed, the rolling not being continuous, it is not useful to have a carrousel coiler, with on-the-fly cutting of the strip.
Moreover, according to the number of passes, the downstream coiler, at the end of the last pass, may be situated on one side or the other of the rolling mill.
In such a case, usually, the inspection length is simply sampled from the strip at the end of the last pass, on one side or the other of the rolling mill.
Obviously, this inspection length must be, then, rejected. Still, in reversible rolling, it is already necessary to reject a significant length of the strip.
Indeed, to enable tensioning of the strip, during the rolling step, in either direction, it is necessary that a certain length of strip which may be called “service length” is wound into several spires on each mandrel.
In certain cases, this service length used stretching the strip, is formed of an extension welded at each end of the strip. The latter may then be rolled conveniently over its whole length but the welding of both extensions then their retraction involves for a certain time and decreases the throughput of the installation. When the reel is of great length, it seems hence preferable to sacrifice, at each end of the strip, a service length qui is not rolled to the thickness requested and must hence be rejected.
Usually, such a reversible roll plant includes, in addition to both winding/unwinding devices, a so-called “first pass” unwinder capable of rehandling reels wound around themselves and without any traction. A reel being placed on the first pass unwinder, the product is unwound therefrom, in a first running direction, while threading its leading end through the cage for engaging it on the winder/unwinder device placed on the other side of the cage and hence acting as a coiler. The product is then wound almost completely around this coiler until its end, forming the tail of the strip, leaves the unwinder, this first pass occurring, hence, without any rolling step.
On must then reverse back for engaging the tail of the strip on the second winder/unwinder device placed on the same side as the first pass unwinder and whereon said end is fastened then wound into superimposed spires. However, the winder/unwinder placed upstream of the rolling mill, is braked so that the strip, driven by the rotation of the cylinders, is tensioned, which enables to start the rolling which is, hence, performed in the reverse direction of the first running direction during this second pass.
The running of the strip is, however stopped before the end of the unwinding operation so as to leave, on the mandrel of the uncoiler, upstream of the cage, a minimal wound length corresponding to the number of spires necessary for keeping the tension of the strip and that is called “service length”.
The rolling may then be performed alternately in one direction and in the other between both winders/unwinders which act as, alternately, a coiler and an uncoiler, but, for holding at each pass the tension necessary to the rolling operation, it is necessary to keep on each mandrel a service length which is hence not rolled. At the end of the last pass, the service length situated at the tail end of the strip and not showing the required qualities must then be eliminated. Similarly, the service length situated at the leading end of the strip and wound inside the reel, should be eliminated to the end of the unwinding operation thereof.
A rolled reel is hence rolled to the requested thickness only over a central useful portion surrounded by two non rolled service lengths, which represent a loss called “scrap”. As indicated above, this loss should be added usually the inspection length which is sampled from the useful portion of the strip exhibiting the required qualities. Such an inspection method hence increases the scrap.
The invention intends, in a reversible mill, to remedy this shortcomings thanks to a new process enabling on-line inspection while preserving high throughput, whereas the rejected length does not exceed both service lengths which must remain wound on each mandrel and does not exhibit hence the require thickness.
The invention also covers a rolling installation for the implementation of the method.
The invention applies hence, generally speaking, to a reversible roll plant, comprising at least one roll cage arranged between two winder/unwinder devices each having a mandrel whereon a service length of the strip is wound into several spires for tensioning the strip, the rolling being performed in several passes while maintaining the winding operation, on each mandrel, of the service length, the strip being rolled to the requested thickness over a useful part ranging between both service lengths.
According to the invention, at the end of the last rolling pass between a winder/unwinder placed upstream of the cage, in the rolling direction and acting as an uncoiler, and a downstream winder/unwinder acting as a coiler, the upstream service length is completely unwound from the upstream uncoiler and is subjected to at least one roll pass, the strip being then cut in the vicinity of the end of its useful to part, so as to release, at its rear end in the direction of the last pass, a length at least equal to a necessary inspection length, whereof at least one part corresponds to the upstream service length which has been rolled at least once and thus provides an image of the aspect failures of the useful part.
As indicated above, the reel to be rolled is often placed first of all on a simple unwinder situated on one side of the rolling mill and from which the strip is unwound to pass through the rolling mill and be attached to the winder/unwinder placed on the other side.
In case when the last reversible pass is an even pass, the strip progresses on the unwinder side. It is advantageous, at the end of the rolling of the upstream service length, that the rear end thereof is maintained clamped between the working rolls and that the rotational direction of said cylinders is then reversed so as to send backwards a sufficient length of strip to sample therein an inspection length separated from the strip after cutting said strip upstream of the cage, in the direction of the last pass, said sampled length being situated on an inspection table and the strip being returned in the direction of the last pass to wind completely on the downstream coiler.
In such a case, the inspection length is rolled twice, first of all in the direction of the last pass then in reverse direction, before being cut and sent toward the inspection table which is placed of the side opposed to the unwinder, relative to the rolling mill.
Conversely, in case when the last reversible pass is an odd pass, the downstream reel whereon the strip is wrapped, is placed on the same side of the rolling mill as the inspection table. The strip may then be cut at a distance from its rear end corresponding to the requested inspection length, this inspection length being rolled only once and sent directly toward the inspection table situated on the same side of the rolling mill.
The invention thus enables to sample from the strip an inspection length whereof at least the greatest part corresponds to one of both service lengths which remains wound on the mandrels de each of the winders/unwinders, this service length passing at least once between the cylinders of the rolling mill, which is sufficient to provide an image of possible defects generated by said cylinders over the useful length of the strip.
Thanks to the invention, the inspection length is hence not sampled from the useful portion but from the tail of the strip which, anyway should have been rejected since it had not been rolled to the requested thickness.
Generally speaking, the invention applies to any reversible mill comprising at least one cage situated between two winder/unwinder devices, but it is particularly advantageous in the case of a reversible mill provided with two rolling cages spaced apart from one another since, in such a case, the scrap is increased by the fact that the strip length included at the end of each pass, between both cages has been rolled only once into the upstream cage and therefore does not exhibit the requested thickness. The length to be rejected then includes the service length remaining wound on the mandrel to which is added the distance between both cages and the total length to be rejected is hence, normally, greater than the necessary inspection length, since the latter may, thus, be easily sampled from the tail of the strip rolled at least once during the last pass.
The invention hence enables to perform an on-line inspection without sampling any inspection length from the useful portion of the strip and, consequently to preserve high production yield.
Besides, the implementation of the method may be conducted at low cost and on existing reversible rolling installations since cutting, switching and inspection means are used which, anyway, were necessary.
The invention also covers an improved rolling mill installation for the implementation of the method according to the invention.
But other features and advantages of the invention will appear in the following description of a particular embodiment of the invention, given solely by way of illustration and without limitation thereto, with reference to the appended drawings whereon:
a to 2j are diagrammatical views of the rolling mill of
In the embodiment represented on Figures, the rolling mill 1 is, moreover, associated with a first pass unwinder 11 capable of receiving a reel 21.
This reel 21 is formed of a sheet metal strip having an initial thickness which ought to be reduced by rolling to obtain a sheet metal strip having a final thickness required. The sheet metal strip is wound around itself to form the reel 21 and is first of all situated on the unwinder 11 which does not include any mandrel. Means 31 enable to grasp the leading end of the sheet metal strip and to guide it in order to pass between the cylinders of both cages 3 and 5 while unwinding to the left, the leading end of the strip being attached on the winder/unwinder 12 placed on the second side of the rolling mill 1 and which then serves as a coiler for winding the sheet metal strip. Said strip hence runs from right to left in this first running pass which takes place without any rolling until the strip is wound completely whereof the rear end, forming the tail, remains clamped between the working rolls of both cages 3 and 5, as represented schematically on
As usual, a second upstream winder/unwinder also called second-pass coiler 13 is arranged between the first pass unwinder 11 and the inlet to the rolling mill 1. The rotational direction of the working rolls of both cages 3 and 5 is then reversed for running the strip from left to right, in a second pass.
The right end of the strip, now the head thereof, is engaged on the mandrel of the winder/unwinder 13 which then operates as a second-pass coiler (
The upstream winder/unwinder 12 which operates as an uncoiler, is braked so as to tension the strip driven by the cylinders of both cages 5 and 3. The rolling may hence start at this second pass.
The rolling is then performed alternately in the first running direction from right to left, for the odd passes, and in the second direction, from left to right, for the even passes, the number of passes depending on the rolling conditions and on the final thickness required.
However, to enable the tensioning of the strip, a service length remains wound on the winder/unwinder 13 acting as an uncoiler for the odd passes as well as on the winder/unwinder 12 acting as an uncoiler for the even passes.
As known, an upstream unbending device 31 of the strip as well as upstream cutting shears 32 are situated immediately upstream of the rolling mill 1, in the first running direction.
Similarly, the upstream cage 3 includes presses 33 enabling to engage the leading end of the strip to be rolled between the trains of rolls of the upstream cage 3.
Preferably, the cages 3 and 5 are of quarto type, i.e. they include respectively two working rolls 30, 50 of smaller radius and two holding cylinders 39, 59 of greater radius.
The downstream cage 5 is identical to the upstream cage 3, except for the fact that the unbending device 51 as well as the engaging presses of the strip 53 are arranged downstream of the second cage 5, so as to enable the operation of the rolling mill in reverse direction.
A switching device 60 enables to guide the strip first of all towards an overhead conveyor, then towards an inspection conveyor forming the inspection table 62. Possibly overhead and inspection conveyors are gathered by an intermediate passage conveyor. When the sheet metal is on the inspection table 62, the inspection step properly speaking is performed by a qualified person having the necessary means.
Downstream of the inspection table 62, the roll plant includes a drum type turning-over device 65 enabling to turn over the sample to inspect it on its other face.
At the end of the inspection step, as will be described below with reference to
Besides, the reels 11, 13 and 12 are carried by jacks enabling the loading and the unloading thereof. The whole installation rests on concrete foundations. A metal stand enables to maintain and to support the different constituents of the installation.
Each of
On
On
d represents diagrammatically the end of the last pass. The reel 21 is fully unwound and the sheet metal strip 100 is wound around the mandrel of the first-pass coiler 12 forming a reel 22. The first pass is complete when the tail end 102 of the strip 100 is close to the upstream cage 3. It is advantageous not to disengage the tail end 102 at the end of the first pass. By disengaging is meant that the tail end 102 runs past the downstream cage 5. The first pass is hence stopped at least when the tail end 102 is situated between the cages. Preferably, the first pass is stopped when the tail end 102 is still upstream of the upstream cage 3.
The operating direction of the rolling mill 1 is then reversed so as to control the running of the sheet metal strip 100 in the reverse direction indicated by the arrow represented on
The second pass may then start, illustrated by
The number N of passes of the rolling cycle depends on the reduction rate to provide so as to obtain the final thickness requested.
However, as indicated above, solely the central useful portion of the strip is rolled to this thickness, both service lengths which must remain wound on the mandrels of both winders/unwinders 12, 13 not being rolled at each pass.
According to the invention, the inspection will be performed on a section sampled from one of both these service lengths which should, anyway, be rejected. This section should be, however, an image of the useful portion so as to exhibit the same aspect thereof and, in particular, the same marks and prints left by the rolls.
To do so, as shown schematically on
As the strip thus remains clamped between the rolls of both cages 5 and 3, the rotational direction of said rolls is reversed so as to cause the strip to re-start in the first running direction, i.e. from right to left, on
The running, from right to left, is carried on until the tail end 101 of the strip, which is the front end in this first running direction, is situated at a distance from the shears 32, situated upstream of the first cage 3, at least equal to the necessary inspection length. In practice, this inspection length is, generally, slightly greater than the service length and the strip may then be cut by the shears 32, as indicated on
The remaining part 105 of the strip, which has remained clamped between the rolls of the cages 3 and 5, is driven towards the left, i.e. in the first running direction and directed by a switching device towards the inspection table 62 represented on
This section 105 corresponding, at least over the greatest part thereof, to the service length, is run twice between the working rolls, respectively in the first running direction, from left to right, on
On
The method of inspection according to the invention hence makes use of the fact that the non-rolled service length, which must be rejected anyway, is employed as an inspection sample since it exhibits the marks and prints left by the rolls. Indeed, although it has not been rolled to the right thickness, the non-rolled length runs between the rolls which hence leave their marks on both faces.
The inspection length must be selected so as to include at least one period of each of the marks of the trains of rolls of the cages of rolling mill. Hence the inspection length includes at least the non-rolled length, but may also be larger if the period of one of the trains of rolls requires it.
The invention hence enables to inspect on line the quality of the rolling while minimising the losses of rolled material to the thickness requested, since the inspection is realised on a part of the sheet metal which should have been rejected anyway, not being of the right thickness. Besides, the inspection operation is not time consuming. Indeed, as shown on
Other embodiment variations of the method according to the invention as well as of the roll plant are possible.
For instance, shears may be situated upstream or downstream of the rolling mill, optionally between the cages of the rolling mill. In case when shears were arranged only downstream of the rolling mill 1, once the inspection sample has been separated from the remainder of the sheet metal strip 100, the rolling mill could not be used any longer as a driving means for the sample towards the inspection table. Appropriate driving means should then be available, capable of moving the sample on the inspection table.
In such a case, however, if an odd number of passes is required, the inspection table may be situated downstream of the rolling mill 1 in the first running direction, and will enable to inspect a sample corresponding to the service length wound on the winder/unwinder 13 and, situated at the tail end in the first running direction.
In such a case, indeed, the inspection table may be placed on the same side as the coiler 12 whereon the strip is wrapped. If shears are available between the second cage 5 and the coiler 12, the latter may cut the strip at a distance from its rear end 102 at least equal to the necessary inspection length. The strip may then be wound completely on the coiler 12 and its rear part, which forms the inspection length, remains clamped between the rolls of the cages 5 and 3 which drive it towards the left, in the first running direction so as to direct it towards the inspection table. In such a case, the inspection section runs only once between the rolls of both cages 5 and 3 but this single passage is sufficient so that the rolls leave their marks and that the inspection length exhibits an aspect significant of that of the useful portion of the strip.
As indicated above, since two reversible cages spaced apart from one another are used, the inspection length remains tensioned between both cages, even after cutting the strip.
The method according to the invention is, however, applicable, to a rolling mill comprising a single reversible cage. In such a case, after being released from the uncoiler, the rear part of the strip is not tensioned any longer but the passage between the working rolls which remain clamped on the strip, enables to leave the same marks on both faces thereof, the inspection length sampled from the rear end of the strip and forming the service length, exhibiting the same aspect as the useful portion of the strip.
Although the invention has been described with reference to a particular embodiment, it is not limited to this embodiment. It covers all the technical equivalents of the means described as well as their combinations within the framework of the invention.
Number | Date | Country | Kind |
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05 52283 | Jul 2005 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2006/001793 | 7/21/2006 | WO | 00 | 1/22/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/010148 | 1/25/2007 | WO | A |
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Number | Date | Country | |
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20080165351 A1 | Jul 2008 | US |