In continuous casting of thin steel strip, molten metal is cast directly by casting rolls into thin strip. The shape of the thin cast strip is determined by, among other things, the surface of the casting surfaces of the casting rolls.
In a twin roll caster, molten metal is introduced between a pair of counter-rotated laterally positioned casting rolls which are internally cooled, so that metal shells solidify on the moving casting roll surfaces and are brought together at the nip between the casting rolls to produce a thin cast strip product. The term “nip” is used herein to refer to the general region at which the casting rolls are closest together. The molten metal may be poured from a ladle through a metal delivery system comprised of a moveable tundish and a core nozzle located above the nip, to form a casting pool of molten metal supported on the casting surfaces of the rolls above the nip and extending along the length of the nip. This casting pool is usually confined between refractory side plates or dams held in sliding engagement with the end surfaces of the casting rolls so as to restrain the two ends of the casting pool.
The thin cast strip passes downwardly through the nip between the casting rolls and then into a transient path across a guide table to a pinch roll stand. After exiting the pinch roll stand, the thin cast strip passes into and through a hot rolling mill where the geometry (e.g., thickness, profile, flatness) of the strip may be modified in a controlled manner.
The “measured” strip flatness and tension profile as measured at a device downstream of the hot rolling mill are insufficient to control in practice the hot rolling mill because, unlike cold mills (where the measured downstream flatness or tension profile of the strip closely resembles the flatness or tension profile produced off the mill), the flatness or tension profile may differ due to the action of creep. At elevated temperatures, steel undergoes plastic deformation in response to the tension stress at the entry and exit of the rolling mill in the form of creep. The plastic deformation occurring outside the roll gap in the regions where the strip enters and exits the mill causes changes in the entry and exit tension stress profiles, strip flatness as well as strip profile.
The high strip temperature at the exit of steel hot mills also makes difficult the measurement of the strip flatness or tension stress profile by direct contact. Non-contact optical methods for flatness measurement have been used. However, such non-contact flatness measurement results in partial flatness measurement, since at any given time only part of the strip exhibits measured flatness defects. In addition, creep in the strip results in the flatness of the strip at the roll stand exit likely being significantly worse than that measured downstream at practical flatness gauge locations.
In twin roll casting of thin strip, the cast strip is thinner than typically found in traditional strip in hot mills. Typically in twin roll casting, the thin strip is cast at a thickness of about 1.8 to 1.6 mm and rolled to a thickness between 1.4 and 0.8 mm. The strip entry temperature to the hot mill is higher than found in the final stand of the typical hot mill, approximately 1100° C. A consequence of thin strip high temperature and casting process is that the strip entry tension is low, and therefore is more susceptible to buckling and creep prior to entry into the hot mill. In addition, in thin strip casting, it is desirable to produce strip of a desired strip profile while maintaining acceptable flatness, since the product may be used as cold rolled replacement. The strip geometry is largely controlled by the caster. Low tensions employed in hot rolling mills results in small local roll-gap errors and loss of tension stress at points across the strip width, and results in strip buckles and poor strip flatness. We have found that tension stress provides a way to control the strip flatness.
A method is disclosed for controlling strip geometry in casting strip having a hot rolling mill comprising the steps of:
measuring an entry thickness profile of an incoming metal strip before the metal strip enters the hot rolling mill;
calculating a target thickness profile as a function of the measured entry thickness profile while satisfying profile and flatness operating requirements;
measuring an exit thickness profile of the metal strip after the metal strip exits the hot rolling mill;
calculating a differential strain feed back from longitudinal strain in the strip by comparing the exit thickness profile with the target thickness profile derived from the measured entry thickness profile; and
controlling a device capable of affecting the geometry of the strip exiting the hot rolling mill in response to at least the differential strain feed-back.
The method of controlling strip geometry in casting strip having a hot rolling mill may further comprise the steps of:
calculating a roll gap pressure profile from the entry thickness profile and dimensions and characteristics of the hot rolling mill;
calculating a feed-forward control reference and/or a sensitivity vector as a function of the target thickness profile and the roll gap pressure profile to allow compensation for profile and flatness fluctuations in the cast strip; and
further controlling the device capable of affecting the geometry of the strip exiting the hot rolling mill in response to the calculated feed-forward control reference and/or the calculated sensitivity vector.
The profile and flatness operating requirements may be selected so that the target thickness profile inhibits strip buckling. The device capable of affecting the geometry of the strip exiting the hot rolling mill may be selected from one or more of the group consisting of a bending controller, a gap controller, a coolant controller, and other devices capable of modifying the loaded roll gap of the hot rolling mill.
The method of controlling strip geometry in casting strip having a hot rolling mill may further comprise the step of generating an adaptive roll gap error vector from the measured exit thickness profile and using the adaptive roll gap error vector in calculating at least one of the feed-forward control reference and the sensitivity vector.
The method of controlling strip geometry in casting strip having a hot rolling mill may further include calculating the target thickness profile by performing at least one of time filtering and spatial frequency filtering.
The method of controlling strip geometry in casting strip having a hot rolling mill may also have the controlling step include performing symmetric feed-back control and asymmetric feed-back control of the bending controller and the gap controller. The controlling step may alternatively, or in addition, include subtracting out systematic measurement errors from the differential strain feed back when the rolling mill is engaged, the systematic measurement errors being generated through comparison of the entry and exit thickness profiles when the rolling mill is disengaged. The controlling step may also include performing temperature compensation and buckle detection, or performing at least one of operator-induced coolant trimming and operator-induced bending trimming.
More particularly, the method for controlling strip geometry in casting strip having a hot rolling mill may be used in continuous casting by twin roll caster comprising the following steps:
(a) assembling a thin strip caster having a pair of casting rolls having a nip therebetween;
(b) assembling a metal delivery system capable of forming a casting pool between the casting rolls above the nip with side dams adjacent the ends of the nip to confine the casting pool;
(c) assembling, adjacent the thin strip caster, a hot rolling mill having work rolls with work surfaces forming a roll gap between them through which incoming hot strip is rolled, the work rolls having work roll surfaces relating to a desired shape across the work rolls:
(d) assembling a device capable of affecting the geometry of the strip exiting the hot rolling mill in response to control signals;
(e) assembling a control system capable of calculating a differential strain feed-back from longitudinal strain in the strip by comparing a exit thickness profile with a target thickness profile derived from a measured entry thickness profile, and generating control signals in response to the calculated differential strain feed-back;
(f) connecting the control system to the device capable of affecting the geometry of the strip exiting the hot rolling mill in response to the generated control signals from the control system.
To perform the method in a twin roll caster molten steel may be introduced between the pair of casting rolls to form a casting pool supported on casting surfaces of the casting rolls confined by the side dams, and the casting rolls counter-rotated to form solidified metal shells on the surfaces of the casting rolls and cast thin steel strip through the nip between the casting rolls from the solidified shells. The device affecting the geometry of the strip being processed by the hot rolling mill may be capable of varying the roll gap of the work rolls, bending by the work rolls, and/or coolant provided to the work rolls in response to at least one of the control signals, to affect the geometry of the hot strip exiting the hot rolling mill.
Also disclosed is a control architecture for controlling strip geometry in casting strip having a hot rolling mill comprising:
an entry gauge apparatus capable of measuring an entry thickness profile of an incoming metal strip before the metal strip enters the rolling mill;
a target thickness profile model capable of calculating a target thickness profile as a function of the measured entry thickness profile while satisfying profile and flatness operating requirements;
an exit gauge apparatus capable of measuring an exit thickness profile of the metal strip after the metal strip exits the rolling mill;
a differential strain feed back model capable of calculating a differential strain feed-back from longitudinal strain in the strip by comparing the exit thickness profile with the target thickness profile derived from the measured entry thickness profile; and
a control model capable of controlling a device capable of affecting the geometry of the strip exiting the hot rolling mill in response to the differential strain feed back.
The target thickness profile model may inhibit strip buckling. The differential strain feed back model may also include temperature compensation capability and buckle detection capability. The differential strain feed back model further may include an automatic nulling capability capable of subtracting out systematic errors from the differential strain feed back when the rolling mill is engaged, the systematic errors being generated through comparison of the entry and exit thickness profiles when the rolling mill is disengaged.
The control architecture for controlling strip geometry in casting strip having a hot rolling mill may further comprise:
a roll-gap model capable of calculating a roll gap pressure profile from the entry thickness profile and dimensions and characteristics of the hot rolling mill, and
a feed-forward roll stack deflection model capable of calculating a feed-forward control reference and/or a sensitivity vector as a function of the target thickness profile and the roll gap pressure profile to allow compensation for profile and flatness fluctuations in the cast strip.
The adaptive roll stack deflection model may be capable of generating an adaptive roll gap error vector from the measured exit thickness profile and using the adaptive roll gap error vector in calculating at least one of the feed-forward control reference and the sensitivity vector. The target thickness profile model may further include at least one of time filtering capability and spatial frequency filtering capability as part of calculating the target thickness profile. The control model may include a symmetric feed back capability and an asymmetric feed back capability for controlling the bending controller and the gap controller.
Again, the device capable of affecting the geometry of the strip exiting the hot rolling mill may be selected from one or more of the group consisting of a bending controller, a gap controller, and a coolant controller. The control architecture may also support at least one of operator-induced coolant trimming and operator-induced bending trimming.
The control architecture may be provided in a thin cast strip plant for continuously producing thin cast strip to controlled strip geometry which comprises:
(a) a thin strip caster having a pair of casting rolls having a nip therebetween;
(b) a metal delivery system capable of forming a casting pool between the casting rolls above the nip with side dams adjacent the ends of the nip to confine the casting pool;
(c) a drive capable of counter-rotating the casting rolls to form solidified metal shells on the surfaces of the casting rolls and cast thin steel strip through the nip between the casting rolls from the solidified shells;
(d) a hot rolling mill having work rolls with work surfaces forming a roll gap between through which cast strip from the thin strip caster may be rolled;
(e) a device connected to the hot rolling mill capable of affecting the geometry of the strip processed by the hot rolling mill in response to control signals; and
(f) a control system capable of calculating a differential strain feed-back from longitudinal strain in the strip by comparing an exit thickness profile with a target thickness profile derived from a measured entry thickness profile, capable of generating the control signals in response the differential strain feed-back, and connected to the device to cause the device to affect the geometry of strip processed by the hot rolling mill in response to the control signals.
In the thin cast strip plant for producing thin cast strip with a controlled strip geometry by continuous casting, the control system may further be capable of calculating a feed-forward control reference and a sensitivity vector, and further capable of generating the control signals the feed-forward control reference, and the sensitivity vector. The feed-forward control reference and the sensitivity vector are calculated as a function of a target thickness profile, derived from a measured entry thickness profile, and a roll gap pressure profile to allow compensation for profile and flatness fluctuations in the cast strip.
These and other advantages and novel features of the present invention, as well as details of illustrated embodiments thereof, will be more fully understood from the following description and drawings.
In the present invention, a synthesized feedback signal (differential strain feed-back) is generated, as described herein, for better control of strip flatness and profile in the rolling mill of a continuous twin roll casting system. Flatness defects may be distinguished from other general vibration and body translational motions of the strip. If not distinguished, false positives can result that would typically indicate an asymmetric defect in the strip and could introduce differential bending control and coolant control problems. Also, using only flatness measurements as the feedback control may allow buckle defects at the mill roll entry and exit of sufficient magnitude to risk pinching and tearing of the strip, without any manifest detectable flatness problems at the downstream gauge location.
The control architecture 200 includes an entry gauge apparatus 210 capable of measuring an entry thickness profile 211 of the incoming metal strip 12 before the metal strip 12 enters the rolling mill 15. The entry gauge apparatus 210 may comprise an X-ray, laser, infrared, or other device capable of measuring an entry thickness profile of the incoming metal strip 12. The entry measurements 211 from the entry gauge apparatus 210 are forwarded to a target thickness profile model 220 of the control architecture 200. The target thickness profile model 220 is capable of calculating a target thickness profile 221 as a function of the measured entry thickness profile 211 such that the change in geometry required to achieve the target thickness profile 221 is insufficient to produce strip buckling (described in detail below). The target thickness profile 221 satisfies strip profile and flatness operating requirements.
The target thickness profile model 220 may comprise a mathematical model implemented in software on a processor-based platform (e.g., a PC). Alternatively, the target thickness profile model 220 may comprise a mathematical model implemented in firmware in an application specific integrated circuit (ASIC), for example. The target thickness profile model 220 may also be implemented in other ways as known to those skilled in the art. Similarly, other models described herein are mathematical models which may be implemented in various ways.
The target thickness profile model 220 also operationally interfaces to a roll-gap model 230 of the control architecture 200. The change in geometry 211′ necessary to maintain the target thickness profile 221 given the current entry thickness profile 211 is forwarded to the roll gap model 230 from the target thickness profile model 220. The roll-gap model 230 is capable of generating a roll gap pressure profile 231 as a function of at least the change in entry geometry 211′, corresponding to the roll gap pressure between the work rolls 16A and 16B of the rolling mill 15. The roll-gap model 230 may also use the physical dimensions and characteristics of the rolling mill equipment along with measurements of the roll force disturbances 216, tensions, and incoming thickness profile 211, to generate the roll gap pressure profile required to achieve the target thickness profile.
The target thickness profile model 220 and the roll-gap model 230 also operationally interface to a feed-forward roll stack deflection model 240. The feed-forward roll stack deflection model provides feed-forward flatness control and feed-forward profile control. The feed-forward roll stack deflection model 240 may be capable of generating actuator profile and flatness control sensitivity vectors 241 and feed-forward control references 242 as a function of at least the target thickness profile 221 and the roll gap pressure profile 231. The actuator profile and flatness control sensitivity vectors 241 and feed-forward control references 242 are used to control the bending controller 250 and a roll gap controller 255 (or some other suitable device that influences the loaded work roll gap of the rolling mill 15) in response to disturbances in the incoming strip thickness profile 211 and roll force disturbances 216 within the rolling mill 15. Bending by the working rolls 16A and/or 16B is controlled by the bending controller 250. A roll gap between the working rolls 16A and 16B is controlled by the roll gap controller 255.
A sensitivity vector represents the effect upon the transverse strip thickness profile or strip flatness which is created by a change in an actuator setting. For example changing the bending while the mill is in a particular operating state will cause the strip profile or flatness to change from an original state A to another state B as shown in the graph 600 of
A feed-forward control reference is a reference for a control actuator, controling bending, required to achieve some control objective for a particular section of strip, such as improved flatness or profile, which is calculated based upon information that is available before that particular section of strip enters the rolling mill. The most common form would be the calculation of an improved bending setting, based upon the measured entry profile, i.e. measured prior to entering the mill, given the current roll force and roll stack geometry (roll sizes, widths etc). Such a calculation is facilitated by means of the mathematical model herein known as the roll stack deflection model 240.
The control architecture 200 also includes an exit gauge apparatus 215 capable of measuring exit features 217 of the metal strip 12 after the metal strip 12 exits the rolling mill 15. The exit gauge apparatus 215 may comprise an X-ray, laser, infrared, or other device capable of measuring an exit thickness profile 217A and/or other features of the exiting metal strip 12 (e.g., strip temperature and strip flatness). The measurements from the exit gauge apparatus 215 are forwarded to a differential strain feedback model 260 of the control architecture 200 which operationally interfaces to the exit gauge apparatus 215. The differential strain feedback model 260 also operationally interfaces to the target thickness profile model 220 and is capable of calculating a differential strain feed-back 261 as a function of at least the calculated target thickness profile 221, the measured exit thickness profile 217A, and a target strain profile 360 (see
The measurements from the exit gauge apparatus 215 are also forwarded to an adaptive roll stack deflection model 270 of the control architecture 200 capable of generating an adaptive roll gap error vector 271 in response to at least the exit thickness profile 217A to cause adaptation of the feed-forward roll stack deflection model 240. The adaptive roll stack deflection model 270 also receives a roll force parameter 216 from the rolling mill 15 which may be used in generating the adaptive roll gap error vector 271.
The control architecture 200 also may include a control model 280 operationally interfacing to the feed-forward roll stack deflection model 240 and the differential strain feedback model 260. The control model 280 is capable of generating control signals 281-283 for controlling at least one of the bending controller 250, the gap controller 255, a coolant controller 290, and other suitable devices that influence a form of the loaded work roll gap of the rolling mill 15, in response to at least the differential strain feed-back 261 and actuator profile and flatness control sensitivity vectors 241. The coolant controller 290 provides coolant to the work rolls 16A and 16B in a controlled manner. The bending controller 250, gap controller 255, and coolant controller 290 each provide respective mill actuator parameters 291-293 to the rolling mill 15 for manipulating the various aspects of the rolling mill 15 as described above herein to adapt the shape of the metal strip 12.
The target thickness profile 221 may be a target per unit thickness profile, and may be based upon a substantial improvement in thickness profile given the incoming entry thickness profile 211, without producing unacceptable buckles in the strip 12. Such a target thickness profile 221 is used instead of only the actual incoming thickness profile 211 in the comparison with the exit thickness profile to produce the feedback error (differential strain feed-back), as is described below herein. Therefore, the rolling mill controllers are forced to drive the exit thickness profile to match the target thickness profile which respects limit constraints set by the buckling characteristics of the strip. Any condition which does not exceed the buckling limit constraints will produce a control response yielding profile and flatness improvements.
The measured entry thickness profile 211 is an input to the target thickness profile model 220 and is processed by performing time filtering and spatial frequency filtering using time filtering capability 222 and spatial frequency filtering capability 223 within the model 220. The target thickness profile model 220 may include a strip model 225 which serves to incorporate buckle limit constraints and/or profile change limit constraints into the target thickness profile 221 being generated by the model 220. Such limits keep the geometry change of the metal strip 12 from approaching parameters that can cause the metal strip 12 to buckle during processing through the thin strip casting plant 100. That is, the target thickness profile 221 incorporates the improvement for the incoming entry thickness profile 211 that is compatible with strip buckling limits. As a result, in the presence of abnormal geometries from the caster, the target thickness profile 221 will automatically track the variation in the cast geometry.
In accordance with an embodiment of the present invention, the target thickness profile model 220 implements the following mathematical algorithm:
H(x)*=H^mill(x)+dHhfspill(x); 221 Target Thickness profile
where H^mill(x)=LSFF(LPF(H(x))); 211″ Low spatial and time frequency filtered incoming strip thickness profile,
and where LSFF( ) is 223 low spatial frequency filter by least squares best fit of low order polynomials,
and where LFP( ) is 222 Low Pass Filter with a time constant set around 1-10 caster roll revolutions,
and where H(x) is 211 Entry Thickness Profile,
and where dHhfspill(x)=sHerror(x)−dHerrorLimited(x); High frequency spillover to target to avoid local buckling, and where
dHerrorLimited(x)=minimum(dHerror(x), Limit_dh(x)); 225 Local geometry change after buckle limiting, and where
Limit_dh(x) is evaluated from Limit_dh(x)=H*(K*Cs*(H/Wc(x))**2+correction for average total strain and applied tension, giving maximum local geometry change to avoid buckling, and where
Therefore, the target thickness profile model 220 is a function of entry geometry, strip tension, total rolling strain, and selection of time and spatial filtering constants. The resultant target thickness profile 221 is forwarded to the feed-forward roll stack deflection model 240 and the differential strain feedback model 260.
The roll gap model 230 also receives a processed version 211′ representing the change in thickness profile necessary to achieve the target thickness profile given the current entry thickness profile. The strip model 225 and the roll gap model 230 account for creep, buckling, and related geometry and stress changes that may occur outside of the roll gap, and for pressure changes that may occur inside the roll gap of the rolling mill 15.
Alternatively, the entry gauge 210 of the control architecture 200 may not be present, or inhibited such that the resultant target thickness profile 221 is based on estimated entry thickness profile information instead of actual measured entry thickness profile information 211. Therefore, the target thickness profile 221 is independent of the actual entry thickness profile 211 in such alternative embodiments.
The feed-forward roll stack deflection model 240 may be a complete finite difference roll stack deflection model or alternatively, a simplified model which predicts the required profile actuator settings to improve the loaded roll gap form to match the desired strip thickness profile. Inputs to the model include the geometry of the rolling mill 15, the incoming strip geometry, the roll gap pressure profile 231 between the strip and the rolls, and the desired or current rolling force 216. Outputs of the model are the optimized actuator control references 242 for feed-forward control and the actuator profile and flatness sensitivity vectors 241 for use in the feedback control scheme.
The differential strain feedback model 260 accepts measurements of exit thickness profile 217A, strip temperature 217B, and strip flatness 217C from the exit gauge 215. The flatness measurements 217C from the exit gauge apparatus 215 are passed through a signal processing stage 330 within the differential strain feedback model 260 to remove body motion components from the measurements. Therefore, measurements caused by the strip rotation, strip bouncing, or strip vibration about a longitudinal axis may be removed. Such signal processing reduces the false positives of non-flatness. The processed exit thickness profile 217A is compared, in the strain error estimator 305, to the target thickness profile 221 to form an initial estimate of a rolling strain profile 310. The raw estimate of rolling strain profile 310 is further processed using automatic nulling capability 320 by subtracting out systematic measurement errors from the rolling strain profile 310 when the rolling mill 15 is engaged. The systematic measurement errors are generated through comparison of the entry and exit thickness profiles when the rolling mill is disengaged. Ideally, no systematic measurement errors are present in the strip casting plant 100, and the measurement entry and exit thickness profiles will be the same when strip casting plant 100 is operating without the rolling mill being engaged. However, this is seldom, if ever, likely. Therefore, the systematic measurement errors are nulled out (taken out of the estimate of rolling strain profile 310).
Also, other exit gauge information may be incorporated into the estimate of rolling strain profile. Signal processing 330, to detect buckled sections, and temperature compensation capability 340 (compensating for the effect of transverse temperature profile) may be performed based on the strip flatness 217C and strip temperature 217B measurements and the results incorporated into the estimate of rolling strain profile 310. As a result, a full width rolling strain profile 350 is formed which is robust to any time based variation in the difference between the profile measurement characteristics that may occur during rolling. The rolling strain profile 350 is compared to a desired target strain profile 360 to form the differential strain feed-back 261 (error) which is fed back to the control model 280.
The differential strain feed-back 261 from the differential strain feedback model 260 is used by the control model 280, along with the actuator profile and flatness control sensitivity vectors 241 to generate a set of control signals 281-283 to the bending controller 250, the roll gap controller 255, and the feedback coolant controller 290. The flatness control sensitivity vectors 241 are used to perform the mathematical dot product operation with the differential strain feed-back 261, the result of which are the scalar actuator errors for the various actuators used in the control scheme. When the flatness control sensitivity vectors 241 are not available from online calculation, then they may be provided from a non real-time source such as offline calculation or manual approximation arrived at via experimental observation. Irrespective of the source of the flatness control sensitivity vectors, the resulting scalar actuator errors are in turn used by the feedback controllers 370 and 380 to perform their function. Within the control model 280, symmetric feedback control capability 370 and asymmetric feed-back control capability 380 are performed to generate the control signals 281 and 282 to the bending controller 250 and the roll gap controller 255.
The potential of a particular region of the strip to buckle is related to the stress and strain conditions in a local area of the strip, rather than to the average state of the strip. Therefore, local buckle detection 390 is also performed within the control model 280 to generate the control signal 283 to the feedback coolant control 290. The control signals 281-283 and the feed-forward control references 242 allow various aspects of the rolling mill 15 to be automatically controlled in order to achieve a desired strip geometry (e.g., profile and flatness) of the metal strip out of the rolling mill 15 without experiencing problems such as strip buckling.
In addition, the bending controller 250 may be further manually adapted by an operator-induced bending trim capability 395, and the coolant controller 290 may be further manually adapted by an operator-induced spray trim capability 399 supported by the control architecture 200. In general, feedback control using segmented spray headers, roll bending, roll tilting, and other roll crown manipulation actuators, as available, may be accomplished to minimize the error in the observed rolling strain profile.
The bending controller 250, gap controller 255, and coolant controller 290 provide mill actuator parameters 291-293 to the rolling mill in response to the control signals 281-283, feed-forward control references 242, and operator trim inputs to achieve the desired strip geometry result. The bending controller 250 controls roll bending of the work rolls 16A and 16B of the rolling mill 15. The gap controller 255 controls a roll gap between the work rolls 16A and 16B. The coolant controller 290 controls the amount of coolant provided to the work rolls 16A and 16B.
Such continuous twin roll casting allows the plant 100 with the features described to respond to the major process disturbances and produce a strip with a substantially improved exit thickness profile given the current strip casting conditions, while avoiding buckling of strip at the entry or exit of the roll bite of the hot mill. The use of the incoming thickness profile information and the correct use of the difference between the incoming and outgoing thickness profile information represent a significant step forward for the technology of profile and flatness control.
In the method 400 of controlling strip geometry in casting strip having a hot rolling mill 15, the device capable of affecting the geometry of the strip exiting the hot rolling mill may be any or all of a bending controller 250, a gap controller 255, and a coolant controller 293.
The method 400 further may include calculating a roll gap pressure profile 231 from the entry thickness profile 211 and dimensions and characteristics of the hot rolling mill, and calculating a feed-forward control reference 242 and/or a sensitivity vector 241 as a function of the target thickness profile 221 and the roll gap pressure profile 231 to allow compensation for profile and flatness fluctuations in the cast strip 12. The device capable of affecting the geometry of the strip exiting the hot rolling mill 15 may be further controlled in response to the calculated feed-forward control reference 242 and/or the calculated sensitivity vector 241. Furthermore, an adaptive roll gap error vector 271 may be generated from the measured exit thickness profile and used in calculating at least one of the feed-forward control reference 242 and the sensitivity vector 241.
In the method 500, the device capable of affecting the geometry of the strip exiting the hot rolling mill 15 may be one or more of a bending controller 250, a gap controller 255, and a coolant controller 290. The control system is further capable of generating a feed-forward control reference 242 and a sensitivity vector 241, and further capable of generating the control signals 281-283 in response to the differential strain feedback 261, the feed-forward control reference 242, and the sensitivity vector 241. The differential strain feed-back 261 is calculated from longitudinal strain in the strip 12 by comparing a measured exit thickness profile 217A with a calculated target thickness profile 221 derived from a measured entry thickness profile 21. The feed-forward control reference 242 and the sensitivity vector 241 are calculated as a function a target thickness profile 221, derived from a measured entry thickness profile 211, and a roll gap pressure profile 231 to allow compensation for profile and flatness fluctuations in the cast strip 12.
The bending controller 250, gap controller 255, coolant controller 290, and other suitable device that influences the loaded work roll gap may be considered to be part of the control architecture 200. Alternatively, the bending controller 250, gap controller 255, coolant controller 290, and other suitable device that may influence the loaded work roll gap may be considered to be part of the rolling mill 15. Similarly, in accordance with certain embodiments of the present invention, various aspects of the control architecture 200 may be considered a part of one model or another model of the control architecture 200. For example, the bending controller 250, gap controller 255, and coolant controller 290 may be considered to be part of the control model 280 of the control architecture 200.
In summary, a method and apparatus of controlling strip geometry in a continuous twin roll caster system having a hot rolling mill is disclosed, with a control architecture using both feed-forward and feed-back to control the geometry of the cast strip exiting the hot rolling mill while preventing buckling of the cast strip. While the invention has been described with reference to certain embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
This patent application claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 60/780,326 which was filed on Mar. 8, 2006, and is incorporated herein by reference in its entirety.
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