The present application is based on PCT filing PCT/JP2020/001065, filed Jan. 15, 2020, the entire contents of which are incorporated herein by reference.
The present invention relates to a rolling control system and a rolling control method.
In a rolling operation, various types of rolling control are executed such that actual measurement values relating to a process of a material to be rolled match respective target values. The rolling control includes a so-called automatic gauge control (hereinafter also referred to as “AGC”) in which a plate thickness in a delivery side of a rolling mill having an affect on a product quality is kept constant in order to bring the plate thickness of the material to be rolled to a desired plate thickness. The rolling control also includes a so-called automatic tension regulator control (hereinafter referred to as “ATR”) in which a tension applied to the material to be rolled is kept constant in an entry side and the delivery side of the rolling mill in order to maintain the product quality and secure an operation stability.
JP2016-93828A discloses a rolling control system in which the AGC and the ATR are switched in accordance with rolling speed of the material to be rolled. The prior art system selects a first control method when the rolling speed is slow whereas a second control method when the rolling speed is fast. In the first control method, the ATR is executed in which the speed of the material to be rolled is controlled such that the entry-side tension of the rolling mill matches a target value and the AGC is executed in which a roll gap of the rolling mill is controlled such that a delivery-side plate thickness matches a target value. In the second control method, the ATR is executed in which the roll gap is controlled such that the entry-side tension matches the target value and the AGC is executed in which the speed of the material to be rolled is controlled such that the delivery-side plate thickness matches the target value.
In the conventional system, when switching from the first control method to the second control method, a deviation between an entry-side tension prior to switching and a target value in the ATR is adjusted. Specifically, when the entry-side tension deviation is within a predetermined range, the entry-side tension deviation is changed to zero. When the entry-side tension deviation is out of the predetermined range, an e entry-side tension deviation is changed to a value obtained by subtracting the predetermined value from the entry-side tension deviation. As a result, it is possible to prevent the AGC control amount after switching from becoming excessive as compared with a case where the entry-side tension deviation is not adjusted.
As described above, in the conventional system, the entry-side tension deviation is adjusted when the control method is switched as the rolling speed increases. However, even if the entry-side tension deviation is adjusted, the adjusted entry-side tension deviation is used to calculate the control amount of the AGC after the switching. Therefore, when the entry-side tension deviation immediately before the switching largely deviates from the predetermined range, the control amount of AGC after the switching may conflict with an upper restriction. This may hinder a continuation of the AGC after the switching.
The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a technique capable of avoiding a situation where it is difficult to continue the AGC after the switching when the switching from the ATR to the AGC is performed in accompany with the increase in the rolling speed.
A first aspect of the present invention is a rolling control system to achieve the above-mentioned object and has the following features.
The control system comprises a rolling stand and a rolling controller.
The rolling controller is configured to execute speed control of which a control operation terminal is speed of a material to be rolled in an entry side of the rolling stand and roll gap control of which a control operation terminal is a roll gap of the rolling stand.
The rolling controller includes: a first plate thickness control part; a second plate thickness control part; a first tension control part; a second tension control part; and a control selection part.
The first plate thickness control part is configured to execute roll gap and plate thickness control that is roll gap control to control a plate thickness of the material to be rolled in a delivery side of the rolling stand.
The second plate thickness control part is configured to execute speed and plate thickness control that is speed control to control the plate thickness.
The first tension control part is configured to execute speed and tension control to control a tension of the material to be rolled in the entry side of the rolling stand.
The second tension control part is configured to execute roll gap and plate tension control to control the tension.
The control selection part is configured to select the speed and tension control and the roll gap and plate thickness control if rolling speed is less than a boundary value, while selecting the roll gap and plate tension control and the speed and plate thickness control if the rolling speed is greater than or equal to the boundary value.
The control selection part is further configured to, if the rolling speed rises across the boundary value, set a speed correction amount to zero and then output it to the second tension control part such that the speed correction amount in the speed and tension control before the transboundary is not reflected to a calculation executed in the speed control amount of the rolling speed at the transboundary.
A second invention has the following feature in the first invention.
The control selection part is further configured to, if the rolling speed rises across the boundary value, calculate a roll gap correction amount according to the speed correction amount and then output it to the second tension control part such that the speed correction amount is reflected to a calculation of a roll gap control amount executed in the roll gap and plate tension control at the transboundary.
A third aspect of the present invention is a rolling control method to achieve the above-mentioned object and has the following features.
The rolling control method is a method comprising the steps of: executing speed control of which a control operation terminal is rolling speed; and executing roll gap control of which a control operation terminal is a roll gap of a rolling stand.
The roll gap control includes roll gap and plate thickness control, and roll gap and plate tension control. The roll gap and plate thickness control is the roll gap control to control a plate thickness of a material to be rolled in a delivery side of the rolling stand. The roll gap and plate tension control is the roll gap control to control a tension of the material to be rolled in an entry side of the rolling stand.
The speed control includes speed and tension control, and speed and plate thickness control. The speed and tension control is the speed control to control the tension. The speed and plate thickness control is the speed control to control the plate thickness.
The rolling control method further comprising the steps of:
A fourth invention further has the following feature in the third invention.
The rolling control method further comprising a step of calculating, if the rolling speed rises across the boundary value, a roll gap correction amount according to the speed correction amount such that the speed correction amount is reflected to a calculation of a roll gap control amount executed in the roll gap and plate tension control at the transboundary.
According to the first or the third invention, if the rolling speed rises across the boundary value, the speed correction amount is set to zero such that the speed correction amount of the speed and tension control before the transboundary is not reflected to the calculation of the speed control amount of the speed and plate thickness control at the transboundary of the rolling speed. Therefore, it is possible to avoid a situation where the speed control amount of the speed and plate thickness control calculated at the transboundary of the rolling speed conflicts with an upper restriction. Therefore, it is possible to avoid a situation where it becomes difficult to continue the speed and plate thickness control after the transboundary of the rolling speed.
According to the second or the fourth invention, if the rolling speed rises across the boundary value, the roll gap correction amount according to the speed correction amount is calculated such that the speed correction amount is reflected to the calculation in the roll gap control amount of the roll gap and plate tension control at the transboundary. Therefore, it is possible to prevent the tension of the material to be rolled in the entry side of the rolling stand from fluctuating significantly after the transboundary of the rolling speed.
Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
A rolling is performed by crushing the material to be rolled 10 with a pair of the work rolls.
Returning to
In the rolling, the plate thickness of the material to be rolled 10 is critical to the quality of the product. Therefore, on the delivery side of the rolling stand 21, a plate thickness meter 60 is provided to measure the plate thickness of the material to be rolled 10. It is also important in the rolling to maintain a quality of a product and to secure an operation stability. For this reason, a tension meter 70 is provided between the rolling stands 20 and 21. The plate thickness meter 60 and the tension meter 70 are connected to the rolling controller 50. Note that a plate thickness meter having the same configuration as that of the plate thickness meter 60 may be provided on the entry side and the delivery side of the rolling stand 20. A tension meter having the same configuration as that of the tension meter 70 may be provided on the entry side of the rolling stand 20 or the delivery side of the rolling stand 21.
The rolling controller 50 includes a first plate thickness control part 51, a second plate thickness control part 52, a first tension control part 53, a second tension control part 54, and a control selection part 55.
The first plate thickness control part 51 executes roll gap and plate thickness control (hereinafter also referred to as “AGC_S”). The AGC_S is the AGC for controlling the plate thickness of the material to be rolled 10 in the delivery side of the rolling stand 21 (i.e., the plate thickness h shown in
The second plate thickness control part 52 executes speed and plate thickness control (hereinafter also referred to as “AGC_Ve”). The AGC_Ve is the AGC for controlling the plate thickness of the material to be rolled 10 in the delivery side of the rolling stand 21 by using the velocity Ve of the material to be rolled 10 in the entry side of the rolling stand 21 as a control operation terminal. The AGC_Ve is executed when the rolling speed is greater than or equal to the boundary value TH.
The first tension control part 53 executes speed and tension control (hereinafter also referred to as “ATR_Ve”). The ATR_Ve is the ATR for controlling the tension of the material to be rolled 10 between the rolling stands 20 and 21 (i.e., the entry side of the rolling stand 21) by using the speed Ve of the material to be rolled 10 in the entry side of the rolling stand 21 as a control operation terminal. The ATR_Ve is executed when the rolling speed is less than the boundary value TH.
The second tension control part 54 executes the roll gap and plate tension control (hereinafter also referred to as “ATR_S”). The ATR_S is the ATR for controlling the tension of the material to be rolled 10 between the rolling stands 20 and 21 by using the roll gap S of the rolling stand 21 as a control operation terminal. The ATR_S is executed when the rolling speed is greater than or equal to the boundary value TH.
As shown in
Similar to the first plate thickness control part 51, the delivery-side plate thickness deviation Δh is input to the second plate thickness control part 52. The second plate thickness control part 52 integrates the delivery-side plate thickness deviation Δh multiplied by an adjustment gain GVAGC and a conversion gain (−1/href) (I control). This conversion gain is a gain for converting the delivery-side plate thickness deviation Δh into a speed correction amount ΔVe. The second plate thickness control part 52 calculates a deviation between a value (ΔVe/Ve) obtained by dividing the integral value by the velocity Ve and its previous value, and sets the deviation as the speed control amount Δ(ΔVe/Ve)AGC.
To the second tension control part 54, the entry-side tension deviation ΔTb is input. The entry-side tension deviation ΔTb is expressed by a difference between an actual result Tbfb of the tension of the material to be rolled 10 in the entry side of the rolling stand 21 and its preset value (a target value) ΔTbref (ΔTb=Tbfb−Tbref). The second tension control part 54 integrates the entry-side tension deviation ΔTb multiplied by an adjustment gain GSATR and a conversion gain ((M+Q)*kb/M) (I control). This conversion gain is a gain for converting the entry-side tension deviation ΔTb into a roll gap correction amount ΔS. “kb” included in the conversion gain is an influence coefficient that indicates a fluctuation of load P due to the fluctuation of the tension of the material to be rolled on the entry side of the rolling stand affects the plate thickness of the material to be rolled in the delivery side of the rolling stand. The second tension control part 54 calculates a deviation between the integral value and its previous value and sets it as a roll gap control amount ΔΔSATR.
Similar to the second tension control part 54, the entry-side tension deviation ΔTb is input to the first tension control part 53. The first tension control part 53 integrates the entry-side tension deviation ΔTb multiplied by an adjustment gain GVATR and a conversion gain (−Ve·kb/h) (I control). This conversion gain is a gain for converting the entry-side tension deviation ΔTb to the speed correction amount ΔVe. The first tension control part 53 calculates a deviation between a value (ΔVe/Ve) obtained by dividing the integral value by the velocity Ve and its previous value, and sets it a speed control amount Δ(ΔVe/Ve)ATR.
Returning to
The reason why such switching is performed in the control selection part 55 will be described referring to
The influence coefficients C4 and C5 include the speed V e in the denominator. Therefore, the influence coefficients C4 and C5 become smaller when the rolling speed is in a high-speed region. The velocity Ve is also included in the denominator of the first-order lag constant Tr (see
In summary, when the rolling speed is in the high speed region, the influence coefficients C4 and C5 become smaller while the influence coefficients C2 and C3 become larger. In addition, the influence coefficient C2 is a subtraction element of the delivery-side plate thickness deviation Δh. Therefore, when the rolling speed is in the high-speed region, it can be understood that the entry-side tension deviation ΔTb tends to change according to the roll gap correction amount ΔS. On the other hand, it can be understood that the entry-side tension deviation ΔTb and the delivery-side plate thickness deviation Δh do not change so much when the speed correction amount ΔVe changes. It can also be understood that even when the roll gap correction amount ΔS changes, the delivery-side plate thickness deviation Δh does not change so much.
The above-mentioned relationship has an opposite content when the rolling speed is in the low-speed region. That is, when the rolling speed is in the low-speed region, the entry-side tension deviation ΔTb does not change so much even when the roll gap correction amount ΔS changes. On the other hand, the entry-side tension deviation ΔTb and the delivery-side plate thickness deviation Δh is likely to change depending on the speed correction amount ΔVe. And the delivery-side plate thickness deviation Δh is likely to change according to the roll gap correction amount ΔS.
From the above, it can be understood that when the rolling speed is in the low speed region, the variation of the roll gap S is valid for the AGC. Therefore, when the rolling speed is less than the boundary value TH, the AGC by using the roll gap S as the control operation terminal (i.e., the AGC_S) is executed. At the same time, the ATR by using the velocity Ve as the control operation terminal (i.e., the ATR_Ve) is executed. Conversely, if the rolling speed is greater than or equal to the boundary value TH, the AGC by using the velocity Ve as the control operation terminal (i.e., the AGC_Ve) is executed. At the same time, the ATR by using the roll gap S as the control operation terminal (i.e., the ATR_S) is executed.
The ATR_Ve, which is executed when the rolling speed is less than the boundary value TH, is executed from a startup of the rolling stand. For this reason, the speed correction amount ΔVe in the ATR_Ve may show a large value depending on the situation of the startup. If the rolling speed exceeds the boundary value TH in such a situation, in accompany with the switching of the AGC and the ATR, the speed control amount Δ (ΔVe/Ve)AGC in the AGC_Ve will be calculated by using the speed correction amount ΔVe is used. As a result, the speed control amount Δ(ΔVe/Ve)AGC may conflict with the upper restriction.
Therefore, in the embodiment, the control selection part 55 is configured as follows.
The trigger circuit 55a outputs a trigger signal when the rolling speed is equal to or greater than the boundary value TH. When the trigger signal is output, the switch 55b is switched from “ON” to “OFF”. That is, prior to the output of the trigger signal, the roll gap control amount ΔΔSAGC which is output from the first plate thickness control part 51 is input to the roll gap controller 40. After the output of the trigger signal, this input is blocked by the switch 55b.
Prior to the output of the trigger signal, the speed control amount Δ(ΔVe/Ve)ATR which is output from the first tension control part 53 is also input to the RAMP circuit 55d. The speed correction amount ΔVe which is used to calculate the speed control amount Δ(ΔVe/Ve)ATR is also input to the RAMP circuit 55d. The speed control amount Δ(ΔVe/Ve)ATR input to the RAMP circuit 55d is input to the limiter 55f. The limiter 55f inputs the upper restriction to the speed controller 30 when the speed control amount Δ(ΔVe/Ve)ATR input to the limiter 55f conflicts with the upper restriction. Otherwise, the limiter 55f inputs the speed control amount Δ(ΔVe/Ve)ATR into the speed controller 30.
When the trigger signal is output, the switch 55c is switched from “OFF” to “ON”. Then, the speed control amount Δ(ΔVe/Ve)AGC output from the second plate thickness control part 52 is input to the limiter 55f. Here, when the trigger signal is output, zero is input to the RAMP circuit 55d via the switch 55c. Therefore, the RAMP circuit 55d resets the speed control amount Δ(ΔVe/Ve)ATR which is output from the first tension control part 53 prior to the output of the trigger signal and resets the speed correction amount ΔVe which is used to calculate the speed control amount Δ(ΔVe/Ve)ATR. Then, after outputting the trigger signal, nothing is output from the RAMP circuit 55d to the limiter 55f.
Therefore, after the output of the trigger signal, only the speed control amount Δ(ΔVe/Ve)AGC output from the second plate thickness control part 52 is input to the limiter 55f. After the output of the trigger signal, the limiter 55f inputs the upper restriction to the speed controller 30 when the speed control amount Δ(ΔVe/Ve)AGC input to the limiter 55f conflicts with the upper restriction. Otherwise, the limiter 55f inputs the speed control amount Δ(ΔVe/Ve)AGC to the speed controller 30.
The HOLD circuit 55g stores the speed correction amount ΔVe which is output from the first tension control part 53. The speed correction amount ΔVe is stored in association with pulsed output signals from the pulse generator 55h. When the trigger signal is output, the speed correction amount ΔVe at this outputting is input from the HOLD circuit 55g to the RAMP circuit 55e. The RAMP circuit 55e calculates and outputs the roll gap correction amount ΔS equivalent to the speed correction amount ΔVe which is input to the RAMP circuit 55e. This roll gap correction amount ΔS is calculated by multiplying the speed correction amount ΔVe by a predetermined adjustment gain.
After the trigger signal is output, the roll gap amount ΔΔSATR which is output from the second tension control part 54 is input to the roll gap controller 40 via the switch 55c. At the outputting of the trigger signal, the roll gap correction amount ΔS which is calculated in the RAMP circuit 55e is added to the roll gap control amount ΔΔSATR. That is, at the outputting of the trigger signal, the roll gap correction amount Δ S is added to the roll gap control amount ΔSATR is input to the roll gap controller 40.
According to the embodiment described above, the speed control amount Δ(ΔVe/Ve)ATR that is output from the first tension control part 53 and the speed correction amount ΔVe that is used for calculating the speed control amount Δ(ΔVe/Ve)ATR are reset when the rolling speed exceeds the boundary value TH value. Therefore, after the timing at which the rolling speed exceeds the boundary value TH, only the speed control amount Δ(ΔVe/Ve)AGC output from the second plate thickness control part 52 is input to the limiter 55f. Therefore, it is possible to avoid a situation where the speed control amount Δ(ΔVe/Ve)AGC conflicts with the upper restriction. Therefore, it is possible to avoid a situation where it becomes difficult to continue the AGC after the timing at which the rolling speed exceeds the boundary value TH.
Here, consider a case where the speed correction amount ΔVe that loosens the tension Tb is output from the first tension control part 53 just before the timing at which the rolling speed exceeds the boundary value TH. If such the speed correction amount ΔVe is ignored, the tension Tb immediately after the rolling speed exceeds the boundary value TH becomes tensile. In this regard, according to the embodiment, the roll gap correction amount ΔS equivalent to the speed correction amount ΔVe at the timing when the rolling speed exceeds the boundary value TH is added to the roll gap control amount ΔSATR. Therefore, it is also possible to suppress a large change in the tension Tb after the timing at which the rolling speed exceeds the boundary value TH.
In the above embodiment, the first plate thickness control part 51 and the like have been described as functions of the rolling controller 50. However, these functions may be implemented separately in a plurality of control devices.
In the above embodiment, the processing executed by the rolling controller 50 is applied to tandem rolling mill. However, this processing may be applied to a single stand rolling mill. In this instance, velocity of a tension reel provided in a front stage or a rear stage of the rolling stand may be controlled by a speed controller, and a roll gap of this rolling stand may be controlled by a roll gap controller.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/001065 | 1/15/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/144882 | 7/22/2021 | WO | A |
Number | Date | Country |
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11-197728 | Jul 1999 | JP |
2015-112614 | Jun 2015 | JP |
2016-93828 | May 2016 | JP |
2016-221553 | Dec 2016 | JP |
Entry |
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Machine translation of JP 2015112614 A (Year: 2015). |
Machine translation of JP H11197728 A (Year: 1999). |
Office Action issued on Jul. 26, 2022, in corresponding Japanese patent Application No. 2021-571111, 8 pages. |
Office Action issued on Aug. 19, 2022, in corresponding Indian patent Application No. 202117032131, 5 pages. |
International Search Report and Written Opinion mailed on Feb. 18, 2020, received for PCT Application PCT/JP2020/001065, Filed on Jan. 15, 2020, 9 pages. |
Office Action issued Jan. 31, 2023 in Korean Patent Application No. 10-2021-7023675, 9 pages. |
International Preliminary Report on Patentability issued Jul. 19, 2022 in PCT/JP2020/001065, 6 pages. (Submitting English translation only). |
Office Action issued on Aug. 17, 2022, in corresponding Korean patent Application No. 10-2021-7023675, 9 pages. |
Office Action issued on Jul. 28, 2021, in corresponding Taiwanese patent Application No. 109115218, 15 pages. |
Office Action issued on Oct. 17, 2023, in corresponding Vietnamese patent Application No. 1-2021-04759, 3 pages. |
Hearing Notice issued Dec. 6, 2023 in corresponding Indian Patent Application No. 202117032131 (English translation included). |
Number | Date | Country | |
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20220126340 A1 | Apr 2022 | US |