JP2016043360A - Rolling control device, rolling control method and rolling control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a preferable control for rolling control performed on the basis of a condition of a material to be rolled at the inlet side and the outlet side of the whole of a plurality of rolling stands.SOLUTION: A detection result of a condition of a material to be rolled flowing into a #2 rolling stand 12 arranged on the most upstream side of a plurality of roll pairs arranged continuously to the material to be rolled and a detection result of a condition of a material to be rolled flowing out from a #4 rolling stand 14 arranged on the most downstream side are obtained, and on the basis of the obtained two detection results, a roll speed of roll pairs other than the #2 rolling stand 12 is controlled in such a way that an inflow amount of the material to be rolled coincides with an outflow amount of the material to be rolled.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a rolling control device, a rolling control method, and a rolling control program.

  In tandem rolling mills, sheet thickness control that is directly related to the product quality of the material to be rolled and tension control that is essential for operational stability are important. In particular, regarding thickness control, high-precision control is performed by installing detectors such as a plate thickness meter that detects a thickness deviation and a plate speed meter that detects the speed of the material to be rolled.

  However, since these detectors are expensive, it is desirable to reduce them as much as possible in order to reduce the capital investment. In addition, when there are a large number of detectors, a lot of maintenance work is required, so that it is desirable to reduce the number of detectors.

  On the other hand, the mass flow constant law, which is a basic expression for rolling control, is based on the premise that the volume of the material to be rolled flowing into the rolling mill is equal to the volume of the material to be rolled out. Using the thickness H, the inlet side plate speed Ve, the outlet side plate thickness h, and the outlet side plate speed Vo, it is expressed by the following equation (1).

  This relationship is established for each stand in the tandem rolling mill, and also when a plurality of rolling mill stands are regarded as one rolling mill stand. For example, when there are four stands from # 1 to # 4, it is also established between the volume of the material to be rolled flowing into # 1 and the volume of the material to be rolled flowing out from # 4 (for example, Patent Documents). 1).

JP-A-11-33612

  As disclosed in Patent Document 1, when a plurality of rolling mill stands are regarded as one rolling mill stand and the control is performed according to a constant law of mass flow, sensors in the middle thereof can be omitted. Can be reduced.

  However, even if a plurality of rolling mill stands are collectively regarded as one rolling mill stand, since a plurality of rolling mill stands are actually included, control corresponding to that is necessary.

  For example, when performing control based on a constant mass flow for one rolling mill stand, it is possible to apply the control without considering the timing on the exit side and the entrance side. On the other hand, when considering a plurality of rolling mill stands as one rolling mill stand, it is necessary to consider the influence on other rolling mill stands due to the change in the control state of one rolling mill stand. , Control becomes complicated.

  The present invention addresses the above-described problems and aims to provide suitable control when performing rolling control based on the state of the material to be rolled on the entry side and the exit side of the entire plurality of rolling mill stands. To do.

  One aspect of the present invention is a rolling control device that controls a tandem rolling mill that rolls a material to be rolled with a plurality of roll pairs, and includes a plurality of roll pairs that are continuously arranged with respect to the material to be rolled. The detection result of the state of the material to be rolled flowing into the most upstream roll pair arranged on the most upstream side and the detection result of the state of the material to be rolled out from the most downstream roll pair arranged on the most downstream side are acquired. Then, based on the two detection results, rolls other than the most upstream roll pair among the plurality of roll pairs continuously arranged so that the inflow amount of the material to be rolled and the outflow amount of the material to be rolled coincide with each other. It is characterized by controlling the pair roll speed.

  By using the present invention, it is possible to provide suitable control when performing rolling control based on the state of the material to be rolled on the entry side and the exit side of the entire plurality of rolling mill stands.

It is a figure showing the whole tandem rolling mill composition concerning the embodiment of the present invention. It is a figure which shows the rolling phenomenon of a tandem rolling mill. It is a figure which shows the successful control of the tandem rolling mill which concerns on a prior art. It is a figure which shows the speed setting method of the tandem rolling mill which concerns on a prior art. It is a figure which shows the successful control of the tandem rolling mill which concerns on embodiment of this invention. It is a figure which shows the load balance of a tandem rolling mill. It is a figure which shows the structure of the inflow amount calculating apparatus which concerns on embodiment of this invention. It is a figure which shows the structure of the outflow amount calculating apparatus which concerns on embodiment of this invention. It is a figure which shows the operation | movement outline | summary of the delivery side plate | board thickness control apparatus which concerns on embodiment of this invention. It is a figure which shows the whole structure of the tandem rolling mill which concerns on the comparative example of this invention. It is a figure which shows the structure of the information processing apparatus which concerns on embodiment of this invention.

  In the present embodiment, in the tandem rolling mill, a plurality of rolling mill stands are regarded as one rolling mill, and based on the state of the material to be rolled on the inflow side and the outflow side of the entire plurality of rolling mills regarded as one rolling mill. A mode of performing mass flow control will be described. Thereby, only a detector is provided on the inflow side and the outflow side of the whole of a plurality of rolling mills regarded as one rolling mill, and a detector configuration at a minimum can be realized by omitting the detector at an intermediate stage.

  Furthermore, in the rolling mill according to this embodiment, among the plurality of rolling mills regarded as one rolling mill, the rolling mill stand arranged on the most upstream side is used as a master stand, and is generated by the upstream rolling mill stand. The control for eliminating the deviation is applied to the downstream rolling mill stand. This is one of the gist according to the present embodiment.

  Here, in the tandem rolling mill, the upstream side is the side on which the material to be rolled is supplied, and the downstream side is the side on which the material to be rolled comes out as a product. The detector can detect the amount of material to be rolled into the material to be rolled (plate thickness x plate speed), and the plate speed can be measured with a plate thickness meter and speedometer, or a roll with a pulse oscillator. It shall be detectable.

In the present embodiment, an example will be described using a four-stand tandem rolling mill constituted by four rolling mill stands 11, 12, 13, and 14 as shown in FIG. As shown in FIG. 1, each of the rolling mill stands 11 to 14 is provided with roll gap control devices 31 to 34 for operating the roll gap, and speed control devices 21 to 24 for operating the roll speed. Yes.

  And in the rolling mill which concerns on this embodiment, appropriate rolling control is enabled by the minimum required sensor structure. As shown in FIG. 1, in the rolling mill according to the present embodiment, a # 1 rolling mill stand 11 is provided with a # 1 stand outlet side plate thickness meter 41 and a # 1 stand outlet side plate speed meter 81.

  The # 4 rolling mill stand 14 is provided with a # 4 stand exit side plate thickness meter 44 and a # 4 stand exit side plate speed meter 84. Further, inter-stand tension meters 51 to 53 are provided between the stands.

  What is important for the rolling mill is the thickness of the material to be rolled, which directly affects the product quality, and the tension for the stability of the rolling operation. In the rolling mill according to the present embodiment, the # 1 stand outlet side AGC 61 operates the # 1 roll gap control device 31 based on the detection result of the # 1 stand outlet side thickness gauge 41.

  On the other hand, the # 4 stand exit side AGC 64 operates the # 4 stand speed control device 24 based on the detection result of the # 4 stand exit side thickness gauge 44. The # 4 stand speed control device 24 according to the present embodiment is controlled by multiplying various operation amounts in addition to the operation by the # 4 stand exit side AGC 64.

  For tension control, # 1- # 2 inter-stand tension control 71 detects the tension between # 1 rolling mill stand 11 and # 2 rolling mill stand 12 with # 1 stand outlet tension meter 51, and # 2 rolling The machine stand roll gap control device 32 is operated.

  The # 2- # 3 inter-stand tension control 72 detects the tension between the # 2 rolling mill stand 12 and the # 3 rolling mill stand 13 by the # 2 stand exit side tension meter 52, and the # 3 rolling mill stand roll. The gap control device 33 is operated.

  The # 3- # 4 inter-tension tension control 73 detects the tension between the # 3 rolling mill stand 13 and the # 4 rolling mill stand 14 with the # 3 stand outlet tension meter 53, and the # 4 rolling mill stand roll. The gap control device 34 is operated.

  Furthermore, in the rolling mill according to the present embodiment, the # 2 rolling mill stand 12 and the # 3 rolling mill are based on the detection results of the # 1 rolling mill stand exit speedometer 81 and the # 4 rolling mill stand exit speedometer 84. The stand 13 and the # 4 rolling mill stand 14 are regarded as one rolling mill, and control based on a constant mass flow rule is performed. Accordingly, the # 2 rolling mill stand 12 is used as the most upstream roll pair, and the # 4 rolling mill stand 14 is used as the most downstream roll pair. Such control is realized by the functions of the inflow amount calculation device 101 and the outflow amount calculation device 102.

  Thickness gauges and speedometers are expensive, and the amount of capital investment is enormous. In addition, since frequent maintenance work is required to maintain measurement accuracy, a minimum detector configuration is desired. In the example of FIG. 1 according to the present embodiment, as described above, since a plurality of rolling mill stands are regarded as one, it is only necessary to provide a plate thickness meter and a plate speed meter only on the exit side and the entrance side. Therefore, the minimum detector configuration as described above can be realized.

FIG. 2 shows the rolling phenomenon from the # 2 stand to the # 4 stand in the tandem rolling mill. Assuming that the # 2 stand inlet side thickness is H2, the inlet side plate speed is Ve2, the # 4 stand outlet side plate thickness is H4, and the outlet side plate speed is Vo4, the following equation (2) is established based on the constant law of mass flow.

  However, the above formula (2) indicates that the part of the material to be rolled that has flowed into the # 2 rolling mill stand 12 at a certain point moves from the # 2 rolling mill stand 12 to the # 4 rolling mill stand 14 and the # 4 rolling mill It is a relational expression when it flows out from the stand 14.

  On the other hand, in rolling control, the roll speed of the rolling mill stand is accelerated or decelerated according to the control. Therefore, when the roll speed is changing, the # 4 rolling mill stand speed when the rolled material flows into the # 2 rolling mill stand, and the rolled material flowing into the # 2 rolling mill stand is the # 4 rolling mill stand. # 4 rolling mill stand speed in the case of flowing out from

As a result, the above equation (2) cannot be directly applied to the sensor output of each part. When the entry side plate thickness H ₂ and entry side plate speed V _e2 of the # 2 rolling mill stand 12 have deviations from the set values, H ₂ , V _e2 and V _o4 of the above formula (2) are set values, respectively. Assuming that the deviation of the inlet side plate thickness is ΔH ₂ and the deviation of the inlet side plate speed is ΔV _e2 , the relationship with the adjustment value ΔV _o4 of the outlet side plate speed to be adjusted in order to maintain the target plate thickness h ₄ can be _{expressed by} Based on (2), it is shown by the following formula (3).

  When the above formula (3) is expanded, the following formula (4) is obtained.

  Furthermore, when the above equation (4) is rearranged using the relationship of the above equation (2), the following equation (5) is obtained.

  In the above formula (5), the speed is a ratio display with respect to the set speed, and the formula can be used even when the tandem rolling mill is accelerating / decelerating.

Among the parameters of the above formula (5), ΔH ₂ and ΔV _e2 can be detected by the # 1 rolling mill stand exit side plate thickness meter 41 and the # 1 rolling mill stand exit side plate speed meter 81. ΔV _o4 can be _detected by a # 4 rolling mill stand exit side plate speedometer 84. Therefore, if the roll speed of the # 4 rolling mill stand 14 or the roll speed of the # 2 rolling mill stand 12 is manipulated so that the above formula (5) is established, it is possible to make the exit side plate thickness h ₄ constant. .

  Here, the left side of the above formula (3) is the amount of inflow into the # 2 rolling mill stand 12 at a certain time, and the right side is the flow to the # 4 rolling mill stand when it is transferred to the # 4 rolling mill stand 14. It is the inflow. Therefore, since there is a time lag from the left side to the right side of the formula (3), when controlling the roll speed of the # 4 rolling mill stand 14 based on the calculation of the formula (5), it is necessary to consider the timing. There is.

_{Here, V e2,} taking into account the reverse ratio _{b 2} is expressed by the following equation (6).

Further, V _o4 is expressed by the following equation (7) in consideration of the advanced rate f ₄ .

Since the exit side plate speed V _o4 of the # 4 rolling mill stand 14 also changes depending on the rolling phenomenon, it is difficult to predict V _o4 in advance. Therefore, it is appropriate to set the # 4 rolling mill stand exit side plate speed V _o4 as the operation end of the plate thickness control.

  FIG. 3 is a diagram showing a mode of speed setting of a rolling mill stand in a general tandem rolling mill. As shown in FIG. 3, the speed of each rolling mill stand is determined by the product of the master speed command MRH and the stand speed command SSRH.

  The speed of the entire tandem rolling mill is increased and decreased using MRH, and acceleration / deceleration is performed. It is SSRH that determines the speed balance between the rolling mill stands, and is determined by the mass flow constant law from the thickness of the entry / exit side of each stand.

  In the tandem rolling mill, the successive control is performed so that the influence of the speed change of a certain rolling mill stand does not affect other rolling mill stands. FIG. 4 is a diagram showing a successful control in a general tandem rolling mill.

  As shown in FIG. 4, the thickness control using the detected value of the # 4 stand outlet side thickness gauge is performed so that the speed of the # 4 rolling mill stand which is the final stand of the tandem rolling mill does not fluctuate. Therefore, although the plate speed of the # 3 rolling mill stand is adjusted, the plate speed of the preceding rolling mill stand is further adjusted so that the rolling state in the further rolling mill stand does not change due to the adjustment. This control is a successive control.

  A stand that prevents the speed from fluctuating during the output of the plate thickness control is called a master stand. In this case, the master stand is a # 4 rolling mill stand. The fact that the speed does not fluctuate means that a control output is output. When the tandem rolling mill accelerates or decelerates, the roll speed of the # 4 rolling mill stand 14 fluctuates naturally.

When the master stand is a # 4 rolling mill stand as in the past, when the plate thickness control operates the speed of the # 3 rolling mill stand, the speeds of the # 2 rolling mill stand and the # 1 rolling mill stand are also controlled by the successive control. It will be. Therefore, the entry side plate speed deviation ΔV _{e2 of} the # 2 rolling mill stand 12 described above also varies.

On the other hand, when the control of the above formula (5) is performed using the # 4 rolling mill stand as the master stand, the operation end becomes the plate speed V _e2 of the # 2 rolling mill stand. Here, there is a time lag between the rolling phenomenon in the # 4 rolling mill stand 14 and the rolling phenomenon in the # 2 rolling mill stand 12, and the # 4 rolling mill stand 14 is later in time series.

Therefore, the detection of the rolling state in the # 4 rolling mill stand 14 cannot be directly used for rolling control at the same point of the material to be rolled in the # 2 rolling mill stand 12. Further, in controlling the # 2 rolling mill stand 12, since it is necessary to consider the fluctuation of the entry side plate speed deviation ΔV _e2 of the # 2 rolling mill stand 12 caused by the success as described above, the control becomes complicated.

Furthermore, the fluctuation according to the above equation (3) occurs with respect to the fluctuation of the entry side plate speed deviation ΔV _e2 of the # 2 rolling mill stand 12 generated by the succession. Therefore, it is necessary to correct the influence at the timing when the material to be rolled reaches the # 4 rolling mill stand 14.

ΔV _e2 varies as well as the roll speed of the # 2 rolling mill stand 12 as well as the # 2 stand reverse speed b ₂ that is a rolling phenomenon as expressed by the above formula (6), but can be removed as a disturbance. It is necessary to remove as much as possible.

  Such a problem is solved by making the master stand the # 2 rolling mill stand 12 in the rolling control according to the present embodiment. In this case, as shown in FIG. 1, the control output destination of the exit side plate thickness control 64 of the # 4 rolling mill stand 14 is the # 4 rolling mill stand 14.

  FIG. 5 is a diagram showing a successful control method when the # 2 rolling mill stand is used as a master stand. The speeds of the # 3 rolling mill stand and the # 4 rolling mill stand are corrected so as not to change the plate speed of the # 2 rolling mill stand 12.

  With reference to FIG. 1 again, the control method of the tandem rolling mill according to the present embodiment will be described. The inflow amount calculation device 101 calculates the correction amount in the # 4 rolling mill stand 14 using the above equation (5).

  The outflow amount setting device 102 transfers the material to be rolled at the inflow amount calculation time to the # 4 rolling mill stand 14 at the # 2 rolling mill stand 12 and outputs a control output to the # 4 rolling mill stand 14. Here, a transfer process is providing the delay period until the detection position reaches the position which performs control according to the detection result, when the state of a to-be-rolled material is detected at a certain point. In the case of the outflow amount setting device 102, a delay period is provided until the portion of the material rolled in the # 2 rolling mill stand 12 reaches the # 3 rolling mill stand 13 or the # 4 rolling mill stand 14.

  Fig.6 (a) is a figure which shows the rolling load of each rolling mill stand set according to the delivery side plate thickness predetermined about each rolling mill stand. For this reason, the state where the rolling load substantially coincides with the set value as shown in FIG.

Here, when only the # 4 rolling mill stand speed is operated by the outflow amount control device 102, the rolling load of the # 4 rolling mill stand deviates from the set value as shown in FIG. In some cases, the rolling load of the rolling mill stand also changes.

  Therefore, it is necessary to operate not only the # 4 rolling mill stand but also the # 3 rolling mill stand while monitoring the stand distribution of the rolling load. Considering this, the outflow amount setting device 102 determines the control output for the # 3 rolling mill stand and the # 4 rolling mill stand.

An outline of the operation of the inflow amount calculation device 101 is shown in FIG. As shown in FIG. 7, the transfer processing unit 110 transfers the detection signal of the # 1 rolling mill stand exit side thickness gauge 41 from the thickness measuring position to the # 2 rolling mill stand position, and enters the # 2 rolling mill stand. The side plate thickness deviation ΔH _{2 is} assumed.

Further, the speed ratio calculation unit 111 obtains ΔV _e2 / V _e2 from the detection signal of the # 1 rolling mill stand delivery side plate speed meter 81, and uses the above formula (5), the speed ratio ΔV on the # 4 rolling mill stand delivery side. _{Find o4} / _Vo4 . This speed ratio ΔV _o4 / V _o4 is used as an index value for controlling the roll speed of the downstream roll pair based on the constant mass flow side.

An outline of the operation of the outflow amount calculation device 102 is shown in FIG. As shown in FIG. 8, the transfer processing unit 121 transfers the speed ratio ΔV _o4 / V _o4 calculated by the inflow amount calculating device 101 to the # 3 rolling mill stand 13 and immediately below the # 3 rolling mill stand. The speed ratio (ΔV _o4 / V _o4 ) # 3 is obtained.

Moreover, the transfer processing unit _{122, (ΔV o4 / V o4)} # 3 was further transport processes, # speed ratio immediately below 4 roll stands (ΔV _o4 / _{V o4)} finding a # 4.

And, for the # 3 rolling mill stand, the outflow amount calculation device 102 multiplies the above (ΔV _o4 / V _o4 ) # 3 by the control gain G ₃ and outputs a control output (1 + ΔV _R3 / V) to the # 3 rolling mill stand. _R3 ) Output _CNT .

For the # 4 rolling mill stand, the control gain G ₄ is multiplied by the above (ΔV _o4 / V _o4 ) # 4, and the speed command calculation unit 123 is measured by the # 4 stand rolling mill stand exit side plate speedometer 84. with _V o4FB, obtains the speed operation amount [Delta] V _R4 of the fourth roll stand according to the following equation (7).

The control gain _{G 4} are a _{(1-G 3).} In the first place, the speed ratio ΔV _o4 / V _o4 is a value obtained from the constant mass flow side by regarding # 2 rolling mill stand 12 to # 4 rolling mill stand 14 as one rolling mill stand. Therefore, basically, the control value only needs to be applied to the # 4 rolling mill stand 14.

On the other hand, in the rolling mill control according to the present embodiment, the control value is distributed to the # 3 rolling mill stand 13 and the # 4 rolling mill stand 14 by the gains G ₃ and G ₄ . Thereby, the bias of the rolling load in each rolling mill stand can be prevented. That is, in this embodiment, the # 2 rolling mill stand 12 is a master stand, and the # 2 to # 4 rolling mill stands regarded as one rolling mill stand other than the # 2 rolling mill stand 12 which is the master stand. For the roll pair, the roll speed is controlled based on the constant mass flow side.

The outflow amount calculation device 102 outputs a control output (1 + ΔV _R4 / V _R4 ) _CNT to the # 4 rolling mill stand based on the speed operation amount ΔVR4 obtained by the above equation (7).

  The control output thus obtained is multiplied by the stand speed command SSRH and output to each rolling mill stand speed control device. In this case, the control output for the # 3 rolling mill stand is subjected to the successive control with respect to the # 4 rolling mill stand speed command.

  In this case, the thickness control 74 on the exit side of the # 4 rolling mill stand operates as shown in FIG. Thereby, the influence by the error of the transfer processes 121 and 122 in the outflow amount setting device 102 can be removed. By using the above configuration, it is possible to suppress the plate thickness fluctuation on the exit side of the # 4 rolling mill stand from the mass flow constant rule of the # 2 rolling mill stand to the # 4 rolling mill stand.

  Here, a case where a control configuration as shown in FIG. 10 is adopted will be described as a comparative example according to the present embodiment. The configuration shown in FIG. 10 is provided with thickness gauges only on the exit side of the # 1 rolling mill stand 11 and the exit side of the # 4 rolling mill stand 14 as in the example of FIG. 1 according to this embodiment. It is a figure which shows the case where the mass flow control which considered the some said stand as one stand is not employ | adopted.

  In the example of FIG. 10, the exit side plate thicknesses of the # 2 rolling mill stand 12 and the # 3 rolling mill stand 13 cannot be detected. For this reason, there is a problem that the plate thickness accuracy deteriorates because the opportunities for plate thickness control are reduced. In addition, since the rolling reduction rate in the # 2 rolling mill stand 12 and the # 3 rolling mill stand 13 is unknown, there is a problem that the rolling load or the motor load is biased to a specific rolling mill stand, or the ratio between the rolling mill stands is deteriorated. Yes.

  More specifically, when the rolling state in each rolling mill stand is as originally assumed, even if the exit side plate thicknesses of # 2 rolling mill stand 12 and # 3 rolling mill stand 13 cannot be detected. The plate thickness system will not deteriorate significantly. Similarly, the load of each rolling mill stand is not biased.

  On the other hand, for example, when a disturbance occurs in the rolling state in the # 2 rolling mill stand, the disturbance generated there affects the # 3 rolling mill stand 13 and the # 4 rolling mill stand 14. In the example of FIG. 10, the above-described problem occurs because such an effect is attempted to be solved by an operation on the # 3 rolling mill stand 13 by the # 4 stand outlet AGC 64.

  In the rolling mill according to the present embodiment, as shown in FIG. 10, a rolling state that can be detected in a state where the detector is omitted, that is, the inflow side of the # 2 rolling mill stand 12 and the outflow of the # 4 rolling mill stand 14. Control by the constant mass flow side. In that case, the master stand is the # 2 rolling mill stand 12 on the upstream side, and the control amount of the downstream rolling mill stand is manipulated in order to maintain the exit side plate thickness of the # 4 rolling mill stand 14 which is the final stage.

According to such an aspect, for example, when a disturbance occurs in the rolling state in the # 2 rolling mill stand, the disturbance is incorporated into the mass flow control as the deviation ΔH ₂ of the entry side plate thickness or the deviation ΔV _e2 on the entry side plate side, As described above, it is used as a control for the # 3 rolling mill stand 13 and the # 4 rolling mill stand 14.

At that time, since the master stand is the upstream # 2 rolling mill stand 12, the function of the transfer processing unit 121 and the transfer processing unit 122 described in FIG. The disturbance can be applied to the # 3 rolling mill stand 13 and the # 4 rolling mill stand 14 in a feedforward manner. Therefore, according to the rolling mill control according to the present embodiment, it is possible to provide suitable control when performing rolling control based on the state of the material to be rolled on the entry side and the exit side of the entire plurality of rolling mill stands. .

  In the above embodiment, the four-stand tandem rolling mill has been described. However, the present invention can be applied to a tandem rolling mill having an arbitrary number of stands based on the same concept. Moreover, in the said embodiment, although demonstrated about the case where the detector was installed in the exit side of # 1 rolling mill stand 11 and the exit side of # 4 rolling mill stand 14, it detected on the other arbitrary exit side of a stand. The same applies to the case where a vessel is installed.

  Moreover, in the said embodiment, although demonstrated about the case where the plate speedometer was installed in the exit side of # 1 rolling mill stand 11 and # 4 rolling mill stand 14, if the plate speed of a to-be-rolled material is detectable. Any means can be used. For example, the rolled material speed between the stands may be obtained by measuring the number of rotations of the roll in contact with the rolled material, or the plate speed is obtained by estimating the advanced rate from the measurement result of the plate thickness meter. May be. Other methods can be used if the speed of the material to be rolled is required.

  Further, the inflow amount calculation device 101 as shown in FIG. 7 and the outflow amount calculation device 102 as shown in FIG. 8 are realized by a combination of software and hardware. Here, hardware for realizing the functions of the information processing apparatuses such as the inflow amount calculation device 101 and the outflow amount calculation device 102 according to the present embodiment will be described with reference to FIG. FIG. 11 is a block diagram illustrating a hardware configuration of the information processing apparatus according to the present embodiment. As shown in FIG. 11, the information processing apparatus according to the present embodiment has the same configuration as a general server, a PC (Personal Computer), or the like.

  That is, the information processing apparatus according to the present embodiment includes a CPU (Central Processing Unit) 201, a RAM (Random Access Memory) 202, a ROM (Read Only Memory) 203, an HDD (Hard Disk Drive) 204, and an I / F 205. Connected through. Further, an LCD (Liquid Crystal Display) 206 and an operation unit 207 are connected to the I / F 205.

  The CPU 201 is a calculation unit and controls the operation of the entire information processing apparatus. The RAM 202 is a volatile storage medium capable of reading and writing information at high speed, and is used as a work area when the CPU 201 processes information. The ROM 203 is a read-only nonvolatile storage medium and stores a program such as firmware.

  The HDD 204 is a nonvolatile storage medium that can read and write information, and stores an OS (Operating System), various control programs, application programs, and the like. The I / F 205 connects and controls the bus 208 and various hardware and networks. The I / F 205 is also used as an interface for the information processing apparatus to exchange information or input information to the rolling mill.

The LCD 206 is a visual user interface for the operator to check the state of the information processing apparatus. The operation unit 207 is a user interface such as a keyboard and a mouse for an operator to input information to the apparatus. In such a hardware configuration, the software control unit is configured by the CPU 101 performing calculations in accordance with a program stored in the ROM 203 or a program read to the RAM 202 from a recording medium such as the HDD 204 or an optical disk (not shown). . The functions of the inflow amount calculation device 101 and the outflow amount calculation device 102 according to the present embodiment are realized by a combination of the software control unit configured as described above and hardware.

  In the above-described embodiment, the case where the inflow amount calculation device 101 and the outflow amount calculation device 102 are configured as separate devices has been described as an example, but may be configured as one device having both functions. The functions may be distributed to a plurality of devices.

11 # 1 rolling mill stand 12 # 2 rolling mill stand 13 # 3 rolling mill stand 14 # 4 rolling mill stands 21, 22, 23, 24 Speed control devices 31, 32, 33, 34 Roll gap control device 41 # 1 stand out Side thickness gauge 44 # 4 Stand outlet thickness gauge 51, 52, 53, 54 Inter-stand tension meter 61 # 1 Stand outlet AGC
64 # 4 stand exit AGC
71 # 1- # 2 Intertension tension control 72 # 2- # 3 Intertension tension control 73 # 3- # 4 Intertension tension control 81 # 1 Rolling mill stand exit speedometer 84 # 4 Rolling mill stand exit speedometer DESCRIPTION OF SYMBOLS 101 Inflow amount calculating device 102 Outflow amount calculating device 110 Transfer processing part 111 Speed ratio calculation part 121 Transfer processing part 122 Transfer processing part 123 Speed command calculating part 201 CPU
202 ROM
203 RAM
204 HDD
205 I / F
206 LCD
207 Operation unit

Claims (8)

A rolling control device for controlling a tandem rolling mill that rolls a material to be rolled with a plurality of roll pairs,
Of the plurality of roll pairs arranged continuously with respect to the material to be rolled, the detection result of the state of the material to be rolled flowing into the most upstream roll pair arranged on the most upstream side, and arranged on the most downstream side And the detection result of the state of the material to be rolled flowing out from the most downstream roll pair,
Based on the acquired two detection results, the inflow amount of the material to be rolled flowing into the most upstream roll pair and the outflow amount of the material to be rolled out from the most downstream roll pair coincide with each other. A rolling control device that controls a roll speed of a roll pair other than the most upstream roll pair among the plurality of roll pairs arranged in a row. Based on the detection result of the state of the material to be rolled flowing into the most upstream roll pair, an inflow amount calculating unit for calculating the amount of inflow of the material to be rolled flowing into the most upstream roll pair,
Based on the detection result of the state of the material to be rolled out from the most downstream roll pair and the calculated value corresponding to the inflow amount of the material to be rolled into the most upstream roll pair, the material flows out from the most downstream roll pair. An outflow amount calculation unit that outputs a control value for controlling the roll speed of the roll pair other than the most upstream roll pair so that the thickness of the material to be rolled is maintained at a set value. The rolling control apparatus according to claim 1. The inflow amount calculation unit is based on the detection result of the state of the material to be rolled flowing into the most upstream roll pair, so that the thickness of the material to be rolled out from the most downstream roll pair is maintained at a set value. Calculate the index value to control the roll speed of the most downstream roll pair,
The rolling control device according to claim 2, wherein the outflow amount calculation unit outputs a control value for controlling a roll speed of a roll pair other than the most upstream roll pair based on the index value.   When the control value is output, the outflow amount calculation unit outputs the control value at a detection position in the material to be rolled where the detection result used in the calculation of the index value based on the control value is detected. The rolling control device according to claim 3, wherein the control value is output at a timing when the target roll pair is reached.   The outflow amount calculation unit distributes the control value obtained based on the index value to a plurality of roll pairs other than the most upstream roll pair among a plurality of roll pairs arranged continuously. The rolling control device according to claim 3, wherein the rolling control device outputs the rolling control device.   The control value of the roll speed of the most downstream roll pair output by the outflow amount calculating unit and the detection result of the state of the material to be rolled flowing out from the most downstream roll pair, The rolling control apparatus according to claim 2, wherein the roll speed of the most downstream roll pair is controlled by a value obtained by combining a control value of the roll speed. A rolling control method for controlling a tandem rolling mill that rolls a material to be rolled with a plurality of roll pairs,
Of the plurality of roll pairs arranged continuously with respect to the material to be rolled, the detection result of the state of the material to be rolled flowing into the most upstream roll pair arranged on the most upstream side, and arranged on the most downstream side And the detection result of the state of the material to be rolled flowing out from the most downstream roll pair,
Based on the acquired two detection results, the inflow amount of the material to be rolled flowing into the most upstream roll pair and the outflow amount of the material to be rolled out from the most downstream roll pair coincide with each other. A rolling control method, comprising: controlling a roll speed of a roll pair other than the most upstream roll pair among the plurality of roll pairs arranged in a row. A rolling control program for controlling a tandem rolling mill that rolls a material to be rolled with a plurality of roll pairs,
Of the plurality of roll pairs arranged continuously with respect to the material to be rolled, the detection result of the state of the material to be rolled flowing into the most upstream roll pair arranged on the most upstream side, and arranged on the most downstream side Obtaining a detection result of the state of the material to be rolled out from the most downstream roll pair,
Based on the acquired two detection results, the inflow amount of the material to be rolled flowing into the most upstream roll pair and the outflow amount of the material to be rolled out from the most downstream roll pair coincide with each other. A rolling control program that causes an information processing device to execute a step of controlling a roll speed of a roll pair other than the most upstream roll pair among the plurality of roll pairs arranged in a row.