JP2020105623A - Plating adhesion amount control device and control method - Google Patents

Abstract

To maintain a balance of a top plating adhesion amount and a back plating adhesion amount, and avoid a contact risk of a nozzle and a steel plate, by keeping a position of a top nozzle and a back nozzle to the steel plate constant, without using a special sensor for detecting a position of a steel plate path, when a nozzle position is automatically controlled by a plating adhesion amount control.SOLUTION: A plating adhesion amount control device 100 comprises: a steel plate path travelling amount estimation part 105 for estimating a travelling amount of a steel plate path position; and a nozzle position control part 103 having a function for shifting a top nozzle position and a back nozzle position corresponding to the travelling amount of the steel plate path position estimated by the steel plate path travelling amount estimation part 105. Furthermore, the steel plate path travelling amount estimation part 105 is made adjusting-neutral, and a plate thickness difference between a current steel plate and a next steel plate, a tension difference before and after a tension change, and a position changing amount before and after a bathing roll operation are configure to simultaneously input an adjusting neutral net as an eccentric amount.SELECTED DRAWING: Figure 16

Description

The present invention relates to a coating amount control apparatus and a control method for depositing a hot-dip galvanizing bath of a desired thickness on a steel plate in a continuous plating plant of a steel line, and particularly, by controlling not only nozzle pressure but also nozzle position automatically. The present invention relates to a plating deposition amount control method for safely continuing control by controlling the deposition amount on the front and back surfaces of a steel plate to respective target values and minimizing the risk of contact between the nozzle and the steel plate when controlling the deposition amount.

The pressure of the nozzle and the position of the nozzle are the operation ends for controlling the amount of plating adhered to the steel plate. The position of the nozzle is an operation end for changing the distance between the nozzle and the steel plate (hereinafter referred to as the nozzle gap). Generally, it is better to operate the nozzle position from the viewpoint of control response and gloss of the plated steel plate, but the relative position of the steel plate viewed from the nozzle changes due to various factors such as plate thickness change, so the nozzle position It is not easy to grasp the distance between the steel sheet and For this reason, the nozzle position is often controlled by an operator's manual operation, and in order to introduce automatic control, the accuracy of the deposition amount is degraded, the imbalance of the deposition amount on the front and back of the steel sheet, and the contact between the nozzle and the steel sheet. Had to solve the danger of.

As a conventional method for performing such a coating amount control, in Patent Document 1, a sensor for detecting the passage position (steel plate path position) of the steel plate in the nozzle portion is additionally provided, and the steel plate path position detected using the sensor is used. Then, an example in which the positions of the front nozzle and the back nozzle are controlled to appropriate values for the steel sheet is shown.

Further, Patent Document 2 discloses a method that includes means for estimating a steel plate path position and corrects the nozzle gap or issues an alarm when the estimated distance between the nozzle and the steel plate becomes a certain value or less. ..

Further, in Patent Document 3, a magnetic force generator capable of controlling the steel sheet in a non-contact manner and a displacement meter capable of detecting the steel sheet path position are provided on the upper and lower portions of the nozzle, and the steel sheet measured by the displacement meter is controlled to an appropriate position. In addition, a method for controlling the distance between the nozzle and the steel plate to a value at which a desired amount of deposited coating is obtained is shown.

JP 2008-280587 A JP, 2009-275266, A JP-A-3-253549

However, in the method of Patent Document 1, since it is necessary to lay a steel plate path position detection sensor, the price of the control system becomes expensive, and maintenance and calibration work of the steel plate path position detection sensor are newly required. There was a problem. Further, since the steel plate path position detection sensor is usually provided on the upper part of the nozzle, the steel plate path position detected by the steel plate path position detection sensor does not correspond to the steel plate path position of the nozzle portion, and therefore the plating adhesion There was a problem that the quantity accuracy was reduced. Further, the detection of the steel sheet path position in the plating plant has a high technical difficulty due to the vibration of the steel sheet, the warp in the width direction, and the like, and there is a problem that it is difficult to detect the steel sheet path position with high accuracy.

The method of Patent Document 2 includes a means for estimating a change in the steel sheet path position when changing the sheet thickness, and further estimating a steel sheet path position by determining a stable control state. However, the steel plate pass position moves not only by changing the plate thickness, but also by operating a roll in the bath (collecting roll, stabilizing roll) or changing the steel plate tension. Since Patent Document 2 does not consider this point, there is a problem in that the estimation accuracy of the steel sheet path position decreases from the time when the roll operation in the bath or the change in tension occurs until the stable control state is established. Furthermore, regarding the relationship between the amount of plate thickness change and the amount of steel plate movement, the plate thickness and steel type of the currently processed steel plate (current steel plate) and the next processed steel plate (next steel plate), roll position in the bath, and tension value Various state quantities affect the operating point. By the way, the hardness and the yield strength change when the steel type is different, so that the movement amount of the steel plate pass position is affected. Since the method of Patent Document 2 does not consider this point, there is a problem in that the estimation accuracy of the steel sheet path position is reduced by not considering the influence of the state quantity.

The method of Patent Document 3 has a problem that the system becomes expensive because a large-scale device for restraining the steel plate is required.

Therefore, the problem to be solved by the present invention, when automatically controlling the nozzle position, accurately estimates the movement of the steel sheet path position without using a special sensor for detecting the steel sheet path position, and the estimation result Is to control the nozzle position. As a result, it is possible to prevent the amount of plating adhered on the front and back of the steel plate from becoming unbalanced, improve the accuracy of the amount of plating adhered, eliminate the risk of contact between the nozzle and the steel plate, and continue control safely. is there.

In order to solve the above-mentioned problems, in the coating amount control device of the present invention, the steel plates that are continuously fed are immersed in a bath of a hot dip plating bath, the hot dip bath is attached to the steel plate, and the steel is pulled up from the bath. After that, a gas is sprayed from the front nozzle and the back nozzle provided on the front and back of the steel sheet to the steel sheet, and the excessively adhered hot dip coating bath is removed to control the plating plant that attaches the hot dip coating bath of the desired thickness to the steel sheet In the coating weight control device, the plate coating speed, the nozzle pressure, the distance between the nozzle and the steel plate, and the coating weight prediction model describing the relationship between the coating weight deposited on the steel plate, and the steel plate with reference to the coating weight prediction model So that the amount of plating adhered to the desired value, a control unit that controls at least one of the nozzle pressure and the nozzle position, the plate thickness switching of the steel plate through the welding point is a joint of the steel plate, the Estimating the amount of movement of the steel plate tension which is the passing position at the nozzle height of the steel plate when at least one of the tension of the steel plate and the position of the in-bath roll that supports the steel plate in the bath changes. , A steel plate path movement amount estimation unit for outputting to the control unit, wherein the steel plate path movement amount estimation unit is at least one of a deviation amount consisting of a plate thickness change amount, a tension change amount, and a bath roll position movement amount. With the input, further, the plate thickness of the steel plate that affects the relationship between the deviation amount and the steel plate path movement amount, the steel type of the steel plate, the tension applied to the steel plate, the state quantity consisting of the position of the roll in the bath, It is characterized by being constituted by a neural net which outputs the amount of movement of the steel sheet path.

According to the present invention, when each of factors such as passage of a welding point, which is a timing at which a steel sheet path position moves, tension change, and roll operation in a bath, a steel sheet path moving amount estimation unit is activated, and a steel sheet corresponding to the factor change is generated. The movement amount of the pass position is calculated, and the nozzle position control unit shifts the front nozzle position and the back nozzle position according to the steel plate pass movement amount. Therefore, since the relative distance between the nozzle and the steel plate can be kept constant, it is possible to prevent the amount of adhesion on the front and back of the steel plate from becoming unbalanced due to the movement of the steel plate path. Further, it is possible to reduce the risk of contact between the nozzle and the steel plate, which occurs when the steel plate approaches one of the nozzles on the front and back.

Furthermore, by simultaneously considering various factors that affect the steel plate path movement amount as inputs to the neural network, the estimation accuracy of the steel plate path movement amount can be improved.

In the adjusting neural net, when the input values of all deviations (thickness difference between the current steel plate and the next steel plate, the tension difference before and after the tension change, the position change amount before and after the roll operation in the bath) are 0, the steel plate path movement amount Estimating 0 is guaranteed by its structural features. By configuring the steel plate path movement amount estimation unit with an adjusting neural network, it is possible to accurately estimate the delicate movement amount of the steel plate path when the deviation amount is small.

It is explanatory drawing which showed the plating plant. It is an example of instruction information. This is processing of the welding point passage determination unit. This is the process of the tension change determination unit. It is a process of the roll operation determination unit in the bath. 3 is a configuration of a neural network that constitutes a steel plate path movement amount estimation unit. This is the process of the learning database construction unit. It is the relative relationship between the nozzle zero point, the front nozzle position, the back nozzle position, and the steel plate. .. It is a block diagram of a learning database. This is the process of the nozzle position control unit. This is the process of the nozzle pressure control unit. It is explanatory drawing when a steel plate path movement amount estimation part is comprised by the adjusting neural network. It is explanatory drawing which showed the coating amount control apparatus. It is explanatory drawing when a steel plate path movement amount estimation part is comprised by three adjusting neural networks. This is the processing of the steel plate path movement amount estimation result selection unit. It is explanatory drawing which showed the coating amount control apparatus of this invention. It is the figure which showed the positional relationship in the horizontal cross section of a nozzle and a steel plate. It is a figure explaining the site|part which measures the plating adhesion amount.

Nozzle gap automatic control can be safely introduced in the plating amount control described in the following embodiments. As compared with the case where only the nozzle pressure is automatically controlled, it is possible to realize higher precision of plating amount control, higher response, and improvement of steel plate surface quality.

FIG. 1 shows an embodiment of the present invention. The coating amount control device 100 (details are shown in FIG. 16) controls the plating plant 150 and deposits a hot dipping bath having a desired thickness on a steel plate (strip) 151.

First, the plating plant 150 will be described. A hot-dip plating bath is stored in a pot (bath) 152 of the plating plant 150, and the steel plates 151 connected at a welding point 156 are continuously fed. The steel plate 151 is supported by a roll 160 in the bath, and is controlled to have a predetermined tension value for each steel plate between the steel plate 151 and the top roll 161. With the passage of the welding point 156, the tension changes from the tension of the steel sheet 151 (current steel sheet, preceding material) currently being treated to the tension of the steel sheet 151 (next steel sheet, following material) to be treated next time.
The steel sheet 151 is once immersed in the hot dip coating bath, and after being pulled up, gas is blown from nozzles 153 consisting of a front nozzle and a back nozzle provided on the front and back of the steel sheet 151 to remove the excessive hot-dip coating bath. By doing so, the amount of plating that adheres is controlled to a desired value. The amount of plating that adheres to the steel plate 151 is determined by the speed of the steel plate 151 (plate speed), the pressure of the gas blown from the nozzle 153, and the distance between the nozzle 153 and the steel plate 151. Since the pressure of the front nozzle and the pressure of the back nozzle are usually the same in consideration of the vibration of the steel plate 151, if the position of the nozzle 153 is controlled so that the steel plate 151 is between the front nozzle and the back nozzle, The amount of adhesion on the front and back can be made the same value.
Here, the passing position at the nozzle height of the steel plate 151 during the plating process is hereinafter referred to as "steel plate pass position". If the distance between the nozzle and the steel plate pass position is the nozzle gap and the steel plate pass position can be estimated, the relative position of the steel plate viewed from the nozzle can be specified. The front nozzle gap can be calculated from the front nozzle position and the steel plate pass position, and the back nozzle gap can be calculated from the back nozzle position and the steel plate pass position.
Further, by operating the roll 160 in the bath, it is possible to change the warp of the steel plate 151 in the width direction. When the steel plate 151 is warped, the amount of plating adhered to the steel plate 151 in the plate width direction becomes different due to this, but the position of the in-bath roll 160 should be controlled so that the steel plate 151 does not have a warp. This makes it possible to correct the phenomenon that the different values are obtained.
On the other hand, the steel plate pass position changes due to changes in plate thickness of the steel plate 151, changes in tension, and roll operation in the bath. When the steel plate pass position changes, the steel plate 151 approaches one of the front and back nozzles and moves away from the other nozzle. When the target values of the amount of plating adhered on the front and back sides are the same, it is necessary to control the position of the nozzle 153 so that the steel plate 151 is located between the front nozzle and the back nozzle even if the steel plate path moves. Different thickness plating may be considered in which the amount of plating adhered on the front and back is intentionally changed, but in this case, it is necessary to control the nozzle 153 at a position in consideration of the difference in the target value of the amount of plating adhered on the front and back. In any case, in order to maintain the balance between the amount of front plating and the amount of back plating, the amount of movement of the steel plate path is correctly estimated at the timing when the steel plate path moves, and the position of the nozzle 153 is set to It is necessary to shift by the amount moved.

The relationship between the amount of plating adhered to the steel plate 151, the plate speed, the nozzle pressure, and the nozzle gap (distance between the nozzle and the steel plate) is represented by, for example, Equation 1. In Equation 1, if the values of the front surface of the steel plate are input to P and D, the plating adhesion amount of the steel plate surface is calculated, and if the values of the back surface of the steel plate are input to P and D, the plating adhesion amount of the back surface of the steel plate is calculated. it can. Further, by inputting a value obtained by averaging P on the front and back of the steel sheet and a value obtained by averaging D on the front and back of the steel sheet, an approximate value of the plating adhesion amount averaging the front and back can be calculated.

In the present embodiment, the following formula 1 is referred to as a plating adhesion amount prediction model. In addition to this, the nozzle height, the steel plate temperature, and the temperature of the hot-dip galvanizing bath may be considered as a model for predicting the coating weight. The front and rear steel plates are connected by welding at a welding point 156, and the welding point 156 usually corresponds to the switching portion of the target coating amount. The coating amount detector 155 is a device for measuring the amount of coating actually attached, and detects and outputs how much coating is attached to the steel plate 151 for each of the front and back of the steel plate 151. In the present embodiment, description will be given by taking as an example the case where the measurement values of the left side, the center, and the right side of the steel plate 151 are output in the width direction (6 points in total). The plating adhesion amount detector 155 is attached at a position separated from the nozzle 153 by several tens to hundreds of tens of meters, and usually, the steel plate is moved in the width direction and averaged, and then the value is output. Therefore, it usually takes several tens of seconds to 2 minutes before the amount of deposited plating corresponding to the nozzle positions P, V, and D can be measured.

FIG. 16 shows the configuration of the plating adhesion control device 100. The plating amount control device 100 receives, from the host computer 140, instruction information including the steel plate number, steel type, plate thickness, plate width, target value of plating amount, etc. for the steel plate 151 to be processed next, and further performs plating. Received from the plant 150 pressure and position of the nozzle 153, speed of the steel plate 151, performance information such as the plating deposition amount actual detected by the plating deposition amount detector 155, from these, referring to the plating deposition amount prediction model 104, the target The control unit 101 includes a nozzle position control unit that calculates a nozzle position and a pressure command that realizes the amount of plating adhered, and the control unit 101 further includes a nozzle pressure control unit 102 and a nozzle position control unit 103. Further, a welding point passage determination unit 106 that determines that the welding point 156 has passed the position of the nozzle 153, and a tension change determination unit that determines that the tension of the steel sheet 151 has changed, based on the record information acquired from the plating plant 150. 107, one of the in-bath roll operation determination unit 108 that determines that the operator has operated the in-bath roll 160, the welding point passage determination unit 106, the tension change determination unit 107, and the in-bath roll operation determination unit 108 A steel plate path movement amount estimation unit 105 that estimates the movement amount of the steel plate path according to the determination result is provided, and the nozzle position control unit 103 has a function of shifting the position of the nozzle 153 according to the output of the steel plate path movement amount estimation unit 105. Equipped with.

In the present embodiment, the steel plate path movement amount estimation unit 105 is composed of a neural network. Therefore, for learning the neural network, the learning database construction unit 110 that extracts the data necessary for learning from the performance information captured from the plating plant 150, and the learning that accumulates the data output from the learning database construction unit 110 The learning database 112 and the learning unit 112 for learning the neural network included in the steel plate path movement amount estimation unit 105 using the data accumulated in the learning database 111.

The function of each unit will be described in detail below with reference to the drawings. FIG. 2 shows an example of the instruction information that the plating amount control device 100 receives from the host computer 140. The instruction information 201 includes basic information such as a steel plate number of a steel plate to be processed next time, a steel type, a plate thickness, a plate length, etc., a control target value, and the like, and is sent before the steel plate is processed. In the example of the instruction information shown in FIG. 2, attribute values such as steel plate number, steel type, plate thickness, and plate width, control command values such as target adhesion amount, upper limit adhesion amount, lower limit adhesion amount, nozzle gap, roll position in bath, etc. The control operating point is included. Actually, in addition to this, there may be cases where the chemical composition of the steel sheet, the place of delivery, and information on the next process are included.

FIG. 3 shows processing executed by the welding point passage determination unit 106. The process is started at the timing when the welding point 156 has passed the position of the nozzle 153, and thereafter, the process is repeated every fixed period (Δt). In S3-1, the tracking value L is initialized. In this flow chart, L indicates the distance from the top of the steel plate to the plated portion. In S3-2, the plate speed of the steel plate 151 is taken from the plating plant 150. Then, a value obtained by multiplying the plate speed V by the calculation cycle Δt is added to L to newly set L. In S3-3, it is determined whether L is longer than the steel plate length L2 fetched from the instruction information 201. If it is not larger, the processing of the steel sheet is continuing, so after Δt has elapsed, the process returns to S3-2 and the processing of S3-2 to S3-3 is repeated. If it is larger, it indicates that the processing of the steel sheet has been completed, and therefore, in S3-4, the determination result of welding point passage is output to the steel sheet path movement amount estimation unit 105. After that, the process returns to S3-1 and the processing of the next steel plate is started.

FIG. 4 shows the processing executed by the tension change determination unit 107. In S4-1, the tension of the steel plate 151 between the bath roll 160 and the top roll 161 is taken in from the plating plant 150 and compared with the value previously taken in. If there is no difference in the comparison result, there is no change in tension, so the process returns to S4-1 and the processes of S4-1 to S4-2 are repeated. If there is a difference in the comparison results, the tension has changed, so in S4-3, the determination result that the tension has changed is output to the steel plate path movement amount estimation unit 105. After that, the process returns to S4-1 to monitor the next tension change.

FIG. 5 shows a process executed by the in-bath roll operation determination unit 108. In S5-1, the position of the in-bath roll 160 is fetched from the plating plant 150 and compared with the previously fetched value. Here, at least one of the in-bath rolls is movable in the horizontal direction, and the in-bath roll position is the horizontal position of the movable rolls or the overlapping amount of the two in-bath rolls in the vertical direction. The amount of intermesh.
If there is no difference in the comparison result, the in-bath roll 160 has not been operated, so the process returns to S5-1 and the processes of S5-1 to S5-2 are repeated. If there is a difference in the comparison results, it indicates that the in-bath roll 160 has been operated and the position has changed. Therefore, in S5-3, it is determined that the in-bath roll has been operated to the steel plate path movement amount estimation unit 105. The judgment result of is output. After that, the process returns to S5-1 and the next roll operation in the bath is monitored.

FIG. 6 shows the configuration of the steel plate path movement amount estimation unit 105. In the present embodiment, the steel plate path movement amount estimation unit 105 is configured by a neural network including an input layer 601, an intermediate layer 602 including one or more layers, and an output layer 603. Various types of neural nets have been reported, but in this embodiment, a neural network of a type in which a signal propagates in one direction from an input layer 601 to an output layer 603, which is referred to as a multilayer type, a hierarchical type, a feedforward type, or the like. Here is an example of a net. The intermediate layer 602 is composed of n intermediate layers from the first intermediate layer 610 to the nth intermediate layer 611, and each neuron 604 transmits/receives a signal through the synapse 605. The number of neurons constituting the output layer is one, and the estimated value of the amount of movement of the steel sheet path calculated through the input layer 601 and the intermediate layer 602 is output. Information necessary for estimating the steel plate path movement amount is input to each neuron of the input layer 601. The steel plate path moves by a value corresponding to the amount of change in the plate thickness at the timing when the plate thickness of the steel plate 151 changes as the welding point passes. Further, the steel sheet path moves by a value corresponding to the amount of change in tension at the timing when the tension of the steel sheet 151 changes. Further, the steel sheet path moves by a value corresponding to the amount of movement of the position at the timing when the position of the roll 160 in the bath changes. From the above, an input neuron for taking in the plate thickness change amount, the tension change amount, and the roll position change amount in the bath is provided. The amount of change in plate thickness, the amount of change in tension, and the amount of change in roll position in the bath are referred to as deviation amounts, which are input to the input layer 601 as deviation amounts 620. In addition, the state quantity when these change is an operating point and affects the relationship between the value of the deviation amount and the steel plate path movement amount. In the case of the present embodiment, the state quantity is the steel type of the steel plate 151, the plate thickness, the plate width, the position of the in-bath roll 160, the height of the nozzle 153 (the distance between the in-bath roll 160 and the nozzle 153), and the like. The layer 601 includes neurons that take these in as state quantities 621. Further, a threshold neuron 612 may be provided, and a constant (1 in this embodiment) is input to the threshold neuron 612. These signals input at the input layer 601 are sent to the intermediate layer via synapses. A constant called a weight is given to each synapse, and a value obtained by multiplying the synapse by the weight is transmitted. For example, Kj shown in Expression 2 is input to the neuron j of the first intermediate layer from the input layer.

In the neuron j having the first intermediate layer, the received Kj1 is subjected to nonlinear processing, converted into Lj, and output to the next layer. As a non-linear processing example, the sigmoid function shown in Expression 3, the Relu function shown in Expressions 4 and 5 are used.

Such calculation is sequentially performed for each neuron in the layer close to the input layer 601, and finally the output of the neuron in the output layer 603 becomes the steel plate path movement amount. The neural network calculation method is introduced in many booklets, such as "Introduction to Mathematics for Understanding Deep Learning" (technical critic). By configuring the steel sheet path movement amount estimation unit 105 with a neural network, it is possible to consider the influence of many parameters that affect the steel sheet path movement amount, and further to consider the complex relationship between each parameter and the steel sheet path movement amount. It is possible to improve the accuracy of estimating the amount of movement of the steel sheet path. Also, since the relationship between the input parameter and the steel plate path movement amount can be acquired by learning using the data acquired from the plating plant 150, there is no need to manually construct the relationship between the input parameter and the steel plate path movement amount, and the plating adhesion amount The load for constructing the control device can be reduced.

Next, a learning method of the neural network provided in the steel plate path movement amount estimation unit 105 will be described. FIG. 7 shows the processing of the learning database construction unit 110. The learning database construction unit 110 constructs a database of teacher signals for learning the neural network provided in the steel plate path movement amount estimation unit 105. From the actual information obtained from the plating plant 150 in S7-1, the information necessary to estimate the amount of movement of the steel sheet path (the amount of plating on the front and back, the nozzle position on the front and back) is input to the neural network. Captured as data to be input to the layer 601 (hereinafter referred to as input data). The steel plate pass position is calculated in S7-2. The steel plate pass position is the distance between the zero point and the steel plate pass position, which is calculated by using the actual values Wt and Wb of the front and back plating amounts, the position Dt of the front nozzle 801, and the position Db of the back nozzle 802 shown in FIG. Calculate as Dp. The zero point in FIG. 8 corresponds to the steel plate pass position when the front and back nozzle positions are adjusted to zero, and at this time, the front and back nozzles are equidistant across the zero point. That is, the front and back nozzle gaps have the same value. After that, it is assumed that the steel plate is moved to the position shown in FIG. 8 due to the change of the plate thickness of the steel plate 151 and the operation of the in-bath roll 160. At this time, the nozzle positions output as the manipulated variables by the plating deposition amount control device 100 are Dt and Db with reference to the zero point, but the actual distances between the nozzles and the plate are D't and D'b. First, it is considered that D't and D'b are obtained and then the steel plate path position Dp is calculated. D't and D'b can be calculated by Equations 6 and 7, respectively.

Using this result, the steel plate path position Dp can be calculated by Equation 8.

Alternatively, the steel plate path position Dp can be calculated by Expression 9.

In FIG. 8, Dp is defined as positive when it is on the right of the zero point and negative when it is on the left. In S7-3, at the timing when Dp changes, the Dp before the change is subtracted from the Dp after the change to calculate the steel plate path movement amount ΔDp. In S7-4, an edit process is performed which sets ΔDp and the input data obtained when the steel plate path position Dp changes, and outputs it to the learning database 111.

FIG. 9 shows the structure of the learning database 111. In the learning database 111, many pairs of neural network input data 901 and output data 902 corresponding to the steel plate path movement amount are stored. Further, the input data 901 includes a deviation amount 903 including a plate thickness change amount, a roll position change amount in the bath, and a tension change amount, and a state amount 904 such as steel type and plate thickness. No. 1 indicates that when the plate thickness change amount, the roll position change amount in the bath, and the tension change amount are all 0, the steel plate pass movement amount is 0. In No. 2, when the steel plate 151 with steel type code 5 has a plate thickness of 1.55 mm to 0.14 mm thinner, the roll position in the bath does not change from 10.6 mm, and the amount of change in tension is 0, the steel plate path is only 0.32 mm, In FIG. 8, it has shown that it moved from the right to the left. The actual input data 901 also includes, as the state quantity 904, other items that affect the amount of movement of the steel sheet path, such as the value of the tension of the steel sheet 151 and the steel type of the next steel sheet.

The learning of the neural network provided in the steel plate path movement amount estimation unit 105 is performed by the learning unit 112.
The learning unit 112 sequentially takes out a combination of the input data 901 stored in the learning database 111 and the corresponding output data 902, and outputs the input data 901 to the input layer 601 of the neural network included in the steel plate path movement amount estimation unit 105. Enter in order. Then, the weight value of the synapse 605 is updated so that the output value of the output layer 603, which is the calculation result, matches the value of the output data 902.
Then, this update process is repeated until the difference between the output value of the output layer 603 and the output data 902 is within a certain range. This is a method called backpropagation in the learning method of the neural network, which can be referred to in many works, for example, "Neural network information processing" (Hideki Aso, Sangyo Tosho). A method using an auto encoder is known as a learning method for a deep neural network having a plurality of intermediate layers, which can also be referred to in many books such as "Deep Learning" (JSAI). As described above, there are various learning methods for the neural network, and it suffices to perform learning using an appropriate method.

FIG. 10 shows a process of the nozzle position control unit 103 included in the control unit 101. The nozzle position control unit 103, according to the instruction information 201 regarding the steel plate 151 received from the host computer 140, preset control for setting the nozzle position suitable for obtaining the target adhesion amount, the steel plate path movement amount estimation unit 105 Nozzle shift control that takes in movement information and moves the nozzle 153 consisting of front nozzle and back nozzle in parallel by a corresponding value, and unbalances the front and back and widthwise adhesion amount from the actual adhesion amount taken in from the plating adhesion amount detector 155. It has three functions of feedback control for detecting and changing the nozzle position in a direction to make them uniform. First, in S10-1, the start factor is determined, and which of preset control, nozzle shift control, and feedback control is to be executed is determined. Any of the start factors can be determined from the performance information captured from the plating plant 150, for example, preset control passes the nozzle position of the welding point 156, nozzle shift control the steel plate path movement amount movement information from the steel plate path movement estimation unit 105. For the reception and feedback control of, the detection of the new adhesion amount from the plating adhesion amount detector 155 may be used as the respective activation factors. When the preset control is activated, the nozzle gap Dn of the next steel plate is fetched from the instruction information 201 in S10-2. In S10-3, the nozzle positions Dc1 to Dc4 controlled for the current steel plate are fetched as the performance information from the plating plant 150. In the present embodiment, a case will be described as an example where four actuators for controlling the nozzle position are provided, one each on the front and back sides and in the width direction, that is, a total of four actuators. That is, the nozzle position on the front side of the front nozzle in FIG. 8 is Dc1, the back side is Dc2, the nozzle position on the front side of the back nozzle is Dc3, and the back side is Dc4. In S10-4, the nozzle positions Dn1 to Dn4 of the next steel plate are calculated according to formulas 10 to 13 and output to the plating plant 150. Refer to FIG. 17 for each parameter (Dc: nozzle position before moving to current steel plate, Dn: nozzle position after moving to next steel plate) of Formula 10 to Formula 13.

In this embodiment, the preset control activation factor is the timing at which the welding point 156 passes through the nozzle position, but it may be desired to calculate in advance in consideration of the time required for the nozzle movement. At this time, the timing at which the welding point 156 passes the bath roll 160 may be set, or a setting such as 5 seconds before the nozzle position passage may be set.
On the other hand, when the activation factor is the movement of the steel sheet pass position, the nozzle shift control is performed. At S10-5, the current nozzle position (nozzle positions Dc1 to Dc4 for the current steel plate) is fetched. Further, in S10-6, the steel sheet path movement amount ΔDp is fetched from the steel sheet path movement amount estimation unit 105. In S10-7, the actuators that operate the nozzles are moved in parallel by .DELTA.Dp in accordance with formulas 14 to 17, command values Dn1 to Dn4 of the nozzle positions are calculated, and output to the plating plant 150.

When a new adhesion amount actual value is fetched from the plating adhesion amount detector 155 and the feedback control is started by using this as a starting factor, the actual value of the plating adhesion amount is fetched from the plating adhesion amount detector 155 in S10-8. .. In the present embodiment, a case will be described as an example in which three points on the front and back sides of the steel plate 151, that is, three points at the center and both ends, that is, a total of six points, are detected. Here, the 6 detection values are defined as follows.
-TL: Adhesion amount on the left side of the steel plate surface-TC: Adhesion amount on the center surface of the steel plate-TR: Adhesion amount on the right side of the steel plate-BL: Adhesion amount on the left side of the back surface of the steel plate-BC: Adhesion amount on the back surface center of the steel plate BR: Adhesion amount on the right side of the back surface of the steel plate In S10-9, the adhesion amount imbalance between the front and back sides and the width direction is calculated. The unbalance is calculated, for example, by the formulas 18 and 19. See FIG. 18 for the parameters of Expressions 18 and 19.

In the present invention, the coating weight detector 155 measures the coating weight by a so-called three-point scanning method. That is, when the coating weight detector 155 moves in the width direction to detect the coating weight, it is temporarily stopped at three locations on the left side, the center, and the right side to detect the coating weight, and the front and back surfaces of the steel plate 151 are detected. For, the measured values at the left side, the center, and the right side in the width direction are output. That is, as described above, a total of 6 measurement values (TL, TC, TR, BL, BC, BR) are output on the front and back sides.
In addition, normally, both-sided average (average value of the above 6 points), front average (TL, TC, TR average value), back average (BL, BC, BR average value) are also output. In this case, for example, The U value in Expression 18 can also be calculated using the front average and the back average.
As a general operation of the coating amount detector, in addition to the three-point scanning method, when the all-scan method (the coating amount detector 155 continuously moves in the width direction to detect the coating amount) is used There is also. Even in this case, the present invention can be applied as it is by performing calculation using the values detected in the vicinity of TL, TC, TR, BL, BC, and BR.

Then, in S10-10, the nozzle position in the direction to eliminate this imbalance is calculated in accordance with Expressions 20 to 23, and is output to the plating plant 150.

Since the plate thickness of the steel plate 151 changes with the passage of the welding point 156, it is possible that the preset control and the nozzle shift control are activated at the same time. Even in that case, S10-2 to S10-4 and S10-5 to S10-7 may be sequentially executed and the results may be integrated. Alternatively, it is conceivable to calculate the nozzle position command value by superimposing Expressions 18 and 19 and Expressions 20 to 23 as in Expressions 24 to 27.

In any case, the present invention can be applied as it is.

FIG. 11 shows a process of the nozzle pressure control unit 102 included in the control unit 101. The nozzle pressure control unit 102, for the next steel plate, preset control for calculating the nozzle pressure that realizes the plating adhesion amount target value instructed by the instruction information 201, taking in a state change such as changing the plate speed of the steel plate 151, Feedforward control that calculates the correction amount of the nozzle pressure that compensates for the influence on the coating weight, the actual coating weight of the coating weight detected by the coating weight detector 155, and the target weight when there is a deviation, this deviation It has three functions of feedback control for calculating the correction amount of the nozzle pressure for reducing In S11-1, the start factor is determined to determine which of preset control, feedforward control and feedback control is to be executed. Any of the starting factors can be determined from the performance information acquired from the plating plant 150. For example, preset control passes through the nozzle position of the welding point 156, feedforward control changes the speed of the steel plate 151, and feedback control detects the amount of adhered plating 155. The detection of the new adhered amount from the above may be used as the respective activation factors. When the preset control is activated, the current plate speed Vc is fetched from the plating plant 150 in S11-2. In S11-3, the target plating adhesion amount of the next steel plate is fetched from the instruction information 201. In S11-4, the nozzle position setting value of the next steel plate is fetched from the nozzle position control unit. Instead of the nozzle position setting value of the next steel plate, the nozzle gap of the next steel plate taken from the instruction information may be used. In S11-5, the plating adhesion amount prediction model is referred to, the preset value of the nozzle pressure is calculated by the mathematical formula 28 using the fetched value, and is output as the operation amount of the nozzle 153.

When the feedforward control is activated, the plate speeds before and after the change are fetched from the plating plant 150 in S11-6. Then, in step S11-7, the nozzle pressure correction amount for compensating for the speed change is calculated by Expression 29, and the current nozzle pressure is corrected. The influence coefficient is the ratio of the nozzle pressure and the speed required to increase or decrease the amount of plating deposition by a unit amount.

When a new adhesion amount actual value is fetched from the plating adhesion amount detector 155 and the feedback control is started by using this as a starting factor, the actual value of the plating adhesion amount is fetched from the plating adhesion amount detector 155 in S11-8. .. In step S11-9, the deviation is calculated from the target adhesion amount Wn fetched from the instruction information 201, and in step S11-10, the nozzle pressure for eliminating the deviation is calculated and output to the nozzle 153 as the operation amount. Specifically, the current nozzle pressure is corrected by a calculation formula according to Formula 30. The influence coefficient is the amount of change in nozzle pressure required to change the amount of plating adhered by a unit amount.

As described above, the control unit 101 includes the nozzle pressure control unit 102 and the nozzle position control unit 103, so that the plating adhered to the steel plate 151 can be controlled to the target value, and the nozzle position can be tracked by following the path movement of the steel plate 151. Therefore, the risk of contact between the nozzle 153 and the steel plate 151 can be eliminated, and the amount of plating adhered on the front and back surfaces can be maintained.

In this embodiment, the speed change of the steel plate 151 is shown as an example of the start factor of the feedforward control of the nozzle pressure control unit 102. However, in addition to this, the operator may manually correct the target value of the plating deposition amount. It is also conceivable that the activation is triggered by a change in the distance between the steel plate 151 and the nozzle 153 due to a change in the plate thickness of the steel plate 151. Even in this case, the feedforward control can be implemented by the same method. Further, in this embodiment, an example in which the double-sided sum of the plating adhesion amounts in the feedback control is controlled by the nozzle pressure has been shown, but it is also possible to change the nozzle position (open and close the nozzle) without changing the pressure. .. Even in this case, the process of the steel sheet path movement estimating unit shown in the present embodiment can be applied as it is. Further, in the present embodiment, the learning database construction unit 110, the learning database 111, and the learning unit 112 are provided inside the plating adhesion amount control device 100, but another computer capable of exchanging signals with the plating adhesion amount control device 100. In addition, it is possible to construct a learning database by periodically taking in actual data from the plating adhesion amount control device 100, learning as necessary, and transmitting the learning result to the steel plate path movement amount estimation unit 105. it can.

Next, as a second embodiment of the present invention, an embodiment will be described in which the estimation of the amount of movement of the steel sheet path is configured by an adjusting neural network including two neural networks. Since the configuration and learning method of the adjusting neural network are described in JP-A-7-121206 and JP-A-8-63203, they are omitted in this embodiment, and a unique configuration when applied to the estimation of the steel plate path movement amount. Will be described in detail only. First, the input is the deviation amount of the plate thickness change amount, the tension change amount, the roll position change amount in the bath, the plate thickness and steel type of the preceding material (current steel plate) and the following material (next steel plate), the tension and the roll position in the bath. , And separate into state quantities. FIG. 12 shows the configuration when the adjusting neural network is applied to the steel plate path movement amount estimation unit 105. The adjusting neural net 1202 is composed of two neural nets, a normal neural net 1203 and an error calculating neural net 1204, and a value obtained by subtracting the output of the error calculating neural net 1204 from the output of the neural net 1203 Output as path movement amount.
The neural network 1203 and the error calculation neural network 1204 have the same configuration, and the synapses 1232 for transmitting and receiving signals between the neurons 1231 have the same weight value. The neural network 1203 includes an input layer 1211, an intermediate layer 1212, and an output layer 1213, and the error calculation neural net 1204 includes an input layer 1241, an intermediate layer 1242, and an output layer 1243.
The input of the input layer 1211 of the neural network 1203 is the same as the input of the neural network shown in FIG. 6, and the input layer 1211 of the neural network 1203 has a neuron for inputting the deviation amount 1221 and a neuron for inputting the state amount 1222. ing. On the other hand, in the input layer 1241 of the neural network 1204 for error calculation, 0 is input instead of the deviation amount (reference numeral 1251) to the neuron corresponding to the deviation amount, and each neuron corresponding to the other state amount 1252 The same value of the state quantity 1222 as the net 1203 is input. When the plate thickness change amount, the tension change amount, and the roll position change amount in the bath are all 0, it is obvious that the steel plate path movement amount should be 0. However, the neural network 1203 and the error calculation neural network 1204 have the same configuration, The value obtained by subtracting the output of the error calculation neural net 1204 from the output of the net 1203 is guaranteed to be always 0 due to its structure. As a result, it is possible to avoid steady deviations in the amount of movement of the steel sheet pass, and to avoid the influence of learning errors of the neural network, and to reduce the amount of change in sheet thickness, tension, and roll position in the bath, It is possible to calculate the movement amount with high accuracy.

In JP-A-7-121206 and JP-A-8-63203, there is a single input layer neuron that inputs 0 to the error calculation neural net 1204, but in this embodiment, the plate thickness change amount, the tension change amount, and the bath change amount Since it is necessary to handle three deviation amounts of the roll position change amount at the same time, the configuration is expanded to input 0 to the three input layer neurons. By doing so, the adjusting neural net 1202 can be applied to the steel plate path movement amount estimation unit 105 of the plating adhesion amount control device 100 that is the target of this embodiment.

Next, as a third embodiment of the present invention, in FIG. 13, the estimation of the steel plate path movement amount is performed by a plurality of adjusting neural nets, and the obtained plurality of steel plate path movement amounts are selected and used for control. An example will be shown. The steel plate path movement amount estimation unit 1301 includes a plurality of adjusting neural nets for estimating the steel plate path movement amount, and the steel plate path movement amount estimation result selection unit 1302 includes the steel plate path movement amount estimation unit 1301. One of the plurality of steel plate path movement amount estimation results calculated by is selected and output to the nozzle position control unit 103 included in the control unit 101.

FIG. 14 shows the configuration of the steel plate path movement amount estimation unit 1401. The steel plate path movement amount estimation unit 1401 which is an example of the steel plate path movement amount estimation unit 1301 includes a first adjusting neural network 1402, a second adjusting neural network 1403, and a third adjusting neural network 1404. .. The first adjusting neural net 1402 is composed of a first neural net 1405 and a first error calculating neural net 1406, and the output of the first neural net 1405 is output from the output of the first neural net 1405. The value obtained by subtracting is output as the steel plate path movement amount. The deviation amount input to the first neural network 1405 is only the plate thickness change amount, and 0 is input to the corresponding input neuron of the first error calculation neural network 1406. In addition, the same state quantity as in the second embodiment is input to the first neural network 1405 and the first error calculation neural network 1406. Similarly, the second adjusting neural network 1403 is composed of a second neural network 1407 and a second error calculating neural net 1408. The output of the second neural network 1407 produces a second error calculating neural network. A value obtained by subtracting the output of 1408 is output as the steel plate path movement amount. The deviation amount input to the second neural network 1407 is only the tension change amount, and 0 is input to the input neuron of the second error calculation neural network 1408 corresponding to this. In addition, the same state quantity as in the second embodiment is input to the second neural net 1407 and the second error calculating neural net 1408. Further, the third adjusting neural network 1404 is composed of a third neural network 1409 and a third error calculating neural network 1410. The output of the third neural network 1409 is used to output the third error calculating neural network 1410. The value obtained by subtracting the output is output as the steel plate path movement amount. The deviation amount input to the third neural network 1409 is only the roll position change amount in the bath, and 0 is input to the input neuron of the third error calculation neural network 1410 corresponding to this. In addition, the same state quantity as in the second embodiment is input to the third neural net 1409 and the third error calculating neural net 1410. As described above, the steel plate path movement amount estimation unit 1301 calculates the steel plate path movement amount corresponding to each of the plate thickness change amount, the tension change amount, and the bath roll position change amount. The result is output to the steel plate path movement amount estimation result selection unit 1302.

In FIG. 13, the processes and configurations of the learning database constructing unit 110 and the learning database 111 are the same as those in the first embodiment, but the learning unit 1303 uses the first adjusting neural network 1402 and the second adjusting neural net 1402. Each of the Sting neural network 1403 and the third adjusting neural network 1404 has a function of individually learning. As the learning method, for example, the method disclosed in Japanese Patent Laid-Open No. 8-63203 may be used.

FIG. 15 shows the processing executed by the steel plate path movement amount estimation result selection unit 1302. In S15-1, the respective determination results of the welding point passage determination unit 106, the tension change determination unit 107, and the bath roll operation determination unit 108 are fetched, and which deviation amount has changed is determined as the activation factor. When it is determined that the activation factor is passing through the welding point, the process proceeds to S15-2, and the steel plate path movement amount calculated by the first adjusting neural net 1402 is selected and output to the control unit 101. When it is determined that the activation factor is a change in tension, the process proceeds to S15-3, and the steel plate path movement amount calculated by the second adjusting neural network 1403 is selected and output to the control unit 101. Further, when it is determined that the activation factor is the roll operation in the bath, the process proceeds to S15-4, and the steel plate path movement amount calculated by the third adjusting neural net 1404 is selected and output to the control unit 101. In this way, an adjusting neural network is provided for each deviation amount, and the adjusting neural network is selected and used according to the activation factor.

According to the present embodiment, by constructing an individual adjusting neural network for each of the deviation amounts, the configuration of each adjusting neural network is simplified, so that the learning becomes easy and after the learning converges. The learning error of can be reduced. As a result, it is possible to improve the estimation accuracy of the steel plate path movement amount corresponding to each deviation amount.

In the coating amount control device 100 of the first embodiment described above, the welding point passage determination unit 106 that determines the welding point passage, the tension change determination unit 107 that determines the tension change, and the in-bath roll are operated. Judging bath roll operation determination unit 108, activated by the determination results of these determination units, at each activation timing, the steel plate path movement amount estimation unit 105 for estimating the movement amount of the steel plate path position, for realizing the target adhesion amount In addition to the nozzle position opening/closing control, a nozzle position control unit 103 having a function of shifting the front nozzle position and the back nozzle position in accordance with the movement amount of the steel sheet path position estimated by the steel sheet path movement amount estimation unit 105 was provided. ..
Further, the steel plate path movement amount estimation unit 105 is configured by a neural network, and a learning database construction unit 110 that selects and edits data for learning the neural network from various data acquired from the plating plant 150, is edited. A learning database 111 for accumulating the acquired data, and a learning unit 112 for learning the neural network using the data of the learning database 111 are provided.

In the plating adhesion amount control apparatus 100 of the second embodiment, the neural net of the steel plate path movement amount estimation unit 105 further outputs the subtraction result of the two neural nets described in Japanese Patent No. 3040901 (Adjusting The neural net 1202) is configured so that the deviations to be input are the thickness difference between the current steel plate and the next steel plate, the tension difference before and after the tension change, and the position change amount before and after the roll operation in the bath. The conventional adjusting neural network is described in detail in "Configuration and Learning Method of Adjusting Neural Network for Performing Model Tuning with High Precision" (The Institute of Electrical Engineers of Japan, D, Vol. 115, No. 4, 1995). ..

It can be widely applied to the control of the coating amount in the steel processing line.

100 coating amount control device 101 control unit 102 nozzle pressure control unit 103 nozzle position control unit 104 plating deposition amount prediction model 105 steel plate path moving amount estimation unit 106 welding point passage determination unit 107 tension change determination unit 108 bath roll operation determination unit 110 Learning Database Constructing Unit 111 Learning Database 112 Learning Unit 140 Upper Computer 150 Plating Plant 151 Steel Plate 153 Nozzle 155 Plating Adhesion Detector 156 Welding Point 1202 Adjusting Neural Network 1203 Neural Net 1204 Neural Net for Error Calculation 1302 Steel Plate Path Movement Quantity estimation result selection section

Claims (16)

Immerse the steel plate continuously sent in the bath of the hot dip plating bath, attach the hot dip plating bath to the steel plate, and after pulling up from the bath, gas from the front nozzle and the back nozzle provided on the front and back of the steel plate to the steel plate In a plating adhesion control device for controlling a plating plant that sprays a hot-dip plating bath having a desired thickness on the steel plate by removing the hot-dip galvanizing bath that is excessively adhered,
Plate speed, nozzle pressure, distance between nozzle and steel plate, and plating adhesion amount prediction model describing the relationship between the amount of plating adhered to the steel plate,
A control unit that controls at least one of the nozzle pressure and the nozzle position, so that the plating adhesion amount adhered to the steel sheet with reference to the plating adhesion amount prediction model becomes a desired value,
When switching the plate thickness of the steel plate through a welding point which is a joint between the steel plates, the tension of the steel plate, and when at least one of the positions of the rolls in the bath supporting the steel plate in the bath changes, Estimating the amount of movement of the steel sheet path position which is the passing position at the nozzle height of the steel sheet, and comprising a steel sheet path movement amount estimation unit for outputting to the control unit,
The steel plate path movement amount estimation unit receives at least one of a deviation amount consisting of a change amount of plate thickness, a change amount of tension, and a movement amount of a roll position in the bath, and further relates to the relationship between the deviation amount and the steel plate path movement amount. It is composed of a neural net that inputs the state quantity consisting of the thickness of the steel sheet, the steel type of the steel sheet, the tension applied to the steel sheet, and the position of the roll in the bath that influences, and outputs the movement amount of the steel sheet path. Characteristic plating amount control device. A welding point passage determination unit that determines that the welding point has passed a specific position of the plating plant,
A tension change determination unit that determines that the tension of the steel sheet has changed,
Equipped with at least one or more bath roll operation determination unit for determining that the roll in the bath has been operated,
The steel sheet path movement amount estimation unit is activated according to the determination result of any of the welding point passage determination unit, the tension change determination unit, and the bath roll operation determination unit, and estimates the movement amount of the steel sheet path position. The plating amount control device according to claim 1. The steel plate path movement amount estimation unit has the neural network and an error calculation neural network that has the same configuration as this neural network and that inputs zero to the neuron to which the deviation amount is input instead of the deviation amount. The adjusting neural network is provided, and the adjusting neural network outputs a value obtained by subtracting the output of the error calculating neural network from the output of the neural network as a steel plate path movement amount. The plating amount control device according to claim 1 or claim 2. The control unit includes a nozzle position control unit that controls the nozzle position,
The nozzle position control unit may move the positions of the front nozzle and the back nozzle in parallel to the changing direction of the steel plate path position by a value corresponding to the movement amount of the steel plate path position output by the steel plate path moving amount estimation unit. ,
The plating amount control device according to any one of claims 1 to 3. From the plating plant, the pressure and position of the front nozzle and the back nozzle, the plate thickness of the steel plate, the tension, the moving speed, the actual value of the amount of plating adhered on the front and back of the steel plate, the position of the bath roll, the deviation is taken in. While storing separately the amount and the state amount, the distance between the front nozzle and the steel plate front side calculated by inputting a signal including the front side plating adhesion amount of the steel plate, the front nozzle pressure and the plate speed into the adhesion amount prediction model. Estimated value, the backside plating adhesion amount of the steel plate, the back nozzle pressure and the estimated value of the distance between the back nozzle and the steel plate back side calculated by inputting the plate speed into the adhesion amount prediction model, the position of the front nozzle, and the back nozzle The steel plate path position is estimated and stored from the position, and the steel plate path movement amount, which is the change amount when the steel plate path position changes, and the corresponding combination of the deviation amount and the state amount are edited as a data pair. And a learning database construction section
A learning database that stores and saves a pair of data edited by the learning database construction unit,
Learning means for causing the neural network to learn the relationship between the combination of the deviation amount and the state amount and the steel plate path movement amount by successively presenting pairs of data stored in the learning database to the neural network. The plating deposition amount control device according to claim 1, 2, or 4, characterized in that. The steel plate path movement amount estimation unit has the neural network and an error calculation neural network that has the same configuration as this neural network and that inputs zero to the neuron to which the deviation amount is input instead of the deviation amount. Comprising an adjusting neural network, the adjusting neural network outputs a value obtained by subtracting the output of the error calculating neural network from the output of the neural network as a steel plate path movement amount,
By presenting the pair of data stored in the learning database to the adjusting neural network one after another, the relationship between the combination of the deviation amount and the state amount and the steel plate path moving amount is presented to the adjusting neural network. The plating amount control device according to claim 5, further comprising a learning means for learning. The steel sheet path movement amount estimation unit inputs the variation amount of the sheet thickness as a deviation amount, further inputs the sheet thickness, the steel type, the tension, the position of the roll in the bath as the state amount, and outputs the steel sheet path movement amount. Second adjustment that inputs the change amount of tension as deviation amount, and further inputs the plate thickness, steel type, tension, position of roll in bath as state amount, and outputs the steel plate path movement amount A third adjusting that inputs the movement amount of the roll position in the bath as a deviation amount and further inputs the plate thickness, steel type, tension, and the position of the roll in the bath as the state amount, and outputs the steel plate path movement amount. The plating deposit amount control device according to claim 1, further comprising at least two neural nets. The plating amount control device,
A welding point passage determination unit that determines that a welding point that is a joint between the steel sheets has passed a specific position of the plating plant,
A tension change determination unit that determines that the tension of the steel sheet has changed,
Equipped with at least one or more bath roll operation determination unit for determining that the roll in the bath has been operated,
The steel sheet path movement amount estimation unit is started according to the determination result of any of the welding point passage determination unit, the tension change determination unit, and the bath roll operation determination unit, and estimates the movement amount of the steel sheet path position,
The control unit includes a nozzle position control unit that controls the nozzle position,
The nozzle position control unit, the value corresponding to the amount of movement of the steel sheet path position output by the steel sheet path movement amount estimation unit, the position of the front nozzle and the back nozzle is moved in parallel to the changing direction of the steel sheet path position,
The plating amount control device,
The determination results of the welding point passage determination unit, the tension change determination unit, and the bath roll operation determination unit are used as activation factors, and the steel plate path movement amount output by the first adjusting neural network and the second adjustment amount are output. A steel plate path movement amount estimation result selection unit for selecting one from the steel plate path movement amount output by the Sting neural network and the steel plate path movement amount output by the third adjusting neural network;
The steel sheet path movement amount estimation result selection unit selects the steel sheet path movement amount output by the first adjusting neural network when the determination result of the welding point passage determination unit is an activation factor, and the tension change determination unit When the determination result of is the activation factor, the steel plate path movement amount output by the second adjusting neural network is selected, and when the determination result of the bath roll operation determination unit is the activation factor, the third adjustment is performed. Select the steel plate path movement amount output by the neural network, output to the nozzle position control unit,
The nozzle position control unit may move the positions of the front nozzle and the back nozzle in parallel to the moving direction of the steel plate path position by a value corresponding to the moving amount of the steel plate path position output by the steel plate path moving amount estimation unit. ,
The plating adhesion amount control device according to claim 7, characterized in that. Immerse the steel plate continuously sent in the bath of the hot dip plating bath, attach the hot dip plating bath to the steel plate, and after pulling up from the bath, gas from the front nozzle and the back nozzle provided on the front and back of the steel plate to the steel plate Is a method for controlling the amount of plating applied, which involves applying a hot-dip bath having a desired thickness to a steel sheet by removing the hot-dip galvanizing bath that is excessively adhered,
The plating adhesion amount control device includes a plating adhesion amount prediction model, a control unit, and a steel plate path movement amount estimation unit,
The plating adhesion amount prediction model describes the relationship between the plate speed, the nozzle pressure, the distance between the nozzle and the steel plate, and the plating adhesion amount that adheres to the steel plate,
The control unit controls at least one of the nozzle pressure and the nozzle position so that the coating amount attached to the steel sheet with reference to the coating amount prediction model becomes a desired value,
The steel plate path movement amount estimation unit is a plate thickness switching of the steel plate through a welding point which is a joint between the steel plates, the tension of the steel plate, and the position of the in-bath roll that supports the steel plate in the bath. Of at least one of the changes, the amount of movement of the steel plate path position, which is the passage position at the nozzle height of the steel plate, is estimated and output to the control unit,
The steel plate path movement amount estimation unit receives at least one of a deviation amount consisting of a change amount of plate thickness, a change amount of tension, and a movement amount of a roll position in the bath, and further relates to the relationship between the deviation amount and the steel plate path movement amount. It is composed of a neural net that inputs the state quantity consisting of the thickness of the steel sheet, the steel type of the steel sheet, the tension applied to the steel sheet, and the position of the roll in the bath that influences, and outputs the movement amount of the steel sheet path. A characteristic method of controlling the amount of plating deposited. The plating amount control device,
A welding point passage determination unit that determines that the welding point has passed a specific position of the plating plant,
A tension change determination unit that determines that the tension of the steel sheet has changed,
Equipped with at least one or more bath roll operation determination unit for determining that the roll in the bath has been operated,
The steel sheet path movement amount estimation unit is activated according to the determination result of any of the welding point passage determination unit, the tension change determination unit, and the bath roll operation determination unit, and estimates the movement amount of the steel sheet path position. The method according to claim 9, wherein the coating amount control method is performed. The steel plate path movement amount estimation unit has the neural network and an error calculation neural network that has the same configuration as this neural network and that inputs zero to the neuron to which the deviation amount is input instead of the deviation amount. The adjusting neural network is provided, and the adjusting neural network outputs a value obtained by subtracting the output of the error calculating neural network from the output of the neural network as a steel plate path movement amount. The method according to claim 9 or 10, wherein the coating amount control is performed. The control unit includes a nozzle position control unit that controls the nozzle position,
The nozzle position control unit may move the positions of the front nozzle and the back nozzle in parallel to the changing direction of the steel plate path position by a value corresponding to the movement amount of the steel plate path position output by the steel plate path moving amount estimation unit. ,
12. The method for controlling the amount of plating adhered according to claim 9, wherein: The plating amount control device includes a learning database construction unit, a learning database, and a learning unit,
The learning database construction unit, the pressure and position of the front nozzle and the back nozzle from the plating plant, the plate thickness of the steel plate, the tension, the moving speed, the actual value of the amount of front and back plating adhered to the steel plate, in the bath A table calculated by inputting the position of the roll, separating and storing the deviation amount and the state amount, and inputting a signal including the front side plating adhesion amount of the steel plate, the table nozzle pressure, and the plate speed to the adhesion amount prediction model. Estimated value of the distance between the nozzle and the steel plate front side, estimated value of the distance between the back nozzle and the steel plate back side calculated by inputting the backside plating adhesion amount of the steel plate, the back nozzle pressure and the plate speed into the adhesion amount prediction model, and the table The steel plate path position is estimated and stored from the position of the nozzle and the position of the back nozzle, and the steel plate path movement amount that is the change amount when the steel plate path position changes, and the corresponding deviation amount and state amount Edit the combination of as a data pair,
The learning database stores and stores a pair of data edited by the learning database construction unit,
The learning means successively presents pairs of data stored in the learning database to the neural net, and thereby the neural network has a relation between the combination of the deviation amount and the state amount and the steel plate path movement amount. The method according to claim 9, 10, or 12, wherein the plating amount control method according to claim 9 is learned. The steel plate path movement amount estimation unit has the neural network and an error calculation neural network that has the same configuration as this neural network and that inputs zero to the neuron to which the deviation amount is input instead of the deviation amount. Comprising an adjusting neural network, the adjusting neural network outputs a value obtained by subtracting the output of the error calculating neural network from the output of the neural network as a steel plate path movement amount,
By presenting the pair of data stored in the learning database to the adjusting neural network one after another, the relationship between the combination of the deviation amount and the state amount and the steel plate path moving amount is presented to the adjusting neural network. The plating amount control method according to claim 13, further comprising a learning means for learning. The steel sheet path movement amount estimation unit inputs the variation amount of the sheet thickness as a deviation amount, further inputs the sheet thickness, the steel type, the tension, the position of the roll in the bath as the state amount, and outputs the steel sheet path movement amount. Second adjustment that inputs the change amount of tension as deviation amount, and further inputs the plate thickness, steel type, tension, position of roll in bath as state amount, and outputs the steel plate path movement amount A third adjusting that inputs the movement amount of the roll position in the bath as a deviation amount and further inputs the plate thickness, steel type, tension, and the position of the roll in the bath as the state amount, and outputs the steel plate path movement amount. The plating deposition amount control method according to any one of claims 9 to 14, further comprising at least two neural nets. The plating amount control device,
A welding point passage determination unit that determines that a welding point that is a joint between the steel sheets has passed a specific position of the plating plant,
A tension change determination unit that determines that the tension of the steel sheet has changed,
Equipped with at least one or more bath roll operation determination unit for determining that the roll in the bath has been operated,
The steel sheet path movement amount estimation unit is started according to the determination result of any of the welding point passage determination unit, the tension change determination unit, and the bath roll operation determination unit, and estimates the movement amount of the steel sheet path position,
The control unit includes a nozzle position control unit that controls the nozzle position,
The nozzle position control unit, the value corresponding to the amount of movement of the steel sheet path position output by the steel sheet path movement amount estimation unit, the position of the front nozzle and the back nozzle is moved in parallel in the changing direction of the steel sheet path position,
The plating amount control device,
The determination results of the welding point passage determination unit, the tension change determination unit, and the bath roll operation determination unit are used as activation factors, and the steel plate path movement amount output by the first adjusting neural network and the second adjustment amount are output. A steel plate path movement amount estimation result selection unit for selecting one from the steel plate path movement amount output by the Sting neural network and the steel plate path movement amount output by the third adjusting neural network;
The steel sheet path movement amount estimation result selection unit selects the steel sheet path movement amount output by the first adjusting neural network when the determination result of the welding point passage determination unit is an activation factor, and the tension change determination unit When the determination result of is the activation factor, the steel plate path movement amount output by the second adjusting neural network is selected, and when the determination result of the bath roll operation determination unit is the activation factor, the third adjustment is performed. Select the steel plate path movement amount output by the neural network, output to the nozzle position control unit,
The nozzle position control unit may move the positions of the front nozzle and the back nozzle in parallel to the moving direction of the steel plate path position by a value corresponding to the moving amount of the steel plate path position output by the steel plate path moving amount estimation unit. ,
The method according to claim 15, wherein the coating weight control method comprises:

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