Meandering control method for hot-rolled steel strip, meandering control device, and hot rolling equipment

The invention claimed is: 1. A meandering control method for a hot-rolled steel strip, the method controlling meandering of the hot-rolled steel strip rolled in finish rolling equipment including n (n≥3) rolling machines each of the rolling machines having a load detector configured to detect rolling loads on an operation side and a driving side and a leveling device configured to adjust rolling amounts on the operation side and the driving side, the method comprising: a meandering amount measurement step of measuring a meandering amount of a traveling hot-rolled steel strip by a meandering amount measuring device installed between an i-th (i≥n) rolling machine and an (i−1)th rolling machine counting from a rolling machine installed on a most upstream side; a differential load detection step of detecting a differential load between the operation side and the driving side from the rolling loads on the operation side and the driving side detected by the load detector provided in the i-th rolling machine; and a leveling control computation step of computing a roll opening degree difference based on the meandering amount of the hot-rolled steel strip measured in the meandering amount measurement step and the differential load detected in the differential load detection step, the roll opening degree difference being an opening degree difference of roll gaps between the operation side and the driving side in the i-th rolling machine, and sending the computed roll opening degree difference to the leveling device provided in the i-th rolling machine, wherein the roll opening degree difference computed in the leveling control computation step, the roll opening degree difference being the opening degree difference of the roll gaps between the operation side and the driving side in the i-th rolling machine, satisfies the roll opening degree difference between the operation side and the driving side in the i-th rolling machine by Expressions (1), (2), and (3) in a control section j, when the control section j is set when a tail end portion of the traveling hot-rolled steel strip is present between a j-th (j≤i−1) rolling machine and a (j+1)th rolling machine counting from the rolling machine installed on the most upstream side, S=α j C (δ−δ j )+β j D (Δ P−ΔP j )+ S j   (1) 0≤α 1 ≤α 2 ≤ . . . ≤α j ≤ . . . ≤α i−1   (2) 0≤β 1 ≤β 2 ≤ . . . ≤β j ≤ . . . ≤β i−1   (3) wherein S is the roll opening degree difference between the operation side and the driving side in the i-th rolling machine, S j is the roll opening degree difference between the operation side and the driving side in the i-th rolling machine when the tail end portion of the hot-rolled steel strip has passed through the j-th rolling machine, α j is a control gain with respect to the meandering amount measured by the meandering amount measuring device, in the control section j, β j is a control gain with respect to the differential load detected from the load detector provided in the i-th rolling machine, in the control section j, δ j is the meandering amount measured by the meandering amount measuring device when the tail end portion of the hot-rolled steel strip has passed through the j-th rolling machine, δP j is the differential load detected from the load detector provided in the i-th rolling machine when the tail end portion of the hot-rolled steel strip has passed through the j-th rolling machine, δ is the meandering amount measured by the meandering amount measuring device, in the control section j, ΔP is the differential load detected from the load detector provided in the i-th rolling machine, in the control section j, C is a change amount of a leveling amount with respect to the meandering amount, and D is a constant determined by a roll diameter, a roll length, number of rolls or a width of a rolling material. 2. The method according to claim 1 , wherein the roll opening degree difference computed in the leveling control computation step, the roll opening degree difference being the opening degree difference of the roll gaps between the operation side and the driving side in the i-th rolling machine, satisfies the roll opening degree difference between the operation side and the driving side in the i-th rolling machine by Expression (4) in a control section i−1A, and satisfies the roll opening degree difference between the operation side and the driving side in the i-th rolling machine by Expression (5) in a control section i−1B, when the control section in a control section i−1 in which the meandering amount measuring device is installed is further divided into the control section i−1A when the tail end portion of the traveling hot-rolled steel strip is present between the (i−1)th rolling machine and the meandering amount measuring device, and the control section i−1B when the tail end portion is present between the meandering amount measuring device and the i-th rolling machine, S=α 1−1A (δ−δ i−1 )+β i−1A D (Δ P−ΔP i−i )+ S i−1   (4) wherein S is the roll opening degree difference between the operation side and the driving side in the i-th rolling machine, S i−1 is the roll opening degree difference between the operation side and the driving side in the i-th rolling machine when the tail end portion of the hot-rolled steel strip has passed through the (i−1)th rolling machine, α i−1 A is a control gain with respect to the meandering amount measured by the meandering amount measuring device, in the control section i−1A, β i−1A is a control gain with respect to the differential load detected from the load detector provided in the i-th rolling machine, in the control section i−1A, δ i−1 is the meandering amount measured by the meandering amount measuring device when the tail end portion of the hot-rolled steel strip has passed through the (i−1)th rolling machine, ΔP i−1 is the differential load detected from the load detector provided in the i-th rolling machine when the tail end portion of the hot-rolled steel strip has passed through the (i−1)th rolling machine, δ is the meandering amount measured by the meandering amount measuring device, in the control section i−1A, ΔP is the differential load detected from the load detector provided in the i-th rolling machine, in the control section i−1A, S=β i−B D (Δ P−ΔP i−1B )+ S i−1B   (5) wherein S is the roll opening degree difference between the operation side and the driving side in the i-th rolling machine, S i−1B is the roll opening degree difference between the operation side and the driving side in the i-th rolling machine when the tail end portion of the hot-rolled steel strip has passed through the meandering amount measuring device, β i−1B is a control gain with respect to the differential load detected from the load detector provided in the i-th rolling machine, in the control section i−1B, ΔP i−1B is the differential load detected from the load detector provided in the i-th rolling machine when the tail end portion of the hot-rolled steel strip has passed through the meandering amount measuring device, ΔP is the differential load detected from the load detector provided in the i-th rolling machine, in the control section i−1B. 3. The method according to claim 2 , wherein the meandering amount measuring device used in the meandering amount measurement step includes an edge position detecting device having an infrared camera configured to image intensity distribution of infrared rays emitted from a surface of the traveling hot-rolled steel strip and an edge position detection unit configured to detect edge positions of both end portions of the hot-rolled steel strip in a width direction from the intensity distribution of infrared rays imaged by the infrared camera, and a meandering amount calculating device configured to calculate the meandering amount of the hot-rolled steel strip based on the edg