Rolling mill, and method for setting rolling mill

The invention claimed is: 1. A rolling mill of four-high or more that includes a plurality of rolls including at least a pair of work rolls and a pair of backup rolls supporting the work rolls, in which any one roll among respective rolls arranged in a vertical direction is adopted as a reference roll, comprising: a load detector which, at a rolling support point position on a work side and a drive side of the backup rolls, detects a vertical roll load that acts in the vertical direction of the backup rolls; a pressing apparatus which, with respect to at least roll chocks of the rolls other than the reference roll, is provided on either one of an entrance side and an exit side in a rolling direction of a workpiece, the pressing apparatus pressing the roll chocks in the rolling direction; a driving apparatus, including a hydraulic cylinder, which, with respect to the roll chocks of the rolls other than the reference roll, is provided so as to face the pressing apparatus in the rolling direction, the driving apparatus moving the roll chocks in the rolling direction; a vertical roll load difference calculation portion which calculates a vertical roll load difference between the vertical roll load detected by the load detector on the work side and the vertical roll load detected by the load detector on the drive side; and a position controller which fixes a rolling direction position of the roll chocks of the reference roll as a reference position, and drives the driving apparatus to control positions in the rolling direction of the roll chocks of the rolls other than the reference roll so that the calculated vertical roll load difference becomes a value within an allowable range. 2. The rolling mill according to claim 1 , wherein a roll located at a lowermost part or an uppermost part in the vertical direction among the plurality of rolls is adopted as the reference roll. 3. The rolling mill according to claim 2 , wherein the driving apparatus is the hydraulic cylinder comprising a roll chock position detection apparatus. 4. The rolling mill according to claim 2 , comprising: a bending apparatus that imparts a bending force to the rolls; wherein the position controller sets a roll gap between the work rolls in an open state, and imparts a bending force by means of the bending apparatus to the roll chocks on a side of the roll that is a position adjustment object. 5. The rolling mill according to claim 4 , wherein the driving apparatus is the hydraulic cylinder comprising a roll chock position detection apparatus. 6. The rolling mill according to claim 1 , comprising: a bending apparatus that imparts a bending force to the work rolls; wherein the position controller sets a roll gap between the work rolls in an open state, and imparts a bending force by means of the bending apparatus to the roll chocks on a side of the roll that is a position adjustment object. 7. The rolling mill according to claim 6 , wherein the driving apparatus is the hydraulic cylinder comprising a roll chock position detection apparatus. 8. The rolling mill according to claim 1 , wherein the driving apparatus is the hydraulic cylinder comprising a roll chock position detection apparatus. 9. A method for setting a rolling mill, the rolling mill being a rolling mill of four-high or more that includes a plurality of rolls including at least a pair of work rolls and a pair of backup rolls supporting the work rolls, and a load detector which, at a rolling support point position on a work side and a drive side of the backup rolls, detects a vertical roll load that acts in a vertical direction of the rolls; the method for setting a rolling mill being executed before reduction position zero point adjustment or before starting rolling, in which any one roll among respective rolls arranged in the vertical direction is adopted as a reference roll, the method comprising: calculating a vertical roll load difference that is a difference between a vertical roll load detected by the load detector on the work side and a vertical roll load detected by the load detector on the drive side; and fixing a rolling direction position of roll chocks of the reference roll as a reference position and moving roll chocks of the rolls other than the reference roll in a rolling direction of a workpiece to adjust positions of the roll chocks so that the vertical roll load difference becomes a value within an allowable range. 10. The method for setting a rolling mill according to claim 9 , wherein a roll located at a lowermost part or an uppermost part in the vertical direction among the plurality of rolls is adopted as the reference roll. 11. The method for setting a rolling mill according to claim 10 , the rolling mill being a four-high rolling mill, wherein: a plurality of rolls provided on an upper side in the vertical direction with respect to the workpiece are taken as an upper roll assembly, and a plurality of rolls provided on a lower side in the vertical direction with respect to the workpiece are taken as a lower roll assembly; the method including performing: a first step of setting a roll gap between the work rolls in an open state, and in a state in which a bending force is imparted by a bending apparatus to the roll chocks of the work rolls, with respect to each of the upper roll assembly and the lower roll assembly, adjusting positions of the roll chocks of the work roll and the roll chocks of the backup roll, and after finishing the first step, a second step of setting the work rolls in a kiss roll state, and adjusting positions of the roll chocks of the upper roll assembly and the lower roll assembly; wherein: the first step includes performing: a first reference value calculation step of causing the rolls to rotate in a predetermined rotational direction, and with respect to each of the upper roll assembly and the lower roll assembly, detecting a vertical roll load on the work side and on the drive side and calculating a first reference value based on a vertical roll load difference that is a difference between the vertical roll load on the work side and the vertical roll load on the drive side, a first control target value calculation step of reversing the rotational direction of the rolls, and with respect to each of the upper roll assembly and the lower roll assembly, detecting a vertical roll load on each of the work side and the drive side and calculating a first control target value based on a deviation between a vertical roll load difference that is a difference between the vertical roll load on the work side and the vertical roll load on the drive side and the first reference value, and a first adjustment step of moving the roll chocks of the work roll of a roll assembly on the reference roll side in the rolling direction or moving the roll chocks of the work roll or the backup roll of a roll assembly on an opposite side to the reference roll in the rolling direction to adjust positions of the roll chocks so that the vertical roll load difference becomes a value within an allowable range of the first control target value; and the second step includes setting the work rolls in a kiss roll state, and performing: a second reference value calculation step of causing the rolls to rotate in a predetermined rotational direction, and with respect to each of the upper roll assembly and the lower roll assembly, detecting a vertical roll load on the work side and on the drive side and calculating a second reference value based on a vertical roll load difference that is a difference between the vertical roll load on the work side and the vertical roll load on the drive side, a second control target value calculation st