Shearing method, shearing device, and shearing facility

The invention claimed is: 1. A shearing method for applying a shear force on a plate-shaped workpiece in a thickness direction to cut the workpiece using a shearing machine comprising a lower blade configured to be in contact with a lower side of the workpiece and an upper blade movable in the thickness direction of the workpiece relative to the lower blade, the upper blade facing the lower blade with a clearance, the clearance extending in a surface direction of the workpiece, the surface direction extending orthogonal to the thickness direction of the workpiece, the method comprising: bringing the lower blade into contact with the lower side of the workpiece; moving the upper blade in the thickness direction until the upper blade is in contact with an upper side of the workpiece while retaining the clearance; starting application of the shear force on the workpiece by moving the upper blade in contact with the upper side of the workpiece further in the thickness direction of the workpiece prior to a fractured surface being created on the workpiece; and producing an increase in the clearance by increasing the clearance in a stepwise manner depending on a relative movement distance between the upper blade and the lower blade in the thickness direction of the workpiece-after the upper blade is in contact with the upper side of the workpiece prior to the fractured surface being created. 2. The shearing method according to claim 1 , wherein the increase in the clearance occurs when the relative movement distance of the upper blade and the lower blade is 100% or less of a reference movement distance, and in the increase in the clearance the clearance is increased to a maximum value, the method further comprising determining the reference movement distance, wherein the reference movement distance is a relative movement distance of the upper blade and the lower blade in the thickness direction of an identical workpiece with the workpiece after the upper blade is in contact with the upper side of the identical workpiece prior to a second fractured surface being created on the identical workpiece with a clearance being fixed at the maximum value. 3. The shearing method according to claim 1 , wherein the increase in the clearance occurs when the relative movement distance of the upper blade and the lower blade is 80% or less of a reference movement distance, and in the increase in the clearance the clearance is increased to a maximum value, the method further comprising determining the reference movement distance, wherein the reference movement distance is a relative movement distance of the upper blade and the lower blade in the thickness direction of an identical workpiece with the workpiece after the upper blade is in contact with the upper side of the identical workpiece prior to a second fractured surface being created on the identical workpiece with a clearance being fixed at the maximum value. 4. The shearing method according to claim 1 , wherein the increase in the clearance occurs when the relative movement distance of the upper blade and the lower blade is 20% or more of a reference movement distance, and in the increase in the clearance the clearance is increased to a maximum value, the method further comprising determining the reference movement distance, wherein the reference movement distance is a relative movement distance of the upper blade and the lower blade in the thickness direction of an identical workpiece with the workpiece after the upper blade is in contact with the upper side of the identical workpiece prior to a second fractured surface being created on the identical workpiece with a clearance being fixed at the maximum value. 5. The shearing method according to claim 1 , wherein the workpiece is a steel sheet having a tensile strength of 270 MPa or more. 6. The shearing method according to claim 1 , wherein the workpiece is a steel sheet having a thickness ranging from 0.2 mm to 2 mm. 7. The shearing method according to claim 1 , wherein the shearing method is performed under a further condition: 5%≤ C/t≤ 20%, where “C” is the clearance between the lower blade and the upper blade in the surface direction, and “t” is a thickness of the workpiece.