Method for refining molten steel in vacuum degassing equipment

The invention claimed is: 1. A method for refining molten steel in vacuum degassing equipment, the method comprising: throwing a powder and a carrier gas toward a bath surface of molten steel in a vacuum vessel of the vacuum degassing equipment through a central hole, the central hole being disposed at a central portion of a top blowing lance that is vertically movable in the vacuum vessel; and supplying a hydrocarbon gas from a fuel ejection hole disposed on a periphery of the central hole and supplying an oxygen-containing gas from an oxygen-containing gas ejection hole disposed on the periphery of the central hole, such that the powder falls on the molten steel while being heated with a flame formed by combustion of the hydrocarbon gas at a leading end of the top blowing lance, wherein: a lance height of the top blowing lance is 1.0 to 7.0 m, the lance height being a distance between a static surface of the bath surface and the leading end during the throwing of the powder, a dynamic pressure P of a jet flow ejected from the top blowing lance is calculated from equations (1) to (5) below such that P is 20.0 kPa or more and 100.0 kPa or less, P=ρ g ×U 2 /2  (1) ρ g =ρ A ×F A /F T +ρ B ×F B /F T +ρ C ×F C /F T +V P /( F T /60)  (2) U =( F T /S T )×(1/3600)  (3) S T =S A +S B +S C   (4) F T =F A +F B +F C   (5) where, in the equations (1) to (5), P is the dynamic pressure (kPa) of the jet flow at an exit of the top blowing lance, ρ g is the density (kg/Nm 3 ) of the jet flow, ρ A is the density (kg/Nm 3 ) of the carrier gas, ρ B is the density (kg/Nm 3 ) of the oxygen-containing gas, ρ C is the density (kg/Nm 3 ) of the hydrocarbon gas, V P is the supply rate (kg/min) of the powder, U is the velocity (m/sec) of the jet flow at the exit of the top blowing lance, S T is the total of the sectional areas (m 2 ) of the central hole, the fuel ejection hole and the oxygen-containing gas ejection hole at the exit of the top blowing lance, S A is the sectional area (m 2 ) of the central hole at the exit of the top blowing lance, S B is the sectional area (m 2 ) of the oxygen-containing gas ejection hole at the exit of the top blowing lance, S C is the sectional area (m 2 ) of the fuel ejection hole at the exit of the top blowing lance, F T is the total of the flow rates (Nm 3 /h) of the carrier gas, the oxygen-containing gas and the hydrocarbon gas, F A is the flow rate (Nm 3 /h) of the carrier gas, F B is the flow rate (Nm 3 /h) of the oxygen-containing gas, and F C is the flow rate (Nm 3 /h) of the hydrocarbon gas. 2. The method according to claim 1 , wherein the powder includes one or more of manganese ores, manganese ferroalloys and CaO-based desulfurization agents. 3. The method according to claim 1 , wherein a degree of vacuum in the vacuum vessel during the throwing of the powder is 2.7 to 13.3 kPa. 4. The method according to claim 2 , wherein a degree of vacuum in the vacuum vessel during the throwing of the powder is 2.7 to 13.3 kPa.