Burner, method for operating burner, and method for melting and refining cold iron source

The invention claimed is: 1. A burner including a combustion supporting gas supply passage which is configured to supply a combustion supporting gas toward a combustion supporting gas ejection outlet provided at the center of a tip end side; a fuel supply passage which is configured to supply a fuel toward a fuel ejection outlet provided around the combustion supporting gas ejection outlet; and a protective nozzle provided from a position surrounding a periphery of the fuel ejection outlet so as to project forward beyond a tip end surface at which the combustion supporting gas ejection outlet and the fuel ejection outlet are provided; wherein the combustion supporting gas supply passage includes a Laval nozzle, and a diameter-enlarged nozzle of which a diameter increases from a tip end of the Laval nozzle toward the combustion supporting gas ejection outlet, and the protective nozzle has a shape which is gradually reduced in diameter forward from the tip end surface, and wherein when assuming a maximum diameter of the diameter-enlarged nozzle is d 3 [m], a diameter at a tip end of the protective nozzle is d 4 [m], and a flow rate of the fuel required to combust at a stoichiometric ratio (oxygen ratio=1) with respect to a flow rate of the combustion supporting gas supplied is Q f [Nm 3 /h], d 3 and d 4 are set such that a flow rate V[Nm/s] of the fuel obtained by dividing Q f by an area A, which is obtained by subtracting an area of an outlet of the diameter-enlarged nozzle from an area of an outlet of the protective nozzle obtained by the following formula (1), satisfy 50≤V≤200 V=(Q f /3600)/A   (1) A=π/ 4×( d 4 2 −d 3 2 ). 2. The burner according to claim 1 , wherein the combustion supporting gas supply passage includes a diameter-equal nozzle of which a diameter from a tip end of the diameter-enlarged nozzle to the combustion supporting gas ejection outlet is the same. 3. The burner according to claim 2 , wherein a groove is provided on the entire inner circumferential surface of the diameter-equal nozzle. 4. The burner according to claim 1 , wherein assuming that the cross-sectional area having the largest diameter at a tip end side in the diameter-enlarged nozzle is A 1 , and the cross-sectional area having the smallest diameter at a proximal end side is A 2 , A 1 and A 2 satisfy 1.5≤A 1 /A 2 ≤3.0. 5. The burner according to claim 1 , wherein an opening angle of the diameter-enlarged nozzle is equal to or larger than an opening angle of the Laval nozzle, and a half apex angle of the diameter-enlarged nozzle is 30° or less. 6. The burner according to claim 1 , wherein the fuel ejection outlet includes a plurality of holes arranged concentrically with the combustion supporting gas ejection outlet. 7. The burner according to claim 1 , wherein the fuel ejection outlet includes a hole concentrically formed with the combustion supporting gas ejection outlet. 8. The burner according to claim 1 , wherein the half apex angle of the protective nozzle is in a range of 5° to 45°. 9. A method for operating a burner according to claim 1 , wherein oxygen having a concentration of 20.95% to 100% is used as the combustion supporting gas. 10. The method for operating a burner according to claim 9 , wherein a flow rate of the fuel ejected from the fuel ejection outlet is 10 m/s or more. 11. The method for operating a burner according to claim 9 , wherein an oxygen ratio is in a range of 1 to 10. 12. A method for melting and refining a cold iron source using a burner according to claim 1 , wherein the method includes a melting step in which the cold iron source is molten, and a refining step in which the cold iron source is refined after the melting step, an oxygen ratio is adjusted in a range of 1 to 5 in the melting step, the oxygen ratio is adjusted in a range of 3 to 10 in the refining step, and a flow rate of the fuel is adjusted independently in the melting step and the refining step.