Oxygen burner and operation method for oxygen burner

The invention claimed is: 1. An oxygen burner having a triple pipe structure in which a center pipe, an inner pipe on an outer side of the center pipe, and an outer pipe on an outer side of the inner pipe are concentrically arranged, and comprising a primary oxygen flow path formed inside the center pipe, a fuel gas flow path formed between the center pipe and the inner pipe, and a secondary flow path formed between the inner pipe and the outer pipe, wherein the oxygen burner comprises a primary oxygen ejection port provided at a tip of the primary oxygen flow path, a plurality of fuel gas supply pipes provided so as to branch a tip end side of the fuel gas flow path, a fuel gas ejection port provided in each of the fuel gas supply pipes, and a secondary oxygen ejection port provided at a tip of the secondary oxygen flow path, the fuel gas ejecting ports are arranged so as to surround the primary oxygen ejection port, the secondary oxygen ejection port is arranged so as to surround the fuel gas ejection ports and the primary oxygen ejection port, and the fuel gas ejection ports are arranged on the same plane and protrude than a tip of the primary oxygen ejection port. 2. An operation method for an oxygen burner, wherein the flow velocity of the primary oxygen ejected from the primary oxygen ejection port is higher than the flow velocity of the fuel gas ejected from the fuel gas ejection ports in the oxygen burner according to claim 1 . 3. The operation method for an oxygen burner according to claim 2 , wherein the flow velocity of the fuel gas ejected from the fuel gas ejection ports is higher than the flow velocity of the secondary oxygen ejected from the secondary oxygen ejection port. 4. The operation method for an oxygen burner according to claim 2 , wherein a relationship between an oxygen flow rate A ejected from the primary oxygen ejection port, an oxygen flow rate B ejected from the secondary oxygen ejection port, and an oxygen flow rate C which is necessary for completely burning the fuel gas ejected from the fuel gas ejection ports is represented by the following formula (1): C /( A+B )≤1  (1). 5. The operation method for an oxygen burner according to claim 3 , wherein a relationship between an oxygen flow rate A ejected from the primary oxygen ejection port, an oxygen flow rate B ejected from the secondary oxygen ejection port, and an oxygen flow rate C which is necessary for completely burning the fuel gas ejected from the fuel gas ejection ports is represented by the following formula (1): C /( A+B )≤1  (1).