Method for treating a waste using a waste gasification melting furnace

The invention claimed is: 1. A method comprising, providing a waste gasification melting furnace comprising: a shaft portion configured to dry and pyrolyze wastes charged into the shaft portion, the shaft portion having a waste charging port and a furnace gas exhaust port provided on an upper side of the shaft portion and an opening on a bottom side of the shaft portion for discharging wastes; a melting furnace portion arranged in such a manner that a core of the melting furnace is shifted from a core of the shaft portion, the melting furnace portion having, on an upper side of the melting furnace, an opening through which pyrolyzed wastes and a carbon-based solid fuel are supplied, and having, on a furnace bottom side of the melting furnace, a tuyere through which oxygen-enriched air for combustion is blown into the melting furnace portion; and a communicated portion configured to connect between the bottom-side opening of the shaft portion and the upper-side opening of the melting furnace portion, wherein the communicated portion includes: a carbonizing grate portion disposed at a position where a load of the wastes charged in the shaft portion is received; a blower configured to blow air used for drying and pyrolysis into the shaft portion from the carbonizing grate portion; and a supply device configured to supply pyrolyzed wastes being on the carbonizing grate portion to the upper-side opening of the melting furnace portion, wherein the carbonizing grate portion includes: a supply carbonizing grate disposed on an upper-stage side of the carbonizing grate portion; and a dry distillation carbonizing grate disposed on a lower-stage side of the carbonizing grate portion, wherein the supply device includes: a first supply device for supplying wastes on the supply carbonizing grate toward the dry distillation carbonizing grate; and a second supply device for supplying carbonized wastes on the dry distillation carbonizing grate toward the melting furnace portion, wherein the first supply device and the second supply device are independent of each other, and wherein the shaft portion is provided directly above the supply carbonizing grate, and treating waste with the waste gasification melting furnace, wherein the waste gasification melting furnace facilitates drying and pyrolysis utilizing combustion heat from wastes themselves in the carbonizing grate portion, wherein the air for drying and pyrolysis is blown into the shaft portion from the carbonizing grate portion in such a manner that the air contains 60% or more of a total amount of oxygen to be blown into the furnace, wherein oxygen delivery supplied from the tuyere in the melting furnace portion is set to be less than 40% of the total amount of oxygen to be blown into the furnace, and wherein a supply rate (V 2 ) of the second supply device is set to be greater than a supply rate (V 1 ) of the first supply device (V 2 >V 1 ), and wherein, when a line connecting between the lower end of the shaft portion in the vicinity of the communicated portion and the front edge of the upper surface of the dry distillation carbonizing grate directly above the upper-side opening is defined as an imaginary line, a ratio of V 1 :V 2 is set to satisfy the condition that carbonized wastes on the dry distillation carbonizing grate have a surface profile closer to the dry distillation carbonizing grate than the imaginary line. 2. The method according to claim 1 , wherein the blower adjusts an amount of air to be blown into the furnace from the carbonizing grate portion in such a manner that a moisture content in wastes supplied from the carbonizing grate portion to the melting furnace portion is equal to or smaller than 10% and a remained amount of fixed carbons is equal to or greater than 3%. 3. The method according to claim 1 , wherein the supply rate of the supply device is controlled in such a manner that a waste charged height in the melting furnace portion is kept within a range between +0.5 m from the tuyere in an upward direction and a lowermost end of the carbonizing grate portion. 4. The method according to claim 1 , wherein the supply rate of the supply device is controlled in such a manner that a differential pressure between a pressure (P 1 ) in the melting furnace portion and a pressure (P 2 ) in a space above the carbonizing grate portion is kept within a range between 0.4 kPa and 2 kPa. 5. The method according to claim 1 , wherein the supply rate of the supply device is controlled in such a manner that a temperature in the carbonizing grate portion is kept within a range between 650° C. and 800° C. 6. The method according to claim 1 , wherein with a value obtained by dividing a theoretical combustion oxygen amount (M 1 ) of fixed carbons contained in the carbon-based solid fuel by a total oxygen amount (M 2 ) of the oxygen-enriched air to be blown into the melting furnace from the tuyere being defined as a melting furnace fuel ratio (M 1 /M 2 ), the melting furnace fuel ratio (M 1 /M 2 ) is set within a range between 0.8 and 1.2. 7. The method according to claim 1 , wherein one or more additional waste charging ports, used for changing a position at which charging wastes into the furnace is performed depending on a kind or property of wastes, are provided at a position different from the waste charging port disposed on the upper portion of the shaft portion. 8. The method according to claim 1 , wherein a carbonizing grate combustion rate in the carbonizing grate portion falls within a range between 300 kg/(m 2 ·h) and 500 kg/(m 2 ·h). 9. The method according to claim 1 , wherein the melting furnace portion has a cylindrical shape; an inverted truncated cone portion forming a narrowed portion is formed between the opening through which wastes from the carbonizing grate portion are supplied and the tuyere; and an inclination angle of the inverted truncated cone portion is greater than 75 degrees.