Apparatus and method capable of monitoring and adjusting in-furnace combustion conditions in real time

The invention claimed is: 1. An apparatus configured for real-time monitoring and adjustment of combustion conditions in a furnace, comprising: a) a furnace having a heating chamber, a burner, a loading gate, an exhaust gas stream port and an exhaust gas stream duct, wherein the burner is configured for introducing a fuel and/or an oxygen-containing gas into the heating chamber so as to form a flame, the loading gate is used for adding a raw material, and a gas produced by combustion in the heating chamber enters the exhaust gas stream duct via the exhaust gas stream port; b) a first sensor and a second sensor of the same type arranged at different positions in the exhaust gas stream duct, and the first sensor is arranged close to the exhaust gas stream port, the second sensor is arranged 5-10 meters downstream of the first sensor, and the difference between the two sensor signals can be used to estimate an atmosphere state in the heating chamber and/or whether post-combustion occurs in the exhaust gas stream duct; c) a control device, for receiving signals of the two sensors, and adjusting the amount of fuel and/or oxygen-containing gas entering the burner according to the difference between the signals wherein both sensors are selected from flame sensors, pressure sensors, oxygen concentration sensors, carbon monoxide concentration sensors or carbon dioxide concentration sensors, wherein the exhaust gas stream duct is built of a refractory material by masonry, and air can enter the exhaust gas stream duct through gaps in the refractory material. 2. The apparatus as claimed in claim 1 , wherein the exhaust gas stream port is located on a chamber wall of the heating chamber, and a gap exists between the exhaust gas stream port and the exhaust gas stream duct. 3. A method for heating a raw material in the apparatus as claimed in claim 1 , comprising: a) introducing the fuel and/or the oxygen-containing gas into the heating chamber of the furnace via the burner, thereby forming the flame to heat the raw material, wherein the gas produced by combustion enters the exhaust gas stream duct via the exhaust gas stream port; b) introducing air into the exhaust gas stream duct; c) arranging the first sensor and the second sensor of the same type in the exhaust gas stream duct, wherein the first sensor is arranged close to the exhaust gas stream port, and the second sensor is arranged 5-10 meters downstream of the first sensor; transmitting signals of the two sensors to the control device, which adjusts the amount of fuel and/or oxygen-containing gas entering the burner according to the difference between the two sensor signals. 4. The method as claimed in claim 3 , wherein a portion of the air enters the exhaust gas stream duct through a gap between the exhaust gas stream port and the exhaust gas stream duct. 5. The method as claimed in claim 3 , wherein when the exhaust gas stream duct is built of a refractory material by masonry, and at least a portion of the air that enters the exhaust gas stream duct enters through gaps in the refractory material. 6. The method as claimed in claim 3 , wherein the raw material comprises any of iron-containing, copper-containing, aluminum-containing or other-metal-containing materials and/or any mixture thereof. 7. The method as claimed in claim 3 , wherein the raw material comprises waste. 8. The method as claimed in claim 3 , wherein the oxygen-containing gas contains at least 80% oxygen by mole percent. 9. The method as claimed in claim 3 , wherein the fuel comprises any of natural gas, other hydrocarbons, petroleum coke and/or any mixture thereof. 10. The method as claimed in claim 3 , wherein the furnace comprises a rotary furnace, a reverberatory furnace and/or a shaft furnace. 11. The method as claimed in claim 3 , wherein the combustion conditions in the furnace comprise: a) a reducing atmosphere when the actual content of oxygen in the furnace is less than the oxygen content theoretically required to achieve full combustion of combustible carbon-containing compounds in the furnace; or b) a neutral atmosphere when the actual content of oxygen in the furnace is approximately equal to the oxygen content theoretically required to achieve full combustion of combustible carbon-containing compounds in the furnace; or c) an oxidizing atmosphere when the actual content of oxygen in the furnace is higher than the oxygen content theoretically required to achieve full combustion of combustible carbon-containing compounds in the furnace. 12. The method as claimed in claim 11 , wherein when both sensors are flame sensors, a) if both flame sensors detect a flame, it is inferred that the atmosphere in the furnace is a reducing atmosphere; b) if the first flame sensor close to the exhaust gas stream port detects a flame at regular time intervals, but the second flame sensor remote from the exhaust gas stream port does not detect a flame, it is inferred that the atmosphere in the furnace is a neutral atmosphere; or c) if neither of the two flame sensors detects a flame, it is inferred that the atmosphere in the furnace is an oxidizing atmosphere. 13. The method as claimed in claim 11 , wherein when both sensors are pressure sensors, a) if the pressure detected by the first pressure sensor close to the exhaust gas stream port is approximately equal to the pressure detected by the second pressure sensor remote from the exhaust gas stream port, it is inferred that the atmosphere in the furnace is a neutral or oxidizing atmosphere; or b) if the pressure detected by the first pressure sensor close to the exhaust gas stream port is lower than the pressure detected by the second pressure sensor remote from the exhaust gas stream port, it is inferred that the atmosphere in the furnace is a reducing atmosphere. 14. The method as claimed in claim 11 , wherein when both sensors are oxygen concentration sensors, a) if the oxygen concentration detected by the first oxygen concentration sensor close to the exhaust gas stream port is lower than a theoretical value for a neutral atmosphere but higher than the oxygen concentration detected by the second oxygen concentration sensor remote from the exhaust gas stream port, it is inferred that the atmosphere in the furnace is a reducing atmosphere; b) if the oxygen concentration detected by the first oxygen concentration sensor close to the exhaust gas stream port is equal to the theoretical value for a neutral atmosphere, and slightly higher than the oxygen concentration detected by the second oxygen concentration sensor remote from the exhaust gas stream port, it is inferred that the atmosphere in the furnace is a neutral atmosphere and post-combustion occurs between the two oxygen concentration sensors; or c) if the oxygen concentrations detected by the two oxygen concentration sensors are both higher than the theoretical value for a neutral atmosphere, it is inferred that the atmosphere in the furnace is an oxidizing atmosphere. 15. The method as claimed in claim 11 , wherein when both sensors are carbon monoxide concentration sensors, a) if the carbon monoxide concentration detected by the first carbon monoxide concentration sensor close to the exhaust gas stream port is higher than the carbon monoxide concentration detected by the second carbon monoxide concentration sensor remote from the exhaust gas stream port, it is inferred that the atmosphere in the furnace is a reducing atmosphere; b) if the carbon monoxide concentration detected by the first carbon monoxide concentration sensor close to the exhaust gas stream port is equal to a theoretical