TH50815B - Furnaces and processes for controlling the oxidation state of the melted material. - Google Patents

Abstract

DC60 (08/12/54) A useful approach to combustion. Oxy-fuel and in furnaces consisting of smelted materials, where both substoichiometric and superstoichiometric combustion and low-velocity injection of fuels and primary and secondary oxidants in the furnace Oxy-fuels are treated in an arrangement where they create both a reducing and oxidizing atmosphere near the annealed surface. Useful methods for burning Oxy-fuel and in furnaces consisting of melted material, where both substoichiometric and superscheometric combustion and low-velocity injection of fuels and primary and secondary oxidants in the furnace are removed. C-fuels are treated in an arrangement where they create both a reducing and near-oxidizing atmosphere on the annealed surface.

Claims (8)

Disclaimer (all) which will not appear on the advertisement page: edit 14/8/2015 1. A method for changing the oxidation state of the transition metal ion type in a furnace, where (I) the furnace is structured for continuous operation. And assembled with parts The filler end, the ejection tip, the melting zone adjacent to the filler tip and the fineing zone are in contact with the fluid with the discharge tip (II). Melt, move along a path From the melting zone to the fine zone And (iii) the furnace has a need for combustion energy in the combustion zone above both the melting zone and the fine standing zone. A method which includes (A) injection into the combustion area at the point above the molten glass. And the lower currents of the bach cover, fuel and primary oxidants in the flat flame structure and the substrate chiometric ratio of not less than approximately 50% of the stochiometric, exudate Sundant Genesis The landscape is a fluid consisting of at least 21 percent by moles of oxygen, both of the fuel and the primary oxidant, injected into the combustion area at approximately 1000 feet per second or less (B A) combustion of the fuel and primary oxidants within the combustion area to produce heat and produce combustion reactions including the unburned fuel (C), injection of secondary oxidants. Go into the combustion area in the injection structure placement Spray flat below the fuel injection point. And primary oxidant, the manner in which the oxidant The secondary is injected between the molten glass. And the fuel injection point And the primary oxidant, the secondary oxidant is a fluid comprising at least approximately 21 percent by moles of oxygen, at a standard velocity of approximately 2000 feet per second or less (D). Oxygen-rich gas close to molten glass, rich gas layer With oxygen with a higher oxygen concentration than molten glass (E), oxygen is transported from the oxygen-rich layer into the molten glass, in this way it drives the redox reaction of the molten metal ion type. At least one type of transition in Molten glass to oxidize the transition metal ion type and (F) the combustion of the secondary oxidant with the unburned fuel to provide additional heat and internal combustion reaction products. Kiln 2. Method of claim 1, where the molar flow ratio of oxygen in primary and secondary oxidants to fuel is superior to that required for complete combustion. 3. Method of claim 1 where either of the primary oxidant or the secondary oxidant, or both, is a fluid comprising at least 50 percent by moles of oxygen. 4. Method of claim 1, where the furnace includes a spring zone at the junction of two convection cells in molten glass and where oxygen-rich is formed near the spring zone. 5. Methods for reducing transition metal ions in molten glass in a furnace where (i) the furnace is structured for continuous operation. And assembled with parts The filler tip, the ejection tip, the melting zone adjacent to the filler tip and the firing zone adjacent to the discharge tip (ii) the glass-forming component is introduced into the melting zone. , Moving along a path From the melting zone to the fine zone And (iii) the furnace has a need for combustion energy in the combustion zone above both the melting zone and the fine standing zone. A method which includes (A) injection into the combustion area at the point above the molten glass. And the lower currents of the bach cover, fuel and primary oxidants in a stepwise flattened flame structure, and the substrate chiometric ratio does not exceed approximately 70 percent of the stochiometric. , The primary oxidant is a fluid containing at least 21 percent by moles of oxygen, both of the fuel. And primary oxidants injected into the combustion area at a speed of approximately 1000 feet per second or less (B) combustion of the fuel and primary oxidants within the furnace to produce heat and Produces combustion reactions that include unburned fuel (C), injection of secondary oxidants into the combustion area in the injection structure arrangement. Spray flat below the fuel injection point. And primary oxidant, the manner in which the injection point of the fuel and the primary oxidant is during the injection of the secondary oxidant and the molten glass, the secondary oxidant is the fluid which consists of Combined with at least about 21 percent by moles of oxygen, at a standard velocity of approximately 2000 feet per second or less (D), the formation of an oxygen-rich gas layer close to molten glass, a rich gas layer. With oxygen with a lower oxygen concentration than molten glass (E), oxygen is transported from the oxygen-rich layer into the molten glass, in this way it drives the redox reaction of the molten metal ion type. At least one type of transition in Molten glass to oxidize the transition metal ion type and (F) the combustion of the secondary oxidant with the unburned fuel to provide additional heat and internal combustion reaction products. Kiln 6. Method of claim 5, where the molar flow ratios of oxygen in primary and secondary oxidants to fuel are lower than required for complete combustion. 7. Method of claim 5 where either of the primary oxidant or the secondary oxidant, or both, is a fluid containing at least 50 percent by moles of oxygen. 8.The method of claim 5, where the furnace includes a spring zone at the junction of two convection cells in molten glass, and where oxygen-rich is formed near the spring zone. -------------------------------------------------- --------------- 1. Methods for combustion, consisting of: (A) injection into the furnace, where (i) the furnace consists of Insertion tip, ejection tip, melting zone Attached to the insertion tip and the fining zone In the contact of the fluid with the ejection tip; (ii) Glassmaking material is placed into the melting zone, traveling along the way from The melting zone to the finishing zone. And (iii) there will be a need for combustion energy throughout the melting zone and the fining zone; melt Which is injected at the point above the fused glass, the fuel and the primary oxidant in flatflame manner. And subsistochiometric ratio that is not less than about 50 percent of that of stoikiometric The primary oxidant is such a fluid that It contains at least 21 percent moles of oxygen. Both fuels and primary oxidants It will be injected into the furnace at a speed of approximately 1000 feet per second or less; (B) combustion fuels and primary oxidants within the furnace To produce heat and Products obtained from the combustion reaction include unreactive oxygen and non-reactive fuels. Is not burnt; (C) The secondary oxidant is injected into the furnace as a flat flame under the injection point of the fuel and primary oxidant. The secondary oxidant is such a fluid that It contains at least about 21 percent moles of oxygen. At a speed of approximately 2000 standard feet per second Or less; (D) Generation of an oxygen-rich gas layer near the molten glass. Gas-rich layer Such oxygen Will oxidize more with at least one serving Or with glass that has been melted Than the primary flow; and (E) Combustion of the secondary oxidant with the unburned fuel. To provide Additional heat And products from the combustion reaction within the furnace