Glass melting furnace

The invention claimed is: 1. A glass melting furnace system, comprising: an oxy-combustion burner, a glass melting furnace, and an extraction device comprising a separation membrane, wherein the glass melting furnace is configured to convey oxygen immediately and directly to the oxy-combustion burner from the extraction device, and the extraction device comprises a ceramic separation membrane configured to separate oxygen from a gaseous mixture comprising oxygen at a temperature of 600-950° C. at a gaseous mixture pressure of not less than 1×10 6 Pa, the glass melting furnace system further comprising: an oxygen reservoir, a first heat exchanger, and a second heat exchanger, wherein the glass melting furnace system is configured to circulate combustion gases from the oxy-combustion burner and a fluid heat-exchange medium through the first heat exchanger, the second heat exchanger is configured to heat the gaseous mixture with the fluid heat-exchange medium, and the furnace is configured to regulate oxygen supply to the burners with the reservoir and configured to supply oxygen from the reservoir directly into the burner or in the immediate vicinity thereof by separate injection. 2. The glass melting furnace system of claim 1 , configured to control a flow rate of oxygen supplying the burner dependent at least partially on temperature, pressure, and flow rate of the gaseous mixture. 3. The glass melting furnace system of claim 1 , configured to determine a difference oxygen content of the gaseous mixture entering the extraction device and of the gaseous mixture after the ceramic separation membrane, thereby measuring a flux of oxygen separated from the gaseous mixture. 4. The glass melting furnace system of claim 3 , further comprising: a ceramic oxide electrode configured to measure residual oxygen content of the gaseous mixture after the ceramic separation membrane. 5. The glass melting furnace system of claim 1 , configured to supply oxygen from the reservoir to maintain the burner upon interruption of a supply of oxygen from the extraction device. 6. The glass melting furnace system of claim 1 , wherein the pressure of the gaseous mixture is from 1×10 6 Pa to 2×10 6 Pa. 7. The glass melting furnace system of claim 1 , further comprising a compressor configured to employ energy from combustion gases from the oxy-combustion burner to direct the gaseous mixture. 8. The glass melting furnace system of claim 4 , wherein the ceramic oxide electrode is a zirconium oxide-based electrode. 9. The glass melting furnace system of claim 1 , wherein the entire oxygen supply to the oxy-combustion burner flows directly from the extraction device. 10. The glass melting furnace system of claim 1 , wherein the extraction device is outside the glass melting furnace. 11. The glass melting furnace system of claim 1 , further comprising: a gaseous mixture passage, wherein the first heat exchanger is connected to an exhaust exit of the glass melting furnace and the gaseous mixture passage is in contact with or passes through the first heat exchanger to heat the gaseous mixture and pass the gaseous mixture to the extraction device.