Fuel-fired burner with internal exhaust gas recycle

The invention claimed is: 1. A method, comprising: providing a fuel-fired burner comprising a burner housing having a fuel inlet coupled to a fuel pipe coupled to a burner nozzle secured to a burner mounting plate that has at least one recycle port, a combustion air inlet for receiving combustion air coupled to a combustion air nozzle positioned beginning at an input to a second chamber within the burner housing having an output spaced apart from a third chamber also within the second chamber, wherein the combustion air nozzle is configured to direct the combustion air into the third chamber, and a jet pump is located entirely inside the burner housing; directing the combustion air using a combustion air fan from the combustion air inlet through the combustion air nozzle; directing fuel through the fuel pipe to the burner nozzle to implement a combustion process that generates a flame originating at the burner nozzle which generates a hot exhaust gas, and operating the jet pump by flowing the combustion air through the combustion air nozzle with a sufficient velocity for creating an impulse that suctions in the hot exhaust gas through the recycle port into the second chamber then into a gas mixing zone extending from an output of the combustion air nozzle to an input end of the third chamber which mixes the hot exhaust gas suctioned in with the combustion air received from the combustion air nozzle, wherein an area ratio of the third chamber to the output of the combustion air nozzle is 1.2 to 3. 2. The method of claim 1 , wherein the jet pump comprises the combustion air nozzle as an input for the combustion air, with an exhaust gas path for receiving the hot exhaust gas positioned between outside of the third chamber and an inside of the second chamber. 3. The method of claim 1 , further comprising a burner discharge sleeve welded onto the burner mounting plate or onto the third chamber. 4. The method of claim 1 , wherein the recycle port comprises an annular shaped region. 5. The method of claim 2 , wherein the hot exhaust gas suctioned into the exhaust gas path is cooled by the combustion air passing over the outside of the second chamber, wherein the cooling of the hot exhaust gas transfers heat to the combustion air to heat the combustion air, which increases an overall thermal efficiency of the combustion process. 6. The method of claim 1 , further comprising using Computational Fluid Dynamics (CFD) simulation to determine at least one design parameter for the fuel-fired burner. 7. The method of claim 6 , wherein the at least one design parameter comprises a size of the recycle port and an orientation of the combustion air nozzle relative to the third chamber. 8. A fuel-fired burner, comprising: a burner housing; a combustion air inlet for receiving combustion air coupled to a combustion air nozzle; the combustion air nozzle positioned beginning at an input to a second chamber within the burner housing having an output spaced apart from a third chamber also within the second chamber, wherein the combustion air nozzle is configured to direct the combustion air into the third chamber; a fuel inlet coupled to a fuel pipe for receiving fuel coupled to a burner nozzle secured to a burner mounting plate that has at least one recycle port; an exhaust gas path for receiving hot exhaust gas from the recycle port, and a jet pump is located entirely inside the burner housing configured to receive the hot exhaust gas from the exhaust gas path, wherein the fuel-fired burner is configured for operating the jet pump by flowing the combustion air through the combustion air nozzle with a sufficient velocity for creating an impulse that suctions in the hot exhaust gas through the recycle port into the second chamber then into a gas mixing zone extending from an output of the combustion air nozzle to an input end of the third chamber which mixes the hot exhaust gas suctioned in with the combustion air received from the combustion air nozzle, wherein an area ratio of the third chamber to the output of the combustion air nozzle is 1.2 to 3. 9. The fuel-fired burner of claim 8 , wherein the jet pump comprises the combustion air nozzle as an input for the combustion air, with an exhaust gas path for receiving the hot exhaust gas positioned between outside of the third chamber and an inside of the second chamber. 10. The fuel-fired burner of claim 8 , further comprising a burner discharge sleeve welded onto the burner mounting plate or onto the third chamber. 11. The fuel-fired burner of claim 8 , wherein the recycle port comprises an annular shaped region. 12. The fuel-fired burner of claim 8 , wherein a size of the recycle port exclusively provides a passive control of the flowing of the hot exhaust flow gas into the jet pump. 13. The fuel-fired burner of claim 9 , wherein the hot exhaust gas suctioned into the exhaust gas path is cooled by the combustion air passing over the outside of the second chamber, wherein the cooling of the hot exhaust gas transfers heat to the combustion air to heat the combustion air, which increases an overall thermal efficiency of the combustion process. 14. The fuel-fired burner of claim 8 , further comprising using Computational Fluid Dynamics (CFD) simulation to determine at least one design parameter for the fuel-fired burner. 15. The fuel-fired burner of claim 14 , wherein the at least one design parameter comprises a size of the recycle port and an orientation of the combustion air nozzle relative to the third chamber. 16. The fuel-fired burner of claim 15 , wherein the size of the recycle port is designed to determine the amount of exhaust flowing into the exhaust gas path which is utilized by the jet pump. 17. The method of claim 1 , wherein a size of the recycle port exclusively provides a passive control of the flowing of the hot exhaust flow gas into the jet pump. 18. The method of claim 17 , wherein the size of the recycle port is designed to determine the amount of exhaust flowing into the exhaust gas path which is utilized by the jet pump.