Furnace combustion system and method

The invention claimed is: 1. A furnace system, comprising: a burner assembly configured to generate combustion products within a primary combustion zone comprising one or more burners; a panel disposed downstream of the burner assembly along a flow path for the combustion products, wherein the panel comprises at least one panel opening; and a secondary combustion air gap defined by one or more spacers disposed between the burner assembly and the panel, such that a secondary combustion zone is established between the burner assembly and the panel, wherein the secondary combustion air gap is downstream from and external to the burner assembly, wherein the burner assembly comprises a venturi plate and at least one of the one or more spacers is configured to contact the venturi plate, and wherein the secondary combustion air gap is disposed downstream of the venturi plate and upstream of the panel. 2. The furnace system of claim 1 , wherein the venturi plate comprises at least one venturi plate opening and the at least one venturi plate opening aligns with the at least one panel opening. 3. A furnace system, comprising: a burner assembly configured to generate combustion products in a primary combustion zone; a vestibule panel; and one or more spacers, wherein the one or more spacers are disposed between a first surface of the vestibule panel and a second surface of the burner assembly, wherein the first surface faces the second surface, wherein the one or more spacers are configured to establish a secondary combustion air gap between the first surface and the second surface and the secondary combustion air gap facilitates a secondary combustion zone downstream of the primary combustion zone, and wherein the burner assembly comprises a venturi plate and at least one of the one or more spacers is configured to contact the venturi plate. 4. The furnace system of claim 3 , comprising a heat exchanger, wherein the vestibule panel comprises one or more openings configured to align with one or more openings of the venturi plate and with one or more tubes of the heat exchanger. 5. A method of manufacturing a furnace system, the method comprising: positioning a panel downstream of a burner assembly within the furnace system to establish a flow path of combustion products from a primary combustion zone in the burner assembly through one or more panel openings in the panel; defining a secondary combustion zone downstream of the primary combustion zone along the flow path by disposing one or more spacers between the burner assembly and the panel, wherein the one or more spacers enable a secondary combustion air gap between the burner assembly and the panel; and integrally forming at least one of the one or more spacers with the panel. 6. The furnace system of claim 1 , comprising a tuning mechanism configured to actuate the one or more spacers to tune a thickness of the secondary air combustion gap. 7. The furnace system of claim 6 , wherein the tuning mechanism comprises a fastener, a crank, the one or more spacers, or any combination thereof. 8. The furnace system of claim 6 , comprising: a sensor configured to detect an operating parameter of the furnace system; and a controller configured to receive, from the sensor, data indicative of the operating parameter of the furnace system, wherein the controller is configured to control the tuning mechanism based on the data indicative of the operating parameter of the furnace system. 9. The furnace system of claim 8 , wherein the operating parameter comprises a temperature or an emissions content of the furnace system. 10. The furnace system of claim 1 , wherein the one or more spacers comprise a spacer structure having a first portion that contacts the panel and a second portion that contacts the burner assembly, wherein the first portion or the second portion comprises a plurality of grooves fluidly coupled with the secondary combustion air gap and an external environment such that the grooves enable a flow of oxidant from the external environment into the secondary combustion air gap. 11. A furnace system, comprising: a burner assembly configured to generate combustion products within a primary combustion zone comprising one or more burners; a panel disposed downstream of the burner assembly along a flow path for the combustion products, wherein the panel comprises at least one panel opening; and a secondary combustion air gap defined by one or more spacers disposed between the burner assembly and the panel, such that a secondary combustion zone is established between the burner assembly and the panel and/or downstream of the panel, wherein the secondary combustion air gap is downstream from and external to the burner assembly, wherein at least one of the one or more spacers is integrally formed with the panel and coupled to the burner assembly via a coupling device. 12. A furnace system, comprising: a burner assembly configured to generate combustion products within a primary combustion zone comprising one or more burners; a panel disposed downstream of the burner assembly along a flow path for the combustion products, wherein the panel comprises at least one panel opening; and a secondary combustion air gap defined by one or more spacers disposed between the burner assembly and the panel, such that a secondary combustion zone is established between the burner assembly and the panel and/or downstream of the panel, wherein the secondary combustion air gap is downstream from and external to the burner assembly, wherein at least one of the one or more spacers is integrally formed with the burner assembly and coupled to the panel via a coupling device. 13. A furnace system, comprising: a burner assembly configured to generate combustion products within a primary combustion zone comprising one or more burners; a panel disposed downstream of the burner assembly along a flow path for the combustion products, wherein the panel comprises at least one panel opening; and a secondary combustion air gap defined by one or more spacers disposed between the burner assembly and the panel, such that a secondary combustion zone is established between the burner assembly and the panel and/or downstream of the panel, wherein the secondary combustion air gap is downstream from and external to the burner assembly, wherein at least one of the one or more spacers is a separate component from the burner assembly and the panel and the at least one of the one or more spacers is coupled to the burner assembly and the panel via a coupling device. 14. A furnace system, comprising: a burner assembly configured to generate combustion products in a primary combustion zone; a vestibule panel; and one or more spacers, wherein the one or more spacers are disposed between a first surface of the vestibule panel and a second surface of the burner assembly, wherein the first surface faces the second surface, wherein the one or more spacers are configured to establish a secondary combustion air gap between the first surface and the second surface and the secondary combustion air gap facilitates a secondary combustion zone downstream of the primary combustion zone, and wherein at least one of the one or more spacers is coupled to the first surface of the vestibule panel via a coupling device. 15. A method of manufacturing a furnace system, the method comprising: positioning a panel downstream of a burner assembly within the furnace system to establish a flow path of combustion products from a primary combustion zone in the burner assembly through one or more panel openings in the panel; defining a secon