Dual input water heater

What is claimed is: 1. A water heater system comprising: a tank for storing water; a flue assembly positioned within the tank and having an inlet end and an outlet end, the flue assembly adapted to transfer heat from flue gases within the flue assembly to water in the tank; a burner in fluid communication with the inlet end of the flue assembly and operable in at least a high input mode and a low input mode to deliver the flue gases to the flue assembly; an exhaust assembly including a fan and being in fluid communication with the outlet end of the flue assembly; a controller; and a sensor coupled to the controller, wherein the controller activates the burner in the high input mode or the low input mode based on an output reading of the sensor, and wherein the flue gases do not condense in the flue assembly when operating in the high input mode, and wherein the flue gases condense in the flue assembly when operating in the low input mode, and wherein operation of the fan reduces a temperature of the flue gases in the exhaust assembly to below a threshold temperature at least in the high input mode, the threshold temperature being a temperature rating of a construction material of the exhaust assembly. 2. The water heater system of claim 1 , wherein the burner is a power burner. 3. The water heater system of claim 1 , wherein the burner is an atmospheric burner. 4. The water heater system of claim 1 , wherein the controller operates the fan to rotate at a first speed when the burner is operating in the high input mode and at a second speed lower the first speed when the burner is operating in the low input mode. 5. The water heater system of claim 1 , wherein the sensor is one of a temperature sensor and a flow sensor, and wherein the controller operates the burner in the high input mode in response to the sensor indicating that a need for heating water in the tank cannot be met at the low input mode. 6. The water heater system of claim 1 , wherein the burner operates in the high input mode or the low input mode based on a performance draw of the water heater system determined by the controller. 7. The water heater system of claim 1 , wherein the fan is adapted to bias the flue gases in a direction from the flue assembly through the exhaust assembly in at least the low input mode. 8. The water heater system of claim 1 , wherein the temperature threshold is no greater than 158F, and wherein the controller operates the fan at a predetermined speed such that the temperature of the flue gases is reduced below the temperature threshold. 9. The water heater system of claim 1 , wherein the low input mode is below 40 kBTU/Hr and the high input mode is equal to or above 40 kBTU/Hr. 10. The water heater system of claim 1 , wherein the exhaust assembly includes a dilution air intake, and wherein the fan dilutes the flue gases with ambient air in the exhaust assembly at least in the high input mode. 11. The water heater system of claim 1 , wherein the fan introduces excessive air into the water heater system for reducing the temperature of the flue gases in the exhaust assembly in at least the high input mode. 12. The water heater system of claim 1 , wherein the exhaust assembly includes a venturi portion and the fan is positioned downstream of the venturi portion in the exhaust assembly, and wherein the venturi portion includes a dilution air intake configured to dilute the flue gases in the exhaust assembly with ambient air in at least the high input mode. 13. A water heater system comprising: a tank for storing water; a flue assembly positioned within the tank; a burner in fluid communication with the flue assembly and operable in at least a high input mode and a low input mode; a controller and a sensor coupled to the controller, wherein the controller activates the burner in the high input mode or the low input mode based on an output reading of the sensor; and an exhaust assembly in fluid communication with the flue assembly, the exhaust assembly including an outlet, a dilution air intake, and a fan having a negative pressure side and a positive pressure side, wherein the outlet is arranged on the positive pressure side of the fan and wherein the dilution air intake is arranged on the negative pressure side of the fan, wherein in the low input mode, flue gases from the burner condense in the flue assembly, and wherein in the high input mode, the flue gases do not condense in the flue assembly. 14. The water heater system of claim 13 , wherein the burner is a power burner. 15. The water heater system of claim 13 , wherein the burner is an atmospheric burner. 16. The water heater system of claim 13 , further comprising wherein the controller is configured to: determine, based at least partially on a signal received from the sensor, whether a heating requirement can be met using the low input mode; operate the burner in the high input mode and operate the fan at a first speed sufficient to draw a flow of dilution air into the exhaust assembly through the dilution air intake, upon determining that the heating requirement cannot be met using the low input mode; and operate the burner in the low-input mode and operate the fan at a second speed sufficient to prevent flue gas from escaping out of the exhaust assembly through the dilution air intake, upon determining that the heating requirement can be met using the low input mode. 17. The water heater of claim 13 , wherein the flue assembly fluidly communicates with the exhaust assembly on the negative pressure side of the fan. 18. The water heater of claim 13 , wherein the flue assembly fluidly communicates with the exhaust assembly on the positive pressure side of the fan. 19. The water heater of claim 13 , wherein at least a portion of the exhaust assembly is located underneath the tank.