Startup and shutdown of cleanup engine and other components in a biomass conversion system

What is claimed is: 1. An integrated biomass conversion system for producing power from solid fuels, comprising: a syngas generator to form producer gas from solid fuels; a cleanup engine in communication with an outlet of the syngas generator to remove tar from the producer gas and create cleaned syngas; a power producing engine in communication with an outlet of the cleanup engine to generate power; a generator flare; a syngas flare actuator, in communication with the outlet of the syngas generator and the generator flare; a cleanup flare; a cleanup flare actuator, in communication with the outlet of the cleanup engine and the cleanup flare; a power engine fuel actuator disposed between the outlet from the cleanup engine and an inlet of the power producing engine; a cleanup air filter; a cleanup air actuator in communication with the cleanup air filter and an inlet of the cleanup engine; a power engine air filter; and a power engine air actuator in communication with the power engine air filter and the inlet of the power producing engine. 2. The integrated biomass conversion system of claim 1 , further comprising: a syngas generator temperature sensor, disposed in the syngas generator; a generator flare temperature sensor, disposed in the generator flare; and a cleanup flare temperature sensor, disposed in the cleanup flare. 3. The integrated biomass conversion system of claim 2 , further comprising a controller in communication with the syngas generator temperature sensor, the generator flare temperature sensor, the cleanup flare temperature sensor, the syngas flare actuator, the cleanup flare actuator, the cleanup air actuator, the power engine fuel actuator and the power engine air actuator. 4. The integrated biomass conversion system of claim 3 , wherein the controller performs a startup of the integrated biomass conversion system by monitoring the syngas generator temperature sensor, the generator flare temperature sensor and the cleanup flare temperature sensor and controlling the syngas flare actuator, the cleanup flare actuator, the cleanup air actuator, the power engine fuel actuator and the power engine air actuator. 5. The integrated biomass conversion system of claim 4 , wherein the controller comprises a non-transitory storage element, containing instructions, which when executed, enable the controller to: start up the syngas generator, while the cleanup engine and the power producing engine are turned off; start the cleanup engine after the syngas generator is fully operational; and start the power producing engine after the cleanup engine is fully operational. 6. The integrated biomass conversion system of claim 5 , wherein starting the cleanup engine comprises: monitoring a temperature of the syngas generator and a temperature of the producer gas in the generator flare; comparing the monitored temperature to a predetermined value; and when the monitored temperature reaches the predetermined value, closing the syngas flare actuator and opening the cleanup air actuator. 7. The integrated biomass conversion system of claim 6 , wherein starting the cleanup engine further comprises opening the cleanup flare actuator and closing the power engine fuel actuator when the monitored temperature reaches the predetermined value. 8. The integrated biomass conversion system of claim 5 , wherein starting the power producing engine comprises: monitoring a temperature of the cleaned syngas in the cleanup flare; comparing the monitored temperature to a predetermined value; and when the monitored temperature reaches the predetermined value, closing the cleanup flare actuator and opening the power engine fuel actuator. 9. The integrated biomass conversion system of claim 8 , wherein starting the power producing engine further comprises: monitoring a temperature of a coolant in the cleanup engine; comparing the monitored coolant temperature to a predetermined value; and when the monitored coolant temperature reaches the predetermined value, closing the cleanup flare actuator and opening the power engine fuel actuator. 10. The integrated biomass conversion system of claim 3 , wherein the controller performs a shutdown of the integrated biomass conversion system by monitoring the syngas generator temperature sensor, the generator flare temperature sensor and the cleanup flare temperature sensor and controlling the syngas flare actuator, the cleanup flare actuator, the cleanup air actuator, the power engine fuel actuator and the power engine air actuator. 11. The integrated biomass conversion system of claim 10 , wherein the controller comprises a non-transitory storage element, containing instructions, which when executed, enable the controller to: stop the power producing engine and the cleanup engine while the syngas generator is operational; and stop the syngas generator after the power producing engine and the cleanup engine have stopped. 12. The integrated biomass conversion system of claim 11 , wherein a speed sensor is used to determine that the power producing engine and the cleanup engine have stopped. 13. The integrated biomass conversion system of claim 11 , wherein stopping the power producing engine and the cleanup engine comprises: closing the cleanup air actuator and closing the power engine fuel actuator. 14. The integrated biomass conversion system of claim 11 , wherein stopping the syngas generator comprises: opening the syngas flare actuator; and stopping a flow of solid fuel to the syngas generator. 15. The integrated biomass conversion system of claim 11 , further comprising: injecting a solvent into the cleanup engine after the syngas generator has stopped generating producer gas. 16. The integrated biomass conversion system of claim 15 , wherein a temperature in the generator flare is monitored using the generator flare temperature sensor to determine when the syngas generator has stopped generating producer gas. 17. A method of starting up the integrated biomass conversion system of claim 1 , comprising: starting up the syngas generator, while the cleanup engine and the power producing engine are turned off; starting the cleanup engine after the syngas generator is fully operational; and starting the power producing engine after the cleanup engine is fully operational. 18. The method of claim 17 , wherein the cleanup engine is warmed prior to being started. 19. The method of claim 18 , wherein the cleanup engine is warmed by passing exhaust from the generator flare through the cylinders of the cleanup engine. 20. The method of claim 18 , wherein heat from the generator flare is used to heat coolant for the cleanup engine. 21. The method of claim 18 , wherein the cleanup engine is operated at lean conditions at startup and heat from the generator flare is used to warm air entering the cleanup engine. 22. The method of claim 21 , wherein a spark plug is used during warmup and ignition timing is between 50° and 0° before top dead center. 23. The method of claim 18 , wherein solar energy is used to heat coolant for the cleanup engine. 24. The method of claim 17 , wherein starting the cleanup engine comprises: monitoring a temperature of the syngas generator and a temperature of the producer gas in the generator flare; comparing the monitored temperature to a predetermined value; and when the monitored temperature reaches the predetermined value, closing t