Methods and systems for controlling the products of combustion

What is claimed is: 1. A combustion system, comprising: a high concentration carbon dioxide (CO 2 ) stream; at least one CO 2 flow regulation device configured to adjust an overall flow rate of the high concentration CO 2 stream and split the high concentration CO 2 stream into a primary diluent stream having a flow rate and a secondary diluent stream having a flow rate, wherein the at least one flow regulation device is further configured to adjust the primary diluent stream flow rate independently of the overall flow rate of the high concentration CO 2 stream; an oxygen supply stream having a flow rate; at least one oxygen flow regulation device configured to adjust the oxygen supply stream flow rate; a mixing device arranged to combine the primary diluent stream and the oxygen supply stream to form an oxygenation stream having a flow rate and an oxygen to CO 2 ratio; a combustion fuel stream having a flow rate and a composition; a combustor consisting of at least a primary combustion zone and a burnout zone, wherein the combustor is configured to mix and combust the oxygenation stream and the combustion fuel stream within the primary combustion zone at a flame temperature and a primary residence time sufficient to produce a hot products stream at about equilibrium conditions, and configured to dilute the hot products stream with the secondary diluent stream within the burnout zone to form a combustion products stream having a lower temperature than the hot products stream; an expansion device configured to expand the combustion products stream to form an expanded products stream having a lower temperature than the combustion products stream; a control system, comprising: a first controller configured to regulate the flow rate of the oxygen supply stream in proportion to the flow rate of the combustion fuel stream so as to produce substantially stoichiometric combustion in the primary combustion zone; a second controller configured to regulate the oxygen to CO 2 ratio of the oxygenation stream by controlling the primary diluent stream flow rate to produce a primary combustion zone flame temperature configured to provide: an adequate margin between a combustor average velocity, a blow-off limit of the combustor, and the primary residence time within the combustor sufficient to produce a combustion products stream at about equilibrium conditions; at least one temperature sensor operatively connected to the control system and the at least one CO 2 flow regulation device and configured to measure the temperature of the combustion products stream and send a signal to the control system, which is configured to adjust the secondary diluent stream flow rate based on the temperature of the combustion products stream to produce a desired temperature of the combustion products stream at some location after an exit of the combustion system; wherein the control system is configured to calculate a set point of the first controller required to produce substantially stoichiometric combustion in the primary combustion zone based upon a flow rate and a composition of the combustion fuel stream; and at least one load controller configured to control the flow rate of the combustion fuel stream to maintain a desired load condition in the expansion device. 2. The system of claim 1 , further comprising at least one oxygen sensor located in the expanded products stream at a location spaced from the exit of the expansion device configured to measure the amount of oxygen in the expanded products stream and send a signal to the control system, wherein the control system is further configured to use the amount of oxygen in the expanded products stream to determine if the combustion in the primary combustion zone is substantially stoichiometric. 3. The system of claim 1 , wherein the flow rate of the secondary diluent stream is controlled passively based on a pressure drop of at least one flow restriction in the flow path of the high concentration CO 2 stream and the secondary diluent stream. 4. The system of claim 1 , further comprising a central controller operatively connected to: the at least one temperature sensor; at least one flow rate device configured to measure the flow rate of the combustion fuel stream and send a signal to the control system; at least one flow composition device configured to determine the composition of the combustion fuel stream and send a signal to the control system; a first flow controller for controlling the primary diluent stream; a second flow controller for controlling the oxygen supply flow rate; a third flow controller for controlling the combustion fuel flow rate; and a fourth flow controller for controlling the secondary diluent stream. 5. The system of claim 4 , wherein the oxygenation stream comprises from at least about 5 volume percent oxygen to at least about 40 volume percent oxygen and the remaining portion of the oxygenation stream comprises from at least about 95 volume percent CO 2 to about 99.9 volume percent CO 2 . 6. The system of claim 4 , further comprising: a high quality fuel gas stream with a flow and a composition; and a low heating value fuel gas stream with a flow and composition; wherein the system is configured to combine the high quality fuel gas stream with the low heating value fuel gas stream to form the combustion fuel stream. 7. The system of claim 6 , further comprising: a fifth flow controller for controlling the high quality fuel gas stream; a sixth flow controller for controlling the low heating value fuel gas stream; and a summation controller operatively connected to the fifth and sixth flow controllers configured to control the flow and composition of the combustion fuel stream to regulate the temperature of combustion and avoid flame burnout. 8. The system of claim 7 , further comprising at least one hydrocarbon analyzer configured to measure the amount of hydrocarbons in the composition of the combustion products stream and operatively connected to at least the sixth flow controller to control the amount of low heating value fuel gas to avoid flame blowout in the combustor. 9. The system of claim 6 , further comprising a high concentration CO 2 makeup stream with a flow and composition configured to combine with the low heating value fuel gas stream and the high quality fuel gas stream to form the combustion fuel stream, wherein the high concentration CO 2 makeup stream is operatively connected to a seventh flow controller operatively connected to the summation controller configured to adjust the flow of each of the streams to generate a substantially constant flow and composition in the combustion fuel stream. 10. The system of claim 1 , wherein the combustion products stream is comprised substantially of water and carbon dioxide (CO 2 ) and the high concentration CO 2 stream is at least partially comprised of the CO 2 portion of the expanded products stream. 11. The system of claim 10 , wherein at least a portion of the CO 2 portion of the expanded products stream is utilized for enhanced oil recovery (EOR). 12. The system of claim 11 , further comprising a post-combustion catalysis apparatus configured to reduce the oxygen content in the combustion products stream prior to utilization for enhanced oil recovery (EOR). 13. The system of claim 12 , wherein the burnout zone comprises a feature selected from the group consisting of: a passive dilution zone having a series of holes configured to cool and quench a liner of the combustor; an active dilution zone having at least one quench port configured to actively deliver the secondary diluent to the combustor to mix