Adaptive range flow titration systems and methods with sample conditioning

What is claimed is: 1. An automated titration system comprising a sample source; a titrant source; a reaction manifold in fluid communication with the sample source and the titrant source for mixing a continuously flowing and refreshed sample stream containing an unknown concentration of an analyte with titrant; a sample pump being in fluid communication with the sample source and continuously pumping the continuously flowing and refreshed sample stream from the sample source through a sample stream inlet into the reaction manifold; a titrant pump in fluid communication with the titrant source and for pumping the titrant into the reaction manifold through a titrant inlet to contact a conditioned continuously flowing and refreshed sample stream; a source of a first conditioning reagent in fluid communication with a first conditioning reagent pump; a source of a second conditioning reagent in fluid communication with a second conditioning reagent pump; the first conditioning reagent pump being for pumping the first conditioning reagent into the reaction manifold to contact the continuously flowing and refreshed sample stream and the second conditioning reagent pump being for pumping the second conditioning reagent into the reaction manifold to contact the continuously flowing and refreshed sample stream, wherein the first conditioning reagent and the second conditioning reagent contact the sample stream to form the conditioned sample stream; a detector for detecting a titration endpoint of the reaction between the analyte and the titrant after contact between the titrant and sample stream in the reaction manifold; and a controller communicatively coupled to the sample pump, the titrant pump, the first conditioning reagent pump, the second conditioning reagent pump, and the detector, wherein the controller controls the sample pump to set a continuous flow rate of the continuously flowing and refreshed sample stream, controls the titrant pump to set the flow rate of the titrant, controls the first conditioning reagent pump to set a continuous flow rate of the first conditioning reagent, controls the second conditioning reagent pump to set a continuous flow rate of the second conditioning reagent, and receives data from the detector to detect a titration endpoint for the reaction between the analyte and the titrant and determine the analyte concentration. 2. The automated titration system of claim 1 , wherein the reaction manifold comprises a liquid mixer downstream from the titrant inlet and upstream from the detector. 3. The automated titration system of claim 2 , further comprising a conditioning manifold upstream from the reaction manifold and titrant inlet and downstream from the sample stream inlet, the first conditioning reagent inlet, and the second conditioning reagent inlet; wherein the conditioned continuously flowing and refreshed sample stream is formed in the conditioning manifold. 4. The automated titration system of claim 3 , wherein the conditioning manifold comprises a liquid mixer. 5. The automated titration system of claim 3 , wherein the conditioning manifold further comprises a mixing loop. 6. The automated titration system of claim 3 , wherein the first reagent conditioning pump pumps the first conditioning reagent into the conditioning manifold. 7. The automated titration system of claim 3 , wherein the second reagent conditioning pump pumps the second conditioning reagent into the conditioning manifold. 8. The automated titration system of claim 1 , wherein the sample pump has a maximum flow rate and a minimum flow rate, and the controller controls the sample pump to adjust the flow rate of the continuously flowing and refreshed sample stream to a flow rate greater than or equal to the minimum flow rate and to a flow rate less than or equal to the maximum flow rate of the sample pump. 9. The automated titration system of claim 8 , wherein the titrant pump has a maximum flow rate and a minimum flow rate, and the controller controls the titrant pump to adjust the flow rate of the titrant to the minimum flow rate and to the maximum flow rate of the titrant pump. 10. The automated titration system of claim 1 , wherein the detector is a light-based detector, an electrochemically-based detector, a biologically-based detector, or a combination thereof. 11. The automated titration system of claim 10 , wherein the detector is an oxidation-reduction potential probe, an amperometric probe, an optical sensor, an electrical resistivity probe, or a combination thereof. 12. The automated titration system of claim 11 , wherein the detector comprises an optical sensor. 13. The automated titration system of claim 1 , wherein the first conditioning reagent is a metal iodide and the second conditioning reagent is an indicator. 14. The automated titration system of claim 1 , further comprising a second titrant source and a second titrant pump in fluid communication with the second titrant source for pumping the second titrant into the reaction manifold through a second titrant inlet to contact the conditioned continuously flowing and refreshed sample stream, wherein the controller controls the second titrant pump to set a second titrant flow rate. 15. The automated titration system of claim 14 , wherein titrant source and the second titrant source have different concentrations of the same titrant. 16. The automated titration system of claim 15 , wherein the titrant source has a titrant concentration that is about 10 times greater than a concentration of the second titrant source. 17. The automated titration system of claim 15 , wherein the controller controls the titrant pump and the second titrant pump so that at each time during the titration, at least one of the titrant pump and the second titrant pump is controlled by the controller to have a continuous flow rate. 18. A method for quantification of a target analyte concentration in a sample stream comprising: continuously flowing and continuously refreshing the sample stream at a variable flow rate through an analyzer comprising a reaction manifold, a conditioning manifold, and a detector, wherein the conditioning manifold is upstream from the reaction manifold; contacting the continuously flowing and continuously refreshing the sample stream with a first conditioning reagent and a second conditioning reagent by continuously adding the first conditioning reagent and the second conditioning reagent to the conditioning manifold to form a conditioned sample stream; quantifying the target analyte concentration by continuously adding a titrant at a titrant concentration to the conditioned sample stream and setting a titrant concentration change by changing the titrant concentration through increasing or decreasing a flow rate of the titrant over a specified range; and detecting a titration endpoint for the reaction between the target analyte and the titrant within a specified target analyte concentration range. 19. The method of claim 18 , further comprising continuously adding the first conditioning reagent and the second conditioning reagent to the sample stream in a concentration proportional to the target analyte concentration. 20. The method of claim 18 , wherein the first conditioning reagent is a metal iodide and the second conditioning reagent is an indicator.