Methods and systems for spillback control of in-line mixing of hydrocarbon liquids

What is claimed is: 1. An in-line fluid mixing system positioned at a tank farm to admix hydrocarbon liquids from a plurality of tanks into a single pipeline, the in-line fluid mixing system comprising: a first set of tanks positioned at a tank farm with at least one tank containing a hydrocarbon fluid therein, each tank in the first set of tanks connected to and in fluid communication with a first header, the first header configured to transport a flow of one or more hydrocarbon fluids from the first set of tanks as a first fluid; a second set of tanks positioned at the tank farm with at least one tank containing a hydrocarbon fluid therein, each tank in the second set of tanks connected to and in fluid communication with a second header, the second header configured to transport a flow of one or more hydrocarbon fluids from the second set of tanks as a second fluid; a first pump having an inlet and an outlet, the outlet of the first pump connected to a first booster pipe and the inlet of the first pump connected to the first header to increase pressure of hydrocarbon fluid flow therethrough; a first meter connected to the first booster pipe and configured to measure a first flow rate; a first spillback pipe having a first connection to the first booster pipe between the first meter and the first pump and a second connection to the first header upstream of the first set of tanks, the first spillback pipe including a first control valve disposed therein, the first control valve configured to adjust a flow rate of hydrocarbon flow through the first spillback pipe between the first booster pipe and the first header; a second pump having an inlet and an outlet, the outlet of the second pump connected to a second booster pipe and the inlet of the second pump connected to the second header to increase pressure of hydrocarbon fluid flow therethrough; a second spillback pipe having a first connection to the second booster pipe downstream of the second pump and a second connection to the second header upstream of the second set of tanks, the second spillback pipe including a second control valve disposed therein, the second control valve configured to adjust a flow rate of hydrocarbon flow through the second spillback pipe between the second booster pipe and the second header; a blend pipe configured to admix hydrocarbon fluid that flows from the first booster pipe downstream of the first meter with hydrocarbon fluid that flows through the second booster pipe downstream of the first connection of the second spillback pipe to create a blend flow; and a blend meter connected to the blend pipe that measures flow rate of the blend flow through the blend pipe. 2. The in-line fluid mixing system of claim 1 , wherein the first spillback pipe includes a first differential pressure transmitter (DPIT) positioned to measure differential pressure of hydrocarbon flow upstream and downstream of the first control valve and the second spillback pipe includes a second DPIT positioned to measure differential pressure of hydrocarbon flow upstream and downstream of the second control valve. 3. The in-line fluid mixing system of claim 2 , wherein differential pressure measured by the first DPIT is used to determine the flow rate of hydrocarbon flow through the first spillback pipe, and differential pressure measured by the second DPIT is used to determine the flow rate of hydrocarbon flow through the second spillback pipe. 4. The in-line fluid mixing system of claim 3 , further comprising one or more controllers in signal communication with each of the first control valve and the second control valve. 5. The in-line fluid mixing system of claim 4 , wherein the one or more controllers controls an open percentage of the first control valve to adjust the flow rate of the hydrocarbon flow through the first spillback pipe and thereby the first flow rate. 6. The in-line fluid mixing system of claim 4 , wherein the one or more controllers controls an open percentage of the second control valve to adjust the flow rate of hydrocarbon flow through the second spillback pipe and thereby a ratio of first flow rate to blend fluid flow rate. 7. The in-line fluid mixing system of claim 4 , wherein the one or more controllers adjusts the first control valve to drive the flow rate of the hydrocarbon flow through the first spill back pipe toward a first set point flow rate. 8. The in-line fluid mixing system of claim 4 , wherein the one or more controller adjusts the second control valve to drive the flow rate of the hydrocarbon flow through the first spill back pipe toward a second set point flow rate. 9. The in-line fluid mixing system of claim 4 , wherein the one or more controllers adjusts at least one of the first control valve or the second control valve to drive a ratio of first flow rate to blend fluid flow rate toward a set point. 10. A method of admixing hydrocarbon liquids from a plurality of sets of tanks into a single pipeline to provide in-line mixing thereof, the method comprising: initiating a blending process that includes blending two or more hydrocarbon liquids over a period of time, at least one of the two or more hydrocarbon liquids being stored in a tank of a first set of tanks and at least another of the two or more hydrocarbon liquids being stored in a tank of a second set of tanks, each tank of the first and second sets of tanks being connected, via one or more pipes, to a blend pipe that is configured to blend the two or more hydrocarbon liquids into a blended hydrocarbon liquid; determining a density of each of the two or more hydrocarbon liquids to be blended during the blending process; and upon initiation of the blending process: determining a first flow rate of hydrocarbon liquids flowing from the first set of tanks into the blend pipe; determining a blend flow rate of the blended hydrocarbon liquid in the blend pipe; determining a second flow rate of hydrocarbon liquids flowing from the second set of tanks into the blend pipe; determining a first spillback flow rate of a flow of hydrocarbon liquids from the first set of tanks that is recirculated in a first spillback loop positioned upstream of the blend pipe, the determining the first spillback flow rate being based on a function of at least density of the hydrocarbon liquids that flow from the first set of tanks and a differential pressure upstream and downstream of a first flow control valve disposed in the first spillback loop; determining a second spillback flow rate of a flow of hydrocarbon liquids from the second set of tanks that is recirculated in a second spillback loop positioned upstream of the blend pipe, the determining the second spillback flow rate based on a function of at least density of the hydrocarbon liquids that flow from the second set of tanks and a differential pressure upstream and downstream of a second flow control valve disposed in the second spillback loop; and in response to a difference between a target ratio and a ratio of the first flow rate and the second flow rate: determining ratio adjustments for the first flow rate relative to the second flow rate; and adjusting the first flow control valve based on the ratio adjustments to modify the first spillback flow rate thereby adjusting the first flow rate to drive the ratio towards the target ratio. 11. The method of claim 10 , wherein at least one of first flow rate or the second flow rate is determined based on the blend flow rate. 12. The method of claim 10 , wherein the flow of hydrocarbon liquids from the first set of tanks that is recirculated in the first spillback loop enters the first spillback loop downstream of a first pump and upstream of