Methods of control for management of hot fuel

We claim: 1 . A method of controlling a fuel supply system of a gas turbine engine, the fuel supply system comprising: a fuel delivery system including a fuel source, a plurality of fuel lines, and at least one fuel pump; a thermal management system comprising at least one heat exchanger in engagement with a first portion of the plurality of fuel lines and configured to increase a temperature of the fuel in the first portion of the plurality of fuel lines; a fuel manifold downstream of the thermal management system and in fluid communication with a second portion of the plurality of fuel lines, the first portion and the second portion being in fluid communication; three or more sensors positioned within at least one of the fuel manifold or the second portion of the plurality of fuel lines, the three or more sensors being configured to identify respective fuel parameters; a bypass system comprising: one or more valves upstream of the first portion of the plurality of fuel lines; and a third portion of the plurality of fuel lines that bypasses the thermal management system, the third portion of the plurality of fuel lines being in fluid communication with the second portion of the plurality of fuel lines; and a fuel control system that is configured to receive data from the three or more sensors indicative of the respective fuel parameters and send a signal to the bypass system to open or close the one or more valves of the bypass system based on the received data from the three or more sensors, wherein the three or more sensors comprise at least one temperature sensor and at least two pressure sensors and the fuel parameters comprise a temperature of the fuel and pressures of the fuel, and wherein the fuel control system is in communication with the fuel delivery system, the thermal management system, and the bypass system, and is configured to: determine a percentage of change of one or more of the fuel parameters, and adjust a temperature of the fuel and/or a pressure of the fuel, via communication with one or more of the fuel delivery system, the thermal management system, and the bypass system, if the percentage of change of the one or more of the fuel parameters exceeds a predetermined percentage of change of the one or more of the fuel parameters: the method comprising: delivering fuel from the fuel source through the plurality of fuel lines by the at least one fuel pump; determining the fuel parameters by obtaining data from the three or more sensors; determining a fuel flow through a nozzle by obtaining data from a flow rate sensor; determining a nozzle flow number based on the determined fuel flow through the nozzle and each of a fuel manifold pressure and a combustor pressure obtained from the three or more sensors; and calculating a percentage of change of the nozzle flow number and determining whether the calculated percentage of change of the nozzle flow number exceeds a predetermined percentage of change of the nozzle flow number; increasing or decreasing an amount of heat supplied to the fuel by the thermal management system when the calculated percentage of change of the nozzle flow number exceeds the predetermined percentage of change of the nozzle flow number. 2 . The method of claim 1 , further comprising: adjusting a differential pressure of a plurality of variable pressure nozzles if the determined percentage of change of the one or more of the fuel parameters exceeds the predetermined percentage of change of the one or more of the fuel parameters. 3 . The method of claim 1 , further comprising: storing a predetermined maximum allowable temperature and a predetermined minimum allowable density in a memory device of the fuel control system; and comparing the fuel parameters with the stored predetermined maximum allowable temperature and predetermined minimum allowable density; and bypassing the thermal management system when a result of the comparison indicates that a determined temperature of the fuel and/or a determined density of the fuel exceeds the predetermined maximum allowable temperature or the predetermined minimum allowable density, respectively. 4 . The method of claim 3 , wherein the predetermined minimum allowable density is between 70% and 95% of the density of the fuel as measured at 0° F. 5 . The method of claim 3 , wherein the predetermined minimum allowable density is between 80% and 95% of the density of the fuel as measured at 0° F. 6 . The method of claim 3 , wherein the predetermined minimum allowable density is between 80% and 88% of the density of the fuel as measured at 0° F. 7 . The method of claim 1 , wherein the predetermined percentage of change is 5% or greater. 8 . A gas turbine engine fuel supply system comprising: a fuel delivery system including a fuel source, a plurality of fuel lines, and at least one fuel pump; a thermal management system comprising at least one heat exchanger in engagement with a first portion of the plurality of fuel lines and configured to increase a temperature of the fuel in the first portion of the plurality of fuel lines; a fuel manifold downstream of the thermal management system and in fluid communication with a second portion of the plurality of fuel lines, the first portion and the second portion being in fluid communication; two or more sensors positioned within at least one of the fuel manifold or the second portion of the plurality of fuel lines, the two or more sensors being configured to identify respective fuel parameters; a bypass system comprising: one or more valves upstream of the first portion of the plurality of fuel lines; and a third portion of the plurality of fuel lines that bypasses the thermal management system, the third portion of the plurality of fuel lines being in fluid communication with the second portion of the plurality of fuel lines; and a fuel control system that is configured to receive data from the two or more sensors indicative of the respective fuel parameters and send a signal to the bypass system to open or close the one or more valves of the bypass system based on the received data from the two or more sensors, wherein the two or more sensors comprise at least one temperature sensor and at least one pressure sensor and the fuel parameters comprise a temperature of the fuel and a pressure of the fuel, and wherein the fuel control system is in communication with the fuel delivery system, the thermal management system, and the bypass system, and is configured to: determine a percentage of change of one or more of the fuel parameters, and adjust a temperature of the fuel and/or a pressure of the fuel, via communication with one or more of the fuel delivery system, the thermal management system, and the bypass system, if the percentage of change exceeds a predetermined percentage of change. 9 . The gas turbine engine fuel supply system of claim 8 , wherein the predetermined percentage of change is 5% or greater. 10 . The gas turbine engine fuel supply system of claim 8 , wherein the fuel control system is further configured to: calculate a nozzle flow number based on the received data from the two or more sensors; determine a percentage of change of the nozzle flow number; and adjust a temperature and/or a pressure of the fuel, via communication with one or more of the fuel delivery system, the thermal management system, and the bypass system, if the determined percentage of change of the nozzle flow number exceeds a predetermined percentage of change of the nozzle flow number. 11 . The gas turbine engine fuel supply system of claim 8 , wherein the fuel control system is further configured to: calculat