Fluid sensor cable assembly, system, and method

What is claimed is: 1. A fluid sensor cable assembly comprising: an internal core body having a length that is elongated from a first end to an opposite second end; a coating disposed around the internal core body; one or more conductive bodies extending along the length of the internal core body, the one or more conductive bodies configured to conduct an interrogation signal along the length of the internal core body, each of the one or more conductive bodies configured to conduct a heating current along the length of the internal core body to heat the fluid sensor cable assembly and conduct reflections of the interrogation signal as distributed phase measurement signals to a computer acquisition system; one or more slots formed in the coating; and one or more optical fibers extending along the length of the internal core body at a designated radial distance from a center axis of the internal core body, wherein the one or more optical fibers are disposed within the one or more slots, and wherein the one or more optical fibers including a plurality of temperature sensitive elements disposed at different locations along the length of the internal core body, the temperature sensitive elements configured to measure heat flux out of the fluid sensor cable assembly at the different locations along the length of the internal core body subsequent to heating the fluid sensor cable assembly by the one or more conductive bodies and communicate the heat flux that is measured via one or more optical fibers to the computer acquisition system. 2. The cable assembly of claim 1 , wherein the one or more optical fibers are disposed within a dielectric tube with a hydrogen scavenging gel or coated with one or more of carbon or a metal. 3. The cable assembly of claim 1 , wherein the temperature sensitive elements include fiber Bragg grating reflectors embedded within the one or more optical fibers. 4. The cable assembly of claim 1 , wherein the distributed phase measurement signals represent amounts of two or more of water, gas, or oil at one or more different distances along the length of the internal core body. 5. The cable assembly of claim 1 , wherein the heat flux that is measured at the different locations represents flow velocities of one or more fluids at the different locations along the length of the internal core body outside of the cable assembly. 6. The cable assembly of claim 1 , wherein the one or more conductive bodies include a single conductive coil helically wound around the internal core body that conducts the heating current and conducts the distributed phase measurement signals. 7. The cable assembly of claim 1 , further comprising a protective layer disposed outside of the one or more conductive bodies, the coating, and the one or more optical fibers. 8. A method comprising: conducting a distributed phase interrogation signal along one or more conductive bodies extending along an elongated core body of a fluid sensor cable assembly, wherein a coating is disposed around the elongated core body, and wherein one or more slots are formed in the coating; receiving distributed phase measurement signals along the one or more conductive bodies in response to conducting the interrogation signal, wherein the distributed phase measurement signals are reflected back along a conductive coil at different locations along a length of the fluid sensor cable assembly and represent an amount of one or more phases of a fluid flowing outside of the fluid sensor cable assembly; heating the fluid sensor cable assembly by conducting a heating current for a designated period of time along the one or more of the conductive bodies; and subsequent to heating the fluid sensor cable assembly, receiving temperature measurements from temperature sensitive elements in one or more optical fibers of the fluid sensor cable assembly at different locations along the length of the fluid sensor cable assembly, the temperature measurements representative of heat flux out of the fluid sensor cable assembly at the different locations, wherein the one or more optical fibers are disposed within the one or more slots, and wherein each of the one or more conductive bodies is configured to conduct the heating current and the distributed phase measurement signals. 9. The method of claim 8 , wherein heating the fluid sensor cable assembly includes alternating between conducting the heating current during a first time period and stopping conduction of the heating current for a subsequent, second time period during one or more heating iterations. 10. The method of claim 8 , further comprising determining a flow velocity of one or more fluids outside of the fluid sensor cable assembly based on the temperature measurements. 11. The method of claim 10 , wherein the flow velocity is determined based on one or more of a duration of a decrease in the temperature measurements, an integral of a waveform representative of the temperature measurements, or a magnitude of noise in the temperature measurements. 12. The method of claim 10 , further comprising determining an injection zone of a subterranean well in which the fluid cable sensor assembly is inserted based on noise in the temperature measurements. 13. The method of claim 8 , further comprising inserting the fluid sensor cable assembly into a subterranean well to obtain the temperature measurements and the amount of one or more phases of the fluid flowing outside of the fluid sensor cable assembly at different depths within the subterranean well. 14. The method of claim 8 , wherein receiving the temperature measurements includes receiving reflections of light along the one or more optical fibers from fiber Bragg grating reflectors disposed at the different locations along the length of the fluid sensor cable assembly. 15. The method of claim 8 , wherein the distributed phase measurement signals represent amounts of two or more of water, gas, or oil at one or more different distances along the length of the elongated core body. 16. A fluid sensor system comprising: one or more fluid sensor cable assemblies configured to be disposed in one or more subterranean wells, the one or more fluid sensor cable assemblies including an elongated internal core body, a coating disposed around the elongated internal core body, one or more slots formed in the coating, one or more optical fibers extending along a length of the one or more fluid sensor cable assemblies and having temperature sensitive elements, one or more conductive coils wrapped around the elongated internal core body along the length of the one or more fluid sensor cable assemblies, wherein the one or more optical fibers are disposed within the one or more slots; and a computer acquisition system configured to be operatively coupled with the one or more fluid sensor cable assemblies, the computer acquisition system configured to conduct, for at least one of the fluid sensor cable assemblies, a distributed phase interrogation signal along the one or more conductive coils and to receive distributed phase measurement signals conducted along the one or more conductive coils in response to conducting the interrogation signal, wherein the distributed phase measurement signals are reflected back along the one or more conductive coils at different locations along the length of the fluid sensor cable assembly and represent amounts of different phases of a fluid at the different locations, wherein the computer acquisition system also is configured to heat at least one fluid sensor cable assembly by conducting a heating current along at least one of the conducti