System and method for non-invasive power and data transmission

The invention claimed is: 1. A system, comprising: a flange configured to couple to a wellhead component of a mineral extraction system, comprising: a base of the flange; an exterior annular tapered portion extending from the base; an interior annular wall extending from the exterior annular tapered portion; and a central cavity base fixed to an axial end of the interior annular wall, wherein the interior annular wall and the central cavity base at least partially define a central exterior cavity exposed to an exterior of the wellhead component, and wherein the interior annular wall and the central cavity base at least partially define an interior annular cavity between the flange and the wellhead component; and an inductive power and data transmission system mounted within the flange, wherein the inductive power and data transmission system comprises a first component and a second component, wherein the first and second components are separated by the interior annular wall, and the first and second components axially overlap with one another relative to a central axis of the flange. 2. The system of claim 1 , wherein the first component comprises a first transformer core disposed within the central exterior cavity, and the second component comprises a second transformer core disposed within the interior annular cavity. 3. The system of claim 2 , wherein the first transformer core comprises: a first core body and a first magnetic coil wound about the first core body, the second transformer core comprises a second core body and a second magnetic coil wound within the second core body, and the first and second transformer cores are configured to inductively couple with one another. 4. The system of claim 1 , wherein the base, the exterior annular tapered portion, the interior annular wall, and the central cavity base are integrally formed as one piece. 5. The system of claim 1 , wherein the central exterior cavity and the interior annular cavity are generally coaxial and concentric with one another. 6. The system of claim 1 , wherein the flange is formed from a generally non-magnetic, low conductivity material. 7. The system of claim 6 , wherein the generally non-magnetic, low conductivity material comprises a nickel-chromium-based alloy. 8. The system of claim 1 , wherein the wellhead component comprises a side outlet extending from an exterior surface of the wellhead component to an annular region within the wellhead component, and wherein the flange is mounted over the side outlet. 9. The system of claim 8 , comprising a valve removal plug secured within the side outlet, wherein the valve removal plug comprises an integrated sensor configured to measure a wellhead operating parameter within the annular region, and wherein the integrated sensor is electrically coupled to the first component or the second component of the inductive power and data transmission system. 10. A method, comprising: flowing a first current through a primary magnetic coil of a first transformer core to generate a first magnetic field, wherein the first transformer core is disposed on a first side of a flange mounted to a wellhead component, and wherein the first transformer core is removable from the first side of the flange when the flange is mounted to the wellhead component; inducing a second current in a secondary magnetic coil of a second transformer core, wherein the second transformer core is disposed on a second side of the flange, wherein the second side of the flange and the wellhead component are in a sealing arrangement when the flange is mounted to the wellhead component; and powering a sensor disposed within a side outlet of the wellhead component with the second current. 11. The method of claim 10 , comprising generating the first current with a power supply and a primary side pulse width modulation drive circuit disposed on the first side of the flange, such that the first current comprises a sinusoidal waveform. 12. The method of claim 11 , comprising storing the second current in a capacitor of a secondary side pulse width modulation drive circuit disposed on the second side of the flange. 13. The method of claim 12 , comprising flowing a first return current through the secondary magnetic coil with the secondary side pulse width modulation drive circuit to generate a second magnetic field and induce a second return current in the primary magnetic coil, wherein the second return current comprises data from the sensor. 14. The method of claim 13 , comprising filtering the second return current with the primary side pulse width modulation drive circuit to extract the data from the sensor. 15. A wellhead system, comprising: a wellhead component, comprising a side outlet extending from an exterior of the wellhead component to a pressure containing region within the wellhead component; a flange mounted over the side outlet, wherein the flange comprises: a central exterior cavity exposed to the exterior of the wellhead component; and an inner annular cavity exposed to the side outlet of the wellhead component, wherein the central exterior cavity and the inner annular cavity are completely separated by an inner annular wall of the flange; and a power and data transmission system, comprising: a first transformer core disposed within the central exterior cavity; and a second transformer core disposed within the inner annular cavity, wherein the first and second transformer cores are configured to inductively couple to one another. 16. The wellhead system of claim 15 , wherein the first transformer core comprises a generally cylindrical core body comprising a first annular recess formed in the generally cylindrical core body and a first magnetic coil wound about the generally cylindrical core body and within the first annular recess, and wherein the second transformer core comprises an annular core body comprising a second annular recess formed in the annular core body and a second magnetic coil wound within the second annular recess. 17. The wellhead system of claim 15 , wherein the first transformer core is electrically coupled to a data acquisition system external to the wellhead component, and the second transformer core is electrically coupled to a valve removal plug secured within the side outlet. 18. The wellhead system of claim 17 , wherein the valve removal plug comprises an integrated sensor configured to measure an operating parameter within the pressure containing region. 19. The wellhead system of claim 15 , comprising a metal to metal ring gasket disposed between the wellhead component and the flange.