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An inductance-stable ultra high temperature circuit coupling transformer (50) used to transmit and receive alternating current power and/or data signals (29″, 33″). Primary (30″) and secondary (34″) windings are formed on nanostructured laminated (31′) primary and secondary steel cores (32″) having

An inductance-stable ultra high temperature circuit coupling transformer (50) used to transmit and receive alternating current power and/or data signals (29″, 33″). Primary (30″) and secondary (34″) windings are formed on nanostructured laminated (31′) primary and secondary steel cores (32″) having a Curie temperature exceeding an ultra high operating temperature. The operating range can extend from ambient to 250° C. or to in excess of 550° C. or up to 700° C. with a change in inductance of less than 10% in various embodiments.

대표청구항 ▼

1. A circuit coupling in a high temperature device with stable inductance throughout an operating temperature range between an ambient temperature and a maximum operating temperature ranging up to at least 500 degrees Celsius, the circuit coupling comprising: an air gap core transformer positioned f

1. A circuit coupling in a high temperature device with stable inductance throughout an operating temperature range between an ambient temperature and a maximum operating temperature ranging up to at least 500 degrees Celsius, the circuit coupling comprising: an air gap core transformer positioned for operation as a telemetry transformer in an operating environment characterized by the maximum operating temperature, and having a primary induction coil assembly and a secondary induction coil assembly in proximity to one another with an air gap distance there between, the transformer characterized by a total inductance less than 100 micro-H during operation at temperatures less than 150° C. and throughout the operating temperature range, wherein the total inductance varies less than ten percent over a range extending from less than 150° C. to at least 500° C.,the primary induction coil assembly comprising a solid primary core material, characterized by a Curie temperature which exceeds that of nanostructured steel, and a primary coil wound about the primary core material, which coil maintains electrical conductivity of itself and maintains electrical isolation from nearby conductors at temperatures in excess of the maximum operating temperature range, the primary coil comprising a metal having a melting point temperature which exceeds that of copper, andthe secondary induction coil assembly comprising a solid secondary core material characterized by a Curie temperature which exceeds that of nanostructured steel, and a secondary coil wound about the secondary core material, which coil maintains electrical conductivity and maintains electrical isolation from nearby conductors at temperatures in excess of the maximum operating temperature range, the secondary coil comprising a metal having a melting point temperature which exceeds that of copper, wherein the primary core material is not connected to the secondary core material. 2. The circuit coupling as in claim 1, wherein the maximum operating temperature ranges up to at least 700 degrees Celsius and wherein the total inductance varies less than ten percent over a range extending from less than 150° C. to at least 700 degrees Celsius. 3. The circuit coupling as in claim 1, wherein a first of the induction coil assemblies is affixed to a stationary component of the device and a second of the induction coil assemblies is affixed to a rotating component of the device which establishes the air gap distance there between periodically upon rotation of the rotating component. 4. The circuit coupling as in claim 3, wherein said rotating component comprises a blade in a gas turbine engine. 5. The circuit coupling as in claim 1, wherein the air gap core transformer is characterized by a total inductance less than 50 micro-H during operation at a temperature less than 150° C. 6. The circuit coupling as in claim 1, wherein the total inductance varies less than ten percent over a range extending from less than 150° C. to at least 550° C. 7. The circuit coupling as in claim 1, wherein at least one of the induction coil assemblies comprises a nanostructured iron alloy solid core comprising at least one of the elements Si, Co, B, C, La and Ni. 8. The circuit coupling as in claim 1, wherein at least one of the induction coil assemblies comprises a solid silicon steel core. 9. The circuit coupling as in claim 1 wherein at least one of the primary and secondary coils comprises a noble conductive wire. 10. The circuit coupling as in claim 1 wherein at least one of the primary and secondary coils comprises Ni-clad copper, Ni, NiCr, or Pt wire. 11. The circuit coupling as in claim 1 wherein at least one of the primary and secondary coils comprises conductive wire with a ceramic coating. 12. The circuit coupling as in claim 1 wherein at least one of the primary and secondary coils comprises a ceramic potting material. 13. In a gas turbine engine having first and second casing sections removably joined together along a joint during operation of the engine, a circuit coupling comprising: a transformer having a primary side comprising a primary core and a secondary side comprising secondary core, the transformer providing stable inductance throughout an operating temperature range between a temperature less than 150° C. and a maximum operating temperature ranging up to at least 250° C., the transformer characterized by a total inductance less than 100 micro-H during operation at the temperature less than 150° C. wherein the total inductance varies less than ten percent over a range extending from less than 150° C. to at least 500° C.,the primary side of the transformer attached to the first casing section proximate the joint and susceptible to exposure to a range of temperatures from less than 150° C. to an operating temperature greater than 250° C. within the engine and the secondary side of the transformer attached to the second casing section proximate the joint and proximate the primary side of the transformer and susceptible to exposure to a maximum operating temperature greater than 250° C., wherein:the primary core and the secondary core of the transformer each comprise a material having a Curie temperature exceeding that of nanostructured steel, and the primary core is not connected to the secondary core. 14. The gas turbine engine of claim 13 wherein the transformer is characterized by a total inductance less than 50 micro-H during operation at a temperature less than 150° C. 15. The gas turbine engine of claim 13 wherein the transformer is characterized by a total inductance which remains stable within 10% of the total inductance in an operating temperature range extending up to at least 550° C. 16. The gas turbine engine of claim 13 wherein the material of the primary and secondary cores of the transformer having a Curie temperature exceeding that of nanostructured steel comprises silicon steel.