Selective heat treatment of metals using a coil-in-furnace system

What is claimed is: 1 . A heat treatment assembly comprising: a first heating source and a second heating source, the first heating source configured to be positioned relative to a first portion of a metal component, and the second heating source configured to be positioned relative to a second portion of the metal component; and wherein the first and second heating sources are configured and dimensioned to provide selective heat treatment to the first and second portions of the metal component in a single-step process; and wherein the first heating source is a furnace, and the second heating source is an induction heating coil; and wherein the first portion of the metal component comprises the entire portion of the metal component, and the second portion of the metal component comprises a partial portion of the metal component. 2 . The heat treatment assembly of claim 1 , wherein the first and second heating sources are independent of one another; and wherein the first heating source is in communication with a first power supply, and the second heating source is in communication with a second power supply. 3 . The heat treatment assembly of claim 1 , wherein the metal component is configured to be positioned within the furnace to heat the metal component, and the induction heating coil is configured to be positioned relative to the second portion of the metal component to provide a coil-in-furnace configuration. 4 . The heat treatment assembly of claim 1 , wherein the first and second heating sources are configured and dimensioned to provide selective heat treatment to the first and second portions of the metal component in a single-step process to achieve location specific microstructure and mechanical properties of the first and second portions of the metal component. 5 . The heat treatment assembly of claim 4 , wherein a hybrid modeling-test approach is utilized to achieve location specific microstructure and mechanical properties of the first and second portions of the metal component. 6 . The heat treatment assembly of claim 1 , wherein the first heating source is configured to heat the first portion of the metal component to a first temperature in the single-step process; and wherein the second heating source is configured to heat the second portion of the metal component to a second temperature in the single-step process. 7 . The heat treatment assembly of claim 6 , wherein the first temperature is different than the second temperature. 8 . The heat treatment assembly of claim 1 , wherein the metal component comprises a nickel-chromium alloy, and wherein the first heating source is configured to heat the first portion of the nickel-chromium alloy to a sub-solvus temperature in the single-step process; and wherein the second heating source is configured to heat the second portion of the nickel-chromium alloy to a super-solvus temperature in the single-step process. 9 . The heat treatment assembly of claim 1 , wherein the first and second heating sources are configured and dimensioned to provide selective heat treatment to the first and second portions of the metal component in a simultaneous single-step process. 10 . A method for selective heat treatment comprising: placing a first portion of a metal component in a first heating source; positioning a second heating source relative to a second portion of the metal component; and providing selective heat treatment to the first and second portions of the metal component, via the first and second heating sources, in a single-step process; wherein the first heating source is a furnace, and the second heating source is an induction heating coil; and wherein the first portion of the metal component comprises the entire portion of the metal component, and the second portion of the metal component comprises a partial portion of the metal component. 11 . The method of claim 10 , wherein the first and second heating sources are independent of one another; and wherein the first heating source is in communication with a first power supply, and the second heating source is in communication with a second power supply. 12 . The method of claim 10 , wherein the metal component is placed within the furnace to heat the metal component, and the induction heating coil is positioned relative to the second portion of the metal component to provide a coil-in-furnace configuration. 13 . The method of claim 10 , wherein providing selective heat treatment to the first and second portions of the metal component, via the first and second heating sources, in the single-step process achieves location specific microstructure and mechanical properties of the first and second portions of the metal component. 14 . The method of claim 13 further comprising utilizing a hybrid modeling-test approach to achieve location specific microstructure and mechanical properties of the first and second portions of the metal component. 15 . The method of claim 10 , wherein the first heating source heats the first portion of the metal component to a first temperature in the single-step process; and wherein the second heating source heats the second portion of the metal component to a second temperature in the single-step process. 16 . The method of claim 15 , wherein the first temperature is different than the second temperature. 17 . The method of claim 10 , wherein the metal component comprises a nickel-chromium alloy, and wherein the first heating source heats the first portion of the nickel-chromium alloy to a sub-solvus temperature in the single-step process; and wherein the second heating source heats the second portion of the nickel-chromium alloy to a super-solvus temperature in the single-step process. 18 . The method of claim 10 , wherein the first and second heating sources provide selective heat treatment to the first and second portions of the metal component in a simultaneous single-step process.