Induction heating using induction coils in series-parallel circuits

What is claimed is: 1. An induction heating method, comprising: selecting at least two induction coil circuits each including a susceptor having a Curie temperature; coupling the induction coil circuits in parallel with each other and each of the induction coil circuits in series with an AC power supply; tuning a resonant frequency of each of the induction coil circuits to match a frequency of the AC power supply; determining by a processor a power level provided to each induction coil circuits; shunting power away from one of the induction coil circuits to the other induction coil circuits, by detuning the circuit, when the susceptor of the one circuit substantially reaches its Curie temperature; and rebalancing with a controller the power applied by the AC power supply to the other induction coil circuits when power is shunted away from the circuit that has reached its Curie temperature, the power delivered to the other induction coil circuits during rebalancing being substantially equal. 2. The method of claim 1 , further comprising: tuning each of the induction coil circuits to substantially match the input resistance of the AC power supply and cancel the inductive reactance of the circuit, the tuning performed by adjusting a tuning capacitor. 3. The method of claim 2 , wherein the tuning includes using a transformer to scale the resistance of one of the induction coil circuits that has reached its Curie point to substantially match the resistance of the AC power supply. 4. A method of heating a part, comprising: providing multiple induction coil heating circuits, each of the circuits including an induction heating coil and a susceptor wherein the susceptor is magnetically coupled with the coil and has a preselected Curie point; electrically coupling the circuits in parallel with each other; placing the induction heating coils in proximity with the part; coupling an AC power supply in series with each of the circuits; using the AC power supply an alternating current the circuits; tuning the resonant frequency of each of the circuits to substantially cancel the inductive reactance of the circuit; shunting power away from one of the induction coil heating circuits to the other induction coil heating circuits, by detuning the circuit, when the susceptor of the one circuit substantially reaches its Curie temperature; rebalancing with a controller the power applied by the AC power supply to the induction coil heating circuits when the susceptor in at least one of the circuits reaches its Curie temperature, the power delivered to the other induction coil heating circuits devices during rebalancing being substantially equal. 5. The method of claim 4 , wherein the tuning is performed using a capacitor having a value that substantially cancels the inductive reactance of the circuit substantially at the Curie point. 6. The method of claim 4 , wherein the tuning is performed using a transformer to scale the resistance of each of the circuits to match the AC power supply and a tunable capacitor. 7. An induction heating device, comprising: an AC power supply; a group of induction coil circuits each including an induction heating coil and a susceptor having a preselected Curie temperature; wherein the induction coil circuits are coupled in parallel with each other and each of the induction coil circuits is in series with the AC power supply, the group of induction coil circuits tuned with the AC power supply to shunt power away from one of the induction coil heating circuits, by detuning the circuit, to at least one other induction coil heating circuit when the susceptor of the one circuit substantially reaches its Curie temperature; and a controller controlling the power supply to the induction coil circuits, shunting power away from the induction coil circuits whose susceptors have reached the Curie temperature to the other circuits, and the power delivered to the other circuits during rebalancing being substantially equal. 8. The induction heating device of claim 7 , wherein each of the induction coil circuits is tuned to match the input resistance of the AC power supply. 9. The induction heating device of claim 7 , wherein each of the induction coil circuits is tuned to resonate at the frequency of current supplied by the AC power supply. 10. The induction heating device of claim 7 , wherein each of the induction coil circuit includes a capacitor providing the circuit with a value of capacitance reactance that is substantially equal to the inductive reactance of the circuit when the susceptor is below its Curie temperature. 11. The induction heating device of claim 10 , wherein the capacitor is a discrete capacitor. 12. The induction heating device of claim 10 , wherein the capacitor is formed by capacitance that is distributed within the circuit. 13. The induction heating device of claim 7 , further comprising: a thermally conductive matrix in which the induction coils and the susceptors are embedded.