High temperature furnace having reconfigurable heater circuits

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows: 1. A high temperature calibration furnace comprising: a core having an elongated central test cavity for testing/calibration of a temperature-sensitive component, the core having at least three electrical heating elements adjacent to the test cavity for heating of the test cavity by a supply of electrical power to the heating elements, the heating elements including a first end heating element adjacent to a first end portion of the test cavity, a second end heating element adjacent to a second end portion of the test cavity opposite the first end portion thereof, and a central heating element between the first and second end heating elements; and control circuitry for managing the supply of electrical power from a power supply to the first end heating element, the second end heating element, and the central heating element, the control circuitry having operating means for periodically configuring interconnections of the first end heating element, the second end heating element, and the central heating element during multiple phases of a duty cycle, including a first phase in which the power supply is electrically connected to the central heating element such that electrical current passes only through the central heating element, a second phase in which the power supply is electrically connected to the first and second end heating elements in series, and a third phase in which the power supply is electrically connected to one of the first and second end heating elements and the central heating element in series such that electrical current passes only through one of the first and second heating elements and the central heating element in series without passing through the other of the first and second end heating elements. 2. The furnace defined in claim 1 , in which the central heating element does not overlap either of the first or second end heating elements. 3. The furnace defined in claim 1 , in which the operating means includes a microprocessor controlling the interconnections of the heating elements during the duty cycle. 4. The furnace defined in claim 1 , in which the operating means configures the interconnections of the heating elements so that the first and second phases are performed at least partially simultaneously. 5. The furnace defined in claim 1 , in which the operating means configures the interconnections of the heating elements so that the phases are performed consecutively. 6. The furnace defined in claim 1 , in which the control circuitry includes a first circuit branch in which a first solid state relay is connected in series with the central heating element, and a second circuit branch in which a second solid state relay is connected in series with the first end heating element and the second end heating element, and in which a third solid state relay is connected between the first and second circuit branches at a first point between the first solid state relay and the central heating element and a second point between the first end heating element and the second end heating element, the operating means controlling the interconnections of the heating elements by periodically controlling the conditions of the solid state relays. 7. The furnace defined in claim 6 , in which the duty cycle has a duration of 0.5 second to 2 seconds. 8. The furnace defined in claim 1 , in which the control circuitry includes a first circuit branch in which a first solid state relay is connected in series with the central heating element, and a second circuit branch in which a second solid state relay is connected in series with the first end heating element and the second end heating element, and in which a third solid state relay is connected between the first and second circuit branches at a first point between the first solid state relay and the central heating element and a second point between the first end heating element and the second end heating element, the operating means including a microprocessor controlling the interconnections of the heating elements during the duty cycle by periodically controlling the conditions of the solid state relays. 9. A method of operating a high temperature calibration furnace having an elongated central test cavity for testing/calibration of a temperature-sensitive component, said furnace having at least three electrical heating elements each adjacent to the test cavity including a first end heating element adjacent to a first end of the test cavity, a second end heating element adjacent to a second end of the test cavity opposite the first end thereof, and a central heating element between the first and second end heating elements, said method comprising managing the supply of power from a power supply to the at least three electrical heating elements by periodically configuring interconnections of the at least three heating elements during multiple phases of a duty cycle, including: during a first phase, electrically connecting the power supply to the central heating element such that electrical current from the power supply passes only through the central heating element; during a second phase, electrically connecting the power supply to the first and second end heating elements in series such that electrical current from the power supply passes only through the first and second end heating elements in series; and during a third phase, electrically connecting the power supply to the central heating element and one of the first and second end heating elements in series such that electrical current from the power supply passes only through the central heating element and one of the first and second end heating elements in series without passing through the other of the first and second end heating elements. 10. The method of claim 9 , including performing the first and second phases at least partially simultaneously. 11. A high temperature calibration furnace comprising: a core having a test cavity; a first end heating element adjacent to a first end portion of the test cavity; a second end heating element adjacent to a second end portion of the test cavity opposite the first end portion thereof; a central heating element adjacent to the test cavity between the first and second end heating elements; and control circuitry that manages a supply of electrical current from a power supply to the first end heating element, the second end heating element, and the central heating element, wherein the control circuitry periodically configures interconnections of the first end heating element, the second end heating element, and the central heating element during multiple phases of a duty cycle, including a first phase in which the power supply is eleectrically connected to the central heating element such that electric current passes only through the central heating element, a second phase in which the power supply is electrically connected to the first and second end heating elements in series such that electrical current passes only through the first and second end heating elements in series, and a third phase in which the power supply is electrically connected to one of the first and second end heating elements and the central heating element in series such that electrical current passes only through one of the first and second heating elements and through the central heating element in series without passing through the other of the first and second end heating elements. 12. The furnace defined in claim 11 , in which the central heating element does not overlap either of the first or second end heating elements.