Hybrid distribution transformer having a power electronic module for controlling input power factor and output voltage

What is claimed is: 1. A hybrid transformer having a primary side for receiving an input voltage and a current from a source and a secondary side for providing an output voltage and a current to a load, the hybrid transformer comprising: a ferromagnetic core; a first winding, a second winding and a third winding wound around the core, wherein at least one of the first, second and third windings is a primary winding for connection to the source, and at least one of the first, second and third windings is a secondary winding for connection to the load; and, an AC-AC converter comprising: a first switching bridge connected to the first winding such that the first switching bridge receives AC power from the first winding and converts the AC power to DC power; a second switching bridge including an output connected to the second winding and structured to receive the converted DC power from the first switching bridge, convert the DC power to AC power, and provide the converted AC power to the load in parallel combination with unconverted AC power from the second winding effective to augment the AC power provided to the load; a DC bridge connected between the first and second switching bridges; and a controller that controls each of the first and second switching bridges to reduce variations in the output voltage in the event of a change in the input voltage, the controller further controlling the first and second switching bridges to continuously control a power factor on the primary side of the hybrid transformer, the controller configured to disconnect the load from the source by opening the first and second switching bridges when the output current exceeds a predetermined limit or when the input voltage drops below a predetermined limit. 2. The hybrid transformer of claim 1 , wherein the first and second windings are secondary windings and the third winding is the primary winding. 3. The hybrid transformer of claim 1 , wherein the first and second windings are primary windings and the third winding is the secondary winding. 4. The hybrid transformer of claim 1 , wherein the DC bridge comprises a plurality of capacitors and one or more taps for providing DC power to a DC load. 5. The hybrid transformer of claim 4 , further comprising a normally open switch and a battery bank connected in parallel with the DC bridge, wherein when an interruption occurs in the input voltage, the switch closes, thereby providing DC power from the battery bank to the second switching bridge. 6. The hybrid transformer of claim 4 , further comprising sensors and a monitoring device for monitor the operation of the hybrid transformer, the monitoring device being connected to the one or more taps to receive DC power from the DC bridge. 7. The hybrid transformer of claim 6 , wherein the monitoring device is an intelligent electronic device (IED) that receives operational data of the hybrid transformer from the sensors, the operational data including currents, voltages and temperatures in the first, second and third windings. 8. The hybrid transformer of claim 7 , wherein the IED comprises the controller. 9. The hybrid transformer of claim 8 , wherein the IED is connected to a remotely located control center by a communication link, the lED transmitting the operational data to the control center and receiving, commands for the controller from the control center. 10. A hybrid transformer for receiving an input voltage and current from a source and providing an output including an output voltage and current to a load, the hybrid transformer comprising: a ferromagnetic core; a first winding, a second winding and a third winding wound around the core, wherein at least one of the first, second and third windings is a primary winding for connection to the source, and at least one of the first, second and third windings is a secondary winding for connection to the load; and, an AC-AC converter comprising: a first switching bridge connected to the first winding; a second switching bridge connected in series with the second winding; a DC bridge connected between the first and second switching bridges; and a controller that controls each of the first and second switching bridges to control the DC voltage across the DC bridge to reduce variations in the output voltage in the event of a change in the input voltage, wherein the controller is structured to operate the second switching bridge so as to receive DC power from the first switching bridge, convert the DC power to AC power, and provide the AC power to the load, wherein the output power includes an AC power transmitted with the second winding unconverted by the first or second switching bridge in addition to the AC power provided with the second switching bridge. 11. The hybrid transformer of claim 10 , further comprising sensors and an intelligent electronic device (IED) that is connected to a remotely located control center by a communication link, the IED comprising the controller and being operational to receive operational data from the sensors, transmit the operational data to the control center and receive commands for the controller from the control center. 12. A hybrid distribution transformer having a primary side for receiving an input voltage and a current from a source and a secondary side for providing an output power including an output voltage and a current to a load, the hybrid distribution transformer comprising: a ferromagnetic core; a first winding and a second winding wound around the core, the first winding having opposing ends, a plurality of turns disposed between the ends and a tap connected to one of the turns, the tap helping define winding portions of the first winding, and wherein one of the first and second windings is a primary winding for connection to the source, and the other one of the first and second windings is a secondary winding for connection to the load; a power electronic module connected to the tap of the first winding and comprising an AC-AC converter including a first converter and a second converter, the first converter being connected in parallel with the second converter and the second converter including an output being connected to the tap; and a control device that controls the power electronic module to receive AC power with the first converter, to convert the received AC power to DC power with the first converter, to receive the converted DC power with the second converter, to convert the DC power to AC power with the second converter, to provide the converted AC power to the load, to regulate variations in the output voltage, to increase voltage across the first winding, and to decrease voltage across the first winding, as well as to control a power factor on the primary side of the hybrid distribution transformer, wherein the output power includes unconverted AC power transmitted with the first winding, and wherein only a portion of the AC power transmitted with the first winding is the AC power provided with the second converter. 13. The hybrid distribution transformer of claim 12 , wherein the first winding is the primary winding and the second winding is the secondary winding. 14. the hybrid distribution transformer of claim 12 wherein the first winding is the secondary winding and the second winding is the primary winding. 15. The hybrid distribution transformer of claim 12 , further comprising first and second switches, the first switch being connected in series with an input to the first converter and the second switch being connected in parallel with an output of the second converter. 16. The hybrid distribu