Transformers with multi-turn primary windings for dynamic power flow control

What is claimed is: 1. A transformer for use in a series-connectable distributed active impedance injection module that is directly connected to a high-voltage transmission line, the transformer comprising: a non-gapped transformer core; a multiple-turn primary winding on the transformer core; a multiple-turn secondary winding on the transformer core; the multiple-turn primary winding being adapted for splicing in series with the high-voltage transmission line; the multiple-turn secondary winding being adapted for connecting to a converter that generates and injects voltages at a phase angle for injection of an inductive or a capacitive impedance onto the high-voltage transmission line; the multiple-turn secondary winding being isolated from ground, wherein one side of the multiple-turn secondary winding is connected to the multiple-turn primary winding to provide a virtual ground at a potential of the high-voltage transmission line; the multiple-turn primary winding increasing the voltage injection of a distributed active impedance injection module. 2. The transformer of claim 1 wherein the multiple-turn secondary is also adapted for connecting to a shorting switch. 3. The transformer of claim 1 wherein the multiple-turn primary winding is comprised of a ribbon conductor. 4. The transformer of claim 3 wherein the multiple turn primary winding is comprised of a braided ribbon conductor. 5. The transformer of claim 3 , wherein a conductive foil is used as conductor for the windings. 6. The transformer of claim 1 , wherein the active impedance injection module is insulated from the ground and is at the potential of the high-voltage transmission line during operation. 7. The transformer of claim 1 , wherein distributed active-impedance injection module is enabled to inject any of an inductive or a capacitive impedance on to the high-voltage transmission line, via the transformer, for line balancing and control of power transfer. 8. A method of providing distributed active-impedance injection in a high-voltage power grid, the method comprising: providing a plurality of active impedance injection modules distributed over transmission lines of the power grid, each active impedance injection module being directly connected in series with a high-voltage transmission line, isolated from ground and configured to inject an inductive or a capacitive impedance onto the high-voltage transmission line, wherein each active impedance injection module comprises a housing that encloses a transformer core having a multiple-turn primary winding on the transformer core and at least one multiple-turn secondary winding on the transformer core, a converter coupled to the at least one multiple-turn secondary winding, a power supply, and a controller coupled to the converter; cutting the high-voltage transmission line into segments at a location where the active impedance injection module is to be connected; and splicing an end of each of a pair of adjacent cut segments of the high-voltage transmission line to a respective end of the multiple-turn primary winding of a respective active impedance injection module; and supporting each housing by the high-voltage transmission line by ends of the multiple-turn primary winding spliced to the ends of the cut segments of the high-voltage transmission line or by insulators attached to a high-voltage transmission line tower or by a separate support structure. 9. The method of claim 8 , wherein the provided injection modules provide line balancing and power flow control capability for the high-voltage transmission line system by injecting active impedances onto the high voltage-transmission lines onto which these are spliced. 10. The method of claim 8 wherein each housing is directly suspended from the respective high-voltage transmission line tower by at least one insulator. 11. An active impedance injection module for distributed dynamic line balancing and power flow control over a high-voltage grid system, the active impedance injection module comprising: a transformer having an un-gapped transformer core, the transformer core having a multiple-turn primary winding and at least one multiple-turn secondary winding thereon; at least one converter coupled to each of the at least one secondary winding; and at least one controller coupled to each of the at least one converter; wherein the transformer, the at least one converter and the at least one controller are housed in a single package forming the active impedance injection module for suspending on a high-voltage power line of the grid system; wherein the active impedance injection module is suspended from the high-voltage power line by cutting the high-voltage power line into two cut ends and splicing two ends of the multiple-turn primary winding to the two cut ends of the high-voltage power line, thereby suspending the active impedance injection module on the high voltage power line at a line voltage isolated from ground.