Continuously variable saturable shunt reactor

The invention claimed is: 1. A continuously variable saturable shunt reactor, comprising: a laminated core having two wound limbs for each phase, said wound limbs being connected by yokes; two network winding branches each being disposed on a respective one of said wound limbs, said network winding branches having high-voltage ends and low-voltage ends; a phase conductor connected to said high-voltage ends of said two network winding branches of a phase; a DC voltage source connected to said low-voltage ends of said network winding branches, said DC voltage source including two stabilized, single-pole-grounded power converters with opposite polarities and two electronic transistor changeover switches; and a control system controlling said electronic transistor changeover switches for each phase, said control system being configured to feed direct current to each of said two network winding branches of a phase in pulses by using a respective one of said electronic transistor changeover switches, and the direct current being fed into each of said two network winding branches at opposite poles from a respective one of said power converters. 2. The continuously variable saturable shunt reactor according to claim 1 , wherein said power converters have an identical construction. 3. The continuously variable saturable shunt reactor according to claim 1 , wherein: said two network winding branches are first and second network winding branches; said power converters are first and second power converters; said transistor changeover switches each have at least first, second and third operating positions; said first operating position connects said low-voltage end of said first network winding branch to said first power converter and connects said low-voltage end of said second network winding branch to said second power converter; said second operating position connects each of said low-voltage ends of said network winding branches to a grounded star point connection; said third operating position connects said low-voltage end of said first network winding branch to said second power converter and connects said low-voltage end of said second network winding branch to said first power converter; and a control of said operating positions of said two transistor changeover switches takes place with a temporal offset of half of a sine period. 4. The continuously variable saturable shunt reactor according to claim 3 , wherein said control system is configured to control an operating current of the saturable shunt reactor by controlling a duration of said first and third operating positions. 5. The continuously variable saturable shunt reactor according to claim 4 , wherein said control system is configured to compare actual and setpoint value amplitudes and positive and negative amplitudes of the operating current of each phase with one another in each case, and to correct a duration of said respective operating positions in a phase to minimize deviations of the amplitudes. 6. The continuously variable saturable shunt reactor according to claim 1 , wherein during a saturated state of one of said wound core limbs, said low-voltage end of said network winding branch disposed on said one wound core limb is grounded by using one of said electronic transistor changeover switches. 7. The continuously variable saturable shunt reactor according to claim 1 , wherein during a prespecified time interval within an unsaturated state of one of said wound core limbs, said low-voltage end of said network winding branch disposed on said one wound core limb is connected to one of said power converters by using one of said electronic transistor changeover switches. 8. The continuously variable saturable shunt reactor according to claim 1 , wherein said control system is configured to automatically control a rate of change in an operating current of the saturable shunt reactor by controlling output voltages of said two power converters. 9. The continuously variable saturable shunt reactor according to claim 1 , wherein said control system is configured to compare amplitudes of an operating current of all phases with one another and to correct a duration of said respective operating positions in the phases to make the amplitudes the same.