Controlling an electrical energy distribution network

The invention claimed is: 1. A method for controlling an electrical energy distribution network in which electrical power is provided from a plurality of network nodes connected via power lines, wherein the plurality of network nodes are controllable network nodes with respective local control units, and the plurality of the controllable network nodes are energy generators, wherein the electrical energy distribution network is coupled to an energy transmission network at a point of common coupling and provides electrical power to the energy transmission network at the point of common coupling, the electrical power originating from the controllable network nodes of the energy distribution network, the method comprising: communicating, by a central control unit in the energy distribution network, with the local control units of the controllable network nodes and the energy transmission network for providing electrical power from the energy distribution network to the energy transmission network; and controlling, by the central control unit, the controllable network nodes in the energy distribution network with the aid of the communication with the local control units and the energy transmission network such that, at the point of common coupling, primary control power and short-circuit power are kept available for the energy transmission network. 2. The method of claim 1 , further comprising controlling, by the central control unit, the energy distribution network such that at the point of common coupling secondary control power, tertiary control power, or secondary control power and tertiary control power are kept available for the energy transmission network, harmonics, subharmonics, or harmonics and subharmonics of the voltage at the point of common coupling are compensated for, or a combination thereof. 3. The method of claim 1 , further comprising controlling, by the central control unit, the energy distribution network such that at the point of common coupling, control reactive power is kept available for the energy transmission network, and wherein the control reactive power is provided for compensating for voltage fluctuations at the point of common coupling. 4. The method of claim 1 , further comprising controlling, by the central control unit, the energy distribution network such that the energy distribution network is operated as an island network in the event of failure of the energy transmission network. 5. The method of claim 1 , wherein communicating, by the central control unit, with the energy transmission network comprises communicating setpoint values for the primary control power and short-circuit power to be kept available from the energy transmission network to the central control unit, communicating, by the central control unit, with the local control units comprises communicating the primary control power and short-circuit power respectively offered by the controllable network nodes to the central control unit by the local control units. 6. The method of claim 1 , further comprising estimating, in the central control unit, present network loading of the energy distribution network, predicting future network loading, or a combination thereof, wherein the central control unit takes account of the present network loading, the future network loading, or the present network loading and the future network loading in the control of the energy distribution network such that a predetermined loading limit of the energy distribution network is not exceeded. 7. The method of claim 6 , wherein estimating the present network loading, predicting future network loading actual values, or a combination thereof comprises, or the method further comprises communicating predictions of parameters of the controllable network nodes from the respective local control units to the central control unit, and communicating, based on the present network loading, the future network loading, or the present network loading and the future network loading, setpoint values of the parameters of the controllable network nodes from the central control unit to the respective local control units. 8. The method of claim 7 , wherein estimating the present network loading, predicting the future network loading actual values, or a combination thereof comprises estimating the present network loading, predicting the future network loading actual values, or a combination thereof from voltage sensors, current sensors, or voltage sensors and current sensors arranged in the energy distribution network outside the controllable network nodes, and wherein the method further comprises communicating weather forecasts to the central control unit, at least a portion of the local control units, or a combination thereof. 9. The method of claim 1 , wherein the point of common coupling is provided at a transformer substation. 10. The method of claim 1 , wherein the controllable network nodes of the energy distribution network that are energy generators comprise one or more regenerative energy generators, the one or more regenerative energy generators comprising respective local control units that communicate with the central control unit in the context of the control of the energy distribution network. 11. The method of claim 10 , wherein the one or more regenerative energy generators comprise one or more wind power installations, one or more photovoltaic installations, one or more hydroelectric power plants, one or more biomass power plants, one or more fossil-fuel power plants, one or more combined heat and power plants, one or more combined cooling, heat and power plants, or any combination thereof. 12. The method of claim 1 , wherein the controllable network nodes of the energy distribution network comprise one or more controllable energy loads, one or more energy stores, one or more microgrids, or any combination thereof with respective local control units that communicate with the central control unit in the context of the control of the energy distribution network. 13. The method of claim 1 , wherein the controllable network nodes of the energy distribution network comprise one or more voltage controllers with respective local control units that communicate with the central control unit in the context of the control of the energy distribution network, wherein the voltage controller or voltage controllers comprise one or more transformers, one or more capacitance banks, one or more series controllers, or any combination thereof. 14. An electrical energy distribution network for providing electrical power, the electrical energy distribution network comprising: a plurality of network nodes connected via power lines, wherein the plurality of network nodes are controllable network nodes with respective local control units, and the controllable network nodes are energy generators, wherein the electrical energy distribution network is coupled to an energy transmission network at a point of common coupling and is operable to provide electrical power to the energy transmission network at the point of common coupling, the electrical power originating from the controllable network nodes of the energy distribution network; a central control unit for communicating for providing the electrical power, the central control unit operable to communicate with the local control units of the controllable network nodes and the energy transmission network, wherein the central control unit is configured to control the energy distribution network with the aid of the communication with the local control units and the energy transmission network such that, at the point of common coupling, primary control powe