Pressure control in a supply grid

The invention claimed is: 1. A method for controlling pressure in a supply grid, wherein the supply grid is configured to supply consumers with a fluid and comprises a plurality of first sensors for measuring flow rates and/or pressures of the fluid at a plurality of first locations in the supply grid, and a pump for pumping the fluid or a valve for controlling a flow of the fluid, the method comprising: training a self-learning system comprising: measuring the flow rates and/or the pressures of the fluid at the plurality of first locations in the supply grid using the first sensors; determining a pressure, by the self-learning system, at a second location among a plurality of second locations in the supply grid based on the flow rates and the pressures measured at the plurality of first locations; determining a difference between the determined pressure and a target value; adjusting the self-learning system taking into account the determined difference; and repeating the measuring, the determining of the pressure, the determining of the difference, and the adjusting of the self-learning system until a specified termination criterion is met; predicting a pressure at the second location among the plurality of second locations in the supply grid using the self-learning system based on the measured flow rates or the pressures of the fluid at the plurality of first locations; and actuating the pump or the valve based on the predicted pressure at the second location. 2. The method of claim 1 , wherein the self-learning system is trained and the pressure control is performed for the plurality of second locations different from the plurality of first locations. 3. The method of claim 1 , wherein the termination criterion occurs when an average difference between the determined pressure at the second location and the target value falls below a specified threshold value. 4. The method of claim 1 , wherein the target value is based on an actual flow rate and/or pressure of the fluid at the second location measured by a second sensor. 5. The method of claim 4 , further comprising: removing the second sensor from the supply grid after the training of the self-learning system. 6. The method of claim 1 , wherein the target value is determined by a simulation. 7. The method of claim 6 , wherein the simulation uses a topology of the supply grid, the locations and type of consumers, and an equivalent consumption profile for each consumer as input data. 8. The method of claim 7 , wherein the input data is reduced prior to the determination of the target value by a series expansion. 9. The method of claim 8 , wherein the series expansion is a principal component analysis. 10. The method of claim 1 , further comprising: positioning the plurality of first sensors at the plurality of first locations in the supply grid such that measurement values of the plurality of first sensors are not correlated. 11. The method of claim 1 , wherein the fluid is water, and wherein the supply grid is a drinking water supply grid or sewage system. 12. The method of claim 1 , wherein the fluid is a gas, and wherein the supply grid is a gas network or district heating supply grid. 13. An apparatus for controlling pressure in a supply grid, wherein the supply grid is configured to supply consumers with a fluid and comprises a plurality of first sensors for measuring flow rates and/or pressures of the fluid at a plurality of first locations in the supply grid, and a pump for pumping the fluid or a valve for controlling a flow of the fluid, the apparatus comprising: a self-learning system capable of training itself by: (1) measuring the flow rates and/or the pressures of the fluid at the first locations in the supply grid using the first sensors; (2) determining a pressure, by the self-learning system, at a second location among a plurality of second locations in the supply grid based on the flow rates and the pressures measured at the plurality of first locations; (3) determining a difference between the determined pressure and a target value; (4) adjusting the self-learning system taking into account the determined difference; and (5) repeating the measuring, the determining of the pressure, the determining of the difference, and the adjusting of the self-learning system until a specified termination criterion is met; a first detection unit configured to detect fluid flow rates or the pressures measured by the plurality of first sensors at the plurality of first locations in the supply grid; a prediction unit configured to predict a pressure at the second location among the plurality of the second locations by the trained self-learning system based on the flow rates or the pressures detected at the plurality of first locations by the first detection unit; and an actuation unit configured to actuate the pump or the valve. 14. An arrangement comprising: a supply grid configured to supply consumers with a fluid; a plurality of first sensors configured to measure flow rates and/or pressures of the fluid at a plurality of first locations in the supply grid; a pump configured to pump the fluid or a valve configured to control a flow of the fluid; and an apparatus configured to control pressure in the supply grid, wherein the apparatus comprises: a self-learning system capable of training itself by: (1) measuring the flow rates and/or the pressures of the fluid at the first locations in the supply grid using the first sensors; (2) determining a pressure, by the self-learning system, at a second location among a plurality of second locations in the supply grid based on the flow rates and the pressures measured at the plurality of first locations; (3) determining a difference between the determined pressure and a target value; (4) adjusting the self-learning system taking into account the determined difference; and (5) repeating the measuring, the determining of the pressure, the determining of the difference, and the adjusting of the self-learning system until a specified termination criterion is met; a first detection unit configured to detect the flow rates or the pressures measured by the plurality of first sensors at the plurality of first locations in the supply grid; a prediction unit configured to predict a pressure at the second location among the plurality of second locations by the trained self-learning system based on the flow rates or the pressures detected at the plurality of first locations by the first detection unit; and an actuation unit configured to actuate the pump or the valve.