Method for pressure and temperature control of a fluid in a series of cryogenic compressors

The invention claimed is: 1. A method for pressure and temperature control of a fluid in a series of cryogenic compressors, said method comprising: detecting an actual speed for each compressor, detecting an actual inlet pressure and an actual inlet temperature at the entry of the most upstream, first compressor of the series, specifying a desired inlet pressure for said first compressor of the series, determining a speed index for each compressor from a maximum speed of the respective compressor and the actual speed of the respective compressor, determining a proportional value from the deviation of the actual inlet pressure from the desired inlet pressure, determining a priority value, wherein the priority value is determined from the proportional value, if the proportional value is smaller than the smallest speed index of all compressors of the series, and wherein the priority value is determined from the smallest speed index among all compressors of the series, if the proportional value is greater than the minimum speed index among all compressors of the series, determining a desired inlet temperature for the first compressor of the series and a desired speed for each compressor, with the aid of the priority value, adjusting the actual inlet temperature of said first compressor to the determined desired inlet temperature, and adjusting the actual speed for each compressor to the determined desired speed for each compressor. 2. The method according to claim 1 , wherein the speed index for each compressor corresponds to the ratio of the difference between the maximum speed and the actual speed of each compressor, and the maximum speed. 3. The method according to claim 1 , wherein the priority value influences the control in such a manner that if the smallest speed index of all compressors is smaller than the proportional value, the actual inlet temperature will be lowered, until the proportional value is smaller than the smallest speed index. 4. The method according to claim 1 , wherein the actual speed of each compressor is determined from a reduced actual speed, and the desired speed of each compressor is determined from a reduced desired speed, wherein the reduced actual speed is determined from the actual speed and an actual temperature at the entry of the respective compressor, and wherein the reduced desired speed is determined from the desired speed at the entry of each compressor. 5. The method according to claim 1 , further comprising determining an integral value from the priority value, wherein the integral value is used to determine a reduced set speed of the respective compressor. 6. The method according to claim 1 , further comprising determining an actual total pressure ratio, wherein the actual total pressure ratio corresponds to the quotient of an actual outlet pressure corresponding to the pressure at an outlet of the farthest upstream compressor, and the actual inlet pressure of the first compressor. 7. The method according to claim 6 , wherein a capacity factor is determined from the actual total pressure ratio and a proportional-integral value of the priority value and an integral value is determined, wherein a reduced desired speed for each compressor is determined as a functional value of control function attributed to the respective compressor, which assigns a reduced desired speed to each value pair, from capacity factor and model total pressure ratio, which is determined by or equal to the actual total pressure ratio. 8. The method according to claim 3 , wherein, if the smallest speed index of all compressors is smaller than the proportional value, the actual inlet temperature is lowered by gradually lowering the determined desired inlet temperature. 9. The method according to claim 3 , wherein the actual speeds of the compressors are not increased as long as the smallest speed index is smaller than the proportional value.