Method for adjusting a Cryogenic refrigeration apparatus and corresponding apparatus

The invention claimed is: 1. A method for adjusting a cryogenic refrigeration apparatus comprising several refrigerators/liquefiers arranged in parallel to cool a single device, each of the several refrigerator/liquefier comprising a working circuit comprising a working gas, the working circuit equipped with at least one valve for controlling the flow of the working gas, the several refrigerators/liquefiers in parallel using identical working gas, each of the several refrigerator/liquefier comprising a respective working gas compression station, a cold box configured to cool a flow of the working gas leaving the compression station to a cryogenic temperature at within 4 K the liquefaction temperature, said flows of the working gas cooled by each of the respective cold boxes of the of the several refrigerators/liquefiers being mixed and then placed in a heat exchange relationship with the single device in order to give up frigories thereto, the cold working gas having exchanged with the single device then being divided into several return flows distributed respectively through the respective compression stations, the method comprising a step of simultaneous measurement, for each of the of the several refrigerators/liquefiers, of the instantaneous value of at least one and the same operating parameter selected from the group consisting of: a flow rate of the working gas returning to the compression station a flow rate of the working gas circulating through the cold box having left the compression station, and a differential in temperature of the working gas between the outbound flow of the working gas and the return flow of the working gas, both flows being situated in the cold box in the same temperature range, and in that the method comprises a step of real-time calculation of the dynamic mean value of the at least one operating parameter for all the several refrigerators/liquefiers the apparatus performing real-time control of the at least one working gas flow control valve of the at least one refrigerator/liquefier as a function of the difference between the instantaneous values of the parameter with respect to said dynamic mean value, so as to cause said instantaneous values of said operating parameter of the several refrigerators/liquefiers to converge toward this dynamic mean value, wherein the working circuit comprises, in the cold box of each of the several refrigerator/liquefier, a main pipe comprising a working gas cooling exchanger immersed in a cryogenic tank of liquefied working gas and a secondary pipe forming a bypass of the main pipe upstream of the cryogenic tank and opening into the latter so as to be able to deliver thereto liquefied working gas produced by the cold box, the main pipe comprising a variable-opening controlled downstream valve situated downstream of the cooling exchanger, the method comprising simultaneous measurement for each of the several refrigerators/liquefiers, of the operating parameter consisting of the instantaneous value of the flow rate of the outlet flow of the working gas in said main pipe downstream of the cooling exchanger, the method comprising a step of real-time calculation of the dynamic mean value of this operating parameter for all of the several refrigerators/liquefiers, the apparatus performing real-time control over the opening/closing of each downstream valve as a function of the difference between the instantaneous values of this operating parameter of the several refrigerator/liquefier in order to make said instantaneous values of said operating parameter of the several refrigerators/liquefiers converge toward this dynamic mean value. 2. The method of claim 1 , wherein the refrigerators/liquefiers are identical, the apparatus performing real-time control of the at least one working gas flow control valve of at least one refrigerator/liquefier as a function of the difference between the instantaneous values of the parameter with respect to said dynamic mean value in order at once to cause said instantaneous values of the flow rates of the return flow of working gas returning toward the compression stations to converge toward a determined identical flow value, to cause the differential in temperature of the working gas between the outbound flow of working gas in the cold box and the return flow of working gas returning toward the compression station to converge toward a determined identical temperature differential value and to cause the flow rate of the flow of cooled working gas at the outlet of each cold box to converge toward a determined identical flow rate value. 3. The method of claim 1 , wherein the compression station of each refrigerator/liquefier comprises two compressors arranged in series on the working circuit and respectively designated “low-pressure compressor” and “medium-pressure compressor”, a bypass circuit for selectively bypassing the low-pressure compressor comprising at least one variable-opening controlled bypass valve, the method comprising simultaneous measurement, for each of the refrigerators/liquefiers, of the operating parameter consisting of the instantaneous value of the flow rate of the return flow of working gas returning toward the compression station, the method comprising a step of real-time calculation of the dynamic mean value of the operating parameter for all the refrigerators/liquefiers, the apparatus performing real-time control of the opening/closing of each bypass valve as a function of the difference between the instantaneous values of the operating parameter of the refrigerator/liquefier concerned in order to cause said instantaneous values of said operating parameter of the various refrigerators/liquefiers to converge toward this dynamic mean value. 4. The method of claim 3 , further comprising simultaneous measurement, for each of the refrigerators/liquefiers, of the differential in temperature of the working gas between the return flow and the outbound flow at the same temperature level in the cold box, and in that control of each bypass valve is corrected as a function of the discrepancy between said differential in temperature for the refrigerator/liquefier concerned and the mean of said temperature differential calculated for all of the refrigerators/liquefiers, the opening/closing of each bypass valve being reduced when the temperature differential for the refrigerator/liquefier concerned increases in terms of absolute value with respect to the mean of said temperature differential. 5. The method of claim 1 , wherein at the outlet of the compression station, each refrigerator/liquefier comprises a variable-opening controlled outlet valve, the method comprising simultaneous measurement, for each of the refrigerators/liquefiers, of the operating parameter consisting of the instantaneous value of the flow rate of the outlet flow of working gas, the method comprising a step of real-time calculation of the dynamic mean value of the operating parameter for all the refrigerators/liquefiers, the apparatus performing real-time control of the opening/closing of each outlet valve as a function of the difference between the instantaneous values of the operating parameter of the refrigerator/liquefier concerned so as to cause said instantaneous values of said operating parameter of the various refrigerators/liquefiers to converge toward this dynamic mean value. 6. The method of claim 5 , wherein each outlet valve is controlled according to a pressure set point measured at the outlet of said valve, the apparatus performing real-time control of the opening/closing of each outlet valve so as to reduce the pressure set point when the instantaneous value of the flow rate of the flow of gas at the outlet of the compression station of the refrigerator/liquefier concerned is greater than said dynamic mean value, and vice versa.