Autonomous cooling of a superconductive dry-cooled MR magnetic coil system

The invention claimed is: 1. A method of operating a magnetic resonance (MR) apparatus having a superconductive MR magnetic coil system which is disposed in a vacuum vessel and is cryogen-free in MR analysis operation, the apparatus having a cryostat for cooling the MR magnetic coil system which comprises a neck tube that leads through an outer shell of the vacuum vessel to the MR magnetic coil system, wherein a cooling arm of a cold head is disposed at least partly within the neck tube, and wherein a closed cavity which is formed around the cooling arm is sealed in a fluid-tight manner with respect to the MR magnetic coil system to be cooled and is at least partly filled with a cryogenic fluid during normal operation of the MR apparatus, wherein the method comprises: (a 1 ) measuring a current temperature T actual in the MR magnetic coil system and comparing T actual with a definable first temperature target value T1 target at which the vacuum vessel is to be pumped out; (a 2 ) if T actual >T1 target , activating a vacuum pump disposed outside the vacuum vessel and opening a first barrier valve in a vacuum conduit that leads from the vacuum pump into the vacuum vessel; (b 1 ) measuring a current pressure P actual in the vacuum vessel and comparing P actual with a definable first target pressure P1 target at which the MR magnetic coil system is to be cooled down to cryogenic temperature; (b 2 ) if P actual <P1 target , activating the cold head for cooling of the cooling arm; (c 1 ) measuring the current temperature T actual in the MR magnetic coil system and comparing T actual with the first temperature target value T1 target ; (c 2 ) if T actual <T1 target , closing the first barrier valve and switching off the vacuum pump; and (d 1 ) measuring the current temperature T actual in the MR magnetic coil system and comparing T actual with a definable second temperature target value T2 target at which the operating temperature of the MR magnetic coil system for MR measurements has been attained and maintaining T actual at the second temperature target value T2 target . 2. The method as claimed in claim 1 , wherein the neck tube is connected via a first valve V1 to a helium feed, and wherein the method further comprises, in a step (e), feeding helium into the neck tube and liquifying said helium. 3. The method as claimed in claim 1 , wherein a feed conduit to the neck tube is connected via a further valve V2 to the vacuum pump, and wherein the neck tube is pumped dry by the steps of: (a 3 ) measuring the current temperature T actual in the MR magnetic coil system and comparing T actual with a definable third temperature target value T3 target from which the neck tube is to be pumped out; and (a 4 ) if T actual >T3 target , actuating the vacuum pump and opening the second barrier valve V2 in a vacuum conduit that leads from the vacuum pump to the neck tube. 4. The method as claimed in claim 3 , wherein, in the event of a failure of the cold head, in a step (d 2 ), the vacuum pump is used to pump away the liquid helium in the neck tube in order to cool the MR magnetic coil system. 5. The method as claimed in claim 1 , wherein the definable temperature target values T1 target , T2 target and T3 target and the definable pressure target value P1 target are selected from the following ranges of values: 5K≤T1 target ≤20K; 3K≤T2 target ≤5K; 250K≤T3 target ≤300K, and 10 −4 mbar≤P1 target ≤10 −3 mbar. 6. An MR apparatus for performing the method as claimed in claim 1 , wherein the MR apparatus further comprises a temperature sensor for measuring a current temperature T actual in the MR magnetic coil system and a first pressure sensor for measuring a current pressure P actual that are present in the vacuum vessel, and wherein a control unit is configured to detect and compare the current temperature T actual in the MR magnetic coil system with defined temperature target values, to detect and compare the current pressure P actual in the vacuum vessel with defined pressure target values, and to actuate the first barrier valve, the vacuum pump and the cold head. 7. The MR apparatus as claimed in claim 6 , wherein the vacuum pump has an at least 2-stage construction and has a turbomolecular pump and a backing pump therefor. 8. A control unit for use in an MR apparatus that performs the method as claimed in claim 1 , wherein the control unit is configured to detect and compare a current temperature T actual in the MR magnetic coil system with defined temperature target values, and to detect and compare a current pressure P actual in the vacuum vessel with defined pressure target values, the control unit comprising: a measurement unit in which a temperature sensor for measuring the current temperature T actual in the MR magnetic coil system and a pressure sensor for measuring the current pressure P actual in the vacuum vessel are connected; an actuation unit for opening and closing the first barrier valve, for activating and deactivating the vacuum pump and for activating and deactivating the cold head, and a processor unit which is disposed as an interface between the measurement unit and the actuation unit for comparison of the sensor parameters detected with the target parameters and the processing of the data for actuation of the cold head, vacuum pump and barrier valve. 9. The control unit as claimed in claim 8 , further comprising a second pressure sensor for measuring the current pressure P HR in the cavity surrounding the cooling arm of the cold head that is connected to the measurement unit, wherein the actuation unit is configured to open and close the second and third barrier valves. 10. The control unit as claimed in claim 9 , further comprising a connection from the neck tube to the vacuum pump, wherein the control unit implements control of V2 to the vacuum pump. 11. The control unit as claimed in claim 9 , further comprising a connection from a helium feed to the neck tube, wherein the control unit implements control of the He feed via the valve V1.