Cryogen-free magnet system comprising a heat sink connected to the gas circuit of a cryocooler

What is claimed is: 1. A cryostat comprising: a vacuum vessel in which a superconducting magnet coil system is arranged; a cryocooler that actively cools the cryostat with a coolant circuit comprising a compressor, a cold head, and a cold finger in thermal contact with the superconducting magnet coil system; and a volumetric vessel that is thermally coupled to the superconducting magnet coil system or to one or more portions of the cryostat that conduct ambient heat to the superconducting magnet coil system, wherein the volumetric vessel is connected to the coolant circuit of the cryocooler via a pressure-resistant line that is guided through at least part of the vacuum vessel, wherein the pressure-resistant line includes at least one fluidic component that is configured to influence a flow rate of a cryogenic fluid through the pressure-resistant line in response to a pressure differential in the pressure-resistant line between the volumetric vessel and the coolant circuit, and wherein the fluidic component is configured to influence the flow rate of the cryogenic fluid such that the cryogenic fluid flows from the volumetric vessel and through the coolant circuit in no less than 15 minutes. 2. The cryostat according to claim 1 , wherein the fluidic component is configured to reduce the flow rate of the cryogenic fluid such that the cryogenic fluid flows from the volumetric vessel and through the coolant circuit in no less than 1 hour. 3. The cryostat according to claim 1 , wherein the fluidic component is configured to reduce the flow rate of the cryogenic fluid such that the cryogenic fluid flows from the volumetric vessel and through the coolant circuit in no less than 3 hours. 4. The cryostat according to claim 1 , further comprising temperature sensors or pressure sensors. 5. The cryostat according to claim 1 , wherein the fluidic component comprises a passive throttle element. 6. The cryostat according to claim 4 , wherein the fluidic component comprises a two-position valve and an electronic control apparatus for the two-position valve, and wherein output signals from the pressure sensors are used to regulate the two-position valve. 7. The cryostat according to claim 4 , wherein the fluidic component comprises a regulating valve and an electronic control apparatus for the regulating valve, and wherein output signals from the pressure sensors are used for regulating the regulating valve. 8. The cryostat according to claim 6 , further comprising an uninterruptible power supply connected to the electronic control apparatus. 9. The cryostat according to claim 7 , further comprising an uninterruptible power supply connected to the electronic control apparatus. 10. The cryostat according to claim 1 , wherein the pressure-resistant line is configured to allow the cryogenic fluid flowing out of the volumetric vessel into the coolant circuit to exchange heat with the one or more portions of the cryostat that conduct ambient heat to the superconducting magnet coil system. 11. The cryostat according to claim 10 , wherein the one or more portions of the cryostat that conduct ambient heat to the superconducting magnet coil system include the cold head of the cryocooler. 12. The cryostat according to claim 10 , wherein the pressure-resistant line comprises a coiled tube arranged around at least parts of the cold finger. 13. The cryostat according to claim 10 , further comprising a radiation shield surrounding the superconducting magnet coil system, wherein the pressure-resistant line comprises at least one heat exchanger in thermal contact with the radiation shield or with a stage of the cold finger. 14. The cryostat according to claim 1 , further comprising a bypass throttle fluidically connected in parallel with the compressor. 15. The cryostat according to claim 1 , wherein the volumetric vessel holds between 0.5 liters and 5 liters. 16. The cryostat according to claim 1 , further comprising a buffer volume arranged in a suction line between the cold head and the compressor. 17. The cryostat according to claim 1 , wherein the superconducting magnet coil generates a magnetic field with strength of between 2 and 20 Tesla. 18. The cryostat according to claim 17 , wherein the cryostat is in a Nuclear Magnetic Resonance (NMR), Magnetic Resonance Imaging (MM), or Fourier Transform Mass Spectrometry (FTMS) apparatus. 19. A cryostat comprising: a vacuum vessel in which a superconducting magnet coil system is arranged; a cryocooler that actively cools the cryostat with a cryogenic fluid in a coolant circuit comprising a compressor, a cold head, and a cold finger in thermal contact with the superconducting magnet coil system; a buffer volume connected to the coolant circuit; and a volumetric vessel that is connected to the coolant circuit and that is thermally coupled to the superconducting magnet coil system or to one or more portions of the cryostat that conduct ambient heat to the superconducting magnet coil system, wherein the volumetric vessel and the buffer volume are connected to the coolant circuit via a pressure-resistant line through which the cryogenic fluid flows and which extends through at least part of the vacuum vessel in the coolant circuit, and wherein the pressure-resistant line includes at least one impedance that reduces a flow rate of the cryogenic fluid through the pressure-resistant line in response to a pressure differential in the pressure-resistant line between the volumetric vessel and the coolant circuit, such that the cryogenic fluid flows from the volumetric vessel to the buffer volume via the coolant circuit in no less than 15 minutes.