Cooling system and method for a magnetic resonance imaging device

What is claimed is: 1 . A cooling system for a low-cryogen superconducting magnet, comprising: a primary cooling loop having at least one liquid reservoir containing a supply of liquid cryogen and a plurality of cooling tubes fluidly coupled to the liquid reservoir and in thermal communication with the superconducting magnet, the liquid cryogen circulates through the cooling tubes for providing primary cooling for the magnet for cooling the magnet to a target temperature; and at least one thermal battery coupled to a component that is cooled to the target temperature by the primary cooling loop, the thermal battery being configured to be cooled by the primary cooling and to absorb heat from the at least one component during an interruption in the primary cooling to maintain the magnet at approximately the target temperature. 2 . The cooling system of claim 1 , wherein: the component is at least one of the superconducting magnet, a coil former configured to support a plurality of coils of the superconducting magnet, and the liquid reservoir. 3 . The cooling system of claim 2 , wherein: the thermal battery includes a high thermal capacity material. 4 . The cooling system of claim 3 , wherein: the material is at least one of gadolinium oxysulfide, gadolinium aluminum perovskite, HoCu 2 and lead. 5 . The cooling system of claim 1 , wherein: the thermal battery is immersed in the liquid cryogen within the liquid reservoir. 6 . The cooling system of claim 1 , further comprising: a thermal shield in thermal communication with a gas storage tank; and a cryocooler having a recondenser fluidly coupled to the gas storage tank and the reservoir; wherein the thermal battery is coupled to the thermal shield. 7 . The cooling system of claim 6 , wherein: the thermal battery includes a high thermal capacity material including at least one of solid nitrogen, water ice and lead. 8 . The cooling system of claim 7 , wherein: the thermal battery is configured to absorb heat from the gas storage tank and the thermal shield. 9 . The cooling system of 1 , wherein: the cryogen is liquid helium. 10 . The cooling system of claim 1 , wherein: the target temperature is approximately 4 Kelvin. 11 . A cooling system for a low-cryogen superconducting magnet, comprising: a primary cooling loop having a cryogen for circulation therethrough, the first cooling loop being in thermal communication with a cold mass and configured to cool the cold mass to a target temperature, the cold mass including at least one of a coil of the superconducting magnet, a support shell for supporting the coil, and a liquid reservoir containing the cryogen; a cryocooler configured to cool the cryogen within the primary cooling loop; and a thermal battery configured to absorb heat from at least one component other than the cold mass and to minimize heat leak from the component to the cold mass. 12 . The cooling system of claim 11 , further comprising: a recondenser fluidly coupled to the liquid reservoir via a conduit; wherein the thermal battery is conductively coupled to at least one of the recondenser and the conduit and is configured to minimize the heat leak from the recondenser to the liquid reservoir. 13 . The cooling system of claim 12 , wherein: the thermal battery includes a foam metal and at least one of helium and nitrogen. 14 . The cooling system of claim 11 , further comprising: a recondenser fluidly coupled to the liquid reservoir; and a gas storage tank fluidly coupled to the liquid reservoir through the recondenser; wherein the thermal battery is thermally connected to the recondenser through a first thermal switch and to the gas storage tank through a second thermal switch. 15 . The cooling system of claim 14 , wherein: the thermal battery is configured to provide auxiliary cooling to the gas storage tank to decrease a cooling system pressure. 16 . The cooling system of claim 15 , wherein: the thermal battery includes a high thermal capacity material including at least one of gadolinium oxysulfide, gadolinium aluminum perovskite, HoCu 2 , lead, solid nitrogen, solid neon, solid argon, silver and copper. 17 . The cooling system of claim 11 , wherein: the cryogen is liquid helium. 18 . A method of cooling a superconducting magnet of an imaging device, the method comprising the steps of: circulating a liquid cryogen through a cooling loop in thermal communication with a cold mass including at least one of a coil of the superconducting magnet, a coil support shell and a reservoir containing the liquid cryogen to cool the cold mass to a target temperature; and at a thermal battery, absorbing heat from the cold mass via conduction between the thermal battery and the cold mass. 19 . The method according to claim 18 , wherein: the thermal battery includes a high thermal capacity material including at least one of gadolinium oxysulfide, gadolinium aluminum perovskite, HoCu 2 and lead. 20 . The method according to claim 18 , further comprising the step of: at the thermal battery, absorbing heat from a thermal shield via conduction between the thermal battery and the thermal shield. 21 . A method of cooling a superconducting magnet of an imaging device, the method comprising the steps of: circulating a liquid cryogen through a cooling loop in thermal communication with a cold mass including at least one of a coil of the superconducting magnet, a coil support shell and a reservoir containing the liquid cryogen to cool the cold mass to a target temperature; and minimizing heat leak from a component of the imaging device to the cold mass by absorbing heat from the component utilizing a thermal battery. 22 . The method according to claim 21 , wherein: the component is a coldhead sleeve of the imaging device. 23 . The method according to claim 21 , wherein: the component is a gas storage tank. 24 . The method according to claim 21 , wherein: the thermal battery includes a high thermal capacity material including at least one of gadolinium oxysulfide, gadolinium aluminum perovskite, HoCu 2 , holmium-copper, lead, solid nitrogen, solid neon, solid argon, silver and copper. 25 . The method according to claim 21 , wherein: the imaging device includes a recondenser fluidly coupled to the reservoir via a conduit; wherein the thermal battery is conductively coupled to at least one of the recondenser and the conduit and is configured to minimize the heat leak from the recondenser to the reservoir.