System and method for insulating a cryogen vessel

What is claimed is: 1. A thermal insulator configured for a superconducting magnet of a magnetic resonance imaging system, the thermal insulator having the form of a multi-layered insulation (MLI) blanket comprising: a first plurality of reflector layers; a non-deformed spacer layer located between each of the multiple adjacent layers within the first plurality of reflector layers; a second plurality of reflector layers; and a deformed non-smooth, non-planar sheet spacer layer that is located between each of the multiple adjacent layers within the second plurality of reflector layers. 2. The thermal insulator of claim 1 , wherein the first plurality of reflector layers define a warm end of the multi-layered insulation (MLI) blanket that is configured to be positioned distal to at least one of a helium vessel or a thermal shield. 3. The thermal insulator of claim 1 , wherein the second plurality of reflector layers define a cold end of the multi-layered insulation (MLI) blanket that is configured to be positioned proximate to at least one of a helium vessel or a thermal shield. 4. The thermal insulator of claim 1 , wherein the deformed non-smooth, non-planar sheet spacer layer comprises a pleated structure. 5. The thermal insulator of claim 1 , wherein the deformed non-smooth, non-planar sheet spacer layer comprises an embossed structure. 6. The thermal insulator of claim 1 , wherein the deformed non-smooth, non-planar sheet spacer layer comprises a crinkled structure. 7. The thermal insulator of claim 1 , wherein the deformed non-smooth, non-planar sheet spacer layer has a varied thickness. 8. The thermal insulator of claim 1 , wherein a number of the first plurality of reflector layers is greater than a number of the second plurality of reflector layers. 9. The thermal insulator of claim 8 , further comprises thirty sets of the first plurality of reflector layers, with non-deformed spacer layers therebetween; and five sets of the second plurality of reflector layers, with deformed non-smooth, non-planar sheet spacer layers therebetween. 10. The thermal insulator of claim 1 , wherein the first and second pluralities of reflector layers are formed from generally planar material sheets. 11. The thermal insulator of claim 1 , wherein the combination of the first and second plurality of reflector layers combined with the non-deformed spacer layers and the deformed non-smooth, non-planar sheet spacer layers form the MLI blanket that is part of the MRI system. 12. A magnetic resonance imaging (MRI) magnet system comprising: a vessel having liquid helium therein; a thermal shield surrounding the vessel; a superconducting magnet located within the vessel; and a thermal insulator surrounding at least a portion of at least one of the vessel or the thermal shield, wherein the thermal insulator comprises: a first plurality of reflector layers having a non-deformed spacer layer located between each of the adjacent reflector layers within the plurality of reflector layers, and a second plurality of reflector layers having a deformed non-smooth, non-planar sheet spacer layer; wherein the combination of the plurality of reflector layers, and the additional plurality of reflector layers combined with the non-deformed spacer layers and the deformed non-smooth, non-planar sheet spacer layers form a multi-layered insulation (MLI) blanket insulating at least one of the vessel or the thermal shield, that is part of the MRI system. 13. The MRI magnet system of claim 12 , wherein the second plurality of reflector layers having the deformed non-smooth, non-planar sheet spacer layers therebetween are positioned proximate to and in thermal contact with at least one of the vessel or the thermal shield. 14. The MRI magnet system of claim 12 , wherein each of the deformed non-smooth, non-planar sheet spacer layer comprises a pleated structure. 15. The MRI magnet system of claim 12 , wherein each of the deformed non-smooth, non-planar sheet spacer layer(s) comprises an embossed structure. 16. The MRI magnet system of claim 12 , wherein each of the deformed non-smooth, non-planar sheet spacer layer(s), comprises a crinkled structure. 17. The MRI magnet system of claim 12 , wherein each of the deformed non-smooth, non-planar sheet spacer layer(s) has a varied thickness. 18. The MRI magnet system of claim 12 , wherein a number of the plurality of reflector layers, having the non-deformed spacer layer therebetween each adjacent reflector laver, within the plurality of reflector layers, is greater than a number of the additional plurality of reflector layers, having the deformed non-smooth, non-planar sheet spacer layers(s). 19. The MRI magnet system of claim 18 , wherein the MLI blanket has non-deformed spacer layers and five deformed non-smooth, non-planar sheet spacer layers. 20. A method of forming a thermal insulator in the form of a multilayered insulation (MLI) blanket that is used with a magnetic resonance imaging system (MRI), the method comprising: deforming a plurality of spacer layers by having the plurality of spacer layers be non-smooth, non-planar sheets; stacking a first plurality of reflector layers with non-deformed spacer layers therebetween; stacking a second plurality of reflector layers with the plurality of deformed non-smooth, non-planar spacer layers therebetween; and forming a multi-layer thermal insulator, in the form of a Multi-Layered Insulation (MLI) blanket, from the stacked first and second pluralities of reflector layers, which contain the non-deformed spacer layers and the deformed non-smooth, non-planar sheet spacer layers. 21. The method of claim 20 , wherein the step of deforming the plurality of spacer layers having the plurality deformed non-smooth, nonplanar sheet spacer layers comprises one of pleating, embossing or crinkling the plurality of spacer layers in order to cause the plurality of spacer layers to become non--smooth, non-planer sheets.