Variable Tg shape memory materials for wellbore devices

What is claimed is: 1. A wellbore device comprising: at least two shape-memory materials: a first shape-memory material comprising a cross-linked polymer having a first crosslinking ratio, where the first shape-memory material has an altered geometric position and an original geometric position, where the first shape-memory material is maintained in the altered geometric position at a temperature below a first onset glass transition temperature, and where the shape-memory material expands from its altered geometric position to its recovered geometric position when it is heated to a temperature above the first onset glass transition temperature, where the first shape-memory material has a first slope change during a first transition state from a first glass state to a first rubber state; and a second shape-memory material comprising a cross-linked polymer having a second crosslinking ratio different from the first crosslinking ratio, where the second shape-memory material has an altered geometric position and an original geometric position, where the shape-memory material is maintained in the altered geometric position at a temperature below a second onset glass transition temperature, and where the shape-memory material recovers from its altered geometric position to its recovered geometric position when it is heated to a temperature above the second onset glass transition temperature, where the second shape-memory material has a second slope change during a second transition state from a second glass state to a second rubber state; and where the first shape-memory material and the second shape-memory material are further different by a parameter selected from the group consisting of: the first onset glass transition temperature is different from the second onset glass transition temperature, the first slope change is different from the second slope change, and both. 2. The wellbore device of claim 1 , wherein the first and second shape-memory materials each comprise a polyurethane. 3. The wellbore device of claim 2 , where the ratios of polyol to polyisocyanate in the polyurethanes of the first and second shape-memory materials are different. 4. The wellbore device of claim 1 where the first shape-memory material and the second shape-memory material are positioned on a billet having a length in a configuration selected from the group consisting of: concentric layers, where one of the shape-memory materials at least partially overlaps the other shape-memory material; side-by-side each other along at least a portion of the length of the billet; and combinations thereof. 5. A method of manufacturing a wellbore device, the method comprising, (a) placing in any order or simultaneously: a first shape-memory material on a billet in an original geometric position where the first shape-memory material has a first onset glass transition temperature and a first slope change during a first transition state from a first glass state to a first rubber state, the first shape-memory material comprising a cross-linked polymer having a first crosslinking ratio; a second shape-memory material on the billet in an original geometric position where the second shape-memory material has a second onset glass transition temperature and a second slope change during a second transition state from a second glass state to a second rubber state, the second shape-memory material comprising a cross-linked polymer having a second crosslinking ratio different from the first crosslinking ratio; (b) altering the original geometric shapes of the first and second shape-memory materials at a temperature at or above both the first and second onset T g to change the original geometric positions of the first and second polyurethane materials respectively; and (c) lowering the temperature of the first and second shape-memory materials to a temperature below the first and second onset T g s, respectively, where the first and second shape-memory materials each maintain their respective altered geometric positions; where the first shape-memory material and the second shape-memory material are further different by a parameter selected from the group consisting of: the first onset glass transition temperature being different from the second onset glass transition temperature, the first slope change being different from the second slope change, and both. 6. The method of claim 5 , wherein the first and second shape-memory materials each comprise a polyurethane. 7. The method of claim 6 where the ratios of polyol to polyisocyanate in the polyurethanes of the first and second shape-memory materials are different. 8. The method of claim 5 where the billet has a length, and where the first shape-memory material and the second shape-memory material have a configuration selected from the group consisting of: concentric layers, where one of the shape-memory materials at least partially overlaps the other shape-memory material; side-by-side each other along at least a portion of the length of the billet; and combinations thereof. 9. A method of manufacturing a wellbore device, the method comprising: (a) mixing a polymer with a crosslinker at a first crosslinker/polymer ratio to form a first crosslinked polymer having a first original geometric position and having a first onset glass transition temperature T g ; (b) mixing the polymer with the crosslinker at a second crosslinker/polymer ratio to form a second crosslinked polymer having a second original geometric position and having a second onset glass transition temperature T g , where the first onset T g and the second onset T g are different; (c) altering the geometric shapes of the first and second crosslinked polymers at a temperature above both the first and second onset T g to change the geometric shapes of the first and second crosslinked polymers respectively; and (d) lowering the temperature of the first and second crosslinked polymers to a temperature below the first and second onset T g s, respectively, where the first and second crosslinked polymers each maintain their respective altered geometry. 10. The method of claim 9 further comprising introducing the first crosslinked polymer and the second crosslinked polymer onto a cylindrical billet. 11. The method of claim 10 where the cylindrical billet has a length, and where the first crosslinked polymer and the second crosslinked polymer have a configuration selected from the group consisting of: concentric layers, where one of the polyurethane materials at least partially overlaps the other polyurethane material; side-by-side each other along at least a portion of the length of the billet; and combinations thereof. 12. A method of installing a wellbore device on a downhole tool in a formation, the method comprising: (a) securing a downhole tool to a string of tubing, the downhole tool comprising a device comprising; a first shape-memory material, the first shape-memory material having an altered geometric position for run-in and an original geometric position, wherein the first shape-memory material is maintained in the altered geometric position for run-in below a first onset glass transition temperature T g of the first shape-memory material, the first shape-memory material comprising a cross-linked polymer having a first crosslinking ratio, and a second shape-memory material, the second shape-memory material having an altered geometric position for run-in position and an original geometric position, wherein the second shape-memory material is maintained in the altered geometric position for run-in below a second onset glass transition temperature T g of the second shap