Translatable heat shrink oven for applying heat shrink film to a silicone rubber bladder

Having thus described various embodiments of the invention, what is claimed as new and desired to be protected by Letters Patent includes the following: 1. A heat shrink apparatus for heat shrinking a shrink film to a bladder, the heat shrink apparatus comprising: a support structure; a hollow heat chamber with opposing end openings, wherein the heat chamber comprises one or more heating elements and is configured to translate over the shrink film and the bladder along the support structure; an actuator configured for translating the heat chamber along a linear path along the support structure down a length of the shrink film and the bladder; and a bladder support system having a plurality of resilient members, wherein the resilient members are spaced apart from each other along a length of the support structure and are at least one of pivotally and resiliently attached to the support structure, wherein the resilient members are configured for cooperatively supporting the shrink film and bladder resting thereon. 2. The heat shrink apparatus of claim 1 , wherein the heat chamber is configured to contact the resilient members during translation of the heat chamber in such a way as to pivot or deflect the resilient members from a first position to a second position such that the heat chamber can pass by the resilient members while the shrink film and bladder rest on and remain cooperatively supported by the resilient members. 3. The heat shrink apparatus of claim 1 , further comprising translation elements slidably connecting the heat chamber with the support structure. 4. The heat shrink apparatus of claim 1 , further comprising a control system in communication with at least one of the actuator and the heating elements and configured to control at least one of velocity of the heat chamber and a temperature of the heating elements. 5. The heat shrink apparatus of claim 1 , further comprising a cooling apparatus configured to blow cool air into the heat chamber, wherein the cooling apparatus is configured to turn on automatically when the heat chamber stops translating over the shrink film and the bladder. 6. The heat shrink apparatus of claim 5 , wherein the cooling apparatus comprises a first air knife at one of the end openings of the heat chamber configured for pulling air out from the heat chamber and a second air knife at another of the end openings of the heat chamber configured for forcing air into the heat chamber. 7. The heat shrink apparatus of claim 1 , further comprising a tensioning system configured to attach to opposing ends of the shrink film and to apply a tensile load to the opposing ends of the shrink film. 8. The heat shrink apparatus of claim 4 , wherein the shrink film is at least one of a heat-shrinkable fluorinated ethylene propylene (FEP) tubing, ethylene, tetrafluorethylene (ETFE) tubing, polyethylene (PE) tubing, polyvinyl fluoride (PVF) tubing. 9. A heat shrink apparatus for heat shrinking a shrink film to a bladder, the heat shrink apparatus comprising: a support structure; a bladder support system having two spaced apart parallel rows of a plurality of pivotal rigid flappers, wherein the flappers in each row are laterally spaced apart from each other and at least one of pivotally and resiliently attached to the support structure, wherein the parallel rows of the flappers are configured for cooperatively supporting the shrink film and bladder thereon; a hollow heat chamber with opposing end openings, wherein the heat chamber comprises one or more heating elements operable to increase a temperature within the heat chamber, wherein the heat chamber is further configured to extend around a portion of the bladder, laterally slide forward and aft over the shrink film and the bladder along the support structure between the two spaced apart parallel rows, and to contact ends of the flappers during translation of the heat chamber, thereby pivoting the flappers from a first position to a second position such that the heat chamber can pass between the two parallel rows; translation elements slidably coupling the heat chamber with the support structure; and an actuator configured for translating the heat chamber along a linear path along the support structure on the translation elements down a length of the shrink film and the bladder. 10. The heat shrink apparatus of claim 9 , further comprising a control system in communication with at least one of the actuator and the heating elements and configured to control at least one of velocity of the heat chamber and a temperature of the heating elements. 11. The heat shrink apparatus of claim 1 , further comprising a cooling apparatus configured to blow cool air into the heat chamber, wherein the cooling apparatus is configured to turn on automatically when the heat chamber stops laterally sliding forward or aft over the shrink film and the bladder. 12. The heat shrink apparatus of claim 11 , wherein the cooling apparatus comprises a first air knife at one of the end openings of the heat chamber configured for pulling air out from the heat chamber and a second air knife at another of the end openings of the heat chamber configured for forcing air into the heat chamber. 13. The heat shrink apparatus of claim 9 , wherein the flappers are pivotally connected to the support structure by hinges and are each biased in the first position when the heat chamber is not contacting the flappers. 14. The heat shrink apparatus of claim 9 , wherein the heat chamber comprises a base and a lid pivotally attached to the base and actuatable between an open position and a closed position. 15. The heat shrink apparatus of claim 9 , further comprising a tensioning system configured to attach to opposing ends of the shrink film and to apply a tensile load to the opposing ends of the shrink film. 16. The heat shrink apparatus of claim 10 , wherein the shrink film is at least one of a heat-shrinkable fluorinated ethylene propylene (FEP) tubing, ethylene, tetrafluorethylene (ETFE) tubing, polyethylene (PE) tubing, polyvinyl fluoride (PVF) tubing, wherein the velocity and temperature is sufficient to heat shrink the FEP, ETFE, PE, or PVF tubing. 17. A method for heat shrinking a shrink film to a bladder, the method comprising: applying the shrink film, in an expanded configuration, over the bladder and a breather positioned over the bladder; placing the shrink film, breather, and bladder onto a bladder support system of a heat shrink apparatus, the bladder support system having two spaced apart parallel rows of a plurality of pivotal rigid flappers, wherein the flappers in each row are laterally spaced apart from each other and at least one of pivotally and resiliently attached to a support structure, wherein the parallel rows of the flappers are configured for cooperatively supporting the shrink film and bladder thereon; attaching opposing ends of the shrink film to the heat shrink apparatus in a configuration to apply a tensile load along a length of the shrink film; placing a heated heat chamber around a portion of the shrink film and the bladder; and translating the heat chamber at least one of forward and aft along a length of the shrink film, the breather, and the bladder, shrinking the shrink film to the breather and the bladder and contacting ends of the flappers during translation of the heat chamber, thereby pivoting the flappers from a first position to a second position in which the heat chamber can pass between the two parallel rows. 18. The method of claim 17 , further comprising a step of controlling at least