Systems and methods of manufacturing flexible spring members for gas spring assemblies

The invention claimed is: 1. A system for manufacturing a flexible spring member dimensioned for forming an associated gas spring assembly, said system comprising: a creel assembly supporting a plurality of spools containing at least one cord having an indeterminate length such that a plurality of cords are supported on said creel assembly; a tensioner assembly spaced apart from said creel assembly and operative to tension said plurality of cords received from said creel assembly; a building mandrel disposed in spaced relation to said tensioner assembly, said building mandrel supported for rotation about a longitudinal axis and reciprocal translation along said longitudinal axis; and, a head assembly supported in a substantially fixed longitudinal position and having a first side and a second side longitudinally opposite said first side, said head assembly including an opening extending therethrough and positioned co-axially relative to said building mandrel such that said building mandrel passes through said opening in said head assembly during reciprocal translation along said longitudinal axis, said head assembly operative to position and redirect said plurality of cords onto said building mandrel during translation and rotation of said building mandrel from said first side of said head assembly to said second side of said head assembly and during translation and rotation of said building mandrel from said second side of said head assembly to said first side of said head assembly. 2. A system according to claim 1 , wherein said creel assembly is one of a plurality of creel assemblies each supporting a plurality of spools containing at least one cord having an indeterminate length. 3. A system according to claim 1 , wherein said creel assembly includes a brake system operatively engaging at least one of said plurality of spools to generate rotational drag thereon. 4. A system according to claim 1 further comprising a cord path arrangement in which said plurality of cords are separated after said tensioner assembly into at least three groupings of cords having an approximately equal number of individual cords. 5. A system according to claim 1 further comprising a machine base supporting said building mandrel and displaceable for translation of said building mandrel along said longitudinal axis. 6. A system according to claim 1 further comprising a control system communicatively coupled with at least one of said tensioner assembly and said building mandrel for operation thereof. 7. A system for manufacturing a flexible spring member dimensioned for forming an associated gas spring assembly, said system comprising: a creel assembly supporting a plurality of spools containing at least one cord having an indeterminate length such that a plurality of cords are supported on said creel assembly; a tensioner assembly spaced apart from said creel assembly and operative to tension approximately equal predetermined lengths of said plurality of cords received from said creel assembly; a building mandrel disposed in spaced relation to said tensioner assembly, said building mandrel supported for rotation about a longitudinal axis and translation along said longitudinal axis; a cord path arrangement in which said plurality of cords are separated after said tensioner assembly into at least three groupings of cords having an approximately equal number of individual cords with at least two of said three groupings of cords separated from one another such that a clearance window providing access to said building mandrel is accessible therethrough; and, a head assembly supported in a substantially fixed longitudinal position, said head assembly including an opening extending therethrough and positioned co-axially relative to said building mandrel such that said building mandrel passes through said opening in said head assembly during translation along said longitudinal axis, said head assembly operative to position and redirect said plurality of cords onto said building mandrel during translation and rotation thereof relative to said head assembly. 8. A system according to claim 4 , wherein at least one individual cord in each of said at least three groupings of cords will have a substantially similar cord path between said tensioner assembly and said head assembly. 9. A system according to claim 8 , wherein each of said individual cords in one of said at least three groupings of cords will have a substantially similar cord path between said tensioner assembly and said head assembly as one of said individual cords in each of the remaining two of said at least three groupings of cords. 10. A method of manufacturing a flexible spring member dimensioned for use in forming a gas spring assembly, said method comprising: providing a plurality of cords having an indeterminate length; tensioning approximately equal predetermined lengths of said plurality of cords; directing said plurality of cords in a radially inward direction through a head assembly that is disposed in a fixed position; securing a first end of said plurality of cords along a building mandrel that is rotatable about a longitudinal axis and translatable through said head assembly along said longitudinal axis; applying a first layer of elastomeric material along said building mandrel; and, rotating said building mandrel in a first rotational direction about said longitudinal axis and translating said building mandrel along said longitudinal axis in a first translational direction relative to said head assembly to tow at least a portion of said predetermined lengths of said plurality of cords through said head assembly and wrap at least said portion of said predetermined lengths of said plurality of cords along said first layer of elastomeric material to form a first reinforcing layer. 11. A method according to claim 10 further comprising securing a second end of said plurality of cords along said building mandrel opposite said first end of said plurality of cords. 12. A method according to claim 11 further comprising severing said plurality of cords along said second end. 13. A method according to claim 12 further comprising applying a second layer of elastomeric material along building mandrel over said first reinforcing layer. 14. A method according to claim 13 further comprising rotating said building mandrel in said first rotational direction about said longitudinal axis and translating said building mandrel along said longitudinal axis in a second translational direction relative to said head assembly that is opposite said first translational direction to tow at least a portion of said predetermined lengths of said plurality of cords through said head assembly and wrap at least said portion of said predetermined lengths of said plurality of cords along said second layer of elastomeric material to form a second reinforcing layer. 15. A method according to claim 14 further comprising securing a third end of said plurality of cords along said building mandrel opposite said second end of said plurality of cords. 16. A method according to claim 15 further comprising severing said plurality of cords along said third end. 17. A method according to claim 16 further comprising applying a third layer of elastomeric material along building mandrel over said second reinforcing layer. 18. A method according to claim 17 further comprising curing said first, second and third layers of elastomeric material on said building mandrel to encapsulate said first and second reinforcing layers therein to form a cured elonga