Elevator tension member

What is claimed is: 1. A tension member for an elevator system, the tension member longitudinally extending along a longitudinal axis and comprising: a plurality of fibers formed into one or more primary strands or cords extending parallel to the longitudinal axis; a plurality of fibers formed into one or more secondary strands or cords extending along the longitudinal axis and through less than a full length of the tension member; and a jacket at least substantially retaining the one or more primary and one or more secondary strands or cords, the one or more secondary strands or cords having a tensile modulus greater than a tensile modulus of the jacket and less than a tensile modulus of the one or more primary strands or cords, the jacket having a jacket width and jacket thickness, the jacket width greater than the jacket thickness; wherein each and every of the one or more primary strands or cords is positioned within a primary tension zone and each and every of the one or more secondary tension strands or cords is positioned outside of the primary tension zone; wherein the primary tension zone is defined by two imaginary planes parallel and equidistant to a center axis of the tension member, the two imaginary planes being parallel to a surface of the jacket corresponding to the jacket width. 2. The tension member of claim 1 , wherein the tensile modulus of the one or more secondary strands or cords is at least about ten times the tensile modulus of the jacket. 3. The tension member of claim 2 , wherein the tensile modulus of the one or more primary strands or cords is about 10-100 times of the tensile modulus of the one or more secondary strands or cords. 4. The tension member of claim 2 , wherein the jacket is made of polyurethane and wherein the one or more primary strands or cords are made of steel. 5. The tension member of claim 2 , wherein the one or more secondary strands or cords are made of aramid. 6. The tension member of claim 5 , wherein the aramid is a para-aramid. 7. The tension member of claim 1 , wherein all of the one or more primary strands or cords are coplanar. 8. The tension member of claim 1 , wherein the one or more secondary strands or cords are located on one side of the primary tension zone. 9. The tension member of claim 1 , wherein the one or more secondary strands or cords are located on both sides of the primary tension zone. 10. An elevator system comprising a traction sheave in frictional contact with the tension member of claim 1 . 11. The elevator system of claim 10 , wherein each of the one or more secondary strands or cords is longer than a contact length between the tension member and traction sheave. 12. The elevator system of claim 10 , further comprising a driving machine that rotates the traction sheave. 13. The elevator system of claim 12 , wherein the tension member extends between an elevator car and a counterweight. 14. A method of forming an elevator tension member extending along a longitudinal axis, the method comprising: arranging primary strands or cords along the longitudinal axis; arranging secondary strands or cords along the longitudinal axis; and at least substantially retaining the primary and secondary strands or cords in a jacket, the secondary strands or cords being shorter than the primary strands or cords and extending less than a full length of the belt, and the secondary strands or cords having a tensile modulus greater than a tensile modulus of the jacket and less than a tensile modulus of the primary strands or cords, the jacket having a jacket width and jacket thickness, the jacket width greater than the jacket thickness; wherein each and every of the primary strands or cords is positioned within a primary tension zone and each and every of the secondary tension strands or cords is positioned outside of the primary tension zone; wherein the primary tension zone is defined by two imaginary planes parallel and equidistant to a center axis of the tension member, the two imaginary planes being parallel to a surface of the jacket corresponding to the jacket width. 15. The method of claim 14 , wherein the primary strands or cords have a tensile modulus that is 10-100 times of a tensile modulus of the secondary strands or cords. 16. The method of claim 14 , wherein the secondary strands or cords are retained in the jacket before the primary strands or cords. 17. The method of claim 14 , wherein the primary strands or cords are retained in the jacket before the secondary strands or cords. 18. The method of claim 14 , wherein the primary strands or cords are retained in a first portion of the jacket and the secondary strands or cords are retained in a second portion of the jacket before the first and second portions of the jacket are fused together to form the tension member. 19. An elevator system comprising: a traction sheave; and a tension member engaging the traction sheave along a contact length, the tension member longitudinally extending along a longitudinal axis and comprising: a plurality of fibers formed into one or more primary strands or cords extending parallel to the longitudinal axis; a plurality of fibers formed into one or more secondary strands or cords extending parallel to the longitudinal axis; and a jacket at least substantially retaining the one or more primary strands or cords and the one or more secondary strands or cords, the one or more secondary strands or cords having a tensile modulus greater than a tensile modulus of the jacket and less than a tensile modulus of the one or more primary strands or cords, wherein the one or more primary strands or cords have a length greater than the contact length and the one or more secondary strands or cords have a length equal to the contact length the between tension member and traction sheave, the jacket having a jacket width and jacket thickness, the jacket width greater than the jacket thickness; wherein each and every of the one or more primary strands or cords is positioned within a primary tension zone and each and every of the one or more secondary tension strands or cords is positioned outside of the primary tension zone; wherein the primary tension zone is defined by two imaginary planes parallel and equidistant to a center axis of the tension member, the two imaginary planes being parallel to a surface of the jacket corresponding to the jacket width.