Self-retractable coiled electrical cable

What is claimed is: 1. A self-retracting coiled cable for use in a downhole environment, the self-retracting coiled cable having a variable length along a center line comprising: an outer insulator sleeve having a longitudinal axis; a spring material positioned within the outer insulator sleeve, the spring material extending within the outer insulator sleeve along the longitudinal axis of the outer insulator sleeve, the spring material holding the outer insulator sleeve in a helical shape around the center line the spring material allowing the self-retracting coiled cable to expand upon an application of an axial force to an end of the self-retracting coiled cable, thereby increasing a length of the self-retracting coiled cable, and the spring material providing a retractive force in opposition to the axial force for retracting the self-retracting coiled cable upon a removal of the axial force from the end of the self-retracting coiled cable, thereby reducing the length of the self-retracting coiled cable; and a plurality of wires extending along the longitudinal axis of the outer insulator sleeve, the plurality of wires disposed symmetrically around the spring material. 2. The self-retracting coiled cable of claim 1 , wherein the self-retracting coiled cable is housed within a first well tool that is positionable in a wellbore, wherein the first well tool is moveable between (i) a longitudinally retracted position and (ii) a longitudinally expanded position. 3. The self-retracting coiled cable of claim 2 , wherein the self-retracting coiled cable is coupled to a downhole connector operable to couple the self-retracting coiled cable to a second well tool. 4. The self-retracting coiled cable of claim 3 , wherein the second well tool comprises a motor module, milling module, tube-cutting module, or key-shifting module. 5. The self-retracting coiled cable of claim 4 , wherein at least one of the plurality of wires is operable for transmitting a communication signal between the first well tool and the second well tool. 6. The self-retracting coiled cable of claim 2 , wherein the first well tool comprises a ball screw threadably coupled to a ball nut, the ball screw operable to cause a downward movement of the ball nut with respect to a housing of the first well tool, wherein the downward movement is operable to cause an interior mandrel to move the first well tool to the longitudinally expanded position. 7. The self-retracting coiled cable of claim 1 , wherein the outer insulator sleeve comprises a flat cross-sectional end shape, and wherein the plurality of wires and the spring material are positioned in a row. 8. The self-retracting coiled cable of claim 1 , wherein the outer insulator sleeve comprises a circular cross-sectional end shape, and wherein the plurality of wires are positioned in a circular configuration with each of the plurality of wires being equidistant from the spring material. 9. The self-retracting coiled cable of claim 1 , wherein at least two of the plurality of wires comprise different gauge sizes. 10. The self-retracting coiled cable of claim 1 , wherein a space comprising an insulator material is positioned between the spring material and each of the plurality of wires. 11. An assembly for use in a high-temperature environment, the assembly having a variable length along a center line and comprising: an outer insulator sleeve having a longitudinal axis; a spring material extending within the outer insulator sleeve along the longitudinal axis of the outer insulator sleeve, the spring material allowing the assembly to longitudinally expand and applying a force for longitudinally contracting the assembly into a helical shape while in the high-temperature environment; and a plurality of wires extending along the longitudinal axis of the outer insulator sleeve, the plurality of wires disposed symmetrically around the spring material. 12. The assembly of claim 11 , wherein the spring material holds the outer insulator sleeve in a helical shape around the center line in resistance to an axial force applied to the assembly substantially parallel to the center line. 13. The assembly of claim 11 , wherein the assembly is housed within a first well tool that is positionable in a wellbore, wherein the first well tool is moveable between (i) a longitudinally retracted position and (ii) a longitudinally expanded position. 14. The assembly of claim 13 , further comprising a downhole connector operable to couple the assembly to a second well tool. 15. The assembly of claim 14 , wherein the second well tool comprises a motor module, milling module, tube-cutting module, or key-shifting module. 16. The assembly of claim 13 , wherein the first well tool comprises a ball screw threadably coupled to a ball nut, the ball screw operable to cause a downward movement of the ball nut with respect to a housing of the first well tool, wherein the downward movement is operable to cause an interior mandrel to move the first well tool to the longitudinally expanded position. 17. The assembly of claim 11 , wherein the outer insulator sleeve comprises a flat cross-sectional end shape, and wherein the plurality of wires and the spring material are positioned in a row. 18. The assembly of claim 11 , wherein at least two of the plurality of wires comprise different gauge sizes. 19. The assembly of claim 11 , wherein a space comprising an insulator material is positioned between the spring material and each of the plurality of wires. 20. A method comprising: positioning a spring material within an outer insulator sleeve and along a longitudinal axis of the outer insulator sleeve of an electrical cable; positioning a plurality of wires along the longitudinal axis of the outer insulator sleeve and symmetrically around the spring material; and forming the electrical cable into a helical shape, wherein, the spring material allows the electrical cable to expand upon an application of an axial force to an end of the electrical cable and applies a force for retracting the electrical cable into the helical shape upon a removal of the axial force from the end of the electrical cable.