NANOSAT electrothermal deployment system

What is claimed is: 1. A deployment system configured for controlled release of apparatus relative to small satellites, comprising: an electrical power source; a reusable energy release device in communication with the power source, the energy release device including an insulative material, and including a resistive element overlying the insulative material for generating heat via the electrical power source; a fusible line affixed to a structural component of the satellite, the fusible line also affixed to at least one deployable apparatus secured to the satellite; wherein the fusible line is configured for contact with the energy release device, and can be melted by the heat of the resistive element, for deployment of the apparatus. 2. The deployment system of claim 1 , wherein the energy release device is a burn bar, and wherein the resistive element is a resistor pad. 3. The deployment system of claim 2 , wherein the burn bar is a cylindrical tube containing the resistor pad, and wherein the resistor pad overlies an external portion of the tube. 4. The deployment system of claim 2 , wherein the fusible line is secured under a tensile force against the resistor pad. 5. The deployment system of claim 1 , wherein the fusible line is a monofilament. 6. The deployment system of claim 1 , wherein a direct contact of the fusible line may be assured by maintaining the line under tension. 7. The deployment system of claim 2 , wherein the burn bar is a solid cylinder. 8. A burn bar adapted to melt a fusible line to cause deployment of an apparatus secured to a small satellite, the burn bar comprising: a reusable resistive element having a substrate body secured to the satellite; an insulative material deposited on an outer surface of the substrate body; a layer of electroconductive material deposited over an external portion of the insulative material; wherein the layer of electroconductive material is a resistor pad; and wherein the fusible line comprises a monofilament secured directly against the resistor pad, such that when the monofilament is electrically heated to its melting point an apparatus secured to the monofilament is released. 9. The burn bar of claim 8 , wherein the monofilament is secured under tension against the resistor pad. 10. The burn bar of claim 9 , wherein the monofilament is under a tensile force of between 10 and 15 pounds. 11. The burn bar of claim 8 , wherein the substrate body comprises a cylindrical tube, and wherein the resistor pad overlies an external portion of the tube. 12. The burn bar of claim 8 , wherein the monofilament is formed of nylon. 13. The burn bar of claim 8 , further comprising a tubular body. 14. The burn bar of claim 8 , further comprising solid Chevron shaped body. 15. A method of deploying an apparatus secured by a fusible line to a nanosat, the method comprising the steps of: providing a resistive element having a substrate body, and securing the substrate body to the nanosat; depositing an insulative material on a peripheral surface of the substrate body; depositing a layer of electroconductive material over portions of the insulative material to form a resistor pad; providing an electrical source within the nanosat, and connecting the resistor pad to the electrical source; and causing the electrical source to heat the fusible line to its melting point to release the apparatus. 16. The method of claim 15 , further comprising stringing a fusible line directly over the resistor pad, and securing the fusible line to the nanosat. 17. The method of claim 16 , further comprising attaching the fusible line to the apparatus to be released. 18. The method of claim 16 , further comprising applying tension to the fusible line to assure direct contact between the fusible line and the electroconductive material until time of apparatus release. 19. The method of claim 16 , further comprising providing an electrical current from the electrical source through the fusible line sufficient to heat the fusible line to its melting point to release the apparatus. 20. The method of claim 19 , further comprising laser etching the electroconductive material to form the resistor pad.