Fabrication of printed fuse

What is claimed is: 1. A power fuse for protecting an electrical load subject to transient load current cycling events in a direct current electrical power system, the power fuse comprising: at least one fuse element assembly comprising: an elongated planar substrate; a plurality of fusible weak spots formed on the planar substrate and being longitudinally spaced from one another on the planar substrate; and a conductor separately provided from the planar substrate and the plurality of weak spots; wherein the conductor comprises a solid elongated strip of metal having no stamped weak spot openings therein and therefore avoiding thermal-mechanical fatigue strain in the conductor when subjected to the transient load current cycling events; wherein the solid elongated strip of metal includes coplanar connector sections that are mounted to respective ones of the plurality of weak spots on the planar substrate and obliquely extending sections bent out of plane of the connector sections to extend above the elongated planar substrate in between the plurality of fusible weak spots; wherein the conductor further comprises first and second terminal tabs that extend coplanar to one another in a plane parallel to but spaced from the connector sections and the substrate. 2. The power fuse of claim 1 , further comprising an arc quenching media that surrounds at least part of the at least one fuse element assembly. 3. The power fuse of claim 1 , wherein the at least one fuse element assembly further comprises a dielectric layer formed over the substrate and nested between the substrate and the plurality of weak spots. 4. The power fuse of claim 1 , wherein the conductor is formed in one piece. 5. The power fuse of claim 1 , wherein the substrate is alumina ceramic. 6. The power fuse of claim 1 , further comprising a housing enclosing the at least one fuse element assembly. 7. The power fuse of claim 1 , wherein the plurality of fusible weak spots are printed on the planar substrate. 8. The power fuse of claim 1 , wherein the power fuse has a voltage rating of at least 500 V. 9. The power fuse of claim 1 , wherein the power fuse has a current rating of at least 150 A. 10. The power fuse of claim 1 , wherein the at least one fuse element assembly comprises first and second fuse element assemblies electrically connected in parallel with each other. 11. A method of fabricating a power fuse for protecting an electrical load subject to transient load current cycling events in a direct current electrical power system, the method comprising: forming a plurality of fusible weak spots on an elongated planar substrate such that the plurality of fusible weak spots are longitudinally spaced from one another on the planar substrate; providing a conductor separately from the planar substrate and the plurality of weak spots, wherein the conductor comprises a solid elongated strip of metal having no stamped weak spot openings therein and therefore avoiding thermal-mechanical fatigue strain in the conductor when subjected to the transient load current cycling events; wherein the solid elongated strip of metal includes coplanar connector sections and obliquely extending sections bent out of plane of the connector sections; and wherein the conductor further comprises first and second terminal tabs that extend coplanar to one another; and mounting the coplanar connector sections of the conductor to respective ones of the plurality of weak spots on the planar substrate such that the obliquely extending sections of the conductor extend above the elongated planar substrate in between the plurality of fusible weak spots and the first and second terminal tabs extend coplanar to one another in a plane parallel to but spaced from the coplanar connector sections and the substrate, thereby completing a first fuse element assembly. 12. The method of claim 11 , further comprising surrounding at least part of the first fuse element assembly with an arc quenching medium. 13. The method of claim 11 , wherein forming a plurality of weak spots comprises printing the plurality of weak spots on the elongated planar substrate. 14. The method of claim 11 , wherein forming a plurality of weak spots further comprises: providing a dielectric layer on the substrate; and forming the plurality of weak spots over the dielectric layer to cover the dielectric layer and to nest the dielectric layer between the substrate and the plurality of weak spots. 15. The method of claim 14 , wherein forming a dielectric layer comprises printing the dielectric layer on the substrate, and forming the plurality of weak spots comprises printing the plurality of weak spots over the dielectric layer to cover the dielectric layer and to nest the dielectric layer between the substrate and the plurality of weak spots. 16. The method of claim 11 , wherein providing a conductor further comprises forming the conductor in one piece. 17. The method of claim 16 , wherein the conductor is formed with support bridges connecting the coplanar connector sections, and mounting the coplanar connector sections further comprises removing the support bridges after the coplanar connector sections of the conductor have been mounted on respective ones of the plurality of weak spots. 18. The method of claim 11 , wherein the substrate comprises alumina ceramic. 19. The method of claim 11 , further comprising: forming a second fuse element assembly; and electrically connecting the first and second fuse element assemblies in parallel with each other. 20. The method of claim 11 , further comprising: electrically connecting the first and second terminal tabs of the conductor with first and second conductive terminals; and enclosing the first fuse element assembly with a housing, leaving at least part of the first and second conductive terminals exposed.