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: a plurality of planar substrates; a plurality of fusible weak spots each formed on one of the plurality of planar substrates; and a conductor separately provided from the plurality of planar substrates and the plurality of weak spots, wherein the conductor comprises an 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, the elongated strip of metal further comprising: coplanar connector sections that are attached to respective ones of the plurality of weak spots; and obliquely extending sections bent out of plane of the coplanar connector sections, wherein the plurality of weak spots are longitudinally spaced apart from one another along the conductor, and the plurality of planar substrates are longitudinally spaced apart from one another along the conductor. 2. The power fuse of claim 1 , wherein one of the plurality of fusible weak spots includes openings. 3. The power fuse of claim 1 , wherein the plurality of fusible weak spots are printed on the planar substrates. 4. The power fuse of claim 1 , wherein each of the plurality of weak spots is attached to a side of one of the coplanar connector sections the same as a valley formed by the coplanar connector section and its neighboring obliquely extending sections. 5. The power fuse of claim 4 , wherein the coplanar connector section forms a pocket sized to receive the weak spot therein. 6. The power fuse of claim 1 , wherein the coplanar connector sections are attached to respective ones of the plurality of weak spots through a first solder and a second solder, the first solder having a melting temperature higher than a melting temperature of the second solder, the first solder deposited over the respective ones of the plurality of weak spots, and the second solder deposited over the first solder. 7. 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 a plurality of planar substrates; providing a conductor separately from the plurality of planar substrates and the plurality of weak spots, wherein the conductor includes an 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, the elongated strip of metal includes coplanar connector sections and obliquely extending sections bent out of plane of the coplanar connector sections; and attaching the coplanar connector sections of the conductor to respective ones of the plurality of weak spots such that the plurality of weak spots are longitudinally spaced apart from one another along the conductor and the plurality of planar substrates are longitudinally spaced apart from one another along the conductor. 8. The method of claim 7 , wherein attaching the coplanar connector sections further comprises attaching one of the plurality of weak spots to its respective one of the coplanar connector sections at a side of the coplanar connector section opposite a valley formed by the coplanar connector section and its neighboring obliquely extending sections. 9. The method of claim 7 , wherein attaching the coplanar connector sections further comprises attaching one of the plurality of weak spots to its respective one of the coplanar connector sections at a side of the coplanar connector section the same as a valley formed by the coplanar connector section and its neighboring obliquely extending sections. 10. The method of claim 7 , wherein the conductor further includes a support bridge connecting the coplanar connector sections, the obliquely extending sections and the support bridge forming a receptacle sized to receive one of the plurality of planar substrates therein, attaching the coplanar connector sections further comprising: aligning the coplanar connector sections with the plurality of planar substrates using the support bridges and the obliquely extending sections; holding the planar substrates in place using the support bridges and the obliquely extending sections during reflow; and removing the support bridges after the coplanar connector sections of the conductor have been attached with respective ones of the plurality of weak spots. 11. The method of claim 7 , wherein forming a plurality of fusible weak spots further comprises: forming the plurality of fusible weak spots on a single piece of planar substrate; and separating the single piece of planar substrate into the plurality of planar substrates such that each planar substrate includes one weak spot. 12. The method of claim 11 , wherein forming the plurality of fusible weak spots on a single piece of planar substrate further comprises applying a first solder to the plurality of weak spots. 13. The method of claim 12 , wherein applying a first solder further comprises: stencil printing the first solder to the plurality of weak spots; and reflowing the first solder on the plurality of weak spots. 14. The method of claim 12 , wherein attaching the coplanar connector sections further comprises: dispensing a second solder on the coplanar connector sections of the conductor, wherein the second solder has a melting temperature lower than a melting temperature of the first solder; placing the plurality of weak spots with the coplanar connector sections such that the first solder and the second solder face each other; and reflowing the first solder and the second solder. 15. The method of claim 7 , wherein attaching the coplanar connector sections further comprises: placing the plurality of weak spots with the coplanar connector sections; and applying weight to at least one of the plurality of planar substrates and the coplanar connector sections. 16. The method of claim 7 , wherein one of the plurality of fusible weak spots includes openings. 17. The method of claim 7 , wherein forming a plurality of fusible weak spots further comprises forming the plurality of fusible weak spots on the plurality of planar substrates by printing the plurality of fusible weak spots on the plurality of planar substrates. 18. The method of claim 7 , wherein one of the coplanar connector sections forms a pocket sized to receive one of the plurality of weak spots, attaching the coplanar connector sections further comprising: disposing the weak spot into the pocket. 19. 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: one or more substrates; one or more fusible weak spots each printed on one of the one or more substrates; and a conductor separately provided from the one or more substrates and the one or more weak spots, wherein the conductor comprises an 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, the elongated strip of metal further comprising: coplanar