Compact high voltage power fuse and methods of manufacture

What is claimed is: 1. A method of manufacturing a high voltage power fuse comprising: connecting a full-range fuse element assembly across a gap between a first terminal fabrication and a second terminal fabrication, the full-range fuse element assembly including first and second metal strip fuse elements defining a plurality of weak spots therein and being connected in parallel to one another, the first metal strip fuse element configured to respond to a short circuit current condition and the second metal strip fuse element configured to respond to an overload current condition; configuring a first set of arc barriers at a first set of locations to surround respective cross sectional portions of the first metal strip fuse element and a second set of arc barriers at a second set of locations to surround respective cross sectional portions of the second metal strip fuse element, wherein the first and second sets of arc barriers are configured to prevent arcing from reaching the first and second terminal fabrications during an opening of the full-range fuse element assembly at one or more of the plurality of weak spots of the first and second metal strip fuse elements, wherein the first set of arc barriers that are configured at the first set of locations separate the first metal strip fuse element from the first and second terminal fabrications, and wherein the second set of arc barriers that are configured at the second set of locations separate the second metal strip fuse element from the first and second terminal fabrications; enclosing the full-range fuse element assembly, the first set of arc barriers, and the second set of arc barriers in a housing after the full-range fuse element is connected and after the first set of arc barriers are configured and the second set of arc barriers are configured; introducing a silicated filler material mixture to the housing to surround and bond to an exposed surface of the full-range fuse element assembly not covered by the first set of arc barriers and the second set of arc barriers and further to a portion of each of the first and second terminal fabrications inside the housing; and drying the silicated filler material mixture. 2. The method of claim 1 , wherein each of the first and second terminal fabrications includes an end plate and a contact block provided on the end plate; wherein connecting a full-range fuse element assembly across a gap between a first terminal fabrication and a second terminal fabrication includes directly attaching opposing ends of the first and second metal strip fuse elements to the contact block of each of the first and second terminal fabrication. 3. The method of claim 1 , wherein each of the first and second terminal fabrications includes a terminal blade, the method further comprising forming a right angle bend in at least one of the terminal blades. 4. The method of claim 1 , wherein each of the first and second terminal fabrications includes an end plate and a terminal blade, the method further comprising: passing an end of the terminal blade through an opening in the end plate; and directly attaching opposing ends of the first and second metal strip fuse elements to the end of the terminal blade. 5. The method of claim 1 , wherein each of the first and second terminal fabrications includes an end plate and a terminal blade, the terminal blades each including apertures formed therein; the method further comprising: fastening each of the terminal blades in the first and second terminal fabrication, via the apertures in the terminal blades, to respective ones of opposing legs of a C-shaped assembly frame; and connecting the full-range fuse element assembly across the gap between a first terminal fabrication and a second terminal fabrication while the terminal blades are fastened to the respective ones of opposing legs of the C-shaped assembly frame. 6. The method of claim 5 , further comprising: prior to fastening of the terminal blades in the first and second terminal fabrication to respective ones of opposing legs of the C-shaped assembly frame, sliding the housing over one of the opposing legs of the C-shaped assembly frame; connecting the full-range fuse element assembly across the gap with the housing in place over one of the opposing legs of the C-shaped assembly frame; after the full-range fuse element assembly is connected, sliding the housing over the one of the opposing legs of the C-shaped assembly frame and over the connected full-range fuse element assembly; and securing the housing to the first and second terminal fabrications to enclose the full-range fuse element assembly. 7. The method of claim 6 , wherein introducing the silicated filler material mixture to the housing is performed while the terminal blades in the first and second terminal fabrication are fastened to the respective ones of opposing legs of the C-shaped assembly frame. 8. The fuse produced by the method of claim 1 , wherein the housing has a compact axial length of about 1.5 inches to about 3 inches, the fuse has a voltage rating of at least 500 VDC and a current rating of 150 A to 400 A, and the fuse has a power density of about 9.0 A/cm to A/cm 3 to about 11.25 A/cm 3 .