High current one-piece fuse element and split body

What is claimed: 1. A high breaking capacity fuse comprising: a first outer insulative layer, the first outer insulative layer having a first cavity formed therein; a second outer insulative layer disposed on the first outer insulative layer, the second outer insulative layer having a second cavity formed therein; a cup-shaped first ceramic insert disposed within the first cavity; a cup-shaped second ceramic insert disposed within the second cavity, wherein the first and second ceramic inserts fit together to define a chamber; and a single piece fusible element disposed between the first outer insulative layer and the second outer insulative layer, the single piece fusible element comprising a first terminal portion, a second terminal portion, a fusible element portion having a plurality of rolls along its longitudinal axis, a first mid portion connecting the fusible element portion to the first terminal portion, and a second mid portion connecting the fusible element to the second terminal portion, wherein the fusible element portion is disposed at least partially within the chamber, wherein the first terminal portion extends along at least one outer surface of the second outer insulative layer, and the second terminal portion extends along at least one outer surface of the second outer insulative layer; wherein each of the first and second terminal portions has grooves formed in opposing sides thereof, and wherein the first outer insulative layer includes tongue portions formed in a top edge thereof, the tongue portions disposed within the grooves. 2. The high breaking capacity fuse of claim 1 , wherein the single piece fusible element is formed from a single piece of conductive material and the fusible element portion comprises a plurality of cutouts disposed along the plurality of rolls. 3. The high breaking capacity fuse of claim 2 , wherein the single piece fusible element comprises a first bend between the first terminal portion and the fusible element portion and a second bend between the second terminal portion and the fusible element portion. 4. The high breaking capacity fuse of claim 3 , wherein the first terminal portion extends along at least a first and a second outer surface of the second outer insulative layer and the second terminal portion extends along at least the second and a third outer surface of the second outer insulative layer. 5. The high breaking capacity fuse of claim 4 , wherein the plurality of bends of the single piece fusible element further comprises a third bend disposed in a distal end of the first terminal portion and a fourth bend disposed in a distal end of the second terminal portion. 6. The high breaking capacity fuse of claim 5 , the first terminal portion comprising a first sub portion arranged between the first and third bend and a second sub portion arranged between the third bend and an end of the first terminal portion, wherein the first sub portion is substantially parallel to the first outer surface and the second sub portion is substantially parallel to the second outer surface. 7. The high breaking capacity fuse of claim 5 , the second terminal portion comprising a first sub portion arranged between the first and third bend and a second sub portion arranged between the third bend and an end of the first terminal portion, wherein the first sub portion is substantially parallel to the third outer surface and the second sub portion is substantially parallel to the second outer surface. 8. The high breaking capacity fuse of claim 1 , wherein the first outer insulative layer and the second outer insulative layer are joined via an ultrasonic welding process. 9. A method comprising: providing a single piece fusible element, the single piece fusible element comprising a first terminal portion, a second terminal portion, a fusible element portion, a first mid portion connecting the fusible element portion to the first terminal portion, and a second mid portion connecting the fusible element portion to the second terminal portion; providing a first outer insulative layer, the first outer insulative layer having a first cavity formed therein; providing a second outer insulative layer, the second outer insulative layer having a second cavity formed therein; providing a cup-shaped first ceramic insert disposed within the first cavity; providing a cup-shaped second ceramic insert disposed within the second cavity, wherein the first and second ceramic inserts fit together to define a chamber; placing the single piece fusible element between the first and the second outer insulative layers with the fusible element portion at least partially disposed within the chamber; and bending the first and second terminal portions out of parallel with the fusible element portion; wherein each of the first and second terminal portions has grooves formed in opposing sides thereof, and wherein the first outer insulative layer includes tongue portions formed in a top edge thereof, the tongue portions disposed within the grooves. 10. The method of claim 9 , wherein the first terminal portion extends along at least one outer surface of the second outer insulative layer and the second terminal portion extends along at least one outer surface of the second outer insulative layer. 11. The method of claim 10 , comprising bending end portions of the first and second terminal portion out of parallel with mid portions of the first and second terminal portions. 12. The method of claim 11 , wherein the first terminal portion extends along at least a first and a second outer surface of the second outer insulative layer and the second terminal portion extends along at least the second and a third outer surface of the second outer insulative layer. 13. The method of claim 12 , wherein the single piece fusible element comprises a third bend disposed in a distal end of first terminal portion and a fourth bend disposed in a distal end of the second terminal portion. 14. The method of claim 9 , comprising joining the first and second outer insulative layers via an ultrasonic welding process.