초록 ▼

A novel shaped charge device that produces a hollow cylindrical jet capable of creating a hole in a target larger than the overall diameter of the device. In the conical family of axisymmetric circular linear shaped charge liners (Conical, Tulip, and Trumpet), this novel swept conical-like profile s

A novel shaped charge device that produces a hollow cylindrical jet capable of creating a hole in a target larger than the overall diameter of the device. In the conical family of axisymmetric circular linear shaped charge liners (Conical, Tulip, and Trumpet), this novel swept conical-like profile shaped explosive device produces a large diameter stretching hollow cylindrical jet and corresponding slug. The hollow jet is formed by peripherally initiating a high explosive (HE) that collapses the circular linear liner into the hollow cylindrical jet. The precision of the circular simultaneous peripheral initiation of the HE billet is accomplished by the use of a novel Circular Precision Initiation Coupler (CPIC). This CPIC uses a single point initiation to create a simultaneous peripheral detonation of the HE billet that collapses and drives the swept liner into a high speed stretching hollow cylindrical projectile, or more commonly called a jet in the industry.

대표청구항 ▼

1. An axisymmetric circular linear shaped charge device, comprising: a liner configured in a partial toroid with a longitudinal axis intersecting an aperture located near the center of said partial toroid, said partial toroid being open-ended on a plane that intersects said longitudinal axis in a pe

1. An axisymmetric circular linear shaped charge device, comprising: a liner configured in a partial toroid with a longitudinal axis intersecting an aperture located near the center of said partial toroid, said partial toroid being open-ended on a plane that intersects said longitudinal axis in a perpendicular manner toward a front end of the shaped charge device, said liner having a hollow conical cross-section extending toward a closed end of the partial toroid as defined by a longitudinal plane that is aligned on said longitudinal axis and an apex of said conical cross-section at a closed end of the partial toroid that extends toward a rear end of said shaped charge device, said liner having an outer surface and an inner surface, said inner surface exposed toward the open end of the front end of the shaped charge device and said liner producing an explosive hollow cylindrical jet stream directed toward said front of said shaped charge device upon detonation of the shaped charge device;a billet of high explosive material having a front end and a rear end located behind and proximate to the outer surface of said liner, said billet configured as a toroid with an internal aperture located proximate to the aperture of the liner, and said billet producing a high explosive detonation effect applied to said liner to produce said hollow cylindrical jet stream;a coupler located in a rear portion of the shaped charge device, said coupler coupled to the rear end of the billet and said coupler producing a detonation wave initiating the high explosive detonation effect of the billet; anda body located around the outer surface of the billet and extending longitudinally the length of the billet, said body having a front end secured to said liner and, said body having a rear end secured to the coupler. 2. The shaped charge of claim 1, further comprising: an attenuator located proximate to the aperture in the billet, said attenuator dampening a detonation wave. 3. The shaped charge of claim 1, wherein said coupler initiates a ring initiation at the rear end of the billet to produce the detonation wave and initiate the high explosive detonation effect of the billet. 4. The shaped charge of claim 1, wherein the coupler provides the critical alignment of the detonator with the coupler high explosive on the longitudinal axis of the shaped charge and provides the critical alignment of the coupler high explosive with the billet which to allow for a precise ring initiation of the billet. 5. The shaped charge of claim 1, further comprising: a center body located proximate to the aperture of said liner and rearward of the billet toward the rear portion of the shaped charge device. 6. The shaped charge of claim 5, wherein the center body is hollow and provides a space for shock attenuation materials used to dampen shock waves. 7. The shaped charge of claim 6, wherein the space within the hollow center body can be used to contain a center projectile producing device. 8. An axisymmetric circular linear shaped charge device, comprising: a liner configured in a partial toroid with a longitudinal axis intersecting an aperture located near the center of said partial toroid, said partial toroid being open-ended on a plane that intersects said longitudinal axis in a perpendicular manner toward a front end of the shaped charge device, said liner having a hollow conical cross-section extending toward a closed end of the partial toroid as defined by a longitudinal plane that is aligned on said longitudinal axis and an apex of said conical cross-section at a closed end of the partial toroid that extends toward a rear end of said shaped charge device, said liner having an outer surface and an inner surface, said inner surface exposed toward the open end of the front end of the shaped charge device and said liner producing an explosive hollow cylindrical jet stream directed toward said front of said shaped charge device upon detonation of the shaped charge device;a billet of high explosive material having a front end and a rear end located behind and proximate to the outer surface of said liner, said billet configured as a toroid with an internal aperture located proximate to the aperture of the liner, and said billet producing a high explosive detonation effect applied to said liner to produce said hollow cylindrical jet stream;a coupler located in a rear portion of the shaped charge device, said coupler coupled to the rear end of the billet and said coupler producing a detonation wave initiating the high explosive detonation effect of the billet;a body located around the outer surface of the billet and extending longitudinally the length of the billet, said body having a front end secured to said liner and, said body having a rear end secured to the coupler; andsaid shaped charge device producing an explosive hollow cylindrical jet upon detonation of said shaped charge device, said hollow cylindrical jet forming a hole in a target material that is wider than the outer diameter of the shaped charge device. 9. The shaped charge of claim 8, further comprising: an attenuator located proximate to the aperture in the billet, said attenuator dampening a detonation wave. 10. The shaped charge of claim 8, wherein said coupler initiates a ring initiation at the rear end of the billet to produce the detonation wave and initiate the high explosive detonation effect of the billet. 11. The shaped charge of claim 8, wherein the coupler provides the critical alignment of the detonator with the coupler high explosive on the longitudinal axis of the shaped charge and provides the critical alignment of the coupler high explosive with the billet which to allow for a precise ring initiation of the billet. 12. The shaped charge of claim 8, further comprising: a center body located proximate to the aperture of said liner and rearward of the billet toward the rear portion of the shaped charge device. 13. The shaped charge of claim 12, wherein the center body is hollow and provides a space for shock attenuation materials used to dampen shock waves. 14. The shaped charge of claim 13, wherein the space within the hollow center body can be used to contain a center projectile producing device. 15. A method of producing an axisymmetric cylindrical jet stream from a circular linear shaped charge device, comprising the steps of: providing a liner configured in a partial toroid with a longitudinal axis intersecting an aperture located near the center of said partial toroid, said partial toroid being open-ended on a plane that intersects said longitudinal axis in a perpendicular manner toward a front end of the shaped charge device, said liner having a hollow conical cross-section extending toward a closed end of the partial toroid as defined by a longitudinal plane that is aligned on said longitudinal axis and an apex of said conical cross-section at a closed end of the partial toroid that extends toward a rear end of said shaped charge device, said liner having an outer surface and an inner surface, said inner surface exposed toward the open end of the front end of the shaped charge device;positioning a billet of high explosive material behind and proximate to the outer surface of said liner, said billet being proximate to the aperture of the liner, and said billet producing a high explosive detonation effect applied to said liner to produce said hollow cylindrical jet stream;positioning a coupler at a rear portion of the shaped charge device in contact with the rear of the billet, said coupler producing a detonation wave and initiating the high explosive detonation effect of the billet;surrounding the shaped charge device with a body around the outer diameter of the billet and extending longitudinally the length of the billet; andproducing an explosive hollow cylindrical jet stream with the liner that is directed toward said front of said shaped charge device upon detonation of the shaped charge device. 16. The method of claim 15, further comprising the step of: providing an attenuator proximate to the aperture in the billet, said attenuator dampening a detonation wave. 17. The method of claim 15, wherein said coupler initiates a ring initiation at the rear end of the billet to produce the detonation wave and initiate the high explosive detonation effect of the billet. 18. The method of claim 15, wherein the coupler provides the critical alignment of the detonator with the coupler high explosive on the longitudinal axis of the shaped charge and provides the critical alignment of the coupler high explosive with the billet which to allow for a precise ring initiation of the billet. 19. The method of claim 15, further comprising the step of: positioning a center body proximate to the aperture of said liner and rearward of the billet toward the rear portion of the shaped charge device. 20. The method of claim 19, wherein the center body is hollow and provides a space for shock attenuation materials used to dampen shock waves. 21. The method of claim 20, wherein the space within the hollow center body can be used to contain a center projectile producing device. 22. The method of claim 15, further comprising the step of: producing an explosive hollow cylindrical jet upon detonation of said shaped charge device, said hollow cylindrical jet forming a hole in a target material that is wider than the outer diameter of the shaped charge device.