Explosively propelled piston assembly

Abstract

An explosively propelled piston assembly (EPPA) comprising an optional mounting plate; at least one lower cylinder fastener; a breach bolt with a base and an upward extending member; a breach plate having a plurality of surround openings; a breach gasket having a plurality of openings; a combustion piston with a base, a center opening, and upward extending side wall and a threaded opening; a piston dampening ring; a combustion cylinder having an upper section, a lower section, upward extending members and at least one ventilation bore; and a plurality of threaded plate fasteners. Once the EPPA is assembled, an explosive charge is placed into the EPPA. The charge is then activated which produces a contained explosive force that actuates the piston, causing the piston to extend outward, applying the force onto an object in contact with or adjacent to the EPPA. The force can be used to produce pushing, flipping, rolling or other movement of the object.

Claims

1. An explosively propelled piston assembly comprising: at least one lower cylinder fastener, a breach bolt with: a base, an upward extending member, a breach plate having a plurality of surround openings, a breach gasket having a plurality of openings, a combustion piston having: a base, a center opening, an upward extending side wall, a threaded opening, a piston dampening ring, a combustion cylinder having: an upper section, a lower section, upward extending members, at least one ventilation bore and a plurality of threaded plate fasteners.

2. The explosively propelled piston assembly of claim 1, wherein an explosive charge is configured within the piston assembly to produce a contained explosive force that causes the piston to extend outward, thereby applying the force onto an object in contact with or adjacent to the piston assembly.

3. The explosively propelled piston assembly of claim 1, wherein the piston assembly is made of metal selected from the group consisting of steel, aluminum, titanium, and a metal composite.

4. The explosively propelled piston assembly of claim 1, wherein the piston assembly is made of carbon fiber.

5. The explosively propelled piston assembly of claim 1, wherein the piston assembly is configured to produce movement of an object, the movement selected from the group consisting of pushing, flipping and rolling.

6. The explosively propelled piston assembly of claim 1, wherein the piston assembly is configured to function as an impact device.

7. The explosively propelled piston assembly of claim 1, wherein the piston assembly is configured to function as a support structure.

8. The explosively propelled piston assembly of claim 1, wherein the piston assembly is watertight.

9. An explosively propelled piston assembly comprising: a mounting plate having a circular center opening and at least one corner opening, securing means inserted through the at least one corner opening and into a surface, a plurality of lower cylinder fasteners extending upward from the mounting plate in a circular configuration, a breach bolt extending upward at a center of the fasteners and mounting plate center opening, the breach bolt comprising a base and an upward extending member, a breach plate located above the breach bolt and having surround openings into which the plurality of lower cylinder fasteners are inserted, and with the breach bolt's upward extending member extending upward through the substantial center of the breach plate, a breach gasket having a plurality of openings that are configured to correspond to the fasteners extending upward through the breach plate, a combustion piston that extends upward from the breach plate, and having a base, a center opening, an upward extending side wall, and a threaded opening, a combustion dampening ring that is located above and interfaces with an upper end of the combustion piston, a combustion cylinder comprising an upper section, a lower section, upward extending members circumventing a perimeter of the lower section, and at least one ventilation bore extending through the combustion cylinder, a combustion piston adapter plate located above the combustion cylinder and having plate bores and at least one corner opening, a plurality of threaded plate fasteners extending downward into and through the adapter plate, and into corresponding openings on an upper end of the combustion piston, and an explosive charge that is placed into the piston assembly and when activated produces a contained explosive force that actuates the piston, causing the piston to extend outward, applying the force onto an object in contact with or adjacent to the piston assembly.

10. The explosively propelled piston assembly of claim 9, wherein the piston assembly is made of metal selected from the group consisting of steel, aluminum, titanium, and a metal composite.

11. The explosively propelled piston assembly of claim 9, wherein the piston assembly is made of carbon fiber.

12. The explosively propelled piston assembly of claim 9, wherein the piston assembly is configured to produce movement of an object, the movement selected from the group consisting of pushing, flipping and rolling.

13. The explosively propelled piston assembly of claim 1, wherein the piston assembly is configured to function as an impact device.

14. The explosively propelled piston assembly of claim 1, wherein the piston assembly is configured to function as a support structure.

15. The explosively propelled piston assembly of claim 1, wherein the piston assembly is watertight.

16. The explosively propelled piston assembly of claim 9, wherein the securing means are selected from the group consisting of at least one screw, at least one bolt, at least one nail and an adhesive.

17. The explosively propelled piston assembly of claim 9, wherein the ventilation bores allow an explosive or pneumatic gas to escape as the piston extends outward, and once the piston is at a final extended length engaging the piston dampening ring, the ventilation bores allow gas to escape, thereby relieving pressure within the piston assembly.

18. The explosively propelled piston assembly of claim 9, wherein the combustion piston adapter plate is configured for a variety of applications or is configured for a single-use specific application.

19. The explosively propelled piston assembly of claim 9, wherein the explosive force is a contained explosive force which results in control and lessening of reactionary effects that occur when using an explosive.

20. The explosively propelled piston assembly of claim 9, wherein the components of the piston assembly are assembled utilizing an opposed keyed interface that is maintained by at least one screw.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is an elevational side view showing an explosively propelled piston assembly (EPPA).

(2) FIG. 2 is an exploded view showing the EPPA.

(3) FIG. 3 is an elevational side view showing the EPPA breach bolt.

(4) FIG. 4 is a top plan view showing the EPPA combustion piston.

(5) FIG. 5 is a top plan view showing the EPPA combustion piston adapter plate.

BEST MODE FOR CARRYING OUT THE INVENTION

(6) The best mode for carrying out the invention is presented in terms that disclose a preferred embodiment of an explosively propelled piston assembly (EPPA), which is know as the “Load Lifter”™. In certain industries it is sometimes necessary to push, flip, roll or perform other movement of an object. One industry that requires this capability is the film/television production. The most typical example of the functionality is when a vehicle experiences a violent action. In order to accomplish a realistic and controlled action, such as a vehicle flipping over, an explosively actuated piston is usually utilized. These devices have been in use for some time, but there are negative aspects to the use. The EPPA 10, as shown in FIGS. 1-5, provides an improved design of an explosively propelled piston that offers increased performance characteristics compared to other/prior art similar devices.

(7) The EPPA is comprised of the following major elements: a mounting plate 12, a breach bolt 24, a breach plate 32, a combustion piston 44, and a combustion cylinder 60. While the EPPA 10 can be placed in any orientation, depending on the requirement of use, for the purpose of this disclosure the EPPA 10 will be described and shown in an upright/vertical orientation, with the force directed upward and outward. Also, the EPPA 10 can be manufactured in a variety of shapes/dimensions, again depending on the requirement of use. For this disclosure, a substantially circular design will be disclosed and shown. Also, it should be noted, that while the EPPA can be utilized both vertically and horizontally, for this disclosure the EPPA will be described from an upright, vertical perspective. To provide the greatest amount of structural integrity the assembly of the EPPA 10 utilizes an opposed/keyed interface that is maintained by at least one, and preferably multiple, attachment means such as screws.

(8) The mounting plate 12, as shown in FIG. 1, has a circular center opening 14 and at least one corner opening 16. By placing at least one screw, at least one bolt, at least one nail or at least one other securing means through the corner opening(s), the mounting plate 12 can be secured onto a surface. It should be noted that for certain applications a mounting plate is not required and/or desired. In these cases, the mounting plate 12 is not utilized, which does not affect the operation of the EPPA 10.

(9) As shown in FIG. 1, extending upward from the mounting plate 12 are a plurality of lower cylinder fasteners 20, preferably arranged in a circular configuration. Extending upward at the center of the fasteners and mounting plate center opening is the breach bolt 24 that has a base 26 (which can also be identified as the bolt head) and an upward extending member 28, as shown in FIGS. 1 and 3. Above the breach bolt 24 is the breach plate 32 that has surround openings 34 into which the plurality of fasteners are inserted. The breach bolt 24 upward extending member 28 extends up through the substantial center of the breach plate 32. A breach gasket 38 preferably made of copper interfaces with the breach plate via a plurality of openings 40 that correspond to the fasteners 20 extending upward through the breach plate 32.

(10) As shown in FIGS. 1 and 4, extending upward from the breach plate 32 is the combustion piston 44 that includes a base 46, a center opening 48, upward extending side wall 50 and a threaded opening 52. Located above and interfacing with the upper end of the combustion piston 44 is a piston dampening ring 56.

(11) As shown in FIG. 1, the combustion cylinder 60 includes an upper section 62 and a lower section 64 with upward extending members 66 circumventing the perimeter of the lower section. Ventilation bores 68 extending through the cylinder 60 allow an explosive 86 or pneumatic gas to escape as the piston extends outward. Once the piston is at a final extended length engaging the piston dampening ring 56, the ventilation bores 68 allow gas to escape, thereby relieving pressure within the EPPA 10.

(12) Above the combustion cylinder 60 is a combustion piston adapter plate 72. As shown in FIGS. 1 and 5, the plate 72 has plate bores 74 and at least one corner opening 76 for securing the plate 72. The design of the adapter plate 72 can be universal for a variety of applications, or can have a use-specific design for specializes application.

(13) As shown in FIG. 1 extending downward into and through the adapter plate are a plurality of threaded plate fasteners 80 that extend into corresponding threaded openings on the upper end of the combustion piston 44.

(14) Once assembled, an explosive charge 86 is placed into the EPPA 10. The charge is then activated which produces a contained explosive force that actuates the piston, causing the piston to extend outward, applying the force onto an object in contact with, or adjacent to, the EPPA. Consistent power from the EPPA 10 is achieved based on the size of the explosive/pneumatic force.

(15) In addition to the previously disclosed pushing, flipping, rolling or other movement, the EPPA 10, can also be used as an impact device or with an adapter for specific tasks such as cutting rope, wire, chain or other materials, or for hurling an object and other user-specific purposes that require instantaneous actuation (i.e., a push).

(16) In an alternate functionality, the piston remains in an extended position after an explosive force. In this position, the piston can be utilized as a support for various objects. Also, if the combustion cylinder chamber is made watertight, the EPPA can be used, with modification, in/under water. It is important to note that the force within the EPPA is a contained force which results in control and lessening of the typical reactionary effects that occur when using an explosive.

(17) While the invention has been described in detail and pictorially shown in the accompanying drawings it is not to be limited to such details, since many changes and modification may be made to the invention without departing from the spirit and the scope thereof. Hence, it is described to cover any and all modifications and forms which may come within the language and scope of the claims.