NL9800007A - Dual pack canister holding two missiles - uses tubes and lattice structure, hinged closure and uses gravity or missile blast to complete closing, electronics using flip=flop switch - Google Patents

Abstract

The appts. includes a missile tube, a central support mechanically connected to one side of the missile tube along its length. A second missile tube is mechanically connected on one side of the second missile tube to the central support along the length of the central support. A longeron, spaced apart from the two missile tubes, has a length that is parallel to the lengths of the missile tubes. A second, longeron spaced apart from the missile tubes, and the first longeron, has a length that is parallel to the length of the missile tubes. A lattice is mechanically connected between a second side of the first missile tube and the first longeron. A second lattice is mechanically connected between a second side of the second missile tube and the first longeron. A third lattice is mechanically connected between a third side of the second missile tube and the second longeron. A fourth lattice is mechanically connected between a third side of the first missile tube and the second longeron.

Description

Dual rocket holder.

The invention provides a missile holder containing two missiles, which is the same size as prior art missile holders containing a single missile. The invented missile holder employs alternative structural methods, improved operation of the front seals, a new approach to the electrical system and an improved shock isolation system using new materials and a new production method.

Figure 1 is a perspective view of a dual rocket holder.

Figure 2 is a cross-sectional view of the dual rocket holder taken along lines 2-2 of Figure 1.

Figure 3 is a cross-sectional view of a shock insulation filling.

Figure 4 shows the front closure of the dual rocket holder.

Figure 5 is a schematic of the electrical system of the dual rocket holder using a flip-flop switch.

Figure 6 is a more detailed electrical diagram of circuit configurations in the dual electrical system.

Figures 7 to 9 are circuit configurations equivalent to the circuit configuration shown in Figure 6 that can be used in the dual electrical system.

Figure 1 is a perspective view of a dual rocket holder 10 used in a preferred embodiment of the invention. Figure 2 is a cross-sectional view of the dual rocket holder 10. The rocket holder 10 has a first rocket tube 11 and a second cylindrical rocket tube 12. The first and second rocket tubes 11 and 12 in the preferred embodiment have a generally circular cross section with a structural bulge 14 , for accommodating an infrared search device (IR) on the missile. The missile tube includes an outer jacket 16 formed by a tube of rigid material, a shock insulation fill 17 that forms a tube that lines the inside of the outer jacket 16, and an inner tube 18 that lines the inside of the shock insulation fill 17. Figure 3 shows a broken-through view of part of a missile tube. In the preferred embodiment of the invention, the outer shell 16 can be made of metal or composite material. The shock insulating pads 17 are cellular urethane sheet material with apertures and are adhesive bonded or mechanically secured within the outer sheaths 16. The apertures 16 are shaped as shown to make a honeycomb. In another embodiment of the invention, the openings 20 may be replaced by air spaces, which may be formed by large bubbles in the urethane. Other soft materials can be used in place of urethane. The inner tube 18 is made of a silicon coating, which reduces friction.

A central structure 22 is mechanically coupled between the outer shells 16 of the first missile tube 11 and the second missile tube 12, thereby mechanically connecting the first missile tube 11 to the second missile tube 12. In the preferred embodiment, the central structure 22 is made of an extruded or formed metal or a pultruded (pultruded) or layered composite material.

Hollow bars forming a first longitudinal beam 24, a second longitudinal beam 25, a third longitudinal beam 26, and a fourth longitudinal beam 27 having longitudinal directions extending substantially along the longitudinal direction of the first and second missile tubes 11 and 12 around the first and second missile tubes 11 and 12 are positioned as shown so that they are substantially parallel to the first and second missile tubes 11 and 12 and are located at the corners of the missile holder. The first longitudinal beam 24 is placed adjacent to the first missile tube 11 and is mechanically coupled to the first missile tube 11. The second longitudinal beam 25 is placed adjacent to the second missile tube 12 and is mechanically coupled to the second missile tube 12. The third and fourth longitudinal beams 26 and 27 are spaced from the first and second missile tubes 11 and 12 so that the third and fourth longitudinal beams 26 and 27 in the central structure 22 are in a common plane. The first, second, third and fourth longitudinal beams 24, 25, 26 and 27 are made of a rigid material such as an extruded or formed metal, or a pultruded or layered composite composite material.

A first frame 29 mechanically couples the first missile tube 11 to the third longitudinal member 26. A second frame 30 mechanically couples the second missile tube 12 to the third longitudinal member 26. A third frame 31 mechanically couples the second missile tube 12 to the fourth longitudinal member 27. A fourth frame 32 mechanically couples the first missile tube 11 to the fourth longitudinal beam 27. The first, second, third, and fourth frames 29, 30, 31, and 32 are formed by rigid straight pieces of material that form diagonal braces 34 that form an intersecting structure, and horizontal struts 35 perpendicular to the longitudinal directions of the longitudinal beams 24 to 27. The first, second, third and fourth frames 29, 30, 31 and 32 form a square tube shape. The diagonal struts 34 and horizontal struts 35 of the first frame 29 extend from the third longitudinal beam 26 to a portion of the first missile tube 11 touching the diagonal struts 34, the ends of the diagonal struts 34 and the horizontal struts 35 mechanically coupled to the third longitudinal beam 26 and the first missile tube 11. The diagonal struts 34 and horizontal struts 35 of the second frame 30 extend from the third longitudinal girder 26 to a portion of the second missile tube 12 tangent to the diagonal braces 34, the ends of the diagonal braces 34 and the horizontal braces 35 being mechanically coupled to the third longitudinal beam 26 and the second rocket tube 12. The diagonal braces 34 and horizontal braces 35 of the third frame 31 extend from the fourth longitudinal beam 27 to a part of the second missile tube 12 tangent to the diagonal braces 34, the ends of the diagonal braces 34 and the horizontal The struts 35 are mechanically coupled to the fourth longitudinal beam 27 and the second missile tube 12. The diagonal struts 34 and horizontal struts 35 of the fourth frame 32 extend from the fourth longitudinal beam 27 to a part of the first missile tube 11 which is tangent to the diagonal braces 34, the ends of the diagonal braces 34 and the horizontal braces 35 being mechanically coupled to the fourth longitudinal beam 27 and the first missile tube 11.

A first number of laterally connecting plates 70 extends perpendicularly within the rocket holder 10 from horizontal struts 35 and the third longitudinal beam 26 to the first and second rocket tubes 11 and 12. The first number of laterally connecting plates 70 are mechanically coupled to the horizontal struts 35, the third longitudinal beam 26, and the first and second missile tubes 11 and 12. A second plurality of laterally connecting plates 71 are mechanically coupled to the horizontal struts 35, the fourth longitudinal beam 27, and the first and second missile tubes 11 and 12. The first and second numbers of laterally joining plates 70 and 71 are made of a rigid material such as formed metal, or layered composite material.

As shown in Figure 4, a first plate 37 is mechanically connected to the horizontal struts 35 of the first frame 29, the third longitudinal beam 26, and the first missile tube 11. A second plate 38 is mechanically connected to the horizontal struts 35 of the second frame. 30, the third longitudinal beam 26 and the second missile tube 12. A third plate 39 is mechanically connected to the horizontal struts 35 of the third frame 31, the fourth longitudinal beam 27, and the second missile tube 12. A fourth plate 40 is mechanically connected to the horizontal struts 35 of the fourth frame 32, the fourth longitudinal beam 27, and the first missile tube 11. The first, second, third and fourth plates 37, 38, 39 and 40 form a square tube that forms the sides of the dual missile holder 10. In the preferred embodiment, the plates are of a metal or a fiberglass material and are constructed to shield the inner region of the missile holder from electromagnetic interference. The plates are not shown in Figure 1 to allow a full view of the frames.

The dual rocket holder 10 has a front end 43 and a rear end 53. A front end 43 is shown in Figure 4. The front end 43 has a first seal 45 and a second seal 46. The first seal 45 covers the first missile tube 11. The first closure 45 is mechanically connected to a front end plate 43 by a first number of hinges 48 that allow opening and closing and resealing the first closure 45. A first spring 51 is mechanically connected to the first number of hinges 48 to facilitate closing of the first closure 45. Other types of memory material can replace the first spring 51. The second closure 46 is mechanically connected to the front end plate 43 by a second number of hinges 49, which allows opening and closing and resealing the second closure 46. A second spring 52 is mechanically coupled to the second number of hinges 49 to facilitate closing of the second closure 46. As shown in Figure 1, the first closure 45 has an inner cone shape. Vertical lifting attachments 50, which allow a crane to lift the dual rocket holder, are attached to the front end 43. The first front closure 45 is constructed to shield the interior of the first rocket tube 11 from electromagnetic interference . The second front closure 46 is constructed to shield the interior of the second missile tube 12 from electromagnetic interference.

The rear closure 53 may be a conventional rear closure as used in other missile holder systems.

Electrical cabling is attached to the dual missile holder by a first electrical connector 56. Figure 5 is a schematic of the electrical system of the dual missile holder. The electrical connector 56 is electrically connected to a first missile 58 and a second missile 59 by a flip-flop switch 62. Figure 6 is a schematic of a flip-flop switch 62. Figures 7 through 9 are diagrams of electrical circuits that can be used in place of the electrical circuit in Figure 6. A protection and activation switch 64 is placed near the electrical connector 56.

In use, the first and second missiles 58 and 59 are stored in the first and second missile tubes 11 and 12, respectively. The dual missile holder 10 is loaded on a ship and the ship's electrical control and power is connected to the dual missile holder 10 by the first electrical connector 56. The safety and activation switch 64 is moved from the safe to the activated position prior to firing. The flip-flop switch 62 provides launch signals only to the first rocket 58. Other electrical information does not pass through the flip-flop switch 62, so that the second rocket 59 can be monitored while the flip-flop switch is open with respect to the second missile 59 and closed to the first missile 61, as shown in Figure 6. The ship's control system launches the first missile 58. The first missile 58 presses open the first front closure 45. The shock isolation fill 17 minimizes the shock propagating from the ship to the first missile 58. The inner tube 18 allows the first missile 58 to easily slip out of the first missile tube 11. Once the first missile 58 has left the first missile tube 11, the first forward closure begins to pull to a closed position, so that gravity and / or the exhaust gases from the first missile 58 cause the first forward closure 45 to close and seal. The flip-flop switch 62 then opens for the first missile 58 and closes for the second missile 59, allowing launch related signals to pass to the second missile 59. The ship's control signal causes the second missile to launch 59. The second rocket 59 opens the second front closure 46. The shock isolation fill 17 minimizes the shock propagating to the outside of the second missile tube 12. The inner tube 18 allows the second missile 59 to easily slip out of the second missile tube 12. Once the second rocket 59 has left the second rocket tube 12, the second front cover begins to pull to a closed position, so that gravity and / or the exhaust gases from the second rocket 59 close and seal the second front cover 46.

In the description and claims, one part can be mechanically bonded to another by mechanical fixings or by welding 66, as shown in Figure 2, or by using an adhesive to effect an adhesive bond.

While a preferred embodiment of the present invention has been shown and described herein, it will be appreciated that various changes and modifications can be made therein without departing from the scope of the invention as defined by the scope of the appended claims.

Claims (4)

A tubular rocket holder comprising a rigid tubular outer shell having an interior and an exterior and a length, a plurality of soft material shock insulation fillings having a first side and a second side lining the interior of the outer shell, the first side being adjacent is located on the inner side of the outer jacket, the shock insulation fillings having openings defining a honeycomb shape, as well as an inner liner adjacent to the second side of the shock insulation fillers, the openings in the shock insulation fillings extending from the outer jacket to the inner liner. 2. Tubular rocket holder, comprising an outer shell of a rigid material, formed in a tubular shape with an inner side and an outer side and a longitudinal direction, a shock insulation filling of a soft material that forms a tubular shape with an inner side and an outer side that defines the inner side of the outer cloak; and an inner tube that forms a tube shape that lines the inside of the shock insulation pad. The device of claim 2, wherein the shock insulation pad is made of urethane and the inner tube is a silicon coating. Device as claimed in claim 3, wherein the shock insulation filling has openings which create a honeycomb shape.