N/A
Ships and other marine vessels include hatches formed in horizontal surfaces and doors formed in vertical surfaces to allow crewmembers and goods to pass through. A hatch or door must be watertight around all of its edges and sufficiently stiff and strong to withstand the forces applied during use. Hatches are typically formed of metal and are heavy to open and close. Thus, a scuttle sized to allow passage of a single person is typically provided within the hatch. The scuttle must also be watertight. The operating mechanisms to open and close both the hatch and the scuttle are conventionally provided on the hatch itself, adding to the weight.
Hatches and scuttles on ships are traditionally made from steel. During many years of marine service, steel hardware has proven to be relatively inexpensive, to have good resistance to damage from routine operational impacts, to provide inherent EMI and EMP shielding, and to perform well in standard fire tests.
Steel hatches and scuttles have several drawbacks, however. Life cycle costs can be high, due to considerable routine maintenance, such as regular painting to prevent corrosion. Also, the heavy weight makes opening and closing of the hatch and/or scuttle unsafe, particularly in rough weather or in other difficult or dangerous circumstances.
A hatch system of the present invention provides a hatch panel formed of a composite material. The composite material contributes to a significant reduction in weight over that of a conventional all-metal hatch and scuttle system. The composite hatch panel is bonded to a metal frame, which allows the composite panel to be readily integrated to a metal coaming structure fixed to the ship surrounding the hatch panel. The operating mechanism to open and close the hatch panel is shifted off the movable hatch panel to the fixed coaming structure. The operating mechanism provides a discrete-to-continuous dogging mechanism to distribute mechanical point loads over a greater percentage of the panel's periphery.
The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings in which:
Referring to
The composite material of the composite material panel 14 is a fibrous reinforcement impregnated with a matrix material. The panel is bonded to or otherwise suitably mounted within the metal frame 16, which allows the composite panel to be readily integrated to the metal coaming structure 18. The frame includes a circumferential wall 22 that conforms to the sides of the composite panel and upper and lower inwardly facing flanges 24. See
The operating mechanism 30 is illustrated in
The shaft mechanism includes a plurality of rocker shafts 52 along each edge of the panel assembly. The rocker shafts are supported for rotation on the coaming at suitable shaft supports 54. At the corners of the panels, the rocker shafts are connected by universal joints 56. Thus, rotation of one rocker shaft causes rotation of the other rocker shafts via the universal joints.
A rocker arm 58 is mounted for rotation on each rocker shaft between the shaft supports. The continuous latching elements 38, such as followers or dogging members, are attached to each rocker arm. In the first stage, rotation of the rocker shafts rotates each follower to contact the latching flange 42 on the panel assembly frame to apply a force along at least a portion that extends continuously along the straight edges of the panel assembly.
A continuous knife edge or lip 62 on the coaming structure extends into the gasket 46 in the recess 44 on the frame 16 of the panel assembly. As the rocker shaft is rotated, the follower pushes against the latching flange, pulling the knife edge into contact with the gasket along the perimeter of the panel assembly. See
In one embodiment, the first stage of rotation is activated by closing the panel assembly to rotate the rocker shaft 52. See
A cam element 74 is also mounted on the universal joint 56. A roller rocker 76 including a roller 78 engages the cam surface 82 of the cam element 74. The roller rocker is mounted to the coaming with a strut and spring mechanism 86 to bias the roller into engagement with the cam surface. Movement of the panel assembly to a closed position causes the roller to snap over the cam surface into a closed position. The cam and the roller rocker are synchronized with the rotation of the duckbill latch to ensure that the rocker shafts are in an open or a closed position relative to the panel assembly's open or closed position. In
In the second stage, the panel assembly is sealed to the coaming structure by pulling the knife edge 62 into sealing engagement with the sealing element or gasket 46. More particularly, the linkage mechanism actuates a plurality of discrete latching elements 36. The discrete latching elements include landing elements 92 pivotably mounted to the rocker arms 58. Each landing element includes a wedge or inclined surface 94. The linkage mechanism includes a plurality of complementary discrete latching members 96 pivotably mounted to the shaft supports 54. One end of the latching member includes a rub pad 98 that rides along an associated wedge. Another end 102 of the latching member is mounted to a planar linkage 104 for movement therewith. The planar linkage includes a plurality of connected links 106 arranged to surround the opening in the coaming structure. A handle 110 actuates the planar linkage. As the planar linkage moves, the discrete latching members rotate, moving the associated rub pads along the wedges, which forces the rocker shaft to rotate further. The further shaft rotation pulls the knife edge into sealing engagement against the gasket. See
In a further embodiment, a transmission 112 is provided at the handle 110. See
Any desired form of composite panel can be used with the present invention, such as a sandwich panel or a panel with integral stiffeners. The panel can be manufactured in a number of ways, such as with a pultrusion process or a vacuum assisted resin transfer molding process (VARTM) other process alternatives include resin transfer molding, press molding, pultrusion of subcomponents, filament winding of circular frame sections, and prepreg layup. The composite material of the hatch panel contributes to a significant reduction in weight over that of a conventional all-metal hatch and scuttle system. By mounting the latching mechanism to the coaming structure rather than to the hatch panel and frame assembly, the weight of the panel and frame assembly that must by lifted by personnel is minimized.
While described in conjunction with a ship or other marine vessel, the hatch or door system of the present invention can be employed in other situations where the hatch system would be useful, such as in openings to provide access to building roofs or in aircraft. Similarly, although the panel is described as being formed of a composite material, it will be appreciated that the various embodiments of the operating mechanism mounted on the surrounding structure are also operable in conjunction with a metal panel. In this case, the metal frame could be integrally formed with the interior panel, for example, as an edge detail. The invention is not to be limited by what has been particularly shown and described, except as indicated by the appended claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 10/357,735, filed Feb. 4, 2003, issued as U.S. Pat. No. 6,953,001, on Oct. 11, 2005, the disclosure of which is incorporated herein by reference. This application claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Application No. 60/354,315 filed on Feb. 4, 2002, the disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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20060075950 A1 | Apr 2006 | US |
Number | Date | Country | |
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60354315 | Feb 2002 | US |
Number | Date | Country | |
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Parent | 10357735 | Feb 2003 | US |
Child | 11248000 | US |