Static structures (e.g. – buildings) – Window or window sash – sill – mullion – or glazing – Intersection of panes having coextensive exposed sustainer
Reexamination Certificate
1999-06-01
2001-11-20
Stephan, Beth A. (Department: 3635)
Static structures (e.g., buildings)
Window or window sash, sill, mullion, or glazing
Intersection of panes having coextensive exposed sustainer
C052S204500, C052S204599
Reexamination Certificate
active
06318035
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention generally relates to a window frame assembly for use in high speed aircraft and a method for installation of a window pane into a window frame when making the window frame assembly. More specifically, the present invention relates to the formation of a window assembly for a high speed aircraft to ensure that a low radar cross section (RCS) is maintained during the various conditions encountered by the aircraft.
2. Background Information
Sensors used in high speed aircraft, in order to properly function, need to be protected from the environment (e.g., wind and rain). This is normally achieved through the placement of an infrared (IR) window on the outer skin of aircraft to protect the sensors and allow them to function properly. An IR window allows radiation to pass through the window and be detected by sensors located behind the window. For high speed aircraft that require a low RCS, IR windows can present a problem. Aircraft require a low RCS to appear as a small object or not appear at all, to a radar detection system. The RCS of an aircraft is a measure of how well the aircraft absorbs radar energy or reflects radar energy in a direction away from the source of the radar energy.
Conventional IR windows placed onto aircraft for protection of sensors include an interface (or ridge) between the window and the window frame that would reflect radar energy directed at the aircraft. As a result, the aircraft's RCS would increase, thereby increasing the chances that a radar system would detect the aircraft. Early design specifications therefore used a 6″ by 6″ diamond shaped window to allow for proper dissipation and reflection of received radar energy due to the joint between the window pane and window frame on an aircraft. However, from a practicality standpoint, a window having such dimensions is too large to place in the surface of an aircraft because of aerodynamic and structural requirements. Minimum bend radius requirements resulted in a need to drastically alter the shape of an aircraft to account for such windows. Smaller windows could have theoretically been used, but would increase the RCS, thereby making the aircraft easily detectable by radar.
Subsequently, efforts turned to removing any interface (or ridge) between the window and the frame. For example, a smaller window was constructed and an electrically conductive epoxy was placed between the window pane and the window frame to make the window flush with the frame.
FIG. 1
shows a partial view of a conventional window frame assembly
100
. The frame assembly includes a window pane
110
and a window frame
130
. A conductive epoxy
120
is placed along the entire radius of the window pane
110
and the window frame
130
to hold the window pane
110
to the window frame
120
. Such a system has drawbacks. When an aircraft is traveling at a great rate of speed and encounters heavy rain (for example, raindrops having a diameter of approximately 2 mm with a rainfall rate of approximately 2 inches per hour), the rain erodes the conductive epoxy located between the window pane and the window frame. After approximately 10 minutes the epoxy will have been entirely eroded, and the epoxy and/or window pane will fall out of the frame thereby increasing the RCS of the airplane as well as possibly damaging sensors behind the window pane.
To account for the effect of heavy rain on the conductive epoxy, soldering of the window into the frame has been attempted. While rain encountered during flight will not erode solder, the large temperature variation that an aircraft will typically encounter (e.g., −65° F. to +250° F.) can cause the window pane to shatter due to the stress induced by the solder on the sides of the window pane. While soft solders have been considered, they are not a practiced solution because of their susceptibility to rain erosion.
U.S. Pat. Nos. 5,818,631 and 4,090,773 each describe the application of a protective layer material onto an IR window. However, neither of these patents address the issue of reducing the RCS of the window. Therefore, there is a need for an aircraft window frame assembly having small window panes which can provide a low RCS.
SUMMARY OF THE INVENTION
The present invention is directed to providing a window frame assembly which reduces an RCS of an aircraft and is small enough to conform with aerodynamic tolerances. In accordance with an exemplary embodiment of the present invention, a method for forming a window frame assembly for use over a predetermined range of temperatures is provided which comprises the steps of: establishing a receiving area for an electrically conductive window; placing said electrically conductive window into the receiving area; applying an adhesive to an area between the receiving area and the electrically conductive window; and raising a temperature of said receiving area and said electrically conductive window to at least an upper limit of said predetermined range to cure the adhesive.
Exemplary embodiments of the present invention include an electrically conductive window frame assembly which comprises: an electrically conductive window pane, having beveled sides; and an electrically conductive window frame, wherein the window frame contains a beveled surface and wherein the beveled surface of the window pane interfaces with the beveled surface of the window frame. In alternate embodiments, an adhesive can be employed to bond the electrically conductive window pane to said electrically conducive window frame and/or retaining clips can be used secure the electrically conductive window pane to the electrically conductive window frame.
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patent: 4937450 (1990-06-01), Wakabayashi et al.
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patent: 4990782 (1991-02-01), Wellman et al.
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patent: 5277384 (1994-01-01), Webb
patent: 5592060 (1997-01-01), Racine et al.
patent: 5818631 (1998-10-01), Askinaze et al.
patent: 6038065 (2000-03-01), Borden
Burns Doane , Swecker, Mathis LLP
Chavez Patrick J.
Lockheed Martin Corporation
Stephan Beth A.
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