BRIEF DESCRIPTION OF THE PRIOR ART Guided airborne detector systems for dynamic airborne systems generally include, as a part of the airborne detector system, a detector guidance section for detecting target location and a control section for controlling airborne system trajectory in response to signals received from the detector guidance section in order to direct the airborne system to a selected target. Such detector and control systems must provide accurate and reliable outputs in order to insure that the desired trajectory is adhered to and that the ultimate target is reached. A problem with the detector and control electronics in such systems has been that magnetic and/or radio frequency interference emanating from the detector and/or the control section and/or other outside sources has been picked up by the airborne system electronics, thereby causing inaccurate readings to be provided, resulting in inaccurate trajectories with resultant failure to arrive at the desired target. For this reason, adequate shielding of the electrical components, cables and electrical interfaces between the detector, guidance and control sections of the

airborne system has been critical to the accuracy and precision of the guidance which is required of the system.

In the prior art, this problem has been minimized by packaging and protecting electronic hardware and connections in the above described dynamic airborne systems from components fabricated from specially formed metallic housings, fastening hardware and interconnect components.

The metallic forms were often expensive to produce, requiring tight tolerances at joint and cable interface areas. Furthermore, if thin metallic components were damaged or joint areas were damaged prior to assembly, system protection against magnetic and/or radio frequency interference could be severely compromised. Though systems of the type described above have been used for many years and represent the prior state of the art, it is apparent that such systems have significant drawbacks including high cost and intricate assembly methods.

SUMMARY OF THE INVENTION In accordance with the present invention, there is provided an assembly which minimizes the above noted problems of the prior art and which can be provided relatively inexpensively as compared with the above described prior art.

Briefly, there is provided an assembly including a two piece enclosure or housing of electrically conductive moldable plastic including a barrel portion and a bulkhead portion. Electrically conductive moldable plastic materials are well known and can be, for example, a moldable plastic material having electrically conductive fibers therein in sufficient quantity to provide electrical conductivity. The enclosure pieces lock together in an overlapping press fit by pushing the larger portion of the barrel into the bulkhead. The barrel contains a groove disposed adjacent the bulkhead portion which receives an

electrically conductive o-ring to provide an electrically conductive path between the barrel and the bulkhead. This provides an electrically conductive shield for the electronic assembly which is disposed in the chamber formed by the bulkhead and the barrel.

The use of electrically conductive plastic forms, which combine parts of relative movement while providing adequate shielding, reduces part count, cost, weight and assembly time. The use of electrically conductive plastics also eliminates the need to machine high tolerances associated with metallic components, thereby reducing cost and the potential for defective parts. The assembly in accordance with the present invention shields the optical sensor, electrical components and provides an adequate electrically conductive path for cable termination using the two piece electrically conductive plastic housing which is joined by an overlapped press fit. Cable termination is achieved using a simple threaded adapter which is fastened into the bulkhead portion, thereby creating an electrically conductive path between electrically conductive material, such as, for example, electrically conductive fibers in the plastic and the metallic cable braid. Both the optical sensor and electrical components are mounted within the two piece housing during assembly.

BRIEF DESCRIPTION OF THE DRAWINGS FIGURE 1 is a side view of a detector assembly in accordance with the present invention; and FIGURE 2 is a cross-sectional view of the detector assembly of FIGURE 1 taken along the line 2-2 of FIGURE 1.

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to FIGURES 1 and 2, there is shown a side view of a detector assembly 1 in accordance with a preferred embodiment of the invention. The assembly is circular in cross-section through its axis. A barrel 3 of electrically conductive material, preferably the same type of material as the bulkhead 4, has an annular groove with an annular electrically conductive o-ring 18 within the groove, this groove being disposed adjacent to bulkhead 4 with the o-ring contacting the bulkhead 4. The combination of the barrel 3, the bulkhead 4 and o-ring 18 substantially form a chamber with an electrically conductive chamber wall other than behind the lens 9. The chamber contains the electronics therein which is demonstrated by way of example by a detector chip 5 and a circuit board 6, both coupled to a portion of the barrel 3 within the chamber. Also shown is the metal adapter 10 threaded into the bulkhead 4, thereby creating an electrically conductive path between the metal cable braid 11 and electrically conductive path between the metal cable braid 11 and electrically conductive chamber wall of the bulkhead 4. The combination of the bulkhead 4, meal adapter 10 and metal cable braid 11 creates an electrically conductive path for wiring, thereby protecting the chamber against outside sources of magnetic and/or radio frequency interference.

The dome portion 2 includes an ellipsoid-shaped portion 22 of circular cross-section with continually increasing radius from the ellipsoid apex and then includes a following portion of circular cross-section with constant

radius 23 extending to the edge of the ellipsoid-shaped portion. A plurality of spaced apart slits 24 extend around the portion 23 and extend in a direction parallel to the axis of the detector assembly 1. The slits 24 permit the tabs 25 formed by and between the slits to be flexible for engagement with the bulkhead portion 4 as will be explained hereinbelow to provide a press fit.

Referring to FIGURE 2, it can be seen that the housing portion 23 of dome portion 2 is preferably thinner than the housing portion 22, thereby providing the flexibility to the portion 23 of the dome portion required for engagement with the bulkhead 4 while providing a rigid housing portion 22. The edge of the dome portion 23 includes an inwardly extending lip 26 which engages in a circular groove 27 disposed in the outer wall of the bulkhead 4 to provide a press fit between the dome portion 2 and the bulkhead 4.

The fit is preferably sufficiently tight and the tabs 25 are sufficiently rigid to require a substantial force to pry the tabs out of the groove 27. A barrel 3 formed of electrically conductive material, preferably the same type of material as the bulkhead 4 has an annular groove with an annular electrically conductive o-ring 18 within the groove, this groove being disposed adjacent the bulkhead 4 with the o-ring contacting the bulkhead. An o-ring 8 to provide a seal between the dome 2 and the barrel 3 is disposed in a groove formed partly in the barrel and partly in the interior wall of the dome portion 22. The combination of the barrel 3 and the bulkhead 4 substantially form a chamber with electrically conductive chamber walls behind the lens 9. The chamber contains the electronics therein which is demonstrated by way of example by a detector chip 5 and a circuit board 6, both coupled to a portion of the barrel 3 within the chamber. A desiccant 7 which is disposed within the housing and external to the chamber as well as the other standard optics required of

the detector assembly are shown and not described since they form no part of the invention herein. Also shown is a cable assembly connection 9 extending out of the housing 1 with wiring therein which also forms no part of the invention and will not be further explained.

It can be seen that there has been provided a simple, low cost enclosure for use as a detector assembly, generally in high speed airborne equipment which is exposed to the environment, which provided the required shielding, yet can be easily assembled.

Though the invention has been described with respect to a specific preferred embodiment thereof, many variations and modifications will immediately become apparent to those skilled in the art. It is therefore the intention that the appended claims be interpreted as broadly as possible in view of the prior art to include all such variations and modifications.