The invention relates to optical systems, and more particularly, to techniques and structures for interfacing a window or dome through which an optical system takes in information.
An optical lens system can be used in numerous scenarios, including commercial, scientific, and military applications. In some such applications, the optical system is included within a fuselage or other protective housing or structure that is configured with a window or dome that effectively allows the optical system to take in information from a scene within the system's field of view (FOV).
One embodiment of the present invention provides an optical dome mounting system. The system includes a plurality of alignment bushings, each having a head portion and a chassis engagement portion. The system further includes a dome mount having a first side for engaging with an optical dome and an opposing side for engaging with a chassis and having a plurality of recesses therein, each recess for floatingly receiving the head portion of a corresponding one of the alignment bushings. The system may further include, for example, the optical dome and/or the chassis. In some eases, each of the alignment bushings has a pin portion that is configured to fit snuggly into a corresponding mounting guide hole of the chassis. In some cases, each of the alignment bushings has a hole portion that is configured to fit snuggly over a corresponding mounting guide pin of the chassis. In some cases, the dome mount further comprises a plurality of contact pads for interfacing with a corresponding contact of the chassis. In some such cases, at least some of the contact pads are raised. In other such cases, at least some of the contact pads are recessed. In some cases, the dome mount is saddle-shaped. In other cases, the dome mount is ring-shaped. In some cases, the dome mount can be bonded to, for instance, an optical dome and/or a chassis with a low outgassing adhesive. In some cases, the system allows for positioning a replacement dome on an optical system such that co-boresight of multiple beam paths is maintained.
Another embodiment of the present invention provides an optical dome mounting system. In this case, the system includes a chassis, an optical dome, and a plurality of alignment bushings, each having a head portion and a chassis engagement portion. The system further includes a dome mount having a first side for engaging with the optical dome and an opposing side for engaging with the chassis and having a plurality of recesses therein, each recess for floatingly receiving the head portion of a corresponding one of the alignment bushings. The dome mount is bonded to at least one of the chassis and/or the optical dome with a low outgassing adhesive. In some cases, each of the alignment bushings has a pin portion that is configured to fit snuggly into a corresponding mounting guide hole of the chassis. In other cases, each of the alignment bushings has a hole portion that is configured to fit snuggly over a corresponding mounting guide pin of the chassis. In some cases, the dome mount further comprises a plurality of contact pads for interfacing with a corresponding contact of the chassis. In some such cases, each of the contact pads is raised. In some eases, the system allows for positioning a replacement dome on an optical system such that co-boresight of multiple beam paths is maintained.
Numerous variations will be apparent in light of this disclosure. For instance, another embodiment of the present invention provides a method for making an optical dome mounting system. The method includes providing a plurality of alignment bushings, each having a head portion and a chassis engagement portion. The method further includes providing a dome mount having a first side for engaging with an optical dome and an opposing side for engaging with a chassis and having a plurality of recesses therein, each recess for floatingly receiving the head portion of a corresponding one of the alignment bushings.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and not to limit the scope of the inventive subject matter.
a illustrates a bottom view of a mounting ring configured in accordance with another embodiment of the present invention.
b through 4b″ each illustrates a cross-section side view, taken across section line b-b, showing details of the mounting ring and alignment bushings shown in
c illustrates a cross-section side view, taken across section line c-c, showing details of the contact pads shown in
c′ illustrates a cross-section side view, taken across section line c-c, showing details of the contact pads shown in
Techniques and structures are disclosed to facilitate efficient replacement of windows/domes of optical systems, such as turreted pointer/tracker systems and seekers and other such gimbal-based or fixed targeting systems. The techniques can be implemented, for example, in a mounting, ring or bezel, wherein the dome/window center of curvature is actively aligned during assembly to a reference feature on a mounting bezel during the dome-to-bezel alignment. This reference feature then mechanically registers the dome-bezel assembly to a given chassis. In some embodiments, the techniques allow for positioning of a replacement window/dome on an optical lens system, such that co-boresight of multiple beam paths is automatically maintained. Conventionally, replacement of a dome assembly requires manual realignment of replacement dome. Such conventional alignment techniques tend to be tedious, labor intensive in a field setting, and may further require fixturing and alignment equipment in the field.
General Overview
As previously explained, an optical lens system is oftentimes included within a fuselage or other protective housing or structure that is configured with a window or dome that effectively allows the optical lens system to take in information from a scene within the system's field of view (FOV). In such applications, the window or dome may have direct exposure to the adverse conditions (e.g., temperature extremes, driven sand, dust, rain, hail, vibration, and/or foreign object debris). Over time, the window or dome may degrade in performance from exposure to such adverse conditions. As a result, it may become desirable to replace the window/dome.
In an effort to reduce down time for a tedious and lengthy custom dome alignment, and in accordance with an embodiment of the present invention, an interchangeable dome assembly is provided by using a common reference feature on all dome assemblies for a given application. As a result, spare domes can be in stock, for instance, at a maintenance facility and replacement entails using a mechanical registration of the dome reference surface to the turret (or other chassis) upon which the dome is installed.
In one such embodiment, the mechanical registration enables positioning of the replacement dome on a turreted system such that co-boresight of multiple beam paths is maintained. For instance, in one such specific case, the multiple beam paths may include an incoming infrared tracker beam and an outgoing laser beam. Other multiple beam path schemes will be apparent in light of this disclosure, and the claimed invention is not intended to be limited to any particular one. For instance, the outgoing beam may include both laser and infrared beams. The beam path scheme will depend on the given application.
In one specific example embodiment employing an optical dome and pointer/tracker gimbal-based turret system for countermeasures (e.g., jamming, etc) against surface-to-air threats, the dome center of curvature is actively aligned during assembly to a reference feature on a dome bezel during the dome-to-bezel alignment. This reference feature then mechanically registers the dome-bezel assembly to the system housing (e.g., jamhead housing or other chassis associated with the optical system) with sufficient accuracy to provide the precise alignment required to meet the co-boresight to the turret optics.
The techniques effectively allow for alignment capture in the factory rather than necessitating a field adjustment, and therefore save labor and eliminate the need for field fixturing and alignment equipment. Any number of applications employing an optical system that requires periodic window/dome replacement can benefit from the techniques provided herein.
Interchangeable Dome Assembly
The chassis can be any type of chassis and the various extraneous implementation details associated therewith are not particularly material to embodiments of the claimed invention, other than the specific features that engage or are otherwise configured specifically to interface with the interchangeable dome assembly, as will be apparent in light of this disclosure, such as the mounting guides and contacts. In addition, the location on the chassis that mates with the interchangeable dome assembly may be dimensioned and shaped or otherwise machined to accommodate corresponding dimensions and shapes of the interchangeable dome assembly.
As can be seen, the interface between the interchangeable dome assembly and the chassis includes two dome mounting guides and four dome contact pads. The dome mounting guides are shown as holes in this example embodiment, but in other embodiments may be pins. Likewise, the dome contacts are shown as recesses in this example embodiment, but in other embodiments may be raised pads. As will be further appreciated in light of this disclosure, the corresponding interface features of the dome assembly can be configured to complement or otherwise operatively couple with the features of the chassis-side interface. Further variations and details with respect to the dome/window mounting guides and contacts will be discussed with reference to
A bonding adhesive may also be used between the chassis and the saddle, in some embodiments. Any number of structural adhesives can be used, depending on the particulars of the application. In one specific example, the structural adhesive may be RTV566 silicone. In a more general sense, any low-outgassing and flexible adhesive sealant may be used to bond the dome to the saddle, as well as to bond the dome assembly to the chassis over, for example, a gimbal assembly.
The shape of the dome mount can be particular to a given application, which in this example case calls for the saddle shape. Other shapes can be used as well, depending on factors such as the shape of the interface between the dome and chassis and the size of the dome. Other embodiments may have, for example, a flat interface between the dome and chassis, where the mount could be ring-shaped. The saddle mount can be made of any suitable material. Example factors to consider include the coefficient of thermal expansion (CTE) of the dome and chassis materials. In one specific example case, for instance, the saddle mount is implemented with Alloy 39 and the chassis with aluminum 6061. Depending on the design and/or geometry, other suitable saddle mount material options include Invar 36®, Alloy 42, and Kovar®, just to name a few. This particular group of materials (including Alloy 39), all of which are produced by Carpenter Technology Corporation, are all low expansion iron nickel alloys that are engineered specifically to provide CTE variability to a designer. As will be appreciated, the claimed invention is not intended to be limited to any particular one or type of mount materials. Other mount materials include, for instance, aluminum, titanium, steel, and alloys thereof.
The dome can be, for example, a hemispherical shape, a volumetric ellipsoidal shape or volumetric polygonal shape. In some embodiments, the dome may be implemented, for instance, with a low-expansion optical material, such as, but not limited to, aluminium oxynitride, silicon, germanium, spina or sapphire. Numerous other suitable dome materials can be used as well, depending on application factors such as the wavelength range of interest, harshness of operating environment, and the desired CTE of the dome, and the claimed invention is not intended to be limited to any particular dome configuration.
a illustrates a bottom view of a mounting ring configured in accordance with another embodiment of the present invention. As will be appreciated, such a mounting ring can be used in place of a saddle-shaped mount in embodiments having a flat interface between the dome and chassis. As can be seen, the mounting rings includes a number of contact pads (four in this example case) and a number of alignment bushings (two in this example case) and a number of fastener holes (six in this example case). The previous discussion with respect to materials and geometries is equally applicable here, and any number of configurations will be apparent in light of this disclosure.
b through 4b″ each illustrates a cross-section side view, taken across section line b-b, showing details of the mounting ring and alignment bushings shown in
e illustrates a cross-section side view, taken across section line c-c, showing details of the contact pads shown in
The foregoing description of the embodiments of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of this disclosure. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.
This application claims the benefit of and priority to U.S. Application No. 61/480,926, filed Apr. 29, 2011, which is herein incorporated by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US12/33884 | 4/17/2012 | WO | 00 | 1/10/2013 |
Number | Date | Country | |
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61480926 | Apr 2011 | US |