Busbars refer to thick strips of metal (e.g., copper or aluminum) that conduct electricity within an electrical system often carrying high current or requiring low inductance. Sometimes busbars from two separate electrical systems need to be connected to transfer electricity between the two electrical systems. The most common method for attaching busbars together has been to use fasteners. Another approach to attach busbars together is to use a sliding-style connector that pushes on the adjoining two busbars from the side. The sliding-style connector relies on a louvered interface to ensure adequate electrical contact and mechanical retention.
In one aspect, a busbar connector includes first and second portions. Each portion includes a rigid member forming an exterior portion of the busbar connector, a conduction member forming an interior portion of the busbar connector and a compliant member having a stiffness less than the rigid member and including a first surface attached to the rigid member and a second surface opposite the first surface attached to the conduction member. The busbar connector also includes a fastener structure configured to secure a first busbar and a second busbar between and in contact with the conduction members of the first and second portions to allow current to flow between the first and second busbars.
In another aspect, a busbar connector includes first and second portions. Each portion includes first and second rigid members forming an exterior portion of the busbar connector, a conduction member forming an interior portion of the busbar connector and a compliant member having a stiffness less than the first and a second rigid members and including a first surface attached to the first and a second rigid members and a second surface opposite the first surface attached to the conduction member. The busbar connector also includes a first fastener structure and a second fastener structure configured to secure a first busbar and a second busbar between and in contact with the conduction members of the first and second portions to allow current to flow between the first and second busbars by applying a force from the exterior portion of the busbar connector to the interior portion of the busbar connector on each of the first and second rigid members substantially in centers of the first and a second rigid members.
In a further aspect, a system includes a line replaceable unit including panels configured to provide radio frequency signals and a first busbar in electrical connection with the panels. The system also includes a busbar connector and a supply bus including a second busbar. The busbar connector includes first and second portions. Each portion includes first and second rigid members forming an exterior portion of the busbar connector, a conduction member forming an interior portion of the busbar connector and a compliant member having a stiffness less than the first and second rigid members and comprising a first surface attached to the first and second rigid members and a second surface opposite the first surface attached to the conduction member. The busbar connector also includes a first fastener structure and a second fastener structure configured to secure a first busbar and a second busbar between and in contact with the conduction members of the first and second portions to allow current to flow between the first and second busbars by applying a force from the exterior portion of the busbar connector to the interior portion of the busbar connector on each of the first and second rigid members substantially in center portions of the first and a second rigid members.
In a still further aspect, a method to connect a first busbar and a second busbar, includes providing a first portion and a second portion. Each portion includes a rigid member forming an exterior portion of the busbar connector, a conduction member forming an interior portion of the busbar connector; and a compliant member having a stiffness less than the rigid member and including a first surface attached to the rigid member and a second surface opposite the first surface attached to the conduction member. The method further includes using a fastener structure to secure the first busbar and the second busbar between and in contact with the conduction members of the first and second portions to allow current to flow between the first and second busbars.
As described herein, a busbar connector (e.g., a busbar connector 20) solves a problem of interconnecting two high-current busbars while minimizing inductance and voltage drop. In addition, the busbar connector can compensate for misalignment and non-coplanarity between busbars due to assembly and manufacturing tolerances. Also, the busbar connector allows for a zero-insertion force and provides a smooth electrical contact region to eliminate damage to the busbars and eliminates foreign object debris. The busbar connector includes a captive feature to ensure that a busbar connector remains with a busbar when disengaged from an electrical connection. Also, a process of connecting and disconnecting busbars to the busbar connector is quick and repeatable.
While the embodiments of the busbar connector described herein are used in a panel array system environment, the busbar connector may be used in any environment that connects two busbars together.
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The panel array system 10 also includes a main distribution bus 16 that provides DC power to the LRUs 14 from a DC power source 19 (
The panels 12 are radio frequency (RF) panels that provide and receive RF signals and are used, for example, in radar or communications. In one example, the panel array system 10 includes four LRUs 14 and a single LRU 14 includes eight panels 12 for a total of thirty-two panels in the panel array system.
In one example, the panel array system 10 is a phased array system. The relatively high cost of phased arrays has precluded the use of phased arrays in all but the most specialized applications. Assembly and component costs, particularly for active transmit/receive channels, are major cost drivers. Phased array costs can be reduced by utilizing batch processing and minimizing touch labor of components and assemblies. Therefore, it is advantageous to provide a tile sub-array (e.g., the panel 12), for an Active, Electronically Scanned Array (AESA) that is compact, which can be manufactured in a cost-effective manner, that can be assembled using an automated process, and that can be individually tested prior to assembly into the AESA. By using a tile sub-array (e.g., a panel) configuration, acquisition and life cycle costs of phased arrays are lowered, while at the same time improving bandwidth, polarization diversity and robust RF performance characteristics to meet increasingly more challenging antenna performance requirements.
In one example, the panel array system 10 enables a cost-effective phased array solution for a wide variety of phased array radar missions or communication missions for ground, sea and airborne platforms. In at least one example, the panel array system 10 provides a thin, lightweight construction that can also be applied to arrays attached to an aircraft wing or a fuselage or a sea vessel or an Unmanned Aerial Vehicle (UAV) or a land vehicle. In one example, a depth, DL, of the LRU 14 is about 4.5 inches, for example. The array of panels 12 is relatively very thin which provides greater flexibility in where the panel array system 10 can be used and the overall size of the array of panels is significantly less than prior approaches.
Other phased arrays and phased array configurations may be found in U.S. Pat. No. 7,348,932 and U.S. Pat. No. 6,624,787, which are incorporated herein in their entirety and are assigned to the same assignee (Raytheon Company of Waltham, Mass.) as the present patent application.
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The two portions 40a, 40b are attached together by screws 48a, 48b (e.g., shoulder screws) extending through the end portions 62a, 62b of the rigid members 42a, 42c and screws 44a, 44b (e.g., clamping screws) extending through center portions 64 of the rigid members 42a, 42c so that the rigid members 42a-42d form exterior (or outer) portions of the busbar connector 20 and the conductor members 52a, 52b form interior (or inner) portions of the busbar connector.
The conductor members 52a, 52b may be resized to accommodate current and/or inductance requirements. In one example, the conductor members 52a, 52b includes a smooth gold-plated copper that allows for multiple cycles of connecting and disconnecting busbars without damage to the busbars or the conductor members themselves.
In one example, the conductor members 52a, 52b are secured to the compliant members 46a, 46b and to the rigid members 42a-42d using screws 56. For example, the screws 56 (e.g., nylon screws) extend through corresponding holes 66 in the conductor member 52b, through corresponding holes 76 in the compliant member 46b and through corresponding holes 86 (e.g., threaded holes) in the rigid members 42c, 42d. In other examples, the compliant members 46a, 46b are bonded to the rigid members 42a-42d and to the conduction members 52a, 52b 46a using one or more of an adhesive, an epoxy and so forth.
The screws 44a, 44b extend through washers 45 (e.g., three washers each) and through the first and second portions 40a, 40b. With respect to the first portion 40a, the screws 44a, 44b extend through corresponding holes 54a, 54b (e.g., threaded holes) at center portions 64 of the rigid members 42a, 42b, through corresponding holes (not shown) in the compliant members 46a, 46b and through corresponding gaps (not shown) in the conductor member 52a. In one example, the holes 54a, 54b are equidistant from the ends 65a, 65b of the rigid members 42a, 42b. With respect to the second portion 40b, the screws 44a, 44b extend through corresponding gaps 68a, 68b in the conductor member 52b, through holes 78a, 78b of the compliant member 46b and through corresponding holes 84a, 84b (e.g., threaded holes) on corresponding center portions 64 of the rigid members 42c, 42d. In one example, the holes 78a, 78b are equidistant from the ends 65a, 65b of the rigid members 42c, 42d. In other examples, the screws 44a, 44b may be replaced by other types of fastener structures such as clamps, latches and so forth. Clips 94 (e.g., c-clips, e-clips) are attached to the screws 44a, 44b to prevent the screws from separating from the busbar connector 20 when the screws 44a, 44b are loosened, which in turn also prevents the first and second portions 40a, 40b from completely separating from each other.
The screws 48a, 48b extend through corresponding holes 58a, 58b on each end portion 62a, 62b of the rigid member 42a and extend through correspond gaps 74a, 74b in the compliant members 46a, 46b and secured to corresponding holes 84a, 84b (e.g., threaded holes) on corresponding end portions of the rigid member 42c. The screws 48a, 48b are a captive mechanism and are used to prevent a particular busbar (e.g., a busbar 102 (
In other examples, the tabs 110 may be used with the screws 48a, 48b to position the busbar 102 so that both busbars 102, 104 spans the conduction members 52a, 52b an equal amount of area, for example. In particular, a busbar 102 may be fabricated such that when sides 116 of the tabs 110 are in contact with the screws 48a, 48b, the busbar 102 extends a distance, X, into the busbar connector 20. Thus, the busbar 102 can be fabricated so that the distance X may be chosen to correspond to the busbar 102 covering a desired amount of a surface area between the conduction members 52a, 52b. Thus, a user is able to connect the busbar 102 to the busbar 104 quickly.
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The busbar connector 20 can also adapt to different busbar thicknesses. For example, if the busbar 102 has a thickness T3 and the busbar 104 has a thickness T4, the busbar connector 20 can accommodate T3>T4, T3=T4 and T3<T4. The busbar connector 20 can also compensate for a misalignment and/or a non-coplanarity between the busbars 102, 104 due to assembly and manufacturing tolerances.
In other examples, the rigid members 42a, 42b are replaced with a single rigid member and the rigid members 42c, 42d are replaced by another single member. In this configuration the ability of the busbar connector 20 to absorb any angular and/or thickness differences that may exist between the two busbars is limited; however, this configuration may be desirable if the busbars 102, 104 are required to conform rather than the busbar connector 20.
Elements of different embodiments described herein may be combined to form other embodiments not specifically set forth above. Other embodiments not specifically described herein are also within the scope of the following claims.
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