Grounding connectors may be used to clamp together two or more conductors to establish an electrical pathway. The conductors may be arranged in a grid configuration with two conductors intersecting at a perpendicular angle. Current grounding conductors require removal of the fastener of the grounding conductor in order to place the perpendicular conductors between the grounding connector. The fastener must then be inserted into the grounding connector and tightened to clamp the perpendicular conductors to establish an electrical pathway.
The present invention provides a grounding cross connector including an upper clamping pad having perpendicular grooves configured to hold a set of grounding conductors, a lower clamping pad having perpendicular grooves configured to hold the set of grounding conductors, and first and second threaded fasteners configured to compress the upper clamping pad and the lower clamping pad against the set of grounding conductors. The present invention further provides for a grounding cross connector that includes the upper clamping pad being configured to pivot about the second threaded fastener to engage the first fastener.
In accordance with another aspect of the invention, a grounding cross connector includes a main clamping pad having perpendicular grooves to hold a set of grounding conductors and first and second threaded posts, a left clamping pad to clamp one of the set of grounding connectors between the left clamping pad and the main clamping pad, and a right clamping pad to clamp another of the set of grounding connectors between the right clamping pad and the main clamping pad.
In accordance with another aspect of the invention, a method is provided comprising inserting a first grounding conductor of a set of grounding conductors in one of a pair of perpendicular grooves in a lower clamping pad, inserting a second grounding conductor in one of a pair of perpendicular grooves in an upper clamping pad, and tightening first and second threaded fasteners to compress the upper clamping pad and the lower clamping pad against the set of grounding conductors.
Objects, features, and advantages of the present invention will become apparent upon reading the following description in conjunction with the drawing figures in which:
The disclosed grounding cross connector is configured such that the upper clamping pad pivots open and closed about one of the fasteners. This pivoting action enables the grounding cross connector to be installed without having to remove any of the components of grounding cross connector. The result is a faster and more efficient instillation.
Reference will now be made to the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the following description to refer to the same or similar parts. It is to be expressly understood, however, that the drawings are for illustration and description purposes only. While several examples are described in this document, modifications, adaptations, and other implementations are possible. Accordingly, the following detailed description does not limit the disclosed examples. Instead, the proper scope of the disclosed examples may be defined by the appended claims.
Grounding cross connector 100 may include an upper clamping pad 101, a lower clamping pad 102, a pair of fasteners 103 and 104 (which can be a screw, bolt, or other types of threaded fasteners), nuts 105 and 106, and washers 120 and 121. The various components included in grounding cross connector 100 may be made of various conducting materials, such as various types of metals.
To assemble grounding cross connector 100, fastener 104 may be inserted through opening 108 in upper clamping pad 101 and opening 115 in lower clamping pad 102 until the head of fastener 104 sits in recess 110. Similarly, fastener 103 may be inserted through opening 107 in upper clamping pad 101 and opening 114 in lower clamping pad 102 until the head of fastener 103 sits in recess 109. Washers 120 and 121 may be respectively slid onto fasteners 103 and 104. Nuts 105 and 106 may be respectively threaded onto the threaded shafts of fasteners 103 and 104.
The design of grounding cross connector 100 allows upper clamping pad 101 to swing or pivot open and closed. This pivoting action allows the end user to install grounding cross connector 100 without having to remove any of the components of grounding cross connector 100, and therefore allows for quicker installation.
To install grounding cross connector 100 on perpendicular conductors 118 and 119, the installer may loosen nut 105 on fastener 103 and nut 106 on fastener 104 so that there is enough room between upper clamping pad 101 and lower clamping pad 102 to insert conductors 118 and 119. The installer may swing open upper clamping pad 101 relative to lower clamping pad 102 (as shown in
Upper clamping pad 101 and lower clamping pad 102 each have a set of perpendicular grooves (i.e., grooves 112 and 113 for upper clamping pad 101 and grooves 116 and 117 for lower clamping pad 102), which allow conductors 118 and 119 to be positioned in either direction. For example, conductor 118 may be placed in groove 112 of upper clamping pad 101 while conductor 119 is placed in groove 117 of lower clamping pad 102, as shown in
With the bottom conductor (which is shown in the example in
When the conductors are in place, the installer evenly torques nuts 105 and 106. The shape of recesses 109 and 110 are designed to match the shapes of the heads of fasteners 103 and 104. As an example,
When the heads of fasteners 103 and 104 become trapped, the top of the heads will be flush with the top surface of upper clamping pad 101. This allows the installer to easily check if the fastener heads are appropriately resting in recesses 109 and 110.
Grounding cross connector 300 may include a main clamping pad 301, a left clamping pad 302 and a right clamping pad 303, washers 308 and 309, and nuts 306 and 307. As shown in
To assemble grounding cross connector 300, threaded rods 304 and 305 may be respectively inserted through opening 318 in left clamping pad 302 and opening 318 in right clamping pad 303. Washers 308 and 309 may then be respectively placed on threaded rods 304 and 305, and then nuts 306 and 307 may follow.
The design of grounding cross connector 300 allows the end user to install conductors 320 and 321 without having to remove any of the components of grounding cross connector 300, and therefore allows for quicker installation. To install grounding cross connector 300 on perpendicular conductors 320 and 321, the installer may loosen nuts 306 and 307 so that there is enough room between main clamping pad 301 and left and right clamping pads 302 and 303 to insert conductors 320 and 321. The installer may insert conductor 320 between left clamping pad 302 and main clamping pad 301 from below grounding cross connector 300 and may insert conductor 320 between left clamping pad 302 and main clamping pad 301 from below.
Main clamping pad 301 has a set of perpendicular grooves 310 and 311, and each of left and right clamping pads 302 and 303 have a groove 316 which allow conductors 320 and 321 to be securely positioned in grounding cross connector 300. For example, conductor 320 may be placed in groove 310 of main clamping pad 301 and groove 316 of left clamping pad 302, while conductor 321 is placed in groove 311 of main clamping pad 301 and groove 316 of right clamping pad 303, as shown in
With conductors 320 and 321 placed in their respective grooves, the installer may tighten nuts 306 and 307 to clamp conductors 320 and 321 between main clamping pad 301 and left and right clamping pads 302 and 303. To ensure that all clamping pads are properly aligned, main clamping pad 301 may include channels 312 and 313 in which notch 314 on left and right clamping pads 302 and 303 may rest.
Note that while the present disclosure includes several embodiments, these embodiments are non-limiting, and there are alterations, permutations, and equivalents, which fall within the scope of this invention. Additionally, the described embodiments should not be interpreted as mutually exclusive, and, should instead be understood as potentially combinable if such combinations are permissive. It should also be noted that there are many alternative ways of implementing the embodiments of the present disclosure. It is therefore intended that claims that may follow be interpreted as including all such alterations, permutations, and equivalents as fall within the true spirit and scope of the present disclosure.
This application is a continuation of U.S. Non-Provisional patent application Ser. No. 16/266,858, filed Feb. 4, 2019, which claims benefit to U.S. Provisional Application No. 62/626,330, filed Feb. 5, 2018, the entirety of all of which are hereby incorporated by reference herein.
Number | Date | Country | |
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62626330 | Feb 2018 | US |
Number | Date | Country | |
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Parent | 16266858 | Feb 2019 | US |
Child | 17021307 | US |