Patent Grant
10727613
Insulation piercing connectors may be used to attach sensing conductors, such as voltage detection lines, to a power cable. Some voltage detection devices may use dual independent electrical connections to each phase of a power cable to perform voltage detection. Voltage detection devices are typically mounted inside of a control panel before a first termination. Mounting a voltage detection device within the control panel provides for limited access and space.
The present invention provides for a voltage detection that utilizes two independent electrical connections to a power cable for voltage detection through an insulation piercing connector.
The following detailed description references the drawings, wherein:
The disclosed insulation piercing connector solves or improves upon one or more of the above noted and/or other problems and disadvantages with voltage detection devices and systems. The disclosed insulation piercing connector provides for a tandem system for sensing voltage in a compact configuration connectable in or out of a control panel. These and other objects, features, and advantages of the present disclosure will become apparent to those having ordinary skill in the art upon reading this disclosure.
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.
Insulation piercing connector 100 may include a top half 101, a bottom half 102, and a blade seal 103 held together by a fastener 104, such as a screw, bolt, or other types of fasteners. Top half 101 and bottom half 102 may be made of various insulating materials, such as various types of polymers/plastics. In one example, top half 101 and bottom half 102 may be made of a glass-filed nylon polymer. Blade seal 103 may be made of a rubber or elastomer. Fastener 104 may be made of an insulating material as well, or may be made of various metals.
A washer 107 (such as a ring washer, spring washer, or other types known in the art) may be positioned between the head of fastener 104 and top half 101 to evenly distribute the compression force applied by fastener 104. The threaded shaft of fastener 104 may be placed through hole 108 in top half 101, hole 111 in blade seal 103, and into a post 114. Post 114 may include a hole having threads therein, where the threads may be formed as integral part of post 114 or may be a metal or plastic threaded insert that is inserted into the hole in post 114. The threads of the threaded shaft of fastener 104 may engage with the threads in the hole in post 114 to compress top half 101, bottom half 102, and blade seal 103 together.
Insulation piercing assembly 133 may provide the electrical connection between power cable 132 (
Insulation piercing assembly 133 may be positioned within bottom half 102 of insulation piercing connector 100. For example, insulation piercing assembly 133 may sit in recesses 119a, 119b of bottom half 102, with the teeth of piercing blades 117a, 117b respectively sitting in grooves 134a, 134b. In alternative implementations, insulation piercing assembly 133 may sit in recesses in top half 101.
Blade seal 103 may be positioned on top of bottom half 102 and insulation piercing assembly 133. Blade seal 103 may include a U-shaped sidewall 109 that partially overlaps a portion of top half 101 and bottom half 102. Blade seal 103 may also include notches 123a-c that may be positioned in holes 121a-c to ensure that blade seal 103 is properly aligned on top of bottom half 102 and insulation piercing assembly 133. Rubberized insulating seals 112a, 112b may respectively cover the teeth of piercing blades 117a, 117b prior to insulation piercing connector 100 being compressed around power cable 132, at which point the teeth of piercing blades 117a, 117b penetrate insulating seals 112a, 112b. Insulating seals 112a, 112b prevent voltage leakage from the connection between piercing blades 117a, 117b and power cable 132 by forming a seal around the portion of the insulating layer penetrated by piercing blades 117a, 117b. The teeth of piercing blades 117a, 117b may be positioned respectfully within grooves 127a, 127b of insulating seals 112a, 112b.
Top half 101 may be placed on top of blade seal 103. Top half 101 and bottom half 102 may respectively have first round ends 124 and 120. When top half 101, bottom half 102, and blade seal 103 are all assembled, round ends 124 and 120 may form a recess 105 in which power cable 132 may be positioned.
As depicted in
As depicted in
The installer may view voltage detection conductors 130a, 130b through viewing holes to visually verify that voltage detection conductors 130a, 130b (or ferrules 131a, 131b, if installed) have been fully inserted into terminal housings 115a, 115b. For example, top half 101 may include recesses 106a, 106b that are subdivided into access holes 125a, 125b and viewing holes 126a, 126b; blade seal 103 may also include viewing holes 113a, 113b that align with viewing holes 126a, 126b of top half 101; and terminal housings 115a, 115b may include viewing holes 122a, 122b that align with viewing holes 113a, 113b of blade seal 103 and viewing holes 126a, 126b of top half 101. The installer may view voltage detection conductors 130a, 130b through the series of viewing holes in top half 101 and blade seal 103 as they are inserted into terminal housings 115a, 115b, and may secure voltage detection conductors 130a, 130b in terminal housings 115a, 115b view fasteners 116a, 116b once the installer has verified that voltage detection conductors 130a, 130b have been fully inserted into terminal housings 115a, 115b.
The installer may secure voltage detection conductors 130a, 130b in terminal housings 115a, 115b by inserting a fastening tool, such as a screw driver through access holes 125a, 125b in top half 101, and access holes 110a, 110b in blade seal 103, to tighten fasteners 116a, 116b.
Insulation piercing connector 200 may include a top half 201, a bottom half 202, and a blade seal 203 held together by a fastener 204, such as a screw, bolt, or other types of fasteners. Top half 201, bottom half 202, and blade seal 203 may be made of various insulating materials, such as various types of polymers/plastics. In one example, top half 201, bottom half 202, and blade seal 203 may be made of a glass-filed nylon polymer. Blade seal 203 may be made of a rubber or elastomer. Fastener 204 may be made of an insulating material as well, or may be made of various metals.
A washer 207 (such as a ring washer, spring washer, or other types known in the art) may be positioned between the head of fastener 204 and top half 201 to evenly distribute the compression force applied by fastener 204. The threaded shaft of fastener 204 may be placed through hole 208 in top half 201, hole 211 in blade seal 203, and into a post 214. Post 214 may include a hole having threads therein, where the threads may be formed as integral part of post 214 or may be a metal or plastic threaded insert that is inserted into the hole in post 214. The threads of the threaded shaft of fastener 204 may engage with the threads in the hole in post 214 to compress top half 201, bottom half 202, and blade seal 203 together.
Insulation piercing assembly 233 may provide the electrical connection between power cable 232 and voltage detection conductors 230a, 230b. Insulation piercing assembly 233 may be made up of components formed of a conductive material such as copper. As shown in the exploded view of insulation piercing assembly 233 in
Insulation piercing assembly 233 may be positioned within bottom half 102 of insulation piercing connector 200. For example, insulation piercing assembly 233 may sit in recesses 219a, 219b of bottom half 202, with the teeth of piercing blades 217a, 217b respectively sitting in grooves 234a, 234b. In alternative implementations, insulation piercing assembly 233 may sit in recesses in top half 201.
Blade seal 203 may be positioned on top of bottom half 202 and insulation piercing assembly 233. Blade seal 203 may include a U-shaped sidewall 209 that partially overlaps a portion of top half 201 and bottom half 202. Blade seal 203 may also include notches 223a-c that may be positioned in holes 221a-c to ensure that blade seal 203 is properly aligned on top of bottom half 202 and insulation piercing assembly 233. Rubberized insulating seals 212a, 212b may respectively cover the teeth of piercing blades 217a, 217b prior to insulation piercing connector 200 being compressed around power cable 232, at which point the teeth of piercing blades 217a, 217b penetrate insulating seals 212a, 212b. Insulating seals 212a, 212b prevent voltage leakage from the connection between piercing blades 217a, 217b and power cable 232 by forming a seal around the portion of the insulating layer penetrated by piercing blades 217a, 217b. The teeth of piercing blades 217a, 217b may be positioned respectfully within grooves 227a, 227b of insulating seals 212a, 212b.
Top half 201 may be placed on top of blade seal 203. Top half 201 and bottom half 202 may respectively have first round ends 224 and 220. When top half 201, bottom half 202, and blade seal 203 are all assembled, round ends 224 and 220 may form a recess 205 in which power cable 232 may be positioned.
As depicted in
As depicted in
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 claims priority to U.S. Provisional Application No. 62/585,095, filed Nov. 13, 2017, the subject matter of which is hereby incorporated by reference in its entirety.
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