The subject matter herein relates generally to electrical connectors and, more particularly, for electrical connectors that are coupled with one or more cables.
Some known electrical connectors are joined with cables to electrically couple the connectors with the cables. For example, the connectors may include contacts that engage a peripheral device. The contacts electrically join the connector with the peripheral device. The cable typically includes one or more conductors extending along the interior of the cable throughout the length of the cable. The cable is connected with the connector with the conductors electrically terminated with the contacts to electrically couple the cable with the contacts. Thus, the connector electrically connects the peripheral device with the cable. Electrical power and/or signals may then be communicated between the peripheral device and the cable. In applications where the peripheral device is a solar module or panel, the connector may communicate electric potential or current from the solar module or panel to another external or peripheral device via the cable.
In some applications, the cables joined with the connectors may experience significant forces that pull the cable away from the connector. For example, environmental factors such as ice and snow may add weight to cables joined to connectors mounted on solar panels. This additional weight may pull the cables away from the connectors. If the cables are not affixed to the connectors in a sufficiently strong manner, the cables may become detached from the connectors. That is, one or more of the conductors in the cables can separate from the contacts in the connector, thereby disrupting an electrically conductive path extending from the contacts to the cable conductors.
Some industry standard-setting organizations such as Underwriters Laboratories Inc. set forth standards for cable retention mechanisms. For example, the organizations may require that a cable joined with a connector mounted to a solar panel be able to withstand a minimum force applied to the cable without separating or removing the cable from the connector. Some known connectors do not meet these standards. For example, the cables of some known connectors may separate from the connectors when the minimum force required by industry standards is applied to the cables. Other known connectors meet the industry standards, but include retention mechanisms that are relatively large. For example, some known solar module connectors include pinch ring and nut combinations to secure cables to the connectors. The pinch ring is a ring that is placed around the cable. The pinch ring includes several slots that permit the ring to be compressed down onto the cable. The nut is placed into the connector. The pinch ring is screwed into the nut to compress the pinch ring onto the cable and to couple the cable with the connector. The pinch ring is compressed around the cable when the nut is screwed down or tightened onto the connector. But, the size of the nut limits the size of the connector. That is, the size of the connector typically must be at least as large as the nut. As a result, the profile height of the connector is limited by the size of the nut. In certain applications, the size of the nut may require the connector to have a profile height that is too large. For example, the location in which some solar module connectors are required may be too small to fit a connector having a nut and pinch ring combination.
Thus, a need exists for a connector assembly that affixes cables to connectors in such a manner to increase the force required to separate the cables from the connectors while maintaining a relatively small profile height of the connector.
In one embodiment, an electrical connector assembly is provided. The connector assembly includes a housing, a cable and a cable retention element. The housing holds contacts that are configured to be electrically joined with a peripheral device. The housing includes a cable port that is disposed at an outer surface of the housing. The cable extends from the cable port of the housing along a cable axis. The cable is electrically coupled with the contacts in the housing. The cable retention element is attached to the cable and is at least partially disposed within the housing. The cable retention element includes a body that is joined with the cable and a wing protruding from the body in a direction oriented at an angle with respect to the cable axis. The wing engages the housing to prevent the cable from being removed from the housing. Optionally, the wing of the cable retention element is encapsulated in the housing. In one embodiment, the direction in which the wing extends from the body of the cable retention element is approximately perpendicular to the cable axis.
In another embodiment, another electrical connector is provided. The connector assembly includes a housing, a cable and a cable retention element. The housing holds contacts that are configured to be electrically joined with a peripheral device. The housing includes a cable port disposed at an outer surface of the housing. The cable extends from the cable port of the housing and is electrically coupled with the contacts in the housing. The cable retention element is attached to the cable and is at least partially disposed within the housing. The cable retention element includes wings protruding from the cable retention element to corresponding outer wing ends. A wingspan extending from one outer wing end to another outer wing end is greater than an inside diameter of the cable port. Optionally, the wings protrude from the cable retention element in opposite directions. The housing may include a mounting side that is configured to be mounted to the peripheral device and an opposite top side. The directions in which the wings protrude from the cable retention element may extend between the mounting side and the top side of the housing.
The connector assembly 102 includes a housing 106 that is joined to several cables 108. While two cables 108 are coupled with the housing 106 in the illustrated embodiment, a different number of cables 108 may be provided. For example, a single cable 108 or three or more cables 108 may extend out of the housing 106. The housing 106 includes contacts 114 that are electrically coupled with the peripheral device 104. In the illustrated embodiment, the contacts 114 are joined with contact tabs (not shown) protruding from the peripheral device 104. Electric potential or current generated in the peripheral device 104 is communicated to the connector assembly 102 via the contacts 114. The cables 108 extend from the housing 106 to plug ends 110. One of the plug ends 110 shown in
The housing 106 extends along a profile height dimension 116 from a mounting side 118 to an opposite top side 120. The mounting side 118 and top side 120 are interconnected by four ends 128-134. First and second ends 128, 130 are approximately parallel to one another while third and fourth ends 132, 134 are approximately parallel to one another. Each of the first end 128 and the second end 130 intersects the third and fourth ends 132, 134. In the illustrated embodiment, each of the mounting side 118 and the top side 120 are located in separate planes that are approximately parallel to one another. The ends 128-134 are approximately perpendicular to the planes of the mounting side 118 and top side 120. The profile height dimension 116 is measured in a direction that extends approximately perpendicular to the mounting side 118 and the top side 120. The mounting side 118 is mounted to a mounting surface 122 of the peripheral device 104. The mounting surface 122 may be opposite of a light incident surface 124 of the peripheral device 104. The light incident surface 124 is the side of the peripheral device 104 that receives light to generate electric potential or current.
In the illustrated embodiment, housing 106 includes a cable port 136 along the outer surface of the housing 106 for each of the cables 108. As shown in
The housing 106 frames a contact window 138 that is an opening extending through the housing 106 from the mounting side 118 to the top side 120. The contacts 114 are disposed within the contact window 138. The contact window 138 permits visual alignment of the contacts 114 with corresponding contacts (not shown) of the peripheral device 104 during assembly of the system 100. The contact window 138 may be filled with an encapsulant or potting compound to seal the contacts 114 in the housing 106. The contacts 114 may be sealed in the contact window 138 to protect the contacts 114 from external environmental factors such as heat and moisture. Alternatively, a cover (not shown) may be used to enclose the contact window 138 from outside environmental factors.
An end portion 206 of each cable 108 includes a cable retention element 208. The cable retention elements 208 are attached to the cables 108. For example, the cable retention elements 208 may be crimped to the outer surfaces of the cables 108 to clamp the cable retention elements 208 to the cables 108. Alternatively, the cable retention elements 208 may be affixed to the cables 108 using other methods such as, for example, an adhesive. As described below, the cable retention elements 208 prevent the cables 108 from being removed from the housing 106 (shown in
Each cable retention element 208 includes a body 210 joined to a plurality of wings 212. While two wings 212 are joined to each of the bodies 210, a different number of wings 212 may be coupled to the body 210. For example, a single wing 212 or three or more wings 212 may be joined to each body 210. Alternatively, instead of discrete wings 212 protruding from the body 210, a collar or ledge (not shown) may extend from the body 210 around all or a portion of the body 210. As shown in
As shown in
In order to affix the cable retention element 208 to the cable 108, the cable 108 is placed into a cradle portion 226 of the cable retention element 208. Once the cable 108 is located in the cradle portion 226, the outer ends 214, 216 are moved toward one another to crimp the body 210 onto the cable 108. As described above, the outer ends 214, 216 are moved toward one another to form the seam 218. In the illustrated embodiment, the cable retention element 208 is coupled to the cable 108 without cutting into or otherwise displacing any part of the cable 108. For example, the cable retention element 208 does not cut into or displace the insulative sheath disposed around the exterior of the cable 108. Alternatively, the cable retention element 208 may cut into or displace a portion of the cable 108 in order to affix the cable retention element 208 to the cable 108. For example, the cable retention element 208 may displace some of the insulative sheath when the cable retention element 208 is crimped onto the cable 108.
The housing 106 is overmolded around the cable retention elements 208 in one embodiment. For example, all or a section of the end portions 206 of the cable retention elements 208 may be placed into a mold along with one or more additional components of the connector assembly 102 (for example, the contacts 114). A dielectric material such as a polymer is placed into the mold over the cable retention elements 208 to surround at least the wings 212 of the cable retention elements 208. Once the dielectric material cures, the housing 106 is overmolded over at least a portion of the cable retention elements 208 to encapsulate at least a portion of the cable retention elements 208 within the housing 106.
The cable retention element 208 engages the housing 106 to prevent the cable 108 from being removed from the housing 106. For example, the cable retention element 208 may secure the cable 108 to the housing 106 such that the force that is applied along the cable axis 126 and that is required to separate the cable 108 from the housing 106 is increased. The wings 212 may be sealed within the overmolded housing 106 to prevent removal of the cable 108 from the housing 106 in a direction along the cable axis 126. In the illustrated embodiment, the wingspan 222 of the cable retention element 208 is greater than an inside diameter 400 of the cable port 136 in the housing 106. The wingspan 222 exceeds the inside diameter 400 in a direction that is approximately parallel to the top side 120 (shown in
The wings 212 extend from the body 210 in the plane of the housing 106. For example, the wings 212 protrude from the body 210 in directions approximately parallel to the top side 120 (shown in
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Dimensions, types of materials, orientations of the various components, and the number and positions of the various components described herein are intended to define parameters of certain embodiments, and are by no means limiting and are merely exemplary embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. Further, the limitations of the following claims are not written in means—plus-function format and are not intended to be interpreted based on 35 U.S.C. §112, sixth paragraph, unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.
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Number | Date | Country | |
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20100311269 A1 | Dec 2010 | US |