Embodiments described herein relate generally to connectors, and more particularly to systems, methods, and devices for connecting and disconnecting electrical connectors.
Electrical connectors, as well as some other types (e.g., mechanical) of connectors, often include a male end and a female end that mechanically couple to each other. In the case of electrical connectors, coupling the male and female ends to each other also creates an electrical connection. These electrical connectors can have a number of varying characteristics. For example, some electrical connectors include only a single pin, while other electrical connectors include over 150 pins, where each pin represents an electrical path for a signal and/or power. As another example, some electrical connectors are somewhat large, while other electrical connectors are small. These characteristics (e.g., number of pins, size) can make manual coupling and decoupling of the male and female portions of an electrical connector a difficult task.
In cases where the manual coupling and decoupling of the male and female portions of an electrical connector are cumbersome, damage can occur to the electrical connector, making the electrical connector inoperable. For example, a pin can break, or a wire connected to a pin can become dislodged. Such damage can be based on one or more of a number of reasons. For example, damage can occur from improperly aligning the male and female end when applying a force to couple or decouple those ends. As another example, damage can occur when there are a large number of wires and some get dislodged from their pin connections in order to properly align the male and female portions.
In general, in one aspect, the disclosure relates to a connector installation tool. The connector installation tool can include an inner surface having a first portion having a first perimeter, where the inner surface forms a cavity that traverses a first length of the inner surface. The connector installation tool can also include an opening having a width and traversing the first length of the inner surface. The connector installation tool can further include a front face located adjacent to and substantially perpendicular to the first portion of the inner surface. The connector installation tool can also include a rear face located adjacent to a distal end of the inner surface, where the rear face is substantially parallel to the front face.
In another aspect, the disclosure can generally relate to a system for assembling an electrical connector. The system can include a first connector end of the connector having a first coupling feature, a first protrusion on its outer surface, and at least one first wire receiver. The system can also include a second connector end of the connector having a second coupling feature, a second protrusion on its outer surface, and at least one second wire receiver, where the second coupling feature mechanically couples to the first coupling feature. The system can further include a connector installation tool coupled to the first connector end. The connector installation tool of the system can include a first inner surface having a first portion having a first perimeter, where the first inner surface forms a cavity that traverses a first length of the first inner surface, and where the first perimeter is substantially the same as a first connector perimeter on a first outer surface of the first connector end. The connector installation tool of the system can also include a first opening having a first width and traversing the first length of the first inner surface. The connector installation tool of the system can further include a first front face located adjacent to and substantially perpendicular to the first portion of the first inner surface, where the first front face abuts against the first protrusion of the first connector end. The connector installation tool of the system can also include a first rear face located adjacent to a distal end of the first inner surface, where the first rear face is substantially parallel to the first front face. The system can also include a compression device that receives the second connector end and the first connector end coupled to the connector installation tool, where the compression device has a first position and a second position, where the first rear face abuts against one side of the compression device and the second connector end abuts against another side of the compression device. The first connector end and the second connector end can be decoupled when the compression device is in the first position. The first connector end and the second connector end can be coupled when the compression device is in the second position.
In yet another aspect, the disclosure can generally relate to a method for coupling two ends of a connector. The method can include receiving a portion of a first connector end of the connector into a cavity of a connector installation tool, where a different portion of the first connector end abuts against a front face of the connector installation tool. The method can also include positioning a second connector end of the connector proximate to the remainder of the first connector end to form an uncoupled connector assembly, where a first coupling feature of the first connector end is positioned proximately to a second coupling feature of the second connector end. The method can further include positioning the uncoupled connector assembly in a compression device, where the compression device is in an open position. The method can also include closing the compression device into a closed position to form a first coupled connector assembly, where closing the compression device couples the first coupling feature to the second coupling feature.
These and other aspects, objects, features, and embodiments will be apparent from the following description and the appended claims.
The drawings illustrate only example embodiments of connector installation tools and are therefore not to be considered limiting of its scope, as connector installation tools may admit to other equally effective embodiments. The elements and features shown in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the example embodiments. Additionally, certain dimensions or positionings may be exaggerated to help visually convey such principles. In the drawings, reference numerals designate like or corresponding, but not necessarily identical, elements.
The example embodiments discussed herein are directed to systems, apparatuses, and methods of connector installation tools. While the Figures shown and described herein are directed to electrical connectors, example connectors can be of other types, such as mechanical connectors. Thus, example connector installation tools described herein are not limited by the type of connector.
A user as described herein may be any person that is involved with installation and/or maintenance of connectors. Examples of a user may include, but are not limited to, a company representative, an electrician, an engineer, a mechanic, an operator, a consultant, a contractor, and a manufacturer's representative.
Example embodiments of connector installation tools will be described more fully hereinafter with reference to the accompanying drawings, in which example embodiments of connector installation tools are shown. Connector installation tools may, however, be embodied in many different forms and should not be construed as limited to the example embodiments set forth herein. Rather, these example embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of connector installation tools to those of ordinary skill in the art. Like, but not necessarily the same, elements (also sometimes called components) in the various figures are denoted by like reference numerals for consistency. Terms such as “first,” “second,” “distal,” “proximal,” “front,” and “rear” are used merely to distinguish one component (or part of a component) from another. Such terms are not meant to denote a preference or a particular orientation.
Referring to
The size and/or shape of each portion of the inner surface 180 can vary based on one or more of a number of factors. Examples of such factors can include, but are not limited to, a size and/or shape of a portion of a connector, the number of wires that are coupled to a portion of the connector, and the size of the compression device. For example, the portion 104 and the portion 106, as shown in
In one example embodiment, the length 146 can be approximately 27.9 centimeters (cm), the diameter 156 can be approximately 21.84 cm, the length 148 can be approximately 41.9 centimeters (cm), and the diameter 156 can be approximately 34.54 cm. In such a case, if the outer surface 102 is also cylindrical, the diameter 154 of the outer surface 102 can be approximately 49.5 cm or 54.1 cm, and the length 144 can be approximately 76.2 cm. The size (e.g., diameter 156) and the cylindrical shape of the portion 106 can be substantially the same as the size and shape of an outer portion of a connector end of a connector. Similarly, the size (e.g., diameter 154) and the cylindrical shape of the portion 104 can be substantially the same as the size and shape of an outer portion of a different connector end of a same or different connector.
In another example embodiment, when the portion 104, the portion 106, and the outer surface 102 are all cylindrically shaped, the length 146 can be approximately 27.9 centimeters (cm), the diameter 156 can be approximately 46.74 cm, the length 148 can be approximately 41.7 centimeters (cm), the diameter 156 can be approximately 59.94 cm, the diameter 154 can be approximately 74.9 cm or 79.5 cm, and the length 144 can be approximately 76.2 cm.
For these two example embodiments, the various lengths are substantially the same, but the diameters differ. However, other example embodiments of a tool and its various portions can have different lengths and/or diameters. Further, while the diameter 156 in these two example embodiments is smaller than the diameter 158, the diameter 156 can be larger than the diameter 158. Although the term “diameter” was used in these two example embodiments to describe the height or width of each portion of the inner surface 180, the term “perimeter” can more generally be used to describe the height or width of each portion of the inner surface 180, regardless of the cross-sectional shape of the inner surface 180.
The portion 108, in this example, is positioned between the portion 104 and the portion 106. The shape of portion 108 in
In certain example embodiments, the connector installation tool 100 includes a front face 111 and a rear face 112. The front face 111 can be located adjacent to and substantially perpendicular to a proximal end of the inner surface 180. When the inner surface 180 includes multiple portions (e.g., portion 104, portion 106, portion 108), the front face 111 can be located adjacent to one of those portions. For example, in
Similarly, the rear face 112 can be located adjacent to and substantially perpendicular to a distal end of the inner surface 180, on an opposite end of the tool 100 from where the front face 111 is located. When the inner surface 180 includes multiple portions (e.g., portion 104, portion 106, portion 108), the rear face 112 can be located adjacent to one of those portions. For example, in
In certain example embodiments, the connector installation tool 100 includes an opening 130 that traverses the length of the inner surface 180 and also the length 144 of the outer surface 102. The opening 130 can have a width 132 that is substantially uniform between the outer surface 102 and each portion, if multiple portions, of the inner surface 180. The width 132 of the opening 130 should be large enough to accommodate the number of wires that connect to an end of the connector.
The connector installation tool 100 can also include at least one beveled surface that is disposed on distal and/or proximal end of the connector installation tool 100. For example, as shown in
A beveled surface (e.g., beveled surface 172) can form an acute angle (e.g., angle 142) between the beveled surface and the inner surface 180. The beveled surface can be used to help insert part of a connector into the cavity 120 formed by the inner surface 180. The length of a beveled surface can be relatively small, so that the vertical component 174 of the length is very small (e.g., 0.015 cm). In some cases, as shown and described below with respect to
The connector installation tool 100 can be made from a single piece, as from a mold, or can be multiple pieces that are mechanically coupled to each other using one or more of a number of coupling devices and/or methods, including but not limited to soldering, compression fittings, slots, tabs, and mating threads. The connector installation tool 100 can be made of one or more of a number of materials that allow the connector installation tool 100 to substantially retain its shape (e.g., the perimeter of any portion of the inner surface does not increase substantially) when the front end 111 and the rear end 112 each have a lateral, inward force applied, as from a compression device. Examples of such materials can include, but are not limited to, metal and plastic.
Referring to
In certain example embodiments, the second end 260 of the connector 290 includes one or more of a number of features. For example, as shown in
Similarly, the first end 270 can include one or more of a number of features. For example, as shown in
The insert 272 can have a sleeve 276 over which the pressure sleeve 271 is disposed. Further, the insert 272 can include a collar 278 against which the pressure sleeve 271 abuts. The pressure sleeve 271 can include one or more features (not shown), such as a notch, to orient the pressure sleeve 271 with respect to the insert 272. Similarly, the insert 272 can include one or more features (e.g., slot 277 on the collar 278) to orient the insert 272 with respect to the pressure sleeve 271 and/or the second end 260.
In certain example embodiments, the shape and size of the outer surface of the pressure sleeve 271 (and in particular the body 274 of the pressure sleeve 271) are substantially the same as the shape and size (perimeter) of the portion 206 of the inner surface 280 of the tool 201. In such a case, the body 274 of the pressure sleeve 271 can be disposed within the cavity 220 of the inner surface 280 of the tool 201.
In addition, the perimeter of the collar 275 of the pressure sleeve 271 can be larger than the perimeter of the portion 206 of the inner surface 280 of the tool 201, so that the collar 275 can abut against the front face 211 of the tool 201 and prevent the body 274 from sliding too far inside of the cavity 220 of the tool 201. As shown in
The tool 201 of
Portion 207 can be included on the inner surface 280 to allow the tool 201 to fit more precisely over a portion of a connector to provide a better compressive force and/or to regulate how much insertion is permitted between the second end 260 and the first end 270 of the connector 290. Similarly, one or more other portions and/or features can be added to the inner surface of a tool to provide more efficient and less destructive coupling and decoupling forces to ends of a connector, and/or to prevent over-insertion and/or under-insertion of one connector end into another.
Referring to
The coupling features 294 of the first end can be configured to mechanically couple to, and also mechanically decouple from, the coupling features 273 of the first end 270.
While
In order to mechanically coupled the second end 260 and the first end 270 of the connector 290 together using the connector installation tool 201, a compressive force is applied to the rear face 285 of the second end 260, and an opposing compressive force is applied to the rear face 212 of the connector installation tool 201. The compressive forces can be applied by one or more of a number of compression devices. For example, as in this case, the compressive forces can be applied by a compression device 310 having a wall 380 and a wall 382. Examples of other compression devices can include, but are not limited to, a press, a compactor, and an adjustable clamp.
In
In
Applying too much compressive force to the second end 260 and the first end 270 of the connector 290 can result in damage to the coupling features 294 and/or the wire receivers 292 of the second end 260 and/or the coupling features 273 and/or the wire receivers 296 of the first end 270. To reduce the likelihood of this occurring, one or more features of the tool 201 can interact with one or more features of the connector 290. For example, as shown in
Since the compression device 310 applies inwardly-directed compression forces, the portions of the components (the connector installation tool 201, the second end 260 of the connector 290, and the first end 270 of the connector 290) should all be substantially aligned with the direction of the compression forces. If not, damage may occur to one or more portions of the connector 290. To help ensure that the components are substantially aligned with the direction of the compression forces, the rear face 212 and the front face 211 of the tool 201 can be substantially parallel to the wall 380, and the rear face 285 of the second end 260 can be substantially parallel to the wall 382. Put another way, the front face 211 and the rear face 212 can be substantially parallel to each other and substantially perpendicular to the portion 204 of the inner surface 280. Similarly, the rear face 285 and the front face 284 can be substantially parallel to each other and substantially perpendicular to the outer surface 282 of the second end 260.
The front face 211 and/or the rear face 212 can be flat. Alternatively, the front face 211 and/or the rear face 212 can be substantially a pointed edge based on a chamfered or beveled surface that transitions from the inner surface 280 to the front face 211 and/or the rear face 212. For example, the beveled surface 177 of the connector installation tool 100 in
While the connector installation tool 201 can be used to fully mechanically couple the second end 260 and the first end 270 of the connector 290, as described above with respect to
Referring to
The connector end 470 of
In this example, the shape and size of the outer surface of the pressure sleeve 471 (and in particular the body 474 of the pressure sleeve 471) are substantially the same as the shape and size (perimeter) of the portion 404 of the inner surface 480 of the tool 401. In such a case, the body 474 of the pressure sleeve 471 can be disposed within the cavity 420 of the inner surface 480 of the tool 401. In addition, the perimeter of the collar 475 of the pressure sleeve 471 can be larger than the perimeter of the portion 404 of the inner surface 480 of the tool 401, so that the collar 475 can abut against the rear face 412 of the tool 401 and prevent the body 474 from sliding too far inside of the cavity 420 of the tool 401.
In certain example embodiments, each wire 442 includes a conductor (not shown) that is encased by insulation 444. As shown in
Referring to
In certain example embodiments, the removal tool 550 has a body 552 that forms a cavity 558 that leads to an open end. The body 552 is shaped and sized to fit within the rear face 285 of the second end 260 of the connector 290. In such a case, the cavity 558 is sized and shaped to house the wire receivers 292 of the second end 260. Thus, the removal tool 550 protects the wire receivers 292 when the connector 290 is extracted from the connector installation tool 100. The removal tool 550 can be removably coupled to the second end 260 with or without the use of a coupling feature on the removal tool 550 and/or the second end 260. Such coupling features can include, but are not limited to, mating threads, compression fittings, tabs, recesses, notches, and slots. The removal tool 550 can be made from one or more of a number of different materials, including but not limited to rubber, plastic, and metal.
In addition, the connector installation tool 100 has a portion 104 of the inner surface that has a shape and perimeter that is substantially similar to (or slightly larger than) the shape and perimeter of the outer surface of the flange 281 of the second end 260 of the connector 290, and yet also smaller than the shape and perimeter of the collar 283 of the second end 260 of the connector 290. In this case, the connector installation tool 201 can be used to remove the connector 290 by turning the connector installation tool 201 around so that first end 270 of the connector is disposed within the cavity 220 formed by portion 104 of the inner surface 180. Because the perimeter of the portion 104 is greater than the perimeter of the outer surface of the flange 281, more of the connector 290 can be disposed within the cavity 120. In this case, the rear face 112 can abut against the collar 283 of the second end 260.
With the removal tool 550 coupled to the second end 260 of the connector 290, the connector 290 can safely be removed (decoupled) from the connector installation tool 100 without damaging the wire receivers 292 and/or other components of the second end 260. The connector 290 can be removed from the connector installation tool 100 by hand, using a compression device (e.g., compression device 310), or using some other device.
Referring now to
In step 604, a second connector end 260 of the connector 290 is positioned proximate to the remainder of first connector end 270 to form an uncoupled connector assembly. In certain example embodiments, a first coupling feature 273 of the first connector end 270 is positioned proximately to a second coupling feature 294 of the second connector end 260. In some cases, a portion of the second connector end 260 can be disposed inside a cavity of an additional connector installation tool.
In step 606, the uncoupled connector assembly is positioned in a compression device 310. In such a case, the compression device 310 is in an open position. In step 608, the compression device 310 is closed into a closed position to form a first coupled connector assembly. In certain example embodiments, closing the compression device 310 couples the first coupling feature 273 of the first end 270 to the second coupling feature 294 of the second end 260. After step 608 is complete, the process can proceed to the END step.
Alternatively, once step 608 is complete, other steps can be performed. For example, the compression device 310 can be opened, and the components of the first coupled connector assembly (e.g., the first end 270, the second end 260, the connector installation tool 201, the additional connector installation tool) can be removed from the compression device 310. Once the first coupled connector assembly is removed from the compression device 310, the connector installation tool 201 (and, if applicable, the additional connector installation tool) can be decoupled from the connector to leave the connector 290, where the first end 270 and the second end 260 can remain mechanically coupled to each other. In such a case, one or more removal tools 550 can be used to help protect the wire receivers (e.g., wire receivers 292) and/or other components of the connector 290 while the connector 290 is decoupled from the connector installation tool 201. The connector 290 can be removed from the connector installation tool 201 by hand, using a compression device (e.g., compression device 310), or using some other device.
In certain example embodiments, when decoupling the connector 290 from the connector installation tool 201, the orientation of the connector installation tool 201 can be reversed. In other words, the first connector end 270 of the connector 290 can be disposed within the cavity 220 formed by the portion 207 and the portion 204, rather than the portion 206. The wires 242 can extend through the opening 230, and a portion (e.g., the collar 283 of the insert 272) of the second end 260 of the connector 290 can abut against the rear face 212 of the connector installation tool 201.
Using example connector installation tools described herein increases the ease of wiring one or both ends of a connector and coupling the ends of the connector to each other. Further, using example connector installation tools reduces the likelihood of causing damage to one or more components (e.g., a wire, a wire receiver, a coupling feature) of the connector as the ends of the connector are coupled to each other. While example embodiments shown herein are for connectors that receive multiple (e.g., 150, 100) wires at one or both ends, example embodiments can also be used for connectors with ends that each receive a single wire.
Further, an example removal tool 550 can be used while coupling connector ends using example connector installation tools and/or while removing a connector from a connector installation tool. In such a case, various components (e.g., wire receivers) of a connector end can be protected from damage while coupling connector ends using example connector installation tools and/or while removing a connector from a connector installation tool.
Although embodiments described herein are made with reference to example embodiments, it should be appreciated by those skilled in the art that various modifications are well within the scope and spirit of this disclosure. Those skilled in the art will appreciate that the example embodiments described herein are not limited to any specifically discussed application and that the embodiments described herein are illustrative and not restrictive. From the description of the example embodiments, equivalents of the elements shown therein will suggest themselves to those skilled in the art, and ways of constructing other embodiments using the present disclosure will suggest themselves to practitioners of the art. Therefore, the scope of the example embodiments is not limited herein.
This application is a divisional application of and claims priority to U.S. patent application Ser. No. 13/950,863, entitled “Connector Installation Tool” and filed on Jul. 25, 2013, and which is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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20160190761 A1 | Jun 2016 | US |
Number | Date | Country | |
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Parent | 13950863 | Jul 2013 | US |
Child | 15065450 | US |