The subject matter herein relates generally to modular plugs.
In electrical systems, there is increasing concern for powering electronic devices. Some electrical systems supply power over typical connectors. For example, industry standard type RJ-45 communication connectors provide Power over Ethernet connections by supplying current along the 8 signal circuits. Such connectors have limited current carrying capability.
A connector capable of having higher current carrying ability is needed.
In one embodiment, a modular plug includes a plug housing, plug contacts held by the plug housing, and a stuffer cap coupled to the plug housing. The stuffer cap includes a cable channel configured to receive a cable therein. The stuffer cap includes an interior side that defines at least a portion of the cable channel. The modular plug includes a strain relief member held by the plug housing. The strain relief member includes a base and a spring beam extending from the base such that the spring beam is cantilevered from the base. The spring beam is configured to engage the cable and thereby pinch the cable between the interior side of the stuffer cap and the spring beam.
In another embodiment, a modular plug includes a plug housing, plug contacts held by the plug housing, and a strain relief member held by the plug housing. The strain relief member includes a base and a spring beam cantilevered from the base. A stuffer cap is pivotally coupled to the plug housing. The stuffer cap includes a cable channel configured to receive a cable therein. The stuffer cap includes an interior side that defines at least a portion of the cable channel. The stuffer cap is configured to press wires of the cable into electrical contact with the plug contacts when the stuffer cap is pivoted to a closed position. The stuffer cap includes a slot that extends through the stuffer cap into the cable channel. The slot is configured to receive the spring beam of the strain relief member therein as the stuffer cap is pivoted to the closed position such that the spring beam pinches the cable between the interior side of the stuffer cap and the spring beam.
In another embodiment, a modular plug includes a cable having an insulative cable jacket and an end, a plug housing, and plug contacts held by the plug housing. A stuffer cap is coupled to the plug housing. The stuffer cap includes a cable channel and an interior side that defines at least a portion of the cable channel. The end of the cable is received within the cable channel. A strain relief member is held by the plug housing. The strain relief member includes a base and a spring beam cantilevered from the base. The spring beam is engaged with the insulative jacket of the cable such that the cable is pinched between the interior side of the stuffer cap and the spring beam.
The jack 12 and plug 14 will be described in terms of electrical connectors having components meeting certain requirements of industry standard type RJ-45 connectors, however the jack 12 and plug 14 may have some components that are outside of or do not comply with such industry standards. For example, the size, shape, position and configuration of certain components may comply with the standard, however the electrical connectors are used as power connectors rather than data connectors and thus may have different components to achieve power transmission. In an exemplary embodiment, the electrical connectors have eight contacts, however the eight contacts are used for power transmission rather than data transmission as is typical of RJ-45 connectors.
The jack 12 includes eight mating contacts 20 that are accessible at a mating end 22 to provide a connection interface for the printed circuit board 16. A housing 26 of the jack 12 may be mounted to the printed circuit board 16. In an exemplary embodiment, the eight mating contacts 20 are electrically commoned as part of one or more power circuits. For example, two power circuits may be provided with four mating contacts 20 in each power circuit. The mating contacts 20 are accessed through an opening 28 in the mating end 22 of the housing 26. A locking mechanism 30 extends into opening 28 that is configured to engage a portion of the plug 14 to retain the plug 14 within the jack 12.
In an exemplary embodiment, a mating interface 32 of the jack 12 defines an RJ-45 modular jack mating interface. The mating interface 32 is defined by features, such as, the size and shape of the opening 28, the positioning of the mating contacts 20 in the opening 28, the spacing of the mating contacts 20, the positioning of the locking mechanism 30, and the like.
The plug 14 has a plug housing 34 having a mating end 36 and a cable end 38. The plug housing 34, at the mating end 36, has a substantially similar cross section as the opening 28 of the jack 12. The mating end 36 is plugged into the opening 28 during mating of the plug 14 with the jack 12.
The plug housing 34 includes a plurality of contact slots 40 formed therein at the mating end 36. Plug contacts 42 are located in each of the contact slots 40. Each plug contact 42 is configured to make electrical contact with one of the mating contacts 20 when the plug 14 is inserted into the jack 12. In the illustrated embodiment, the plug 14 includes eight plug contacts 42 that are accessible at the mating end 36 to provide a connection interface for corresponding wires 44 (shown in
The plug 14 includes a latch 50 for latching the plug 14 to the jack 12, utilizing the locking mechanism 30 within the jack 12. The latch 50 extends from a top 52 of the plug housing 34 proximate to the mating end 36.
In an exemplary embodiment, a mating interface 54 of the plug 14 defines an RJ-45 modular plug mating interface. The mating interface 54 is defined by features, such as, the size and shape of the exterior of the plug housing 34 at the mating end 36, the positioning of the plug contacts 42 along the plug housing 34, the spacing of the plug contacts 42, the positioning of the latch 50, and the like.
It is to be understood that the benefits described herein are also applicable to other types of electrical connectors, having other standardized mating interfaces, which may carry fewer or greater numbers of contacts in alternative embodiments. The following description is therefore provided for illustrative purposes only and is but one potential application of the subject matter described herein.
The leadframe assembly 60 is configured to be loaded into the plug housing 34. In an exemplary embodiment, the leadframe assembly 60 includes a first leadframe 64 and a second leadframe 66. The first and second leadframes 64, 66 form first and second power circuits for the plug 14. The first and second leadframes 64, 66 are configured to be connected to different wires 44 of the power cable 18.
In an exemplary embodiment, the first leadframe 64 defines a positive terminal of the plug 14 and the second leadframe 66 defines a negative terminal of the plug 14. Different groups of the plug contacts 42 are ganged together by the first and second leadframes 64, 66. For example, in an exemplary embodiment, the plug 14 includes 8 plug contacts 42 with four of the plug contacts 42 defining a first group of plug contacts 42 associated with the first leadframe 64 and four of the plug contacts 42 define a second group of plug contacts 42 that are associated with the second leadframe 66. In an exemplary embodiment, the first leadframe 64 and the second leadframe 66 are vertical stacked with the plug contacts 42 being internested at the mating end 36 of the plug housing 34 when assembled.
The first leadframe 64 includes a commoning pad 70, a plurality of the plug contacts 42 extending forward from the commoning pad 70 and a terminating leg 72 extending rearward from the commoning pad 70. The commoning pad 70 electrically commons the first group of plug contacts 42 together. In an exemplary embodiment, the plug contacts 42 are formed integral with the commoning pad 70. For example, the plug contacts 42 and the commoning pad 70 may be stamped from a metal sheet to form the leadframe.
The terminating leg 72 is positioned for terminating to the corresponding wire 44 of the power cable 18. In the illustrated embodiment, the terminating leg 72 includes spikes 74 that are configured to pierce the wire 44. The wire 44 may be a stranded wire conductor, or alternatively may be a solid conductor. Other types of terminating features may be provided in alternative embodiments for mechanically and electrically connecting the first leadframe 64 to the wire 44. For example, the terminating leg 72 may include an insulating displacement contact, a crimp barrel, a spring beam, or another type of terminating feature.
The second leadframe 66 includes a commoning pad 80, a plurality of the plug contacts 42 extending forward from the commoning pad 80 and a terminating leg 82 extending rearward from the commoning pad 80. The commoning pad 80 electrically commons the second group of plug contacts 42 together. In an exemplary embodiment, the plug contacts 42 are formed integral with the commoning pad 80. For example, the plug contacts 42 and the commoning pad 80 may be stamped from a metal sheet to form the leadframe.
The terminating leg 82 is positioned for terminating to the corresponding wire 44 of the power cable 18. In the illustrated embodiment, the terminating leg 82 includes spikes 84 that are configured to pierce the wire 44. The wire 44 may be a stranded wire conductor, or alternatively may be a solid conductor. Other types of terminating features may be provided in alternative embodiments for mechanically and electrically connecting the second leadframe 66 to the wire 44. For example, the terminating leg 82 may include an insulating displacement contact, a crimp barrel, a spring beam, or another type of terminating feature.
During assembly, the leadframe assembly 60 is loaded into the plug housing 34. For example, the leadframe assembly 60 may be loaded into the plug housing 34 through the cable end 38. Optionally, the first and second leadframes 64, 66 may be loaded into the plug hosing 34 together as a unit. Alternatively, the first and second leadframes 64, 66 may be separately and individually loaded into the plug housing 34. When the leadframe assembly 60 is loaded into the plug housing 34, the plug contacts 42 are arranged at the mating end 36 of the plug housing 34. The terminating legs 72, 82 are positioned proximate to the cable end 38 of the plug housing 34 for terminating to the wires 44.
The stuffer cap 62 includes securing features 90 configured to engage corresponding securing features 92 of the plug housing 34. In the illustrated embodiment, the securing features 90 constitute clips or tabs extending from the stuffer cap 62. In the illustrated embodiment, the securing features 92 constitute openings that receive the securing features 90. The securing features 90, 92 are used to secure the stuffer cap 62 to the plug housing 34 in the pre-staged, open position and/or the closed position.
The stuffer cap 62 includes wire channels 94 that receive corresponding wires 44. The wires 44 are loaded into the wire channels 94 in a wire loading direction. Once the wires 44 are fully loaded into the wire channels 94 the stuffer cap 62 may be moved to the closed position. As the stuffer cap 62 is moved to the closed position, the stuffer cap 62 forces the wires 44 into electrical contact with the leadframe assembly 60 by forcing the spikes 74, 84 through insulation of the wires 44.
In an exemplary embodiment, the stuffer cap 62 includes a strain relief feature 96 used to provide strain relief for the power cable 18. In the illustrated embodiment, the strain relief feature 96 includes a lid or cover that may be closed tightly around the power cable 18 to provide strain relief between the power cable 18 and the plug 14. Other types of strain relief features may be provided in alternative embodiments.
Any of the plug contacts 42 may be ganged together depending on the particular application. In an exemplary embodiment, the plug contacts 42 at positions 1, 3, 5, 7 are electrically commoned together as part of the first leadframe 64 (shown in
The plug 114 has a plug housing 134 having a mating end 136 and a cable end 138. The plug housing 134 includes a plurality of contact slots 140 formed therein at the mating end 136. Plug contacts 142 are located in each of the contact slots 140. The plug contacts 142 may be substantially similar to the plug contacts 42 (shown in
In the illustrated embodiment, the plug 114 includes eight plug contacts 142 that are accessible at the mating end 136 to provide a connection interface for corresponding wires 144 (shown in
In an exemplary embodiment, a mating interface 154 of the plug 114 defines an RJ-45 modular plug mating interface. The mating interface 154 is defined by features, such as, the size and shape of the exterior of the plug housing 134 at the mating end 136, the positioning of the plug contacts 142 along the plug housing 134, the spacing of the plug contacts 142, the positioning of a latch 150, and the like.
The plug 114 includes a stuffer cap 162 configured to receive the wires 144 of the power cable 118 and configured to be coupled to the plug housing 134. The stuffer cap 162 is used to electrically connect the wires 144 to the leadframe assembly 60 of the plug 114 during assembly. For example, the wires 144 may be pressed into electrical contact with the leadframe assembly 60 when the stuffer cap 162 is coupled to the plug housing 134. In the illustrated embodiment, the stuffer cap 162 is pivotably coupled to the plug housing 134. The stuffer cap 162 may include pins or posts 164 extending into the plug housing 134 that operate as an axle for the stuffer cap 162. Alternatively, the stuffer cap 162 may be formed integral with the plug housing 134 and is connected thereto at a living hinge.
Plugs 14, 114 are provided that define power connectors having RJ-45 mating interfaces. The plug contacts 42, 142 are electrically commoned as part of leadframes that define power terminals of the plugs 14, 114. Having many plug contacts 42, 142 electrically commoned together allows higher current caring capability for the plugs 14, 114, as compared to electrical connects where only one or two of the plug contacts carry current.
The plug 214 has a plug housing 234 having a mating end 236 and a cable end 238. The plug housing 234 includes a plurality of contact slots 240 formed therein at the mating end 236. Plug contacts 242 (not visible in
In the illustrated embodiment, the plug 214 includes eight plug contacts 242 that are accessible at the mating end 236 to provide a connection interface for corresponding wires 244 (shown in
The plug 214 may meet certain requirements of industry standard type RJ-45 connectors. For example, the size, shape, position and configuration of certain components may comply with the standard. In an exemplary embodiment, the mating interface 254 of the plug 214 defines an RJ-45 modular plug mating interface. The mating interface 254 is defined by features, such as, the size and shape of the exterior of the plug housing 234 at the mating end 236, the positioning of the plug contacts 242 along the plug housing 234, the spacing of the plug contacts 242, the positioning of a latch 250, and the like.
The plug 214 is not limited to meeting certain requirements of industry standard type RJ-45 connectors. Rather, the plug 214 may be any type of modular plug that meets certain requirements of any industry standard(s). Moreover, the illustrated embodiment of the plug 214 is used as a power connector rather than a data connector and therefore may have different components to achieve power transmission. But, the plug 214 is not limited to being used as a power connector. Rather, the plug 214 may transmit data signals in addition or alternative to transmitting power, no matter which type of modular plug the plug 214 is and which industry standard(s) the plug 214 conforms to. For example, although described as a “power cable”, the cable 218 may additionally or alternatively transmit data signals. In some embodiments, the plug 214 does not transmit power.
The plug 214 includes a stuffer cap 262 configured to receive the wires 244 of the power cable 218 and configured to be coupled to the plug housing 234. The stuffer cap 262 is used to electrically connect the wires 244 to the leadframe assembly 260 of the plug 214 during assembly. For example, the wires 244 may be pressed into electrical contact with the leadframe assembly 260 when the stuffer cap 262 is coupled to the plug housing 234. In the illustrated embodiment, the stuffer cap 262 is pivotably coupled to the plug housing 234 such that the stuffer cap 262 is pivotable between a pre-staged position and a closed position with respect to the plug housing 234. The stuffer cap 262 is shown in the closed position in
One or more pivot pins and/or one or more pivot posts may extend into one or more corresponding openings of the plug housing 234 to operate as an axle for the pivoting action of the stuffer cap 262. In the illustrated embodiment, the stuffer cap 262 includes opposite pivot posts 264 (only one is visible in
One example of using one or more pivot pins includes providing a single pivot pin (not shown) that extends through the stuffer cap 262 and has opposite ends that extend into the opposite openings 266 of the plug housing 234. In addition or alternatively to any pivot posts 264 and/or any pivot pins, the stuffer cap 262 may be formed integral with the plug housing 234 and connected thereto at a living hinge that enables the pivoting action of the stuffer cap 262.
The stuffer cap 262 includes securing features 290 configured to engage corresponding securing features 292 of the plug housing 234 to secure the stuffer cap 262 in the pre-staged position relative to the plug housing 234. In the illustrated embodiment, the securing features 90 constitute embossments 290a (only one is shown herein) that extend outward from opposite sides 272, 274 of the stuffer cap 262. The securing features 292 of the plug housing 234 constitute ledges 292a (only one is visible in
The plug housing 234 optionally includes one or more openings 273 that receive the embossments 292a therein when the stuffer cap 262 is in the closed position, as is shown in
Other arrangements may additionally or alternatively be used to secure the stuffer cap 262 in the pre-staged position. For example, the securing features 290, 292 are not limited to using the snap-fit connection, but rather may use any other type of connection, such as, but not limited to, using an interference-fit (i.e., press-fit) connection, using stiction between the stuffer cap 262 and the plug housing 234 (e.g., at the pivot axle), using a latch-type connection, using a threaded connection, and the like. Moreover, the securing features 290, 292 are not limited to the respective embossments 290a and ledges 292a, but rather may additionally or alternatively include any other type of connection structure, such as, but not limited to, a tab, a notch, a post, an opening, a latch, a clip, a clamp, a threaded fastener, and the like.
As described above, the plug 214 includes the leadframe assembly 260. In the illustrated embodiment, the leadframe assembly 260 includes two leadframes, namely a first leadframe 364 and a second leadframe 366. The first and second leadframes 364, 366 form first and second power circuits for the plug 214. The first and second leadframes 364, 366 are configured to be connected to different wires 244 of the power cable 218. Although two are shown and described herein, the leadframe assembly 260 may include any number of leadframes.
In an exemplary embodiment, the first leadframe 364 defines a positive terminal of the plug 214 and the second leadframe 366 defines a negative terminal of the plug 214. Different groups of the plug contacts 242 (not visible in
The first leadframe 364 includes a commoning pad 370, a plurality of the plug contacts 242 extending forward from the commoning pad 370 and a terminating leg 372 extending rearward from the commoning pad 370. The commoning pad 370 electrically commons the first group of plug contacts 242 together. In an exemplary embodiment, the plug contacts 242 are formed integral with the commoning pad 370. For example, the plug contacts 242 and the commoning pad 370 may be stamped from a metal sheet to form the first leadframe 364.
The terminating leg 372 is positioned for terminating to the corresponding wire 244 of the power cable 218. In the illustrated embodiment, the terminating leg 372 includes spikes 374 that are configured to pierce the wire 244. Other types of terminating features may be provided in alternative embodiments for mechanically and electrically connecting the first leadframe 364 to the wire 244. For example, the terminating leg 372 may include an insulating displacement contact, a crimp barrel, a spring beam, or another type of terminating feature.
The second leadframe 366 includes a commoning pad 380, a plurality of the plug contacts 242 extending forward from the commoning pad 380 and a terminating leg 382 extending rearward from the commoning pad 380. The commoning pad 380 electrically commons the second group of plug contacts 242 together. In an exemplary embodiment, the plug contacts 242 are formed integral with the commoning pad 380. For example, the plug contacts 242 and the commoning pad 380 may be stamped from a metal sheet to form the leadframe.
The terminating leg 382 is positioned for terminating to the corresponding wire 244 of the power cable 218. In the illustrated embodiment, the terminating leg 382 includes spikes 384 that are configured to pierce the wire 244. Other types of terminating features may be provided in alternative embodiments for mechanically and electrically connecting the second leadframe 366 to the wire 244. For example, the terminating leg 382 may include an insulating displacement contact, a crimp barrel, a spring beam, or another type of terminating feature.
Referring now solely to
Other arrangements may additionally or alternatively be used to secure the stuffer cap 262 in the closed position. For example, the securing features 291, 293 are not limited to using the snap-fit connection, but rather may use any other type of connection, such as, but not limited to, using an interference-fit (i.e., press-fit) connection, using stiction between the stuffer cap 262 and the plug housing 234 (e.g., at the pivot axle), using a latch-type connection, using a threaded connection, and the like. Moreover, the securing features 291, 293 are not limited to the respective window 291a and embossment 293a, but rather may additionally or alternatively include any other type of connection structure, such as, but not limited to, a tab, a notch, a post, a ledge, a latch, a clip, a clamp, a threaded fastener, and the like.
Referring again to
The stuffer cap 262 includes a slot 286 that extends through the stuffer cap 262 into the cable channel 282. Specifically, the slot 286 extends through a wall 288 of the stuffer cap 262 that includes the interior side 284c. The slot 286 extends through the interior side 284c of the wall 288 such that an end 290 of the slot 286 communicates with the cable channel 282. The slot 286 extends completely through the wall 288 such that an opposite end 292 of the slot is open. As will be described below, the slot 286 is configured to receive a portion of the strain relief member 296 therein to enable the strain relief member 296 to engage the power cable 218 when the stuffer cap is pivoted to the closed position. Although shown as having the general cross-sectional shape of a rectangle, the slot 286 may have any other shape (and may have any size) that enables the slot 286 to receive the strain relief member 296 such that the strain relief member 296 engages the power cable 218.
As briefly described above, the plug 214 includes the strain relief member 296. The strain relief member 296 is optionally integrally formed with at least one of the plug contacts 242. In the illustrated embodiment, the strain relief member 296 is integrally formed with the leadframe 366. For example, the strain relief member 296, the second group of plug contacts 242, and the commoning pad 380 may be stamped from a sheet of material as an integral structure to form the leadframe 366 and strain relief member 296. In some alternative embodiments, the strain relief member 296 is integrally formed with the leadframe 364. Moreover, in some other alternative embodiments, the strain relief member 296 is integrally formed with the plug housing 234. For example, the strain relief member 296 and the plug housing 234 may be fabricated using the same mold.
The strain relief member 296 is held by the plug housing 234. In the illustrated embodiment, the leadframe 366 is held by the plug housing 234 such that the strain relief member 296 is held by the plug housing 234. In embodiments wherein the strain relief member 296 is formed integrally with the plug housing 234, the strain relief member 296 is considered to be held by the plug housing 234.
In the illustrated embodiment, the strain relief member 296 extends outward from the commoning pad 380 of the leadframe 366. Specifically, the strain relief member 296 includes a bridge 294 that extends outward from the commoning pad 380 to a base 298 of the strain relief member 296. But, the strain relief member 296 may additionally or alternatively extend from any other portion of the leadframe 366, for example one or more of the plug contacts 242.
The strain relief member 296 includes the base 298. One or more spring beams 300 are cantilevered from the base 298. Specifically, each spring beam 300 extends from the base 298 such that the spring beam 300 is cantilevered from the base 298. In the illustrated embodiment, the strain relief member 296 includes two spring beams 300a, 300b. But, the strain relief member 296 may include any number of the spring beams 300. As will be described below, the spring beams 300 are configured to engage the power cable 218 and thereby pinch the power cable 218 between the sniffer cap 262 and the spring beams 304. Each of the spring beams 300a, 300b may be referred to herein as a “first” and/or a “second” spring beam.
The spring beam 300a extends from the base 298 to an end 302 of the spring beam 300a. The spring beam 300b extends from the base 298 to an end 304 of the spring beam 300a. As can be seen in
The spring beams 300 are resilient springs that are configured to be deflected as the spring beams 300 are engaged with the power cable 218. In the illustrated embodiment, the ends 302, 304 of the spring beams 300a, 300b are configured to deflect in the direction of the arrow A, whether or not the ends 302, 304 are mechanically connected to each other. As can be seen in
The spring beams 300 are optionally angled relative to the connection axis 215 (not shown in
Assembly of the plug 214 will now be described. The power cable 218 can be loaded into the cable channel 282 of the stuffer cap 262 when the stuffer cap 262 is in the pre-staged position shown in
The natural bias of the spring beams 300 against the deflection applies a pinching force to the power cable 218 that pinches the power cable 218 between the spring beams 300 and the interior side 284a of the stuffer cap 262. The pinching force provides the power cable 218 with strain relief. The natural biasing forces of the spring beams 300 that act against deflection of the spring beams 300 may be selected to provide a predetermined pinching force, which may have any value. Optionally, the predetermined pinching force is selected such that the power cable 218 is at least partially compressed between the interior side 284a and the spring beams 300. The power cable 218 may be compressed by any amount. Moreover, the predetermined pinching force may be selected such that the insulative jacket 278 of the power cable 218 is not cut (e.g., penetrated) by the spring beams 300 and/or the interior side 284a.
The deflection of the spring beams 300 may enable the strain relief member 296 to provide strain relief to a variety of different cable sizes and/or shapes. For example, the deflection of the spring beams 300 may enable the same strain relief member 296 to be used with two or more different cables 218 that have different sizes than each other. Moreover, the deflection of the spring beams 300 may enable the strain relief member 296 to provide strain relief to a variety of different cable sizes and/or shapes without cutting the insulative jackets of the cables. Each spring beam 300 may deflect by any amount and may have any natural biasing force that enables the strain relief member 296 to provide strain relief to a cable.
Plugs 14, 114, 214 are provided that define power connectors having RJ-45 mating interfaces. The plug contacts 42, 142, 242 may be electrically commoned as part of leadframes that define power terminals of the plugs 14, 114, 214. Having many plug contacts 42, 142, 242 electrically commoned together allows higher current caring capability for the plugs 14, 114, 214 as compared to electrical connects where only one or two of the plug contacts carry current.
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.
This application is a continuation-in-part of U.S. patent application Ser. No. 13/586,408, filed Aug. 15, 2012, and entitled “MODULAR PLUG FOR POWER APPLICATIONS”, the subject matter of which is herein incorporated by reference in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
6231387 | Kameyama | May 2001 | B1 |
7021967 | Mullin | Apr 2006 | B2 |
7578695 | Boeck et al. | Aug 2009 | B2 |
8298922 | Schumann et al. | Oct 2012 | B2 |
8714994 | Daily et al. | May 2014 | B2 |
20080057793 | Gerber et al. | Mar 2008 | A1 |
20130045642 | Wu | Feb 2013 | A1 |
Number | Date | Country |
---|---|---|
1 914 844 | Apr 2008 | EP |
Number | Date | Country | |
---|---|---|---|
20140051278 A1 | Feb 2014 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13586408 | Aug 2012 | US |
Child | 13763007 | US |