Portable electronic devices, such as gaming devices, mobile telephones, portable televisions, electronic book reader devices, and the like, are becoming increasingly popular. These devices typically are powered by batteries. Many devices also include an alternating current (AC) power adapter that allow the devices to run on AC current from a receptacle, and may also be used to recharge the batteries of the device. Typically, AC adapters are designed for use with a particular type of receptacle standard (e.g., prong configuration, power rating, and frequency). Some existing AC travel adapters include provisions that allow the adapters to be used with multiple different electrical plug standards.
Users often store or transport portable electronic devices along with their AC adapters in a carrying case or backpack, for example. Because most AC adapters have prongs that protrude from the adapter to be plugged into an outlet, the prongs are often bent or damaged during transport. The protruding prongs may also cause damage to a screen or housing of the portable electronic device.
Users often unplug AC adapters by pulling on a cord of the AC adapter adjacent to a plug. However, unplugging an AC adapter by pulling on the cord adjacent to the plug has the potential to damage the cord, possibly resulting in a fault, short, or even electrical shock to the user.
The detailed description is set forth with reference to the accompanying figures. In the figures, the left-most digit(s) of a reference number identifies the figure in which the reference number first appears. The use of the same reference numbers in different figures indicates similar or identical items.
As discussed above, when transported with portable electronic devices, the prongs of existing AC adapters have the potential to be damaged by, and/or to cause damage to, the portable electronic device during transport. Also, existing AC adapters are prone to damage by users unplugging them by pulling on their cords.
This disclosure describes examples of electrical power adapters that include retractable prongs that can be retracted during non-use to protect the prongs from being damaged or causing damage to the electronic device or other equipment. This disclosure also describes examples of electrical power adapters that additionally or alternatively include retractable power outputs that can be retracted during use to prevent users from pulling on a cord adjacent to the adapter to remove the adapter from a receptacle.
The electrical power adapters are described in the context of AC travel adapters usable to provide power to a portable electronic device from a variety of different electrical outlet standards. However, aspects of this disclosure may be applicable to other sorts of electrical power adapters, such as direct current (DC) power adapters or the like. Also, aspects of this disclosure, such as the retractable prongs, for example, may be applicable to electrical power adapters other than travel adapters. Still further, aspects of this disclosure may be applicable to provide power to electronic devices other than portable electronic devices.
The plug units 104 can be removably coupled to the power unit 102 via a suitable connection means 106. Details of the connection means 106 are shown in the detail views A and B to the side of
A release button 112 is provided on the power unit 102 to selectively release the spring latch 110 when depressed by a user. This provides a secure connection between the power unit 102 and the respective plug units 104, which can be quickly and easily be detached by actuation of the release button 112. However, in other implementations, other types of removable connection means, such as snap fits, latch mechanisms, threaded fits, slots, grooves, or the like may be used to couple the plug units 104 to the power unit 102. Referring back to the illustrated implementation, the mating components of the connection means 106 (i.e., the collar 108 and spring latch 110) may be reversed, such that the collar 108 is disposed on the power unit 102 and the spring latch 110 is disposed on the plug unit 104. Moreover, other types of release mechanisms (e.g., levers, slides, knobs, dials, etc.) may be used to disengage the plug units 104 from the power unit 102.
The power unit 102 includes electrical terminals 114 that engage with corresponding electrical terminals 116 on the plug units. When a plug unit 104 is coupled to the power unit 102 by the spring latch 110 (or other connection means), the electrical terminals 114 of the power unit 102 are firmly pressed against the electrical terminals 116 of the plug unit to provide a reliable electrical connection. In some implementations, when the plug unit 104 is coupled to the power unit 102, the electrical terminals 114 and 116 may be spring biased toward one another to provide an even more secure connection. In that case, the spring force between the electrical terminals 114 and 116 may also cause the plug unit 104 to be ejected from the power unit 102 when the release button 112 is depressed, rather than simply being released.
Alignment indicia may also be provided on the power unit 102 and/or the plug units 104 to aid a user in aligning the two units for connection. The alignment indicia may include linear indicia (as shown), dots, shapes, colors, words, or any other indicia that aid a user in aligning the two parts relative to one another. The alignment indicia may be recessed (as shown) or raised to provide tactile feedback to a user, or may be flush with the surfaces of the power unit 102 and plug units 104.
The power unit 102 also includes an electrical output 118 for outputting electrical power to power an electronic device (not shown). In the illustrated example, the electrical output 118 comprises a universal serial bus (USB) port. However, in other implementations, other types of electrical outputs could additionally or alternatively be used.
As discussed above, users often store or transport portable electronic devices along with their AC adapters in a carrying case or backpack, for example. AC adapters having prongs that protrude from the adapter may be bent or damaged during transport and/or the protruding prongs may also cause damage to the portable electronic device. Some existing AC adapters have prongs that fold away during storage. However, if the prongs fold too easily, they tend to fold up unintentionally when a user tries to plug the adapter into an outlet. If, on the other hand, the prongs do not fold easily, it can be difficult to fold the prongs out for use.
This disclosure describes AC adapters that have prongs 200 that can be retracted during storage or non-use (as shown in
As mentioned above, users often unplug AC adapters by pulling on a cord of the AC adapter adjacent to a plug. However, unplugging an AC adapter by the cord has the potential to damage the cord, possibly resulting in a fault, short, or even electrical shock to the user. Also, in some examples, this may result in the cord becoming detached from the AC adapter body.
The power adapter 100 described herein includes an electrical output 118, which is retractable during use to prevent users from grasping the cord adjacent to the plug to remove the power adapter from an outlet. In the non-use position (shown in
Additionally, because the electrical output 118 is retracted within the housing during use, a plug of the power cord is substantially housed within and protected by the housing. If a user bumps the power adapter 100 while it is plugged into an outlet (e.g., while vacuuming), the contact will likely be with the housing of the power adapter 100 or the flexible body of the power cord. This minimizes the likelihood of damage to the less flexible plug of the power cord.
At 300, a plug unit 104 is coupled to the power unit by pressing the two parts substantially axially together. As discussed above, the plug unit 104 may comprise any of a variety of different plug configurations. As the parts are pressed together, the spring latch 110 of the power unit 102 slides past and latches behind the collar 108 of the plug unit 104.
At 302, the power adapter 100 is shown in a disassembled condition, similar to that of
At 304, the power adapter 100 is shown after the plug unit 104 has been coupled to the power unit 102 by pressing the two parts together. In this position, the collar 108 of the plug unit 104 is engaged and retained by the spring latch 110 of the power unit 102 to securely couple the plug unit 104 to the power unit 102. Also, a USB plug or other power cord has been plugged into the electrical output 118 to transmit power from the power adapter 100 to an electronic device.
At 306, the plug unit 104 has been rotated relative to the power unit 102 by about 90 degrees. The rotation of the plug unit 104 relative to the power unit 102 caused the prongs 200 to be extended from the housing of the plug unit 104 and the electrical output 118 to be retracted into the housing of the power unit 102. The position shown at 306 defines the use position for the power adapter 100. In this position, the prongs 200 are extended and can be plugged into a wall socket to provide power to the electronic device via the power cord. Also, the electrical output 118 is retracted to deter users from grasping the power cord to unplug the power adapter 100. When the user is finished using the electronic device, the power adapter can be unplugged by grasping the housing of the power adapter 100 and removing it from the wall socket.
The user may then proceed to retract the prongs 200 and extend the electrical output by rotating the power unit 104 back to the position shown at 304.
At 308, the user may remove the plug unit 104 from the power unit 102 (for storage or to exchange one plug unit for another) by pressing the release button 112. Depressing the release button 112 expands the spring latch 110 disengaging it from the collar 108 of the plug unit 104 and allowing the two parts to be separated (or ejecting the plug unit 104 from the power unit 102).
The electrical terminals 114 are disposed at one end of the power converter 402 for engagement with terminals 116 of the plug units 104 to receive power from the plug unit 104. In some implementations, the electrical terminals 114 may be spring biased relative to the rest of the power converter 402 to provide a secure connection with the electrical terminals 116 on the plug unit 104. The electrical output 118 is not visible in this view, but is disposed on the power converter 402 on the side opposite the electrical terminals 114. The power converter 402 is retained in the housing 400 by a snap fit, but in other implementations may be retained by an interference fit, press fit, fasteners, adhesive, or any other suitable connecting means.
A spring latch retainer 406 is disposed in the plug-unit-engaging end of the housing 400 to hold the spring latch 110 in place in the housing 400. The release button 112 is disposed in a side of the housing 400 and is biased outward by a conical spring 408. When the release button 112 is depressed, tabs (not shown) on the back of the release button 112 engage ends of the spring latch 110 and expand the spring latch 110 in the direction of the arrows in detail view A in
When the plug unit 104 is coupled to the power unit 102, castellated protrusions 514 on the actuation sleeve 504 engage complimentary features of the power unit housing 400 to fix the actuation sleeve against rotation relative to the power unit 102. Thus, when the plug unit 104 is rotated relative to the power unit 102 (i.e., toward use position 304), the actuation sleeve 504 of the plug unit does not rotate with the other components of the plug unit 104. Consequently, as the plug unit 104 is rotated relative to the power unit 102, the prong assembly 502 is projected outwardly from the housing 500 as the dowel pins 508 are driven vertically in the vertical guide grooves 512 by the helical grooves 510 of the actuation sleeve 504. That is, as the plug unit 104 is rotated relative to the power unit 102, the prong assembly 502 is allowed to both rotate and translate vertically relative to the actuation sleeve 504, but is constrained by the vertical guide grooves 512 to move only vertically relative to the plug unit housing 500.
The ends of the helical grooves 510 include a locking notch 516. When the dowel pins 508 reach the ends of the helical grooves 510, they seat in these locking notches 516 (i.e., when the prong assembly is fully extended as shown in position 304). The locking notches 516 prevent the dowel pins 508 from sliding back down the helical grooves 510 due to compressive forces caused by, for example, a user pressing on the prongs 200 into a snug wall socket. Thus, the locking notches 516 prevent the prongs 200 from retracting unintentionally. To retract the prong assembly 502 requires a user to rotate the plug unit 104 relative to the power unit 102 to disengage the dowel pins 508 from the locking notches 516. Such rotational motion is unlikely to occur during plugging or unplugging the power adapter 100, thereby minimizing the likelihood that the prongs 200 will be retracted unintentionally.
An endplate 518 is secured to the end of the housing 500 by a plurality of fasteners 520 or other attachment means. The endplate 518 includes apertures configured to accommodate the prongs of the particular plug type when the prongs are extended, as in
While the exploded views of
Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described. Rather, the specific features and acts are disclosed as illustrative forms of implementing the claims.