None
This disclosure relates to a portable light bulb system. More particularly, to a portable, battery powered light bulb system including a bulb releasably secured to a mounting bracket affixed to a support surface to allow for multiple mounting configurations and control modes.
Electronic lighting is critical for indoor, outdoor and nighttime activities. Electronic lighting is typically provided from fixed locations, where a light source receives electrical power from a fixed and wired power source. Such lighting is useful in illuminating a particular area, but lacks the flexibility of more portable lighting systems. Generally, such a dual-purpose system would require extensive investments in parallel and separate fixed and portable lighting systems. Internally-powered portable lighting systems have been developed to provide illumination in more varied locations and situations. However, such internally-powered portable lighting systems are not optimized to provide illumination both in fixed locations and in varied locations. For example, conventional flashlights and lanterns are limited in the number of way including the ability to be easily mounted in a location and controlled by a remote switch.
Accordingly, there is an unmet need for a portable light bulb system able to provide illumination in a variety of configurations and situations.
In some embodiments of the present disclosure, a portable light bulb system includes a bulb including a housing, a manually-operated switch, a main body, and an light source. The main body of the bulb has base portion and a neck portion, wherein the neck portion has at least one longitudinal fin and the base portion has plurality of rings that are arranged substantially parallel to each and not forming a continuous thread. The portable light bulb system also has a mounting bracket that has a projection that extends from a bracket flange. The projection is configured to receive an extent of bulb when the portable light bulb system is in a first use position. The portable light bulb system also is configured to have a second use position, where the bulb is removed from the mounting bracket, brought to a second region that is distant from the mounting bracket, and the operation of the bulb provides illumination to the second region.
In some embodiments of the present disclosure, a mounting bracket is configured to receive the bulb base, and a separable connector is configured to releasably secure the bulb base to the mounting bracket. Thus, the portable light bulb system provides the user with multiple mounting modes, including a hand-held mode where the bulb is held by a user's hand, a static mode where the bulb is releasably secured to the mounting bracket, a suspended mode where the bulb is suspended by a retractable securing element, and a magnetic mode where the bulb is magnetically releasably attached to a magnetic surface.
In some embodiments of the present disclosure, a portable light bulb system includes a bulb including a housing, a manually-operated switch, a main body, and an light source. The main body of the bulb has base portion and a neck portion, wherein the neck portion has at least one longitudinal fin and the base portion has plurality of rings that are arranged substantially parallel to each and not forming a continuous thread. The portable light bulb system also has a remote module that wireless controls the operation of the internal light source of the bulb. The operation of the bulb may be controlled by a remote module in a first use position, while being controlled by the manually-operated switch in a second use position.
The drawing figures depict one or more implementations in accord with the present teachings, by way of example only, not by way of limitation. In the figures, like reference numerals refer to the same or similar elements.
While this disclosure includes a number of details and embodiments in many different forms, there is shown in the drawings and will herein be described in detail particular embodiments with the understanding that the present disclosure is to be considered as an exemplification of the principles of the disclosed methods and systems, and is not intended to limit the broad aspects of the disclosed concepts to the embodiments illustrated.
As shown in
The bulb 14 also has a main body 30 that includes a collar portion 31, a neck portion 32 and a base portion 34, wherein the neck 32 extends between the collar 31 and the base 34. As shown in
As shown in
The neck 32 includes one or more fins 42 that extend outwardly from the main body exterior 46 and substantially extend between the collar 31 and the base 34. The fins 42 may substantially fill the curvilinear shape of the exterior of the neck 46, such that the neck 32 has a cone shaped profile, best illustrated in
As shown in
As shown throughout the Figures, including
As shown in
As shown in
As shown throughout the figures, the system 10 includes a means for releasably securing the base 34 of the main body 30 within the receptacle 76 of the mounting bracket 18. In particular, the securing means includes a first component positionally associated with the main body 30, preferably the base 34, and a second component positionally associated with the mounting bracket 18, preferably the receiver 76. In certain embodiments, the first component is a magnet 70 and the second component is a metal disk 72. Alternatively, the first and second components may be spring ball detent, elastically deformable protrusions that extend inwardly from the inner surface of the receiver 76, bayonet style connector, a pin and socket, or other similar types of connectors. It should be noted that, no rotation, meaning more than 360 degrees, is required for the disconnection force FD once the securing means is released.
As shown in
In certain embodiments, the base 34 may have a height along the longitudinal bulb axis 54 and defined between the lower surface 38 and an uppermost edge 29, which is less than the height of the housing 26 and less than half the height of the neck 32. The base 34 has an outer diameter, at its widest point provided by the rings 52, which is greater than the inner diameter of the socket that receives a conventional 110 volt electrical light bulb. For example, the base 34 has an outer diameter of 1.15 inches, while a conventional 110 volt electrical light bulb socket (e.g., Edison screw number 26, E26, or International Electrotechnical Commission standard sheet 7004-21A) has an inner diameter of approximately 1 inch. The increased diameter of the base 34 helps prevent the bulb 14 from accidentally being placed in a conventional 110 volt electrical light bulb socket. In addition, the increased dimensions of the bulb 14, namely at the base 34, provides a larger handle which may improve the user's handling and interaction with the bulb 14. Even if the base 34 was somehow forced into an E26 socket, it cannot be threaded within the socket because the base 34 lacks threads, as neither the rings 52 nor the grooves 50 form a thread.
The base 34 can be formed of organic materials, metals, ceramics, polymers, plastic, and/or other similar materials. In some embodiments the base 34 may be formed from injection molded plastic and/or may be made from the same material as the main body 30. Like the main body 30, the bulb base may be opaque in color. The opaque color obscures various electrical components disposed within the bulb 14 from a user's view. In certain embodiments the base 34 may be a different color than the neck 32, while in other embodiments the base 34 may be the same color as the neck 32. One exemplarily embodiment includes where the base 34 is a chrome color and the neck 32 is a white color.
The mounting bracket 18 includes a projection 74 that extends substantially perpendicular from a mounting bracket flange 78. In embodiment shown in the figures, the projection 74 is a substantially cylindrical projection, where the top surface of the flange 78 and the outer surface of the projection 74 intersect at approximately a ninety degree angle. While other degrees of intersection between the top surface of the flange 78 and the outer surface of the projection 74 may be used, a ninety degree angle may be beneficial because less material is used to fabricate the mounting bracket 18.
The projection 74 also defines a receiver 76 that is cooperatively dimensioned with the base 34 to allow for releasable insertion of the base 34, without rotation, into the receiver 76. The interior surface 74a of the projection 74 that defines the receiver 76 lacks threads and is substantially smooth, as best shown in
The bulb magnet 70 and the metal disk 72 allow for the bulb 14 to be removed from the receiver 76 by a disconnection force FD that is directed away from mounting bracket 18. The disconnection force FD is orientated substantially perpendicular to the mounting bracket flange 78 and/or substantially parallel to the longitudinal bulb axis 54 (see
In alternative embodiments, the connector 66 is adapted to provide a friction fit between the inner surface 75 of the projection 74 and the outer surface 35 of the base 34. In this embodiment, the inner diameter of the projection 74 is nearly the same size as the diameter of the outer surface 35 of the base 34. This connection force FC will cause the wall of the projection 74 to elastically deform outwardly to accept the base 34 and when the base 34 is removed the wall of the projection 74 will return back to their static or normal position. In other embodiments, the connector 66 may be a single thread or a partial thread, which may require the connection force FC and disconnection force FD to have an angular component, but this angular component requires less than multiple 360 degree rotations. Still in further embodiments, the connector 66 may be spring loaded pins, hook-and-loop panels, adhesives, and/or other fasteners.
In other embodiments, the connector 66 may include supplemental securement elements 73. Supplemental securement elements 73 may include molding inwardly extending securement elements into the wall of the receiver 76. These inwardly extending elements may be designed such that they reduce the diameter of the receiver 76 to substantially the same size as the diameter or the bulb base at the grooves 50, which is less than the diameter of the base 34 at the rings 52. Thus, to couple the bulb 14 to the mounting bracket 18, a connection force is applied to the bulb 14, which will cause the wall of the projection 74 to deform outwardly to accept the rings 52 of the base 34. The continued application of the connection force on the bulb 14 will cause the wall of the projection 74 to return back to their static or normal position once the supplemental securement elements 73 are located within a groove 50. This may be repeated multiple times, until the base 34 comes into contact with the base of the projection 74. It should be understood that in alternative embodiments, the supplemental securement elements may include spring loaded pins, adhesives, and/or other types of similar fasteners.
As shown in
The mounting bracket 18, including flange 78 and the projection 74, can be formed of organic materials, metals, ceramics, polymers, plastic, and/or other similar materials. In some embodiments, the mounting bracket 18 can be formed from injection molded plastic and/or may be made from the same material as the main body 30. Also, the mounting bracket 18 may have a match the opaque color of the main body 30 may provide a pleasing aesthetic to the portable light bulb system 10.
As shown in
The LED 104 is electrically connected to the control circuitry 102 and mounted over the same by at least the post 136. The control circuitry 102 is comprised of various circuit components, including diodes, capacitors, inductors, and resisters. And in certain embodiments, the control circuitry 102 may include a radio and an antenna. The control circuitry 102 receives user inputs from various sources (e.g., a switch or the radio) and in response alters or changes the operational mode of the bulb 14 by modifying the power supplied to the internal light source 100. A user input received by the control circuitry 102 may be generated from a manually-operated switch 120. This manually-operated switch 120 allows the user to manually change the operational mode of the bulb 14 by sending a signal to the control circuitry 102, which in turn alters the illumination brightness or operational mode of the internal light source 100. In certain embodiments the operational modes includes constant illumination modes of varying brightness levels, zero illumination, and various flashing illumination modes.
The system 10 can be arranged and illuminated in a plurality mounting configurations. In particular, the system 10 can be configured in a first use position, where the mounting bracket 18 is affixed to a support surface 22 and the bulb 14 is releasably secured to the mounting bracket 18 through application of the connection force FC. In this first use position, the internal light source 100 of the bulb 14 can be illuminated to provide light in a region proximate to the mounting bracket 18. Additionally, the system 10 is configured in a second use position, where the bulb 14 may be disconnected from the mounting bracket 18 by the application disconnection force FD and brought to a second region distant from the mounting bracket. In second use position, the bulb 14 may be arranged in one of a plurality of positions, including (i) hand-held, (ii) temporarily resting on or against a support surface 22, or (iii) hung from a fixed point, such as on a hook, by the multi-positional securement member 58. In this second use position, the internal light source 100 of the bulb 14 can be illuminated to provide light in a region that is distant from to the mounting bracket 18. The user can return the system to the first use position by releasably connection the bulb 14 to the mounting bracket 18. Accordingly, the system 10 provides the user with immense flexibility in illuminating different areas, including areas distant from the support surface 22 where the mounting bracket 18 is affixed.
It should also be understood, that the operational mode of internal light source 100 can be changed regardless of the mounting configuration of the bulb 14. In particular, the operational mode of the internal light source 100 may be changed from a bright illumination mode 210 to a dim illumination mode 212, while the bulb 14 is hand-held, releasably secured to the mounting bracket 18, suspended by the multi-positional securement member 58, or magnetically releasably attached to a magnetic surface.
Another user input received by the control circuitry 102 may be generated from a remote wireless module 11, as shown in
Two different non-limiting embodiments of a module 11 are disclosed in
Referring to
The wireless communication device 126 of the module 11 (see
The mode selector 354 is coupled to or a part of the motion sensing unit 350. The mode selector 354 can be set to multiple positions, which includes AUTO or OFF. Setting the mode selector 354 to AUTO permits the motion sensor 148 to control the operational mode or the illumination of the internal light source 100 of the paired bulb 14. For example, when the mode selector 354 of the module 311 is set to AUTO, the motion sensing unit 350 is active and waiting to detect motion of a user. Once the motion sensing unit 350 detects motion of a user, a signal is sent to the wireless communication device 126 of the module 311, which in turn transmits a signal to the control circuitry 102 contained within the paired bulb 14. The control circuitry 102 then illuminates the internal light source 100 for a predefined amount of time (e.g., 5 minutes). Once this predefined amount of time expires, the control circuitry 102 extinguishes the light that is emitted from the internal light source 100. It should be understood that this cycle is reset each and every time motion is detected by the motion sensing unit 350. Alternatively, if the mode selector 354 is set to the OFF position, then the motion sensing unit 350 will not be supplied with power and will not detect movement. When the mode selector 354 is set to the OFF position, the module switch 124 may be used to change the operational modes of the paired bulb 14, as discussed above in connection with the switch 120 and the flow chart shown in
The time selector 358 is coupled to or a part of the motion sensing unit 350. The time selector 358 may be set by the user in a plurality of positions, wherein each position represents a different amount of illumination time (e.g., one minute, three minutes, or five minutes). For example, the user may set the time selector 358 to three minutes and the mode selector 354 to AUTO. Then, once the motion sensing unit 350 detects motion of a user and determines that three minutes is set on the time selector 358, a signal is sent to the wireless communication device 126 of the module 311, which in turn transmits a signal to the control circuitry 102 contained within the paired bulb 14. The control circuitry 102 then illuminates the internal light source 100 for three minutes. After three minutes has passed, the wireless communication device 126 of the wireless motion sensor 148 sends a second signal to the paired bulb 14 to extinguish the internal light source 100. It should be understood that this cycle is reset each and every time motion is detected by the motion sensing unit 350. Alternatively, the control circuitry 102 could include circuitry that determines that three minutes has elapsed since the internal light source has been illuminated and as a result the control circuitry, without an additional signal from the wireless motion sensor 148, may extinguish the internal light source 100. It should be understood that in this alternative embodiment, the this cycle may be reset by the module 311 sending an additional signal to the pair bulb 14, which in turn will reset the timer contained within the control circuitry 102 of the bulb 14.
It may be desirable to control multiple bulbs 14 utilizing a single module 11 and/or to use different remotes 11 to control different bulbs 14 when they are within close proximity (e.g., within the same room) to one another. To facilitate this arrangement, the wireless communication device 126 contained within the modules 11, 311 and the control circuitry 102 contained within the bulbs 14 may have the ability to switch between a plurality of communication channels, including an A Channel 202 and a B Channel 204, as shown in
To select or change the communication channel, the module 11, 311 and the bulb 14 may contain a channel selector 180, best shown in
To pair or connect the bulb 14 to the module 11, 311, the channel selectors 180 on both of these devices must be set to the same channel (e.g., Channel A 202). Once the channel selectors 180 on both the bulb 14 and module 11, 311 are set to the same channel (e.g., Channel A 202), the user can use the module 11, 311 to control the operational mode or illumination of the internal light source 100, as discussed above. It should be noted, that additional bulbs 14 that are within close proximity (e.g., the same room) and set to the same channel (e.g., Channel A 202) will be controlled by the single module 11, 311. In other words, the user can control multiple bulbs 14 with a single module 11 by setting the channel selectors 180 on each device to the same channel. This may be desirable when the user wants to place multiple bulbs 14 within a room and wants one module 11, 311 to operate all of the bulbs 14 in that room.
Alternatively, the bulb 14 channel selector 180 may be set to one channel (i.e. Channel A 202), while the module 11, 311 channel selector 180 is set to a different channel (i.e., Channel B 204). In this situation, the module 11, 311 will not be paired or connected to the bulb 14; this in turn prevents the module 11, 311 from controlling the bulb 14. This arrangement may be desired by the user when the user has multiple bulbs 14 within close proximity to one another and does not want the module 11, 311 to control all of the bulbs 14. For example, the user may have installed the mounting bracket 18 in the closet and the module 11, 311 on the wall, while having extra bulbs 14 in the closet. In this situation, the user may desire to place the module 11, 311 to Channel A 202 and the mounted bulb 14 to Channel A 202, while setting the extra bulbs 14 to different channels (e.g., Channel B 204) or positions (e.g., OFF 200) to ensure that the extra bulbs 14 are not illuminated when the module 11, 311 is activated.
Another operational example is when the user desires a bulb 14 that is installed in the entry of a house to illuminate once they walk into the entry point, while ensuring that a bulb 14 located in the closet only illuminates when another module 11 is activated, while further ensuring that the bulb 14 located under the sink is not illuminated when either module 11, 311 is activated. In this example, the user may utilize and set the module 311 to Channel A 202 and place it at the baseboard of the wall in a location where the sensing unit 350 will detect motion when the user enters the entry point. The user may also utilize and set a module 11 to Channel B 204 and place it in an easy to reach location near the closet entrance. Finally, the user may set the bulb 14 that is under the sink to the OFF 200 setting. This example is one of multiple examples that could be desired in the configuration of multiple bulbs 14, modules 11, 311, and channels 200-204.
The disclosed wireless portable light source system 10 enables numerous benefits over prior lighting systems. Unlike a lighting system that merely offers wireless functionality or merely offers portable functionality, the present disclosure provides for a system that synergistically and advantageously combines at least all of these features to create a unified system providing flexibility, portability and remote operation capabilities.
While the foregoing has described what are considered to be the best mode and/or other examples, it is understood that various modifications may be made therein and that the subject matter disclosed herein may be implemented in various forms and examples, and that the teachings may be applied in numerous applications, only some of which have been described herein. It is intended by the following claims to claim any and all applications, modifications and variations that fall within the true scope of the present teachings. Other implementations are also contemplated.
This application is a continuation of patent application Ser. No. 16/571,309 filed Sep. 16, 2019, which will issue as U.S. Pat. No. 10,584,839 on Mar. 10, 2020, which is a continuation of patent application Ser. No. 16/411,778 filed May 14, 2019, which issued as U.S. Pat. No. 10,415,765, which is a continuation of International PCT Application No. PCT/US17/61594, filed Nov. 14, 2017, which claims the benefit of priority under 35 U.S.C. § 119(e) to Provisional Patent Application No. 62/461,516, filed Feb. 21, 2017 and Provisional Patent Application No. 62/421,697, filed Nov. 14, 2016, which applications are incorporated in their entirety herein by reference and made a part hereof.
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Number | Date | Country | |
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Parent | 16571309 | Sep 2019 | US |
Child | 16812922 | US | |
Parent | 16411778 | May 2019 | US |
Child | 16571309 | US | |
Parent | PCT/US2017/061594 | Nov 2017 | US |
Child | 16411778 | US |