The present invention relates to lighting and decor for aquariums. More particularly, the present invention relates to providing power to lighting and decor in an aquarium.
Residential aquarium keeping is a mature and established industry in the United States and around the world. A basic version of an aquarium includes a transparent container for aquatic life to be viewed and housed within. These containers are typically constructed of either glass or a transparent plastic material such as acrylic or polystyrene, but may be made of other transparent or semi-transparent materials. Basic aquatic environments of this nature are limited in their ability to sustain suitable conditions and water quality for all but a handful of robust and hearty fish. Often more appropriate for the health and well-being of the aquatic organisms is the addition of filtration, lighting, oxygenation, temperature control, chemical and biological balance.
In accordance with one construction, an aquarium includes a wall separating an internal environment within the enclosure from an external environment outside of the enclosure, and a power transmission system that transmits power wireless through the wall. The power transmission system includes a power source and an external inductor coupled to the power source, the external inductor coupled to the wall. The power transmission system also includes an internal inductor coupled to the wall and separated from the external inductor by the wall, and an internal element disposed within the enclosure, the internal element coupled to the internal conductor.
In accordance with another construction, an aquarium includes a base defining a base perimeter and a wall extending from the base perimeter and surrounding the base to define a substantially water tight interior space, at least a portion of the wall being substantially transparent to visible light. A power source is disposed outside of the interior space and operable to receive an AC power supply and to output an external power supply. An external inductor is coupled to the wall and receives the external power supply from the power source. An internal inductor is disposed in the interior space adjacent the external inductor. The internal inductor is operable to output an internal power in response to the receipt of the external power at the external inductor. An electrical element is electrically connected to the internal inductor and operable in response to receipt of a portion of the internal power.
The aquarium 18 includes a base 20 and a removable top (not shown). The illustrated aquarium 18 is constructed of glass, acrylic, clear plastic, or other material that separates and defines an internal environment 22 and an external environment 26. The aquarium 18 includes a glass wall 30 that extends from the base 20 and is clear and transparent, although in some constructions the wall 30 or a portion of the wall 30 is opaque. The internal environment 22 is substantially water tight enabling it to contain an aquatic environment. In some constructions the internal environment 22 is dry or semi-arid in order to contain other animals such as snakes, lizards, birds, hamsters, guinea pigs, spiders, crickets, frogs, toads, etc.
With continued reference to
As illustrated in
The system 10 further includes an internal inductor 50 and a wire 54 that couples the internal inductor 50 to the internal element 14 within the aquarium 18 to provide power from the internal inductor 50 to the internal element 14. In some constructions the internal inductor 50 is coupled directly to the internal element 14 without the use of the exposed wire 54. As illustrated in
The wall 30 provides a separation barrier between the internal and external environments 22, 26 through which power is transferred wirelessly and inductively from the external inductor 38 to the internal inductor 50. Electromagnetic principles enable power transmission through the wall 30, which is typically an electrical insulator or electrically non-conductive material.
In one construction illustrated in
The power transmission system 10 eliminates the need for the power cord 40 to extend over a top edge of the aquarium 18 and into the aquarium 18, thus alleviating problems (e.g., impingements from aquarium covers, filters, and other structures, water dripping down the power cord, pinching of the power cord, crimping of the power cord, animals chewing, clawing, or burrowing into the power cord, etc.) that exist in current power transmission applications, as well as providing a more aesthetically pleasing appearance.
As discussed herein, the internal inductor 38 and the external inductor 50 are disposed on opposite sides of the wall 22 and are preferably connected to the wall 22. Many options are available for connecting the internal inductor 38 and the external inductor 50 to the wall including but not limited to, double-sided tape, adhesives, magnets, suction cups, brackets or fixtures, and the like.
Various features and advantages of the invention are set forth in the following claims.
This application claims priority to U.S. Provisional Application No. 61/765,278, filed Feb. 15, 2013, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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61765278 | Feb 2013 | US |