This invention relates to a submersible device, and more particularly to an aquatic toy having a selectable buoyancy.
Numerous children's activity devices are useful to entertain and stimulate children playing in water. For example, some toy devices can be thrown into water, such as, for example, a pool. These devices can be of limited use since they either sink to the bottom of the pool or float on the surface of the water.
Thus, a need exists for a device that can be neutrally buoyant at varying depths of a pool.
A submersible device according to an embodiment of the invention includes a container configured to be selectively buoyant in a liquid. The container can have at least one of a variety of different buoyancy systems. For example, in one embodiment the container includes a reservoir where the volume can be adjusted. In another embodiment, the container includes a reservoir in communication with a pump configured to control the intaking and expelling of a liquid.
In another embodiment, the container defines a first partitioned section and a second partitioned section. The first partitioned section is substantially liquid resistant and the second partitioned section defines a hole in communication with an exterior of the container. An actuator is configured to receive an input from a user and is configured to modify an interior volume of the second partitioned section based on the input.
The submersible device described herein can be placed into a liquid, such as, for example a pool of water. For example, the apparatus can be configured as an aquatic activity device or toy that becomes neutrally buoyant at a designated depth and emits audible sounds. The device described herein can be used in multiple aquatic games. For example, a user can set a depth for the device to become neutrally buoyant and throw it into the pool. In some embodiments, another user may then search for the device by listening and following the audible signal.
For example, a user can set the depth for the submersible device 100 to become buoyant in a pool via the actuator 110. The submersible device 100 can then begin to emit audible signals. After the submersible device 100 enters the water, it will submerge and maintain the user-selected depth. Another user can then search for the submersible device under the water only relying on his/her hearing.
As shown in
In another embodiment, the outer portion of the container 302 is configured to be camouflaged with its surrounding liquid. The outer portion of the container 302 can be, for example, formed to have a color to substantially match the color of the surrounding liquid. For example, the container 302 can be formed of the color blue to camouflage the container 302 while submerged in a pool of water. Alternatively, the container 302 and as many of its internal components as possible can be, for example, substantially translucent making the submersible device 300 less visible. Alternatively, a combination of colored and translucent material can be used. For example, the container 302 and its internal components can be composed of a substantially translucent blue material to camouflage the device 300 in a pool of water.
As shown in
In some embodiments, the second partitioned section can include a reservoir in communication with the hole and can be configured to have an adjustable volume. In some other embodiments, the submersible device can include a sensor and a pump. The sensor can be coupled to the pump and can be disposed within the second partitioned section. The pump can be configured to expel water from or take water into, the reservoir based on a signal from the sensor. In other embodiments, the audio system of the submersible device may be actuated upon entering the water via a signal from the sensor.
In some embodiments, audible signals are emitted from the device for a time period. The emitting of audible signals is discontinued if a second user input is received in the time period.
In some embodiments, the method can include sensing an amount of liquid received within the device and sending a control signal to a pump when the amount of liquid received in the device reaches a predefined amount for neutrally buoyancy at the depth. For example, a sensor disposed within the reservoir can measure the amount of liquid in the reservoir. Once an amount of liquid correlating to the buoyancy desired is reached, the sensor can send a signal to the pump to stop the submersible device from receiving any more liquid.
In some embodiments, the method can include propelling the submersible device in the liquid. Propelling the submersible device via a propulsion system can increase the level of effort and difficulty for the user to find and deactivate the device. The propelling of the device can be, for example, constant or for randomly selected time intervals. In such embodiments, the submersible device can include a propulsion system that can be coupled to the container and configured to propel the container. At least a portion of the propulsion system can be in communication with the exterior of the container. Propulsion systems can include, for example, propeller systems, water jet systems, paddle wheel systems, etc.
Similarly, in some embodiments, the depth of a device can be varied during the time period. For example, after a first user-selected depth is reached the depth of neutral buoyancy can change by, for example, varying the volume of the reservoir. The submersible device can rise from a deeper depth to a shallower one and/or vice versa. Such changes in the depth of neutral buoyancy can occur for fixed or varied time intervals within the overall time period.
In some embodiments, a frequency of the audible signals can be varied during the time period. For example, the frequency can be selected to be associated with the depth of neutral buoyancy of the device. Similarly, in some embodiments, a volume of the audible signals can be varied during the time period. For example, the volume can be selected to be associated with the depth of neutral buoyancy of the device. Alternatively, the volume can increase as the time period nears expiration. Alternatively, the frequency of the audible signal and/or the volume of the audible signal can be user-selected. For example, a user can select a frequency to distinguish their submersible device from other submersible devices in the same body of liquid, for example, a community pool.
In some embodiments, a visual indicator can be displayed to the user. The visual indicator can show, for example, the amount of time left to deactivate the device, internal component information, user instructions, etc. The amount of time left for a user to deactivate the device can be indicated by, for example, a countdown timer, a flashing light, and the like. For example, the frequency of the flashing light can increase as time for the user to find and deactivate the device decreases.
In some embodiments, a series of consecutive time periods can be established by the device. In other words, after a first user finds and deactivates the device, the submersible device can signal a second user to find and deactivate the device. The time period for the first user ends and the time period for the second user begins upon the first user deactivating the device.
The sensor 674 is coupled to the pump 676 and is configured to expel or intake liquid based on a signal from the sensor 674 to control the buoyancy of the submersible device. Pumps can include, for example, a positive displacement pump, a centrifugal pump, and the like. In other embodiments, the pump 676 either intakes or expels liquid from the reservoir based on a feedback signal from the sensor 674 to counteract deviations from the selected depth of neutral buoyancy.
The visual display 682 can be configured to selectively produce a visual output with at least a portion of the visual output being visible from an outside container. In other words, the visual interface 680 is coupled and sends signals to the visual display 682 to communicate information to the user. In some embodiments, the visual display 682 can be visible after a user-specified time period. For example, a user may not be able to locate the submersible device even with loud audible signals and a visual display of a countdown timer. Therefore, the submersible device can display a visual beacon after a period to time enabling the user to find the device. The beacon can be, for example, a high-intensity flashing light, a colored light, and the like. Similarly, an audible beacon can be used alone or in combination with the visual display to assist the user in locating the device after the time period has ended.
In another alternative embodiment, the submersible device can include a timer that is coupled to the audio system and can be configured to activate and/or deactivate the audio system based on the timer. In an another alternative embodiment, the submersible device can include a memory storage device coupled to the container and configured to store user-specified input including at least one of the selected buoyancy or the user-specified time period.
In yet another alternative embodiment, the submersible device can have an audio system with an audible output that has a frequency at a first time within the user-specified time period and a frequency at a second time within the user-specified time period different from the frequency at the first time. Similarly, in some embodiments, the submersible device can have an audio system with an audible output that has a volume at a first time within the user-specified time period and a volume at a second time within the user-specified time period different from the volume at the first time.
In some embodiments, as seen in
In some embodiments, the actuator can have pre-set positions indicated by a tactile and/or audio response for a given position (e.g. a “click” for a position). The pre-set positions can be associated with specific depths of selected buoyancy. For example, one position can be associate with a depth of neutral buoyancy of 3 feet.
While various embodiments have been described above, it should be understood that they have been presented by way of example only, and not limitation. While specific embodiments have been particularly shown and described, it will be understood that various changes in form and details may be made.
For example, a submersible device can include various combinations and sub-combinations of the various embodiments described herein.
This application claims priority to Provisional Application No. 60/779,930, filed Mar. 8, 2006, the entire disclosure of which is hereby incorporated by reference.
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Number | Date | Country | |
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20080057822 A1 | Mar 2008 | US |
Number | Date | Country | |
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60779930 | Mar 2006 | US |