The present invention is generally directed to a toy or amusement device, and more particularly to an underwater device for generating or shooting a vortex ring.
It is entertaining to generate or watch a bubble ring being generated, whether in air or in a liquid medium, such as water. Both the children and adults are known to engage in such an activity. For instance, children learn to make soap bubbles at an early age. Likewise, the adults are often seen to amuse others and themselves by generating smoke rings when smoking a cigarette, pipe, or cigar. Watching the rings or bubbles rise up in the air or through a liquid, is not only uplifting, but also aesthetically very pleasing.
Various devices for generating bubbles and rings are available in the prior art, as shown in U.S. Patents/Publications Nos. 3,372,873; 3,589,603; 4,534,914; 5,042,819; 5,052,813; 5,100,242; 5,947,784; 6,007,237; 6,488,270; 6,736,375; 6,824,125; 7,191,774; 7,300,040; 2004/0088894; 2004/0217490; 2006/0214316; 2007/0200260; 2010/0015879; and 2010/0184523.
The present disclosure is directed to various aspects of the present invention.
One aspect of the present invention includes an underwater device for generating or shooting a vortex ring.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring of a liquid, such as water, and a fluid, such as air. In particular, the device generates a vortex ring that is entrained with air.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that is hand-held.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that is manually-powered.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that is self-contained in that it includes a supply of unpressurized fluid or air.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that has a volume capacity to produce multiple consecutive vortex rings before reloading. In particular, the device is configured to fire repeatedly to produce five to fifty vortex rings with one full chamber of air.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring, wherein the air for rings is ejected by the same force of water being ejected substantially simultaneously.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that is simple in design and whose function is not adversely impacted by jostling, shaking, or playful manhandling, etc.
Another aspect of the present invention includes an underwater device that can shoot a vortex ring to a distance of about 5-25 feet in the water.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring, wherein the vortex ring can be pointed and/or directed at a target at will. The device can, therefore, be used to engage in underwater games that are fun, playful, and/or competitive.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that can more preferably be used by scuba or skin divers, or other users/enthusiasts, to ward off hostile marine life, or simply for sports/recreation.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that is automatic or self-priming. In other words, the device need not be cocked or recocked. The device can, therefore, be used repeatedly without interruptions, or the need to take it out of water.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that includes a source of compressed/pressurized fluid or air, which source can be a regular size scuba tank, a pony tank, or a cartridge.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring that is self-contained in that it includes a supply of compressed/pressurized fluid or air.
Another aspect of the present invention includes an underwater device for generating or shooting a vortex ring to a distance of about 40 feet or more in the water.
Another aspect of the present invention includes an underwater device for generating a vortex ring, including a liquid chamber, and a fluid chamber contiguous to the liquid chamber and separated by a partition wall. The liquid chamber includes a generally rigid section and a compressible section. The rigid section includes an opening for selectively loading the liquid chamber with a liquid and for discharging a vortex ring therefrom.
Another aspect of the present invention includes a hand-held underwater device for generating a liquid vortex ring, including a liquid chamber, and an air chamber contiguous to the liquid chamber and separated by a partition wall. The liquid chamber includes a generally rigid section and a compressible section. The rigid section includes an opening for selectively loading the liquid chamber with a liquid and for discharging a vortex ring therefrom. A conduit supplies air from the air chamber to an area adjacent the opening to be entrained in the vortex ring.
Another aspect of the present invention includes a self-contained underwater amusement device for shooting a liquid vortex ring, including a liquid chamber, and an air chamber contiguous to the liquid chamber and separated by a partition wall. The liquid chamber includes a liquid accelerator section and a compressible section. The accelerator section includes an opening for loading the liquid chamber with a liquid. A conduit supplies air from the air chamber to an area adjacent the opening to be entrained in the vortex ring. A plurality of actuators move the compressible section for creating an internal pressure to shoot the vortex ring from the opening.
Another aspect of the present invention includes an underwater device for generating a vortex ring, including a liquid chamber, and a fluid chamber contiguous to the liquid chamber and separated by a partition wall. A liquid propulsion member is positioned within the liquid chamber, and an opening selectively loads the liquid chamber with a liquid and discharges a vortex ring therefrom.
Another aspect of the present invention includes a self-priming underwater device for generating a vortex ring entrained with a fluid, including a handle, a housing including front and rear sections, a trigger for supplying a fluid to the housing, a piston assembly in the rear section of the housing and including a yoke, a piston movable in the yoke, and a plate for displacing a liquid, and a splitter for diverting one portion of the fluid to the piston assembly to thereby move the piston. The front section of the housing includes an opening for discharging a vortex ring therefrom, and a fluid supply member is positioned adjacent the opening for supplying another portion of the fluid to be entrained in the vortex ring.
Another aspect of the present invention includes a hand-held self-priming underwater device for shooting a vortex ring entrained with a fluid, including a handle, a housing extending substantially rectilinearly with the handle and including front and rear sections, a trigger for supplying a fluid to the housing, a piston assembly in the rear section of the housing and including a yoke, a piston movable in the yoke, and a plate for displacing a liquid, and a splitter for diverting one portion of the fluid to the piston assembly to thereby move the piston. The front section of the housing includes an opening for discharging a vortex ring therefrom, and a fluid supply member is positioned adjacent the opening for supplying another portion of the fluid to be entrained in the vortex ring. A wall is provided between the handle and the housing and includes a first surface facing the housing and a second surface facing the handle. The yoke is disposed on the first surface and includes a port through which the piston moves. A generally circular recess is defined by the yoke and the inside of the housing.
One of the above and other aspects, novel features and advantages of the present invention will become apparent from the following detailed description of a preferred embodiment(s) of the invention, as illustrated in the drawings, in which:
As best shown in
Preferably, the front shell 10 is generally cone- or funnel-shaped, and the rear shell 12 is concave or dome-shaped. Both the front and rear shells 10 and 12 are, preferably, made of a clear or colored plastic, or the like rigid material. Alternatively, the front and rear shells 10 and 12 may be made of metal, or other solid or translucent material.
A fluid-supply assembly 22 includes a one-way check valve 24, mounted preferably centrally on the partition wall 16, an inlet tube 26, and an outlet tube 28. The fluid (or air) from the fluid chamber 20 passes through the check valve 24 and exits the outlet tube 28 at the opening 30 thereof, which is strategically positioned adjacent a front opening 32 of the underwater device UD. The front opening 32 is used to shoot vortex rings VR therefrom, as well as to initially fill (or load) the chamber 18 with the liquid.
As best shown in
The underwater device UD further includes front and rear handles 36 and 38, preferably mounted on each of the left and right sides of the front and rear shells 10 and 12, respectively. The handles 36 and 38 can be integrally molded with the respective shells 10 and 12, or made separately. It will be appreciated that the front and rear handles 36 and 38 can be squeezed, jerked, or snapped together quickly by a user U (
The preferred shape of the front shell 10 enhances or maximizes the force of liquid, such as water, to be discharged through the front opening 32 of the underwater device UD, as a toroid, even when a small force is utilized to squeeze the front and rear handles 36 and 38. In other words, the front shell 10 functions as an accelerator for the water, when the underwater device UD is actuated or fired.
As best shown in
Although variable, it is preferred that the liquid and fluid chambers 18 and 20, occupy about three-fourth and one-fourth of the overall volume of the underwater device UD, respectively.
Referring to
The rear shell 52 and the middle compressible section 54, together form a liquid chamber 56 for holding, for example, water W. As best shown in
A fluid-supply assembly 64 includes a one-way check valve 66, an inlet tube 68, and an outlet tube 70. The outlet tube opening 72 is positioned adjacent the front opening 74 of the underwater device UD2, to supply a fluid, such as air, to be entrained in the vortex ring or slug of water exiting therethrough. The inlet tube 68 runs along the outer periphery of the front shell 50 and terminates in the fluid chamber 58. Although not shown, clips or other suitable mechanical fasteners, or adhesive, may be used to secure the fluid-supply assembly 64 in place.
As in the first preferred embodiment UD, a hole 76 is provided but in the rear shell 52 to allow the air to vent from the liquid chamber 56. Likewise, left and right sets of front and rear handles 78 and 80, are provided on each side of the front and rear shells 50 and 52, respectively, to allow the user U to move or squeeze the shells 50 and 52, to operate or fire the underwater device UD2.
Referring to
The front and rear shells 90 and 92, and the middle compressible section 94, together define a liquid chamber 96 for holding a liquid, such as water W. The front shell 90 includes a front opening 98 which is used to fill the chamber 96 with the liquid, as well as to shoot vortex rings VR therefrom.
The third embodiment of the underwater device (UD3) is different from the embodiments described above in that an external housing 100 serves as a fluid chamber for supplying a fluid, such as air, in the form of bubbles 102 in front of the front opening 98, via a series of tiny holes 104. A suitable slider 106 is provided to selectively cover one or more of the holes 104, to vary the amount or location of the exiting series of the bubbles 102. As in the previous embodiments, left and right sets of front and rear handles 108 and 110, are mounted on the front and rear shells 90 and 92, respectively. The underwater device UD3 is particularly suitable for users who are unable to, or do not desire to, squeeze the handles 108 and 110 too hard to shoot vortex rings VR through the front opening 98.
As best shown in
Referring to
The interior of the housing 120 includes a liquid chamber 122 and a fluid chamber 124, separated by a partition wall 126, which is preferably cone-shaped. As best shown in
A fluid-supply assembly 130 is positioned in the hump section 128 and includes a one-way check valve 132, an inlet tube 134, and an outlet tube 136. The outlet tube opening 138 is positioned adjacent the front opening 140 of the underwater device UD4. The inlet tube 134 terminates in an upper section 142 of the fluid chamber 124, where the front and rear baffles 144 and 146 provide an air-dam zone 148 for the inlet tube 134. The air-dam zone 148 prevents the liquid from entering the inlet tube 134.
As best shown in
As best shown in
Left and right handles 168 and 170 are provided to allow a user to grasp the underwater device UD4 for use. As best shown in
In underwater device UD4, the liquid or water enters the housing 120 through the rear opening 176 and exits via the front opening 140 in the form of vortex rings VR, when a user jerks or shakes the device UD4 back and forth in an underwater environment (arrow X in
As best shown in
In the various embodiments of the underwater device illustrated herein, the ratio of the diameter of the front opening (32, 74, and 98) to the overall diameter of the device, is 0.6-1.6 to 4, preferably 0.8-1.2 to 4, and more preferably 1 to 4. In this regard, it is noted herewith that although the embodiments are illustrated with a single, circular front opening, it is within the scope of the invention to vary the shape and number thereof for enhancing the performance, efficiency, and/or functionality of the device. For instance, it may be desirable to shoot more than one vortex rings simultaneously, and of different sizes. Therefore, an embodiment of the underwater device can be devised, where more than one front opening, of different shapes and/or sizes shapes, is provided. It is also within the scope of the present invention to provide a suitable mechanism for generating a sound, or some sort of audio signal, when the front and rear handles are actuated or snapped together to fire the device. For example, an audible mechanism can be incorporated in the device of the present invention to generate a crunching or a high-pitch squeak, or the like sound when the device generates vortex rings. It is further within the scope of the invention to add a suitable mechanism that generates a visual indicator or illumination, which signals the firing of the device, and/or simply highlights the vortex rings or their paths of travel through the water.
In order to shoot multiple vortex rings VR, without reloading of the underwater device of the present invention, it is preferred that the volume of the liquid chamber be about three times of the fluid chamber. This construction would produce about five to fifty vortex rings with one full chamber of air. It is noted herewith that the volumes of the liquid and fluid chambers may be varied to increase or decrease the number of vortex rings to be shot without the need for reloading of the device with water and fluid.
Referring to
As best shown in
The handle 200 includes a conventional trigger assembly 214 disposed between an inlet line 216 and an outlet line 218. The inlet line 216 supplies a compressed or pressurized fluid or air coming from a source, which can be a regular scuba tank ST typically used by scuba divers (
Although not shown, the trigger assembly 214 may be designed in a manner to allow more fluid or air to flow to the fluid outlet line 218, when pulled hard, and to allow smaller amounts of the fluid or air to flow when a softer pull is exerted.
Preferably, the housing 202 is in the shape of a stubby barrel, including a front portion 220 and a rear portion 222. The front portion 220 includes a somewhat shallow, cup-shaped nose 224 with an opening 226 for discharging vortex rings VR therefrom. A piston assembly 228 is provided in a cylinder or yoke 230. The yoke 230 is itself preferably centrally mounted on the front surface 232 of the wall 212.
The piston assembly 228 includes a piston 234 slidably positioned inside the yoke 230, and a larger front plate 236. The diameter of the front plate 236 is provided such that it has a tight clearance with the interior surface 237 of the housing 202, forming a fluid-tight seal therebetween, while sliding back and forth during use of the underwater device UD5. The yoke 230 and the interior surface 237 of the housing 200, define a circular recess 238, where various other components best shown in
As best shown in
As best shown in
Referring to
As best shown in
In order to optionally entrain the vortex rings VR with a pigment or color or the like, an optional dye assembly 268 is provided in the front portion 222 of the housing 200. As best shown in FIGS. 17 and 23-26, the dye assembly 268 preferably includes a chamber 270, which can selectively communicate with the interior of the housing 202 via a port 272 and a corresponding hole 274 in the housing 200. As can be seen from
In order to assist the user in properly, securely, and comfortably holding the underwater device UD5, especially when firing, a foldable side handle H is provided on one side of the housing 202.
Although not shown, suitable stops or abutment members may be provided on the inside of the front portion 220 of the housing 202 at the junction point 255, to limit the frontal movement of the plate 236, or to prevent over-shooting thereof.
Referring to
The vortex rings VR formed by the underwater device UD of the present invention, are estimated to travel 12-16 feet through the water and bounce off the water surface when the underwater device UD is pointed towards the top. As also noted above, the unique design and construction of the underwater device UD allows for generating or shooting five to fifty vortex rings with one full chamber of air. In other words, once the underwater device UD is fully primed and loaded, multiple consecutive vortex rings can be shot one after another without having the need to bring the device out of the water to reload with air.
The second preferred embodiment of the underwater device UD2 operates in the same manner. The third embodiment of the underwater device UD3 also operates in a similar fashion, except that since the air in the external housing 100 automatically escapes in the form of bubbles through the tiny holes 104, the force with which the front and rear handles are needed to be snapped or to be squeezed, is relatively low, compared to the force needed in the first and second embodiments UD and UD2. As a result, this embodiment (UD3) is believed to be particularly suited for very young children, or those users who are unable to squeeze the front and rear handles hard.
As to the use and operation of the fourth preferred embodiment, the underwater device UD4 is primed or loaded in the same manner as the other embodiments discussed above. Once loaded with air and water, the device UD4 is simply jerked or thrust back and forth to force the water out through the front opening 140, as spinning slugs or toroids. During this movement, a portion of the water is displaced into the fluid chamber 124, via the compression hose 150 building a pressure therein, which forces a burst of air through the outlet tube opening 138, from the inlet tube 134 to the check valve 132 and through the outlet tube 136. This burst of air gets entrained in the water slugs being formed substantially simultaneously adjacent the front opening 140. In order to shoot or fire consecutive vortex rings, the user U merely need to keep thrusting the device UD4 back and forth, as shown by arrow X in
With respect to the use and operation of the fifth preferred embodiment, the underwater device UD5 is primed or loaded by submerging in water. By simply holding it under water, the front portion 220 of the housing 202 will get filled up with the water W entering through the front opening 226. At this point, the device UD5 is primed or fully loaded. In order to shoot a vortex ring VR, the user U simply actuates the trigger 214, which allows a portion of the compressed or pressurized fluid or air to be injected into the chamber 248, causing the piston 234 and plate 236 to thrust forwardly. This action will result in swift, high pressure displacement of the water W, present in the front portion 220 of the housing 202, in the form of a toroid or slug of spinning water out of the front opening 226. Substantially simultaneously, a tiny burst of fluid or air is supplied to the toroid of spinning water by the opening 256 of the line 252. This fluid or air will be entrained in the low-pressure region of the vortex or toroid forming a bubble ring. As discussed above, the pressure in the chamber 248 will drop (no more supply of fluid or air from the outlet line 218) to a level lower than the retraction pressure of the springs 240 and 242. As a consequence, the piston 234 and plate 236 will retract to their initial position, creating a void in the front portion 220 of the housing 202, which void will instantly be filled with the surrounding water through the front opening 226, thereby automatically priming the underwater device UD5 for the next firing. In this manner, the underwater device UD5 can be fired repeatedly without cocking or recocking, or taking it out of the water.
The vortex rings VR produced by the underwater device UD5 are estimated to travel 40 feet or more through the water.
While this invention has been described as having preferred sequences, ranges, steps, materials, structures, shapes, configurations, features, components, or designs, it is understood that it is capable of further modifications, uses and/or adaptations of the invention following in general the principle of the invention, and including such departures from the present disclosure as those come within the known or customary practice in the art to which the invention pertains, and as may be applied to the central features hereinbefore set forth, and fall within the scope of the invention and of the limits of the appended claims.
This is a continuation-in-part (CIP) application of U.S. applications Ser. No. 12/929,439, filed Jan. 25, 2011, and Ser. No. 29/371,380, filed Jan. 25, 2011, both of which are hereby incorporated herein in their entirety by reference. This application further claims the priority benefit of U.S. Provisional Patent Applications Ser. No. 61/376,867, filed Aug. 25, 2010, and Ser. No. 61/457,328, filed Mar. 1, 2011, both of which are also hereby incorporated herein in their entirety by reference.
Number | Date | Country | |
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61376867 | Aug 2010 | US | |
61457328 | Mar 2011 | US |
Number | Date | Country | |
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Parent | 12929439 | Jan 2011 | US |
Child | 13067017 | US | |
Parent | 29371380 | Jan 2011 | US |
Child | 12929439 | US |