The disclosed embodiments relate generally to rotary generator and, in particular, to a floating rotary generator for converting a water current in a body of water into electric energy.
Green energy has become a global phenomenon, with countries funding, and consumers demanding, renewable energy production methods that generate less carbon than fossil fuels, such as oil, coal, and the like, and that emit fewer undesirable byproducts, such as carbon dioxide, methane, nitrous oxide, etc. It is known in the art to provide renewable energy systems that harvest energy from wind and sun. One drawback is that these systems cannot generate energy in the absence of wind and sun. It is known to produce energy from water flow. One drawback of such prior art systems is that they often required a portion of the waterway to be permanently ceded to the system, to the exclusion of other desirable uses of the waterway. It would therefore be desirable to provide a readily removable system for generating energy from a waterway.
When exploring the wilderness it is often desirable to bring a system for generating electricity. As noted above, while portable solar and wind-generated systems are known to produce electricity, they are dependent on the sun shining and/or the wind blowing. It is known to provide propeller-driven portable water-powered electric generators, but for shallower waterways, these systems require multiple smaller generators strung across the waterway. It would be desirable to use a single generator to capture power across a shallow stream or river. While it is known to provide larger propeller-driven portable water-powered electric generators, these systems often require deep water. It would therefore be desirable to provide a portable system for generating energy from a shallow low-flow waterway.
Although portable water-powered electric generators are known, such prior art systems are heavy, costly, fragile, and/or expensive to maintain. It would therefore be desirable to provide a light reasonably priced, sturdy, easily repaired and maintained system for generating energy from a waterway.
The deficiencies described above are overcome by the disclosed implementation of a fluid-driven energy output assembly. The assembly has an electric generator coupled to an arm assembly having four arms connected radially outward from a central hub. Attached to each arm is a small sprocket connected to a larger sprocket with a chain. The larger sprocket is journaled through a float to an impeller that is located under the water when the float is floating on the water. The remaining three arms are similarly constructed except that the impellers associated with each of the four arms are offset from the nearest impellers by forty-five degrees. In operation, the assembly is floated and anchored in a moving body of water. As the water current flows across the assembly the current pushes against the full face of the impeller moving downstream, while moving across the streamlined edge of the impeller moving upstream to drive the arm assembly in a clockwise motion. The farthest upstream and farthest downstream impellers are angled forty-five degrees relative to the flow of the water current, but in opposite directions, so as to push the arm assembly in a clockwise motion, thereby turning the electric generator and generating electricity.
Other implementations of fluid-driven energy output assemblies are disclosed, including implementations directed to mesh geared and deep-water fluid-driven energy output assemblies.
The present invention will now be described, by way of example, with reference to the accompanying drawings in which:
The system of the present invention converts fluid current into electric energy. The system described below is distinguished over earlier systems in that the present system is portable and may be used to generate large amounts of electricity in shallow streams. The use of long arms and rotating impellers increase the torque supplied to the electric generator to increase electric output. One embodiment of the present system uses four arms that rotate around a central hub. Provided on the ends of the arms are with floats and rotating impellers. The impellers rotate at a rate half that at which the arms rotate around the central hub. This difference in rotation rate causes the impellers to receive the liquid flow, such as a current of the water flow at an angle that drives the arms in a clockwise direction. The electric generator may either store the electricity on an onboard battery, or transmit the electricity via wire to the shore for any desired use.
An embodiment of the liquid driven energy output assembly of the present invention is shown generally as (10) in
Secured to the bottom of the central float (12) is a stainless steel ring (24), that is used to connect an anchor line (26), which is turn connected to an anchor (28). Stainless steel rings (24), anchor lines (26), and anchors (28) are all well known in the art and are preferably selected for this embodiment of the invention to secure the output assembly (10) to the bed (30) of the stream (32) river, or other body of water into which the output assembly (10) is placed. The ring (24) is preferably secured to the central float (12) closer to the bow (18) than to the stern (20), but not so far toward the bow (18) that the anchor line (26) pulls the bow (18) under the water (22) during maximum water current flow.
Secured to the top of the central float (12) is an electric generator (32). The generator (24) may be or any type known in the art, but is preferably a direct current electric generator. The generator (24) may be coupled to a battery (34), such as those known in the art, or coupled to an insulated wire (36) to transmit the electric output to the shore (38).
The arm assembly (14) is journaled to a shaft (40) of the electric generator (32) by a bearing (not shown) or similar assembly to allow the arm assembly (14) to rotate relative to the electric generator (32). The arm assembly (14) has four arms (42), (44), (46), (48) coupled to a central steel hub (50) that is bolted, or otherwise secured to the shaft (40) of the electric generator (32). In the preferred embodiment, but may have three, five, or any desired number of arms. As the four arms (42), (44), (46), (48) are similar except for having impellers offset forty-five degrees from one another, description will be limited to a single arm (42). The arm (42) is a steel bar with its near end (52) welded or otherwise secured to the hub (50) and offset from the adjacent arms (44), (46), by forty-five degrees.
As shown in
Like the central float (12), the arm float (64) is preferably constructed of a rigid outer shell (16) made of thermoplastic, fiberglass, carbon fiber, or the like, filled with a buoyant material (not shown), such as expandable foam, closed-cell extruded polystyrene foam, air, or the like. The arm float (64) may be solid polystyrene foam or the like and may be constructed of any desired dimensions, but is preferably provided with a tapered bow (68) and a flat stern (70) and is longer and narrower than the central float (12). For use in fast flowing or turbulent water, the arm float (64) may be larger, longer, and wider, and for use in slower, calmer water the arm float (64) may be smaller, shorter, and narrower. Secured to the underside of the arm float (64) is a rudder (72), that is preferably constructed of aluminum or similarly rigid material. The rudder (70) has a spine (74) secured on one end to the top of the stern (68) of the arm float (64) and on the other end to a tapered plate (76). The length of the spine (74) and the configuration of the plate (76) is preferably adapted to efficiently exploit the depth, water current, and turbulence of body of water in which the output assembly (10) will be used.
A second bushing (78) is secured to bottom interior of the float bracket (62) and around a shaft (80). The shaft (80) is provided through the float bracket (62) and through another bushing (82) secured to the underside of the arm float (64). The shaft (78) is secured to an impeller (84) by a bracket (86), which is secured to both the shaft (78) and the impeller (84) by bolts, weldments, or the like. The impeller (84) is preferably constructed of a rectangular piece of aluminum 1 cm to 200 cm high, 0.1 cm to 5 cm thick, and 5 cm to 500 cm long, more preferably 5 cm to 50 cm high, 0.2 cm to 2 cm thick, and 10 cm to 100 cm long, and most preferably 10 cm high, 0.5 cm thick, and 40 cm long, but may be constructed of steel, fiberglass, plastic or any desired material of any desired dimensions. The dimensions of the impeller (84) are preferably adapted to efficiently exploit the depth, water current, and turbulence of body of water in which the output assembly (10) will be used, as well as the desired electric output of the output assembly (10).
The top of the shaft (80) is secured to a large sheave (not shown) or large toothed sprocket (88). The sprocket (88) such as known in the art, preferably has between 2 and 160 teeth (90), more preferably between 10 and 50 teeth (90), and most preferably 32 teeth (90). The sprocket (78) may be of any desired dimensions, but is preferably provided with twice the number of teeth as the sprocket (58). Teeth (90) of the sprocket (78) are coupled to teeth (92) of the sprocket (58) by a flexible endless band, such as a belt or a chain (94) in a manner such as that known in the art. To operate the energy output assembly (10), the energy output assembly (10) is placed in a body of water (22), such as a stream or a river. The anchor (28) is secured to the bed (30) of the body of water (22). Alternatively, the anchor line (26) may be secured to a post (not shown) in the water (22) or on the shore, or may be secured to a floating vessel (not shown). As shown in
The impeller (98) toward the starboard of the energy output assembly (10) is angled perpendicular to a line parallel to the flow of the water current (102). When the water (22) in the current (102) strikers the impeller (98), the impeller (98) presents a profile fully facing the current (102), thereby causing the current (102) to impart a force on the impeller (98) to the stern. This causes the impeller (96) to turn the arm assembly (14) clockwise relative to the central float (12) and the electric generator (32). The impeller (100) toward the stern of the energy output assembly (10) is angled forty-five degrees counterclockwise from a line parallel to the flow of the water current (102). When the water (22) in the current (102) strikers the impeller (100), the impeller (100) presents an angled profile to the current (102) thereby causing the current (102) to impart a force on the impeller (100) to both the port and stern. As the impeller (100) cannot move to the stern, the current (102) forces the impeller (100) port, causing the arm assembly (14) to turn clockwise relative to the central float (12) and the electric generator (32).
As the arm assembly (14) rotates clockwise, the differential between the number of teeth (90) on the sprockets (58) and the number of teeth (92) on the sprockets (78) causes the impellers (84), (96), (98), and (100) to rotate one half of a revolution for each revolution of the arm assembly (14). This means that whichever impeller is to the port is always parallel to the water current (102), the whichever impeller is to the bow is always rotated forty-five degrees clockwise relative to the current (102), whichever impeller is to the starboard is always perpendicular to the current (102), and whichever impeller is to the stern is always rotated forty-five degrees counterclockwise relative to the current (102). In this manner, except when an impeller is perfectly parallel to the flow of the water current (102), all of the impellers (84), (96), (98), and (100) are constantly forcing the arm assembly (14) toward a clockwise rotation.
As the arm assembly (14) rotates clockwise, the arm assembly (14) rotates the shaft (40) of the electric generator (32) clockwise, thereby causing the electric generator (32) to produce electricity. The electricity produced may either be stored in the battery (34), or transmitted via the wire (36) for use as desired.
Although the invention has been described with respect to a preferred embodiment thereof, it is to be understood that it is not to be so limited since changes and modifications can be made therein which are within the full, intended scope of this invention as defined by the appended claims.
Number | Name | Date | Kind |
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4494007 | Gaston | Jan 1985 | A |
20190031301 | De Haas | Jan 2019 | A1 |