The present invention relates generally to the field of paddlewheel apparatus for moving water, and more particularly, to a height-adjustable paddlewheel apparatus including a plurality of fixed, tri-curved paddles supported by at least one hub coupled to a motor driven shaft, wherein the paddle design provides improved rigidity, energy transfer and reduced drag as compared to conventional paddlewheel apparatus.
Various species of algae are now being commercially grown for a variety of uses including bio-fuel feedstock and health supplements, among others. Algae are desirable in that they can be grown year round under the right temperature conditions, have relatively short generation times, and require readily available and inexpensive nutrients for growth, such as sunlight, water and carbon dioxide. Algae are also desirable in that they can be grown in adverse conditions, such as saline and brackish water.
Algae are typically grown in open bio-ponds and shallow raceways in which it is necessary to create a current to prevent the algae from becoming stagnant. It is also necessary to prevent algae from remaining at the surface of the pond in which sunlight exposure may be too great, or remaining at the bottom of the pond in which there is too little sunlight exposure, both of which are adverse to growth. Conventionally, to address these issues, paddlewheels have been deployed within ponds and raceways to introduce a current. These conventional paddlewheel designs, however, suffer from several disadvantages, some of which include utilizing large flat paddles that require large amounts of energy to move through the water, paddle structures that are cupped in the direction of rotation and retain water as the paddles leave the water, and paddlewheels that are fixed in height in relation to the pond floor, thus causing cavitation and the raising of liners in lined ponds.
Accordingly, to overcome the disadvantages of conventional paddlewheel designs, and to improve the creation of current in a bio-pond or raceway, a paddlewheel apparatus and methods of operation are provided that include an energy efficient paddle design, height adjustability, sensor control to optimize paddlewheel rotational speed and construction including materials adapted to withstand both fresh and salt water conditions.
In one aspect, a paddlewheel apparatus is provided including a lightweight, energy efficient paddle design that reduces drag, increases the amount of water moved, and does collect water as the paddles leave the water.
In another aspect, a paddlewheel apparatus is provided including a control system that receives an input from a sensor module regarding at least one of liquid density and water current, and control the rotational speed of the paddlewheel based upon the output.
In yet another aspect, a paddlewheel apparatus is provided that is readily adjustable in height to accommodate various pond depths.
In yet another aspect, a paddlewheel apparatus is provided for creating and maintaining a current in a bio-pond or raceway.
To achieve the foregoing and other aspects and advantages of the present invention, in one embodiment a paddlewheel apparatus is provided including a paddlewheel axle, first and second spaced apart annular wheel hubs mechanically coupled to and locked in rotation with the paddlewheel axle, and a plurality of elongated, tri-curved paddles each being arranged generally parallel to a longitudinal axis of the paddlewheel axle and being cooperatively supported by the first and second wheel hubs, wherein the plurality of paddles are arranged at predetermined intervals around the circumference of the first and second annular wheel hubs and spaced apart from the paddlewheel axle.
Each of the tri-curved, also referred to herein as “Z-shaped,” paddles is continuous and is bent or otherwise formed to define an inner paddle portion for providing rigidity to the paddle, a center paddle portion positioned at an angle with respect to the inner paddle portion for moving water, and an outer paddle portion positioned at an angle with respect to the center paddle portion for reducing paddle drag. The center and outer paddle portions together define a cup-shape that opens in the direction opposite the rotational direction of the paddlewheel apparatus so as not collect water therein as each paddle leaves the water. The first and second wheel hubs define slots in which the paddles are received and secured therein.
The paddlewheel apparatus further includes first and second fixed supports for supporting the paddlewheel axle and a motor coupled to the paddlewheel axle through a gearbox for rotating the paddlewheel axle. The apparatus further optionally includes a sensor module including at least one of a liquid density sensor and a water current sensor, and a motor speed regulator for receiving an output from the sensor module and regulating a voltage supplied to the motor to control the rotational speed of the paddlewheel axle in accordance with at least one of the liquid density and water current outputs.
In another embodiment, a paddlewheel apparatus is provided including a paddlewheel axle supported about each end by first and second fixed supports, first and second spaced apart annular wheel hubs mechanically coupled to and locked in rotation with the paddlewheel axle, a plurality of elongated Z-shaped paddles each cooperatively supported by the first and second wheel hubs, wherein the plurality of paddles are arranged at predetermined intervals around the circumference of the first and second annular wheel hubs and spaced apart from the paddlewheel axle, and a motor for rotating the paddlewheel axle.
In yet another embodiment, a method of creating current in a bio-pond is provided including providing a paddlewheel apparatus including a paddlewheel axle supported about each end by first and second fixed supports, first and second spaced apart annular wheel hubs mechanically coupled to and locked in rotation with the paddlewheel axle, a plurality of elongated Z-shaped paddles, a motor for rotating the paddlewheel axle through a gearbox, a sensor module including at least one of a liquid density sensor and a water current sensor, and a motor speed regulator for regulating the voltage supplied to the motor. The method further includes increasing or decreasing a rotational speed of the paddlewheel axle in response to the output of the sensor module by regulating the voltage supplied to the motor.
Additional features and advantages of the invention will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the invention as described herein. It is to be understood that both the foregoing general description and the following detailed description present various embodiments of the invention, and are intended to provide an overview or framework for understanding the nature and character of the invention as it is claimed. The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification.
These and other features, aspects and advantages of the present invention are better understood when the following detailed description of the invention is read with reference to the accompanying figures, in which:
The present invention will now be described more fully hereinafter with reference to the accompanying drawings in which exemplary embodiments of the invention are shown. However, the invention may be embodied in many different forms and should not be construed as limited to the representative embodiments set forth herein. The exemplary embodiments are provided so that this disclosure will be both thorough and complete, and will fully convey the scope of the invention and enable one of ordinary skill in the art to make, use and practice the invention. Like reference numbers refer to like elements throughout the various figures.
Referring to the figures, various embodiments and deployments of an energy efficient paddlewheel apparatus are shown and described. The paddlewheel apparatus may be constructed from any materials, and is preferably constructed from lightweight materials adapted for long term use in both fresh water and saltwater applications without component degradation. Suitable paddlewheel material examples include, but are not limited to, stainless steel, fiberglass and aluminum. Various components of the apparatus may be mechanically coupled or fastened together using any number of conventional methods, and the specific methods described herein are not intended to limit the invention.
Referring to
The paddlewheel 22 further includes at least one annular wheel hub 50 for supporting a plurality of paddles 52. Referring specifically to
The wheel hubs 50 define slots 56 in which portions of the paddles 52 are received within and secured. The paddles 52 may be secured using any conventional fastener or by welding. Preferable fasteners are preferably low profile to reduce drag in the water. The paddles 52 are secured in predetermined intervals about the circumference of the wheel hubs with their longitudinal axis arranged generally parallel to the longitudinal axis 30 of the paddlewheel axle 28, and with the general lateral axis arranged generally perpendicular to a tangent of the wheel hub. The paddles preferably define a width less than the radius of the wheel hubs 50, and thus are spaced apart from the paddlewheel axle 28 providing an internal material void in the paddle to reduce rotational mass, prevent the paddles from collecting water and reducing materials.
Each paddle 52 is elongated and tri-curved, also referred to herein as “Z-shaped,” and is preferably constructed from a continuous piece of material bent, formed or molded to define the proper shape. Each paddle 52 defines an inner paddle portion 56 positioned closest to the axle 28 for providing rigidity to the paddle, a center paddle portion 58 positioned at an angle with respect to the inner paddle portion 56 for moving water, and an outer paddle portion 60 positioned furthest from the axle 28 and at an angle with respect to the center paddle portion 58 for reducing paddle drag.
The tri-curve paddle 52 is specifically designed for moving algae in culturing ponds. The inner paddle portion 56 is designed to add rigidity to the paddle 52 allowing a small amount of paddle area while the bend increases the structural support allowing for fewer wheel hub support sections along long paddle length distances. The center paddle portion 58 is the key water moving section of the paddle 52. The outer paddle portion 60 transfers the final energy of the sweep of the paddle 52 in the pond to continue along its final path. Thus, the paddle shape aids in energy transfer, unlike conventional flat or cupped paddles in which the final sweep of the paddle creates a drag on the system and a load on the motor.
Referring to
Referring to
The apparatus further includes a height adjustment mechanism including holes defined through the mounting plate 48 for allowing threaded rods 70 to pass therethrough. Thus, the threaded rods 70 are secured about one end to the axle 28, and secured about their other end to the supports 32 and 34. The height adjustment mechanism may include a simple nut and bolt locking arrangement on the threaded rod to the gearbox/motor mounting plate 48, and the paddlewheel portion has the ability to be raised and lowered to adjust the position of the paddles 52 with respect to the pond floor 66. The motor/gearbox unit 46 is preferably positioned above the surface of the water. The ability to raise or lower the paddles 52 in relation to the pond floor is important for efficient water flow, minimizing cavitation, and creating a non-turbuent mixing. Further, in applications including a pond liner, the ability to position the paddles away from the liner prevents it from being pulled up.
Referring again to
In operation, the motor speed regulator 72 is set to a predetermined pond current water velocity for the given growth cycle of an algae species. The motor speed regulator 72 maintains the current speed by a variety of measurements including monitoring the density of the water (i.e., the level of growth of the algae strands), and water current speed. This information is used to determine the correct rotational speed of the paddles. Less energy is required when the water density is low and the current high.
The paddlewheel apparatus further optionally includes a carbon dioxide exhaust tube 76 for injecting carbon dioxide into the water to saturate the water with gas. The tube 76 is preferably mounted along the front edge of the water entry side onto the paddlewheel support structure. The length of the tube 76 corresponds to the length of the paddles 52. The placement of the injection tube 76 at the paddle entry point optimizes the infusion of carbon dioxide into the algae water. Carbon dioxide is a key feedstock nutrient to promote the growth of algae. Normal air absorption by algae from the air is about 2%. This method of injection of carbon dioxide into the water increases the absorption rate by 5 fold, taking advantage of the water cavitation effect created as the paddles 52 move the water.
Referring to
In response to the output of the motor speed regulator 72, the motor 24, preferably an electric motor known to those skilled in the art, turns the reduction gearbox 26, which in turn rotates the paddlewheel axle 28 and paddles 52. The paddlewheel apparatus works on the principle of pushing the water along the raceway 78 by the force of the tri-curved paddles 52 sweeping across the entire width w of the shallow water in the pond. The diameter of the paddlewheel, the number of paddles, and the required speed of the rotation of the paddles is determined by the specific strand of algae being grown, the height of the water that holds the algae, and the support wall or brim height to insure the motor and gear box are above the flood plane of the pond. No set hub diameter, number of hubs, number of paddles or the overall dimensions of the tri-curve paddle length or width for the are defined for this reason.
While a paddlewheel apparatus has been described with reference to specific embodiments and examples, it is envisioned that various details of the invention may be changed without departing from the scope of the invention. Furthermore, the foregoing description of the preferred embodiments of the invention and best mode for practicing the invention are provided for the purpose of illustration only and not for the purpose of limitation.
This application claims priority to U.S. Provisional Application Ser. No. 61/069,287 filed Mar. 12, 2008.
Number | Date | Country | |
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61069287 | Mar 2008 | US |