초록 ▼

Multiple, timed three-lobed rotor that are more efficient yet uncomplicated and easy to produce. A rotor lobe with additional reaction surfaces near the tip to increase the angle of rotation that produces power. A “flow through” rotor having end plates that facilitate mounting more tha

Multiple, timed three-lobed rotor that are more efficient yet uncomplicated and easy to produce. A rotor lobe with additional reaction surfaces near the tip to increase the angle of rotation that produces power. A “flow through” rotor having end plates that facilitate mounting more than one rotor on a common axis with rotationally varied timing and sequence, such that power delivery is smooth. A flow shielding and directing device that increases the efficiency of reaction surface rotors. Possibilities include replacement or augmentation of: existing electrical energy prime mover dynamos, air compressing, pumping, milling, and other power needs. The dynamo can be built using low-tech, low-cost materials and methods, and is inherently resistant to over speed and damage from periodically high velocity fluid flow.

대표청구항 ▼

1. A method of producing power from a free stream fluid flow comprising the steps:a) providing a means to redirect a fluid flow,b) providing a main means for reactive energy capture,c) providing a means for rotational energy conversion,d) providing a support means,e) providing means for antifriction

1. A method of producing power from a free stream fluid flow comprising the steps:a) providing a means to redirect a fluid flow,b) providing a main means for reactive energy capture,c) providing a means for rotational energy conversion,d) providing a support means,e) providing means for antifriction rotation,f) providing a flow direction sensing means,g) providing a rotational position adjusting means,h) adjusting the rotational timing of a plurality of said main means for reactive energy capture such that rotational power delivery is consistent and without fluctuation,i) mounting the rotationally timed plurality of said main means for reactive energy capture onto said support means using said means for antifriction rotation such that rotation may occur with minimal friction,j) coupling said rotational position adjusting means to said means to redirect a fluid flow such that said means to redirect a fluid flow directs fluid flow to maximize rotational energy capture of each main means for reactive energy capture according to flow direction information provided by said flow direction sensing means,k) providing secondary reactive means to increase the reactive effort the fluid flow exerts on said main reactive energy capture means, as the fluid initially contacts the said reactive energy capture means,l) providing a means of placing weight in the void area formed between the secondary and main reactive means; whereby vibration and rotational speed variations are minimized.m) attaching said means for rotational energy conversion to the plurality of timed reactive energy capture means such that useful work may be accomplished. 2. The method of claim 1 comprising the further step of providing a blended reactive means to increase the reactive effort the fluid flow exerts on said main reactive energy capture means, as the fluid flow leaves the blended reactive energy capture means. 3. A prime mover dynamo comprising:a) A rotor set comprising more than one substantially identical rotors on a common axis; said rotors having two, or three, or four lobes; and said rotors oriented such that they are rotationally separated by an angular degree measure equal to 360 degrees divided by the number of lobes per rotor, and further divided by the number of rotors in the set;b) a rotor set support structure with anti-friction means that interposes said rotors with the axis of rotation substantially normal to a fluid stream; andc) lobe tips with a secondary reaction means whereby the angle of rotation that produces power is increased, and optional weight may be placed for balance, and rotational energy storage; andd) an energy conversion device selected from the group comprising: electrical current generators, air or vapor compressors, PTO unit, pumps, mechanical drives, saws, and mills; whereby rotational energy from the rotors is smoothly converted into useful work. 4. A prime mover dynamo of claim 3 where there is a second set of substantially identical rotors on a common axis but rotate the opposite direction in response to the fluid flow, and the energy conversion device is an electrical generator, such that the relative velocity of moving electromagnetic generating elements is the sum of the rotational velocities of the two rotor sets. 5. A prime mover dynamo rotor of claim 3 with a slotted flow deflector that reduces the amount of fluid striking the back side of the rotor reaction members; said deflector comprising a plurality of vanes and slots arranged in a sector of approximately 90 degrees of the circumference of a cylinder swept by the rotor. 6. A prime mover dynamo rotor of claim 3 with a slotted flow deflector that reduces the amount of fluid striking the back side of the rotor reaction members; said deflector comprising a plurality of vanes and slots arraigned in a sector of approximately 90 degrees of the circumference of a cylinder swept by the rotor; said deflector having a means to keep it aligned with flow from variable directi on. 7. A prime mover dynamo rotor with an axis of rotation comprising: three or four main concave reaction surfaces, each said surface extending from a line parallel to the axis but displaced from the axis by a distance equal to the overall radius of the rotor divided by any where from 4 to 10; and each said surface ending at a tip point on the circumference of the rotor diameter that is at an approximately right angle from a line extending from the axis to the origin of the main reaction surface; and each said main reaction surface having a preferred axial measure between 0.25 and 1 times the rotor radius and secondary reaction surfaces extending from the tip point of each main reaction surface inward toward the axis of rotation such that the angle relative to the free stream fluid flow is between 4 degrees and 16 degrees when the tip point is in the rotational position that places the tip point at the upstream most location, said secondary surface extending inward a distance between 4% and 25% of the rotor radius; whereby a reaction force from the fluid stream is available to turn said rotor a few degrees of rotation earlier than the tip point enters the point perpendicular to the stream flow, said secondary reaction surface forming a retention area for balance weight and additional rotational mass. 8. The rotor of claim 7 wherein secondary reaction surfaces further comprising a blended reaction surface extending from the most inward point of the secondary reaction surface inward toward the axis at an angle sufficient to cause it to meet the main reaction surface at a point that is between 2 and 4 times the radial distance the secondary reaction surface extends inward; whereby yet additional rotation is caused as fluid flows out of the rotor, and a void retention area for balance weight and additional rotational mass is formed.