Embodiments of the present disclosure are directed to a pump that can extract energy inherent in air pressure due to the gravitational pull on the Earth's atmosphere.
According to an embodiment of the disclosure, there is provided a pumping apparatus that includes a container positioned over a left column and a right column that contains at least a first fluid, wherein the container includes a reflective wall at a left end and a reflective wall at a right end, a left intake valve and a right intake valve that respectively connect the left column and the right column to the container, a left pump and a right pump respectively associated with the left column and the right column, upper and lower connecting pipes that connect the left column and the right column below the container, a plurality of one-way gates, each positioned at an entrances of one of the upper and lower connecting pipes in each of the left and right columns, a main turbine positioned to be driven by fluid flowing through the upper and lower connecting pipes, a left auxiliary turbine and a right auxiliary turbine respectively disposed in the left and right columns, a third fluid disposed in the upper and lower connecting pipes, and the left column and a right column, wherein main turbine and the left and right auxiliary turbines generate electric power due to the flow of the third fluid through the left and right columns and the upper and lower connecting pipes.
According to a further embodiment of the disclosure, the main turbine and the left and right auxiliary turbines include flywheels.
According to a further embodiment of the disclosure, the container includes operable ports in a side wall and a top of the container, wherein placement of the ports is determined to optimize flow of the fluid in the container.
According to a further embodiment of the disclosure, each pump is a variable speed pump.
According to a further embodiment of the disclosure, the container contains a second fluid, wherein the first and second fluids are stratified with the first fluid above the second fluid.
According to a further embodiment of the disclosure, the first fluid and the second fluid are gases of different densities, and the third fluid is a liquid.
According to a further embodiment of the disclosure, the first fluid and the second fluid are liquids that are immiscible and incompressible.
According to a further embodiment of the disclosure, the apparatus a flexible bladder between the first fluid and the second fluid.
According to another embodiment of the disclosure, there is provided a method of operating a pumping apparatus, including pumping a first fluid from a top of a left column through an open right intake valve into a container, and opening lower gates of a connecting pipe that connects the left column to a right column, wherein a vacuum is created in the left column that pulls up a third fluid in the left column, which flows across lower turbine blades of a main turbine in the connecting pipe, stopping pumping in the left column, closing the right intake valve and the lower gates, wherein the first fluid in the container moves toward a right reflective wall of the container, pumping the first fluid from a top of the right column toward an open left intake valve and opining and upper gates of the connecting pipe, wherein a vacuum is created in the right column that pulls up the third fluid, and the third fluid flows across upper turbine blades of the main turbine, stopping pumping in the right column, closing left intake valve and the upper gates, wherein the first fluid in the container moves toward the left reflective wall of the container, and pumping the first fluid from the top of the left column toward the open right intake valve and opening the lower gates, wherein a vacuum is created in the left column that pulls up the third fluid, and the third fluid flows across lower turbine blades of the main turbine.
Exemplary embodiments of the disclosure as described herein generally include pumps that can extract energy inherent in air pressure due to the gravitational pull on the Earth's atmosphere. Accordingly, while the disclosure is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the disclosure to the particular forms disclosed, but on the contrary, the disclosure is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure. With regard to the drawing figures, like reference numerals may designate like elements having the same configuration. In addition, relative dimensions and ratios of portions in the drawings may be exaggerated or reduced in size for clarity and convenience in the drawings, and any dimension are exemplary and non-limiting.
Referring to
An operation of an apparatus according to an embodiment of the disclosure includes 5 states, herein referred to as State 1, . . . , State 5, of which States 2 to 5 are cyclically repeated. States 1 to 5 are described with respect to
State 1: State 1 is a startup state, with no established air current in the shaped container 11. Referring now to
State 2: Referring now to
State 3: Referring now to
State 4: Referring now to
State 5: Referring now to
The Fluid 3 movement is based on the action of a hydraulic ram. Fluid 3 is set in motion by the creation of temporary vacuums at the tops of the left and right columns 12l, 12r. Speed of the pumps 14l, 14r at the top of each column 12l, 12r is determined by an optimal balance of electricity expended and power created. Unlike the liquid exiting from the bottom of a filled soda straw, which depends on the pull of gravity alone, the movement of Fluid 3 in the two columns 12l, 12r is augmented by a “free” constant push of atmospheric pressure against a vacuum in the opposite column.
Closing the pumps 14l, 14r in states 2 and 4 causes the creation of “fluid hammer”. The energy of the fluid hammer is captured by the compression of Fluid 2 at the top of the columns 12l, 12r. The height of the columns 12l, 12r, the amount of Fluid 2, and the amount of Fluid 3 can be optimized to capture a maximum amount of energy.
Closing the pumps 14l, 14r also causes the remaining energy in Fluid 2 in the container 11 to create a seiche that pushes into the corresponding reflective wall. A return of this energy toward the opposite wall creates a region behind it of reduced pressure, into which the pumps 14l, 14r can direct air flow. In other embodiments, the container includes ports 19 in the side walls and roof that can be opened or closed to allow an inflow of air from the top or the side walls that may augment the movement of Fluid 2 toward the opposing wall.
The placement and the opening/closing of ports in the container can manipulate pressure to create a micro-climate to maximize push. If an apparatus according to an embodiment of the disclosure can develop distinct masses of air at varying pressures that move in a predictable pattern, then a timing sequence can be developed and optimized to exploit the high/low air pressures during the intake and exhaust of Fluid 2 from the columns 12l, 12r. According to further embodiments of the disclosure, baffles may be disposed in the shaped container to direct the circulating fluid masses and to increase/decrease their velocities at several points in the shaped container. For example, using a funnel to speed up a circulating fluid mass in the container at the point where a pump is exhausting fluid into the container may provide a fluid mass of lower pressure as an exhaust target for the pump. According to further embodiments of the disclosure, by using ports on the walls and roof of the shaped container, an apparatus according to an embodiment of the disclosure can also use the pressure of the ambient air outside the container to increase/decrease pressures in the container at advantageous points.
The use of a fluid, such as a gas, heavier than air (Fluid 2 vs. Fluid 1) is based on the assumption that a stratified body of gases in the container will concentrate the seiche in the lower portion of the vessel. In some embodiments, a bladder of flexible material can be placed between Fluid 1 and Fluid 2 to prevent excessive mixing.
The shape of the container 11 may be rectangular, oval, or some combination of curved and flat walls that can maximize the power of the seiche. The top of each intake valve 13l, 13r may be shaped to maximize the creation of a partial vacuum on the pump side as the reflected seiche passes back over.
Additional configurations are possible in other embodiments with the goal of establishing a beneficial micro-climate in the shaped container. For example, the reflective walls 18l, 18r can be shaped to direct oncoming energy in the form of a fluid wave (the seiche) at an angle other than 180 degrees. For example, the wave can be reflected to either side at an angle of 60 degrees and, after traveling a specified distance, encounter another reflective wall or an intake valve of another vertical column filled with Fluid 2 at the top and a mostly non-compressible fluid on the bottom. This additional column may be connected by piping to the original two vertical columns 12l, 12r and to the main turbine 17m. Alternatively, in other embodiments, the additional column may be connected to zero, one, or more vertical columns with or without turbine-driving piping mechanisms.
Reflecting the fluid wave at an angle other than 180 degrees may establish a continuous rotational motion for the fluid wave. Coupled with a specifically shaped container, such as a covered circular or oval bowl, and coupled with the opening and closing of side wall and ceiling ports of the container, a timing sequence can be established to maximize the use of “free energy” derived from the constant atmospheric pressure that is present outside and above the container.
In some embodiments of the disclosure, Fluid 1, Fluid 2, and Fluid 3 may be fluids of different densities. In other embodiments of the disclosure, Fluid 1 and Fluid 2 may be gases of different densities, where at least Fluid 2 is denser than air, and Fluid 3 is be a liquid, such as water. In other embodiments, Fluid 1 and Fluid 2 may be gases with essentially the same density. In still other embodiments, Fluid 1, Fluid 2, and Fluid 3 may be liquids of different densities. In other embodiments, Fluid 1 and Fluid 2 are liquids that are immiscible and incompressible.
While the present disclosure has been described in detail with reference to exemplary embodiments, those skilled in the art will appreciate that various modifications and substitutions can be made thereto without departing from the spirit and scope of the disclosure as set forth in the appended claims.
This application claims priority from U.S. Provisional Application No. 62/184,747, of Joseph C. Haddad, filed in the U.S. Patent and Trademark Office on Jun. 25, 2015.
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