PATENT CLAIM ANALYSIS

Application Number: 16147874
Application Type: Utility
Filing Date: 2018-10
Publication Date: 2019-01
Patent Classification: ["290", "00100R"]

Abstract:
The present invention is directed to a system for producing energy via use of gravity. The system is for generating energy, and in particular electrical energy, by utilizing the abundant force of gravity that exists and then integrating such a force into a system design of energy power generation by converting the force of gravity into potential energy then into kinetic energy and from kinetic energy back into potential energy again, by using the system's autonomous methodology of fluid recycling to produce electric power generation in the process.

Claim (Index 12):
A system for producing energy via use of gravity, said system comprising:\n a pulley support assembly (PSA) comprising a supporting structure, a plurality of electric motors, and a plurality of pulley and cable systems, wherein said pulley and cable systems are operationally supported by said supporting structure, wherein said system for producing energy is set to a potential status, at t=0, prior to initiation of operation and motion processes of said system, wherein said pulley and cable systems comprise a plurality of pulleys and a plurality of cables that engage in said operation and in said motion processes of said system via electromechanical contact, and wherein said electric motors are in operational communication with said pulley and cable systems to carry out said operation and said motion processes of said system; a fluid tank system comprising an upper fluid tank, a lower fluid tank, and a plurality of fluid transfer path controls, wherein said fluid tanks are positioned vertically with respect to one another, wherein said fluid tanks are in communication with said pulley and cable systems and said electric motors to operate and to set in said motion processes of said system, wherein each of said fluid tanks comprises a sufficient amount of fluid, wherein said upper fluid tank comprises a plurality of extensions for transferring fluid along a plurality of fluid transfer paths from said upper fluid tank into corresponding fluid transports cells of a plurality of fluid transports cells (FTCs), and further comprises a plurality of fluid transport cell release platforms (FTCRPs) and at least one fluid transport cell emergency platform (FTCEP), wherein at least one of said FTCEPs provides energy to initiate said system, wherein at least one of said FTCEPs also re-initiates said motion processes of said system when said motion processes stop, wherein each fluid transfer path includes corresponding fluid transfer path controls to regulate the transfer of fluid in and out of said fluid transfer path, wherein said lower fluid tank is positioned on a supporting surface and comprises a lower fluid tank platform, wherein said lower fluid tank collects descending fluid from said upper fluid tank via corresponding FTCs that descend via gravity from said upper fluid tank, wherein said lower fluid tank platform comprises at least one opening that enables fluid from descending FTCs of said plurality of FTCs to enter into said lower fluid tank, and wherein said FTCRPs provide means of temporary support to potential heights on said upper fluid tank and release from said potential heights to descend their corresponding FTCs and corresponding fluid displacement tanks (FDTs) as corresponding FTCs and FDTs are designed to operate in descending and ascending motion processes, and wherein said FTCRPs serve to stabilize corresponding FTCs and FDTs and temporarily lock them in place, upon their return from said lower fluid tank to a potential state position on said upper fluid tank in a continuous fluid recycling process once again, wherein another affected set of corresponding FTCRPs of corresponding FTCs will be triggered to initiate the same mechanisms for a next round of fluid entry into said plurality of fluid transfer paths while corresponding FTCs simultaneously will deny fluid entry to corresponding plurality of fluid transfer paths which in turn will adhere to said descending and ascending motion processes; said FDTs in communication with said pulley and cable systems, said plurality of electric motors, corresponding FTCs, corresponding fluid lift mechanisms, and said upper and lower fluid tanks, wherein each of said FDTs comprises an upper section and a lower section that is connected vertically to said upper section, wherein said upper section comprises an upper end and a lower end, wherein said lower section comprises an upper end and a lower end, and is sufficiently submerged in the fluid that is present in said lower fluid tank, wherein said lower end of said upper section is connected to said upper end of said lower section, wherein said upper section is thinner in length and width but taller in height than said lower section, and wherein said upper section and said lower section create a fluid transfer path from inside said lower fluid tank onto said upper fluid tank; a plurality of external tanks (ET), wherein each of said plurality of external tanks is comprised of an upper surface external tank (USET) and a sub-surface external tank (SSET) and is in communication with corresponding FDT, said fluid tank system, a plurality of corresponding electric motors, said plurality of cables, said plurality of pulleys and corresponding FTCs, wherein said plurality of corresponding USETs provide the vertical stabilization to plurality of corresponding FDTs upon its ascending and descending processes while said plurality of corresponding SSETs provide the mechanisms to elevate the fluid from said lower fluid tank into said upper fluid tank contributing to fluid recycling process of said system; a plurality of fluid lift mechanisms, wherein each of said fluid lift mechanisms is in communication with corresponding FDT, corresponding ET, said fluid tank system, said plurality of pulleys, said plurality of cables, a plurality of corresponding electric motors, and corresponding FTCs, wherein each of said fluid lift mechanisms provides a lifting force on one hand and a descending force on the other, to each corresponding door platform assembly (DPA), integral part to each FDT, which will elevate, upon ascend or lift, corresponding FDT with its contained fluid from inside said lower fluid tank to about surface level of a kinetic tank platform and will descend corresponding FDT with its contained fluid, upon disengagement of its lift force back into its original position, that is from about surface level of said kinetic tank platform back inside into said lower fluid tank, where it will be pulled tight into corresponding SSET by a corresponding door platform assembly cable (DPAC) driven by its corresponding electric motor, wherein upon descend of corresponding FDTs, the fluid within said lower section of corresponding FDTs will be displaced by the existing corresponding fluid in corresponding SSET into said upper section of corresponding FDTs and the already existing fluid within said upper section of corresponding FDTs will be ejected or displaced onto said upper fluid tank of about equal volume to said volume displaced from said lower section of corresponding FDTs thus achieving potential fluid height and recycling in the upward direction resulting in increased potential and kinetic energies of said system; and a plurality of FTC lift assemblies in communication with said pulley and cable systems, said plurality of electric motors, said plurality of FTCRPs, said at least one FTCEP, said plurality of fluid lift mechanisms, said plurality of FDTs, said at least two ETs, said plurality of fluid transfer path controls, at least one electric generator (EG), and said upper and lower fluid tanks, wherein each of said FTC lift assemblies moves corresponding FTCs and ETs in a vertical motion, upward and downward, and provides controlled descent of potential fluids through corresponding FTCs, wherein each of said FTC lift assemblies powers a corresponding electric generator via gravity thus producing electricity to the grid, wherein said FTCs act as potential fluid transport containers of controlled fluid descent from said upper fluid tank onto said lower fluid tank and act as power givers of motion to a corresponding electric generator, wherein said FTCs facilitate potential controlled descent of fluid and will drive a corresponding electric generator and that will supply electricity to the grid, wherein descending FTCs provide the required force, upon engaging corresponding fluid lift mechanisms, to uplift corresponding FDTs with contained fluid while ascending corresponding FTCs provide, in absence of force, upon disengagement of said corresponding FTCs to corresponding fluid lift mechanisms, that triggers into motion corresponding electric motors which will pull corresponding DPAC to lower corresponding FDTs with contained fluid back to its original held position, inside said lower fluid tank and subsequent inside said SSET, and in the process uplift onto said upper said fluid tank about the same amount of fluid as that discharged by its corresponding FTCs upon descent from said upper fluid tank onto said lower fluid tank, wherein said FTCs provide a triggering or operating force to activate or deactivate corresponding fluid transfer path controls, corresponding fluid lift mechanisms, corresponding electric motors, and corresponding FTCRPs, wherein electrical switch contact is made by corresponding FTCs at a corresponding strike point contact junction (SPCJ) and corresponding kinetic energy strike platform (KESP), corresponding trigger switch (TS) located on corresponding KESP where an electric power source is connecting, or disconnecting by the absence or presence of such contact, corresponding electric motors that will operate corresponding fluid transfer path controls, corresponding fluid lift mechanisms, and corresponding FTCRPs, said at least one electric generator is powered by said plurality of FTC lift assemblies, wherein said at least one electric generator delivers power to the grid, wherein, after said system is initiated, for said system to operate in its modular expansion form requires introduction into said motion processes an electromechanical sequence, and wherein said electromechanical sequence is for command and control to synchronize and regulate said motion processes of its operational components throughout operation of said system; and at least one power source providing energy to initiate operation and said motion processes of said system by triggering a corresponding FTCEP, wherein said at least one power source also re-initiates said motion processes of said system when said motion processes stop, wherein said system is reset for re-initiation of said motion processes at an affected, corresponding FTC pair section of said system, and wherein said at least one power source also provides energy to continue and maintain said motion process of said system.

Metadata:
- Claim Count in Document: 65.0
- Percentile: 97.0
- Lexical Diversity: 1.84314
- Patent Class: 290.0
- Transitional Phrase Type: open
- Component Type: 1
- Foreign Priority: False
- Related Applications: ['15353735', '15769310', '15714402', '10925680', '11833491']

Analysis Scores:
- 35 USC 101 Eligibility (BERT): 0.4845173184800284
- 35 USC 102 Novelty (BERT): 0.7002908120498913
- Combined Prediction Score: 0.5060946678370146
- Mean Citation Score: 242.746934
- Max Citation Score: 735.90753
- Similarity Product: 702.292950794615

Labels:
- Claim Label 101: 1
- Claim Label 102: 1
- Claim Label 103: 1
- Claim Label 112: 0
- Combined Label: 1
- Label 101 Adjusted: 1

Dataset: test