This invention relates in general to a fixed guard(s)/cap(s) and/or screen(s) apparatus (single and/or double formation) shall effect multiple aspects for example the nacelle and inlet for numerous craft, jets, turbojet, turboprop and turboshaft engines—(Helicopters and other VTOL aircraft) such as
This invention relates in general to a fixed guard(s)/cap(s) and/or screen(s) apparatus (single and/or double formation) shall effect multiple aspects for example the nacelle and inlet for numerous craft, jets, turbojet, turboprop and turboshaft engines—(Helicopters and other VTOL aircraft) such as power plants or the like. This apparatus contains the rotational system(s) which may be applied to the engine shaft attached apparatus and/or pole that allows the mechanism to function by self-induced movement, without limiting engine thrust. Additional security measures have been introduced to the guard(s), cap(s) and/or screen(s) apparatus, which includes a gaseous intake cavity, centrifuge, chamber, manifold and processes—static free and or purification chamber, and a particle collector without limiting engine thrust.
대표청구항▼
1. The process of a gaseous fluid cavity system, the process comprising of centrifugally separating particles from the gaseous fluid by a plurality of vanes providing divergence through force of said particles of gaseous fluid cavity yielding energy defined by the formula S=Fkc3A/4 hG→Energy S=Therm
1. The process of a gaseous fluid cavity system, the process comprising of centrifugally separating particles from the gaseous fluid by a plurality of vanes providing divergence through force of said particles of gaseous fluid cavity yielding energy defined by the formula S=Fkc3A/4 hG→Energy S=Thermodynamic—gaseous fluid said so particles is ingested in the gaseous intake cavity system and produced;F=Force—induced as gaseous fluid said so particles is ingested and within gaseous intake cavity;k=constant of energy—in a gaseous intake cavity;c3=a constant with 3 spatial dimension;A=area of gaseous intake cavity;4 h=forces defined as strong, weak, electromagnetic, and gravitational;G=gravity—gravitational pull of said so forces and particles;Energy=defined as kinetic, electromagnetic, electrostatic, electrochemical, and thermodynamic. 2. The process of a gaseous intake guard system having an elongated housing a longitudinal axis and a gaseous intake cavity for gas separating particles to purify said gaseous intake guard system comprising; one or more vanes mounted defined also as guards and configured in communication within gaseous intake cavity of said housing; housing configured to be in a predetermined shape;Mount of one or more vanes also known as guards defined as a mechanical/frame system in said housing; gaseous fluid undergoes centrifugation providing divergence through force in separating particles of gaseous intake cavity through mechanical/frame system for energy by receiving and discharging particles defined by the formula S=Fkc3A/4 hG→EnergyS=Thermodynamic—gaseous fluid said so particles is ingested in the gaseous intake cavity system and produced;F=Force—induced as gaseous fluid said so particles is ingested and within gaseous intake cavity;k=constant of energy—in a gaseous intake cavity;c3=a constant with 3 spatial dimension which may vary dimension or be dimensionless;A=area of gaseous intake cavity;4 h=forces defined as strong, weak, electromagnetic, and gravitational;G=gravity—gravitational pull of said so forces and particles;Energy=defined as kinetic, electromagnetic, electrostatic, electrochemical, and thermodynamic. 3. The process recited in claim 2, forces wherein defined kinetic energy. 4. The process recited in claim 2, forces wherein defined electrochemical. 5. The process recited in claim 2, forces wherein defined electrostatic. 6. The process recited in claim 2, forces wherein defined electromagnetic. 7. The process recited in claim 2, forces defined thermodynamic. 8. The process recited in claim 2, wherein the gaseous intake guard system is in fluid communication with a turbine. 9. The process recited in claim 2, wherein configuration is rectangular and opening is said the inlet. 10. The process recited in claim 2, wherein gaseous intake guard system is in fluid communication with a turbo ramjet. 11. The process recited in claim 2, wherein gaseous intake guard system is in fluid communication within a power plant. 12. The process of a gaseous intake guard system having a housing, with a gaseous intake cavity in producing gas separation process to purify particles for combustion comprising: one or more perforated guards configured to be in communication with said housing;perforated guards for gas separating particles in purifying process;housing configured in predetermined shape;particles compress and undergo centrifugation in the gaseous intake ward system through force in separating particles in the system and induce a passageway for energy by receiving and discharging particles from housing for leaner and cleaner gas defined by formula S=Fkc3A/4 hG→EnergyS=Thermodynamic—gaseous fluid said so particles is ingested in the gaseous intake cavity system and produced;F=Force—induced as gaseous fluid said so particles is ingested and within gaseous intake cavity;k=constant of energy—in a gaseous intake cavity;c3=a constant with 3 spatial dimension which may vary dimension or be dimensionless;A=area of gaseous intake cavity;4 h=forces defined as strong, weak, electromagnetic, and gravitational;G=gravity—gravitational pull of said so forces and particles;Energy=defined as kinetic, electromagnetic, electrostatic, electrochemical, and thermodynamic. 13. The process recited in claim 12, wherein perforated guards is cylindrical. 14. The process recited in claim 12, wherein system includes two guards spaced apart. 15. The process recited in claim 12, wherein two guards spaced apart system induce centrifugation of said particles. 16. The process recited in claim 12, wherein two guards spaced apart system mounted for rotational movement for centrifugation. 17. The process recited in claim 12, wherein gaseous intake guard system is in fluid communication with a turbine. 18. The process recited in claim 12, wherein guard is rectangular. 19. The process recited in claim 12, wherein guards constructed as a rectangular rig, within said cavity articles induce centrifugation process creating dual vortexes on each side for combustion. 20. The process of a gaseous intake guard system for a turbine having a housing and a gaseous intake cavity for gas separating particles to purify for leaner gas with noise reduction comprising: one or more perforated guards congruent to housing;one or more guards configured to be in predetermined shape;one or more guards construct a conical configuration;said conical configuration is perforated, conical said in communication within gaseous intake cavity;centrifugation of gaseous fluid through force separating particles of gaseous intake cavity for receiving and discharging said particles defined by the formula S=Fkc3A/4 hG→EnergyS=Thermodynamic—gaseous fluid said so particles is ingested in the gaseous intake cavity system and produced;F=Force—induced as gaseous fluid said so particles is ingested and within gaseous intake cavity;k=constant of energy—in a gaseous intake cavity;c3=a constant with 3 spatial dimension which may vary dimension or be dimensionless;A=area of gaseous intake cavity;4 h=forces defined as strong, weak, electromagnetic, and gravitational;G=gravity—gravitational pull of said so forces and particles;Energy=defined as kinetic, electromagnetic, electrostatic, electrochemical, and thermodynamic. 21. The process recited in claim 20, where perforated conical defined as open triangular guards are saw tooth. 22. The process recited in claim 20, wherein two guards are perforated, cylindrically, spaced apart, and mounted for rotational movement wherein between guards defines centrifugation. 23. The process recited in claim 20, wherein one or more guards are stationary. 24. The process recited in claim 20, wherein one or more guards retract. 25. The process recited in claim 20, wherein one or more guards said construct into perforated conical formation wherein between defines centrifugation. 26. The process recited in claim 20, wherein one or more guards said perforated conical formation is rotational. 27. The process recited in claim 20, wherein one or more guards spaced apart perforated cylindrically and mounted for rotational movement wherein between guards defines centrifugation can be a independent system. 28. The process recited in claim 20, wherein one or more guards of said construct into a perforated conical formation wherein defines centrifugation can be a independent system. 29. The process recited in claim 20, wherein guards and said conical configured are independent and interchanged. 30. The process recited in claim 20, wherein said housing has an end location for discharge of particles, wherein end location is a nozzle.
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